US20240271859A1 - Vacuum insulated structure with thermal bridge breaker with heat loop - Google Patents
Vacuum insulated structure with thermal bridge breaker with heat loop Download PDFInfo
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- US20240271859A1 US20240271859A1 US18/644,741 US202418644741A US2024271859A1 US 20240271859 A1 US20240271859 A1 US 20240271859A1 US 202418644741 A US202418644741 A US 202418644741A US 2024271859 A1 US2024271859 A1 US 2024271859A1
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- liner
- wrapper
- refrigerator
- channel
- thermal bridge
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Images
Classifications
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D21/00—Defrosting; Preventing frosting; Removing condensed or defrost water
- F25D21/04—Preventing the formation of frost or condensate
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D23/00—General constructional features
- F25D23/06—Walls
- F25D23/062—Walls defining a cabinet
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D23/00—General constructional features
- F25D23/06—Walls
- F25D23/065—Details
- F25D23/066—Liners
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D2201/00—Insulation
- F25D2201/10—Insulation with respect to heat
- F25D2201/14—Insulation with respect to heat using subatmospheric pressure
Definitions
- the present device generally relates to insulated structures, in particular, to a vacuum insulated refrigerator cabinet that includes a thermal bridge breaker that includes a heat loop and interconnects a wrapper and one or more liners and cooperates with the liners to define refrigerated storage compartments.
- One type of insulated structure includes a wrapper and a liner.
- the wrapper and liner are generally spaced-apart to form a cavity therebetween that is filled with an insulating material.
- this cavity may be filled with a vacuum insulated core material.
- thermal bridge breaker In order to hold the vacuum, it is necessary to provide an airtight seal between the wrapper, one or more liners, and the thermal bridge breaker. Further, thermal conduction between component parts of a refrigerator is sought to be avoided to reduce condensation.
- a refrigerator in at least one aspect of the present concept, includes a wrapper having a wall portion and a flange portion with a transverse portion disposed therebetween.
- the flange portion of the wrapper extends outwardly in a forward direction from the transverse portion of the wrapper and is substantially parallel to the wall portion of the wrapper.
- a liner is spaced-apart from the wrapper to define a vacuum insulated cavity therebetween.
- the liner includes a wall portion and a flange portion with a transverse portion disposed therebetween.
- the transverse portion of the liner is an angled portion extending outwardly towards the wrapper, and the flange portion of the liner extends outwardly in a forward direction from the transverse portion of the liner and is substantially parallel to the wall portion of the liner.
- the transverse portion of the wrapper is an angled portion extending inwardly towards the liner.
- a thermal bridge includes a first channel, a second channel and a third channel. A portion of the flange portion of the wrapper is received in the first channel, and a portion of the flange portion of the liner is received in the second channel.
- a conduit is received in the third channel and is configured to circulate a heated medium around a perimeter of the refrigerator.
- a refrigerator in yet another aspect of the present concept, includes a liner received within a cavity of a wrapper to define a vacuum insulated cavity therebetween.
- the wrapper and the liner each include a wall portion and a flange portion with an angled transverse portion disposed therebetween.
- the transverse portion of the wrapper is angled inwardly towards the liner, and the transverse portion of the liner is angled outwardly towards the wrapper.
- the flange portion of the wrapper extends further in a forward direction than the flange portion of the liner.
- a thermal bridge interconnects the wrapper and liner and includes first and second channels. A portion of the flange portion of the wrapper is received in the first channel, and a portion of the flange portion of the liner is received in the second channel.
- FIG. 1 is isometric view of a refrigerator including a vacuum insulated cabinet structure
- FIG. 2 is an exploded isometric view of a vacuum insulated cabinet structure
- FIG. 3 is a rear isometric view of the vacuum insulated cabinet structure of FIG. 2 as assembled;
- FIG. 4 is a cross-sectional view of the refrigerator of FIG. 1 taken at line IV;
- FIG. 5 is a fragmentary cross-sectional view of the thermal bridge taken from location V of FIG. 4 ;
- FIG. 6 is a fragmentary cross-sectional view of the thermal bridge taken from location VI of FIG. 4 ;
- FIG. 7 is cross-sectional view of the thermal bridge taken from location VII of FIG. 4 ;
- FIG. 8 is a fragmentary cross-sectional view of the thermal bridge of FIG. 5 having a portion of a conduit coupled thereto;
- FIG. 9 is a fragmentary cross-sectional view of the thermal bridge of FIG. 6 having a portion of a conduit coupled thereto;
- FIG. 10 is a is a fragmentary cross-sectional view of the thermal bridge of FIG. 7 having a portion of a conduit coupled thereto;
- FIG. 11 is a top perspective view of the vacuum insulated cabinet structure of FIG. 3 with portions thereof shown in phantom to reveal a conduit loop;
- FIG. 12 A is a top perspective view of a refrigerator cabinet, according to one embodiment
- FIG. 12 B is an exploded top perspective view of the refrigerator cabinet of FIG. 12 A , according to one embodiment
- FIG. 12 C is a cross-sectional view taken at line IC-IC of FIG. 12 A , according to one embodiment
- FIG. 13 A is a cross-sectional view taken at line II-II of FIG. 12 A , according to one embodiment
- FIG. 13 B is a graph depicting the thermal conductivity of various insulator materials as a function of gas pressure
- FIG. 14 A is a schematic depiction of a refrigerator cabinet insulator filling system, according to one embodiment
- FIG. 14 B is a flow chart of a refrigerator cabinet insulator filling method, according to one embodiment
- FIG. 15 A is a schematic depiction of a refrigerator cabinet insulator filling system, according to one embodiment.
- FIG. 15 B is a flow chart of a refrigerator cabinet insulator filling method, according to one embodiment.
- the terms “upper,” “lower,” “right,” “left,” “rear,” “front,” “vertical,” “horizontal,” and derivatives thereof shall relate to the device as oriented in FIG. 1 .
- the device may assume various alternative orientations and step sequences, except where expressly specified to the contrary.
- the specific devices and processes illustrated in the attached drawings, and described in the following specification are simply exemplary embodiments of the inventive concepts defined in the appended claims. Hence, specific dimensions and other physical characteristics relating to the embodiments disclosed herein are not to be considered as limiting, unless the claims expressly state otherwise.
- a described feature is equal or approximately equal to a value or description.
- a “substantially planar” surface is intended to denote a surface that is planar or approximately planar.
- “substantially” is intended to denote that two values are equal or approximately equal. In some embodiments, “substantially” may denote values within about 10% of each other, such as within about 5% of each other, or within about 2% of each other.
- a refrigerator 1 includes a vacuum insulated cabinet structure 2 which, in the embodiment of FIG. 1 , further includes a refrigerator compartment 28 positioned above a freezer compartment 44 . Doors 5 and 6 are provided to selectively provide access to the refrigerator compartment 28 , while a drawer 7 is used to provide access to the freezer compartment 44 .
- the vacuum insulated cabinet structure 2 is surrounded by an exterior wrapper 8 in assembly.
- the configuration of the refrigerator 1 is exemplary only and the present concept is contemplated for use in all refrigerator styles including, but not limited to, side-by-side refrigerators, whole refrigerator and freezers, and refrigerators with upper freezer compartments.
- the vacuum insulated cabinet structure 2 generally includes a thermal bridge 10 .
- the thermal bridge 10 or thermal breaker, includes a frame 12 having an upper opening 12 A and a lower opening 12 B with a mullion portion 14 disposed therebetween.
- the thermal bridge 10 further includes an upper portion 10 A, a middle portion 10 B and a lower portion 10 C.
- a rear portion of the upper opening 12 A of the thermal bridge 10 defines a front portion 28 A of a refrigerator compartment 28 ( FIGS. 3 and 4 ), as further described below, when the vacuum insulated cabinet structure 2 is assembled.
- a rear portion of the lower opening 12 B of the thermal bridge 10 defines a front portion 44 A of a freezer compartment 44 ( FIGS.
- the thermal bridge 10 may be referred to herein as a trim breaker, such as the trim breaker 172 shown in FIG. 12 C .
- the description of the thermal bridge 10 also describes the trim breaker 172 , as shown in FIG. 12 C .
- the vacuum insulated cabinet structure 2 further includes a refrigerator liner 16 having a top wall 18 , a bottom wall 20 , opposed sidewalls 22 , 24 , and a rear wall 26 . Together, the walls 18 , 20 , 22 , and 24 cooperate to define a rear portion 28 B of the refrigerator compartment 28 when the vacuum insulated cabinet structure 2 is assembled (see FIGS. 3 and 4 ).
- the refrigerator liner 16 further includes a front edge 30 disposed on a front portion thereof. The front edge 30 is disposed along the top wall 18 , the bottom wall 20 and the opposed sidewalls 22 , 24 in a quadrilateral ring configuration.
- the refrigerator liner 16 may be referred to herein as an inner liner, such as inner liner 118 shown in FIG. 12 C .
- inner liner 118 shown in FIG. 12 C .
- the description of the refrigerator liner 16 (and the front edge 30 , the transverse portion 82 and the flange portion 84 thereof) also describes the inner liner 118 shown in FIG. 12 C .
- a freezer liner 32 is provided and includes a top wall 34 , a bottom wall 36 , opposed sidewalls 38 , 40 , and a rear wall 42 . Together, the walls 34 , 36 , 38 , and 40 cooperate to define a rear portion 44 B of the freezer compartment 44 when the vacuum insulated cabinet structure 2 is assembled (see FIGS. 3 and 4 ).
- the rear wall 42 is shown in FIG. 2 as being a contoured rear wall that provides a spacing S for housing mechanical equipment 43 ( FIG. 4 ) for cooling both the refrigerator compartment 28 and freezer compartment 44 .
- Such equipment may include a compressor, a condenser, an expansion valve, an evaporator, a plurality of conduits, and other related components used for cooling the refrigerator and freezer compartments 28 , 44 .
- the freezer liner 32 includes a front edge 46 disposed on a front portion thereof.
- the front edge 46 is disposed along the top wall 34 , the bottom wall 36 and the opposed sidewalls 38 , 40 in a quadrilateral ring configuration.
- the front edge 30 of the refrigerator liner 16 and the front edge 46 of the freezer liner 32 define first and second openings 31 , 47 that are configured to couple with coupling portions disposed about the upper and lower openings 12 A, 12 B of the thermal bridge 10 , as further described below.
- the vacuum insulated cabinet structure 2 further includes the exterior wrapper 8 which, in the embodiment of FIG. 2 , includes a top wall 50 , a bottom wall 52 , opposed sidewalls 54 , 56 , and a rear wall 58 which cooperate to define a cavity 59 .
- the wrapper 8 further includes a front edge 60 which is disposed along an opening 61 of the cavity 59 which is further disposed along the top wall 50 , the bottom wall 52 , and the opposed sidewalls 54 , 56 so as to be a circumventing frontmost edge 60 of the exterior wrapper 8 presented in a quadrilateral ring configuration.
- the front edge 60 of the exterior wrapper 8 is coupled to coupling portions of the thermal bridge 10 around the liners 16 , 32 .
- the thermal bridge 10 interconnects the exterior wrapper 8 and the refrigerator liner 16 and the freezer liner 32 when assembled.
- the refrigerator liner 16 and freezer liner 32 are received within the cavity 59 of the exterior wrapper 8 when assembled, such that there is a spacing VC ( FIG. 3 ) between the outer surfaces of the refrigerator liner 16 and the freezer liner 32 relative to the inner surfaces of the exterior wrapper 8 .
- the spacing VC may be referred to herein as a gap 126 ( FIG.
- the exterior wrapper 8 may be referred to herein as an external wrapper, such as external wrapper 122 shown in FIG. 12 C .
- external wrapper 122 shown in FIG. 12 C .
- the description of the exterior wrapper 8 (and the front edge 60 , the transverse portion 76 and the flange portion 78 thereof) also describes the external wrapper 122 shown in FIG. 12 C .
- the wrapper 8 may be made from sheet metal, polymer materials, or other suitable materials.
- the wrapper 8 is contemplated to be made from a sheet metal material that is formed utilizing known steel forming tools and processes.
- the refrigerator liner 16 and the freezer liner 32 are also preferably made from a sheet metal material utilizing known steel forming tools and processes.
- the thermal bridge 10 may be formed from a material having a low thermal conductivity.
- the thermal bridge 10 may be fabricated by thermoforming a sheet of thermoplastic polymer material.
- the thermal bridge 10 may be constructed of a material that is substantially impervious, such that oxygen, nitrogen, carbon dioxide, water vapor, and/or other atmospheric gasses are sealed out of the vacuum cavity VC ( FIG. 3 ) defined in the spacing or gap that is formed between the wrapper 8 and liners 16 , 32 as discussed in more detail below.
- the thermal bridge 10 may comprise a plurality of layers, wherein layers of polymeric material are selected to provide impermeability to gasses, such that the thermal bridge 10 provides for an air-tight connection between the wrapper 8 and the liners 16 , 32 which allows for a vacuum to be held between the thermal bridge 10 , the wrapper 8 and the liners 16 , 32 in the vacuum cavity VC ( FIG. 3 ).
- the thermal bridge 10 may also be formed from any suitable material that is substantially impervious to gasses to maintain a vacuum in the vacuum cavity VC.
- the material used to comprise the thermal bridge 10 is also contemplated to have a low coefficient of thermal conductivity to reduce or prevent transfer of heat between the metal wrapper 8 and the metal liners 16 , 32 which have a high coefficient of thermal conductivity.
- the thermal bridge 10 is preferably formed utilizing a molding process, and specifically, may include a reaction injection molding (RIM) process as further described below.
- RIM reaction injection molding
- the thermal bridge 10 is likely formed in a mold using a polyurethane material.
- Other materials suitable for an RIM process may include, but are not limited to, polyureas, polyisocyanurates, polyesters, polyphenols, polyepoxides, thermoplastic elastomers, polycarbonate, and nylon materials.
- the thermal bridge 10 could be overmolded to the refrigerator liner 16 , the freezer liner 32 and the wrapper 8 at the respective front edges 30 , 46 , 60 thereof.
- the vacuum insulated cabinet structure 2 can be a unitary part after the thermal bridge 10 is cast onto the front edges 30 , 46 , 60 , of the liners 16 , 32 and the wrapper 8 .
- the thermal bridge 10 can be comprised entirely of a material having a low thermal conductivity (such as glass, ceramic, or polymeric materials), or can by partially comprised of such materials.
- the front edge 30 of the refrigerator liner 16 includes linear portions disposed around the top wall 18 , bottom wall 20 and opposed sidewalls 22 , 24 at front portions thereof, such that front edge 30 of the refrigerator liner 16 is generally quadrilateral.
- the front edge 46 of the freezer liner 32 includes linear portions disposed around the top wall 34 , bottom wall 36 and opposed sidewalls 38 , 40 at front portions thereof, such that front edge 46 of the freezer liner 32 is also generally quadrilateral.
- the profile of the combination of the liners 16 , 32 is preferably somewhat smaller than the profile of the wrapper 8 . In this way, the vacuum cavity VC ( FIG.
- the vacuum cavity VC is configured to receive an insulating material (not shown) that may be described as a vacuum core material.
- the vacuum core material may comprise a plurality of preformed individual core panels that are preformed and positioned between wrapper 8 and the liners 16 , 32 during assembly prior to the installation of the thermal bridge 10 .
- the vacuum core material may comprise silica powder or other suitable loose filler material that is inserted (e.g. blown) into the vacuum cavity VC after wrapper 8 , liners 16 , 32 , and thermal bridge 10 are formed into a unitary composite structure.
- the front edges 30 , 46 of the liners 16 , 32 are spaced-apart from each other at the linear portions thereof disposed along the bottom wall 20 of the refrigerator liner 16 and the linear portion disposed along the top wall 34 of the freezer liner 32 . Further, the front edges 30 , 46 of the liners 16 , 32 disposed along the opposed sidewalls 22 , 24 and 38 , 40 of the liners 16 , 32 , and the top wall 18 of the refrigerator liner 16 and the bottom wall 36 of the freezer liner 32 are spaced-apart from the linear portions defining the front edge 60 of the wrapper 8 in assembly.
- the thermal bridge 10 connects to the front edge 60 of the wrapper 8 , and further connects to the front edge 30 of the refrigerator liner 16 , and to the front edge 46 of the freezer liner 32 , thereby interconnecting the components. In this way, the thermal bridge 10 interconnects the wrapper 8 and the liners 16 , 32 .
- the wrapper 8 is typically exposed to ambient room temperature air, whereas the liners 16 , 32 are generally exposed to refrigerated air in the refrigerator compartment 28 or the freezer compartment 44 .
- the thermal bridge 10 being made of a material that is substantially non-conductive with respect to heat, the thermal bridge 10 reduces transfer of heat from the wrapper 8 to the liners 16 , 32 .
- the thermal bridge 10 may include linear portions that are interconnected to form a ring-like structure having a quadrilateral perimeter or outer coupling portion 62 and quadrilateral inner coupling portions 64 , 66 .
- the inner coupling portions 64 , 66 define upper and lower openings 12 A, 12 B that generally correspond to the openings 31 , 47 defined by the front edges 30 , 46 of the refrigerator liner 16 , and freezer liner 32 of the cabinet structure 2 .
- the outer coupling portion 62 is coupled to the front edge 60 of the wrapper 8 .
- the inner coupling portions 64 , 66 are disposed inside of the outer coupling portion 62 and set back therefrom, as further described below.
- the inner coupling portions 64 , 66 are coupled to the front edges 30 , 46 of the refrigerator liner 16 , and freezer liner 32 , respectively.
- the thermal bridge 10 may have various shapes and configurations as may be required for a particular application, and it is further contemplated that the thermal bridge 10 can be used in a refrigerator having multiple liners (as shown in FIG. 2 with a refrigerator liner 16 and a freezer liner 32 ) or in a refrigerator having a single liner for use as a refrigerator or freezer only.
- the outer coupling portion 62 may be referred to herein as a wrapper joint, such as wrapper joint 172 B shown in FIG. 12 C .
- the description of the outer coupling portion 62 (and the first channel 67 thereof) also describes the wrapper joint 172 B shown in FIG. 12 C .
- the inner coupling portion 64 may be referred to herein as a liner joint, such as liner joint 172 A shown in FIG. 12 C .
- the description of the inner coupling portion 64 (and the second channel 69 thereof) also describes the wrapper joint 172 B shown in FIG. 12 C .
- the refrigerator 1 is shown in a cross-sectional view having the refrigerator liner 16 and freezer liner 32 coupled to the thermal bridge 10 at upper and lower openings 12 A, 12 B, respectively.
- the wrapper 8 is also coupled to the thermal bridge 10 , such that the thermal bridge 10 interconnects the wrapper 8 with the refrigerator liner 16 and freezer liner 32 .
- the thermal bridge 10 of the present concept is coupled to the liners 16 , 32 and wrapper 8 to hermetically seal the components together as a unitary whole as shown in FIG. 3 .
- FIG. 3 In the cross-sectional view if FIG.
- the thermal bridge 10 is shown as defining the front portion 28 A of the refrigerator compartment 28 , with the refrigerator liner 16 defining the rear portion 28 B of the refrigerator compartment 28 .
- a mating joint between the refrigerator liner 16 and the thermal bridge 10 is identified at reference numeral 29 .
- the thermal bridge 10 is shown as defining the front portion 44 A of the freezer compartment 44 , with the freezer liner 32 defining the rear portion 44 B of the freezer compartment 44 .
- a mating joint between the freezer liner 32 and the thermal bridge 10 is identified at reference numeral 45 .
- the metal materials of the cooled liners 16 , 32 are inset from the surfaces of the refrigerator that are exposed to ambient room temperatures, such as the metal wrapper 8 and a sealing surface of the thermal bridge 10 .
- the configuration of the thermal bridge 10 insulates the highly conductive metallic materials of the liners 16 , 32 from the areas most prone to conductive heat influences.
- the overall configuration of the thermal bridge 10 is further described below.
- the upper portion 10 A of the thermal bridge 10 is shown having a body portion 70 with a front forward facing sealing surface 72 and an inwardly projecting extension 74 .
- the front sealing surface 72 is a generally vertical forward facing sealing surface that provides a substantially planar surface for seal members of the doors, such as doors 5 and 6 shown above in FIG. 1 , to seal against when closed.
- the inwardly projecting extension 74 of the body portion 70 of the thermal bridge 10 projects in a substantially horizontal manner at the upper portion 10 A of the thermal bridge 10 and provides a substantially planar surface which defines the front portion 28 A of the refrigerator compartment 28 , as shown in FIG. 3 .
- the body portion 70 of the thermal bridge 10 includes a first portion (the upright outwardly facing sealing surface 72 ) and a second portion (the inwardly projecting extension 74 that extends orthogonally to the upright sealing surface 72 ) to provide an overall L-shaped body portion 70 .
- the inwardly projecting extension 74 is positioned around the entire upper opening 12 A of the thermal bridge 10 to define the front portion 28 A of the refrigerator compartment 28 from all four sides thereof.
- the upper opening 12 A of the thermal bridge 10 defines an opening into the refrigerated compartment 28 in assembly.
- the inwardly projecting extension 74 extends inwardly a distance D 2 as shown in FIG. 5 from the sealing surface 72 .
- the sealing surface 72 also extends around the entire upper opening 12 A of the thermal bridge 10 to define a fully encircling sealing surface 72 for the refrigerator compartment 28 .
- the configuration of the body portion 70 of the thermal bridge 10 provides for the outer coupling portion 62 to be disposed outside of the inner coupling portion 64 .
- outer coupling portion 62 is specifically disposed above of the inner coupling portion 64 .
- the outer coupling portion 62 is positioned on a rear side 72 B of the sealing surface 72 and includes a first channel 67 which opens inwardly. As shown in FIG. 5 , the front edge 60 of the wrapper 8 is received in the first channel 67 .
- an outwardly opening channel 68 is shown disposed on a front side 72 A of the sealing surface 72 .
- the outwardly opening channel 68 is configured to receive tubing for a heat loop, as further described below with specific reference to FIG. 8 .
- the inner coupling portion 64 includes a second channel 69 which, much like first channel 67 , is disposed on the rear side 72 A and opens inwardly. As shown in FIG. 5 , the front edge 30 of the refrigerator liner 16 is received in the second channel 69 of the thermal bridge 10 .
- the thermal bridge 10 extends across a gap or vacuum cavity VC between the wrapper 8 and the refrigerator liner 16 to interconnect the wrapper 8 and the refrigerator liner 16 .
- the body portion 70 of the thermal bridge 10 includes first and second channels 67 , 69 which open inwardly in a first direction, and further includes a third channel, outwardly opening channel 68 , which opens outwardly in a second direction that is opposed to or opposite from the first direction.
- the front edges 60 , 30 of the wrapper 8 and the refrigerator liner 16 are disposed in the first and second channels 67 , 69 , respectively.
- the outer coupling portion 62 is disposed along an upper portion of the sealing surface 72 of the body portion 70 of the thermal bridge 10 at the upper portion 10 A of the thermal bridge 10 .
- the outer coupling portion 62 , and the channel 67 thereof, is outboard of the inner coupling portion 64 , and the channel 69 thereof.
- the inner coupling portion 64 is staggered or offset relative to the outer coupling portion 62 . Specifically, in the embodiment shown in FIG.
- the inner coupling portion 64 is disposed inward and below the outer coupling portion 62 , and the channel 67 thereof, as the inner coupling portion 64 is disposed on an end of the inwardly projecting extension 74 of the body portion 70 of the thermal bridge 10 .
- This interconnection can include an adhesive or sealant medium disposed in the first channel 67 to adhere the components together in an airtight manner for retaining a vacuum between the thermal bridge 10 and the wrapper 8 and liner 16 in the vacuum insulated cavity VC.
- the refrigerator liner 16 includes an angled transverse portion 82 extending off of top wall 18 thereof, and leading to an end flange portion 84 which is received in the second channel 69 of the inner coupling portion 64 . The angle of transverse portion 82 of the refrigerator liner 16 allows for the inner surface of top wall 18 to align with the inwardly projecting extension 74 of the thermal bridge 10 .
- the end flange portion 84 provides a surface for the thermal bridge 10 to adhere to the refrigerator liner 16 .
- This interconnection can include an adhesive or sealant medium disposed in the second channel 69 to adhere the components together in an airtight manner for retaining a vacuum between the thermal bridge 10 and the wrapper 8 and liner 16 in the vacuum insulated cavity VC.
- the transverse portion 82 of the refrigerator liner 16 extends inwardly towards the vacuum insulated cavity VC. In this way, the transverse portion 82 of the refrigerator liner 16 extends towards the wrapper 8 .
- the transverse portion 76 of the wrapper 8 extends inwardly towards the vacuum insulated cavity VC in an opposed direction as compared to the angle of the transverse portion 82 of the refrigerator liner 16 . In this way, the transverse portion 76 of the wrapper 8 extends towards the refrigerator liner 16 .
- This configuration is also shown in FIG. 12 C , wherein the external wrapper 122 and the inner liner 118 include transverse portions extending into the gap 126 disposed between the external wrapper 122 and the inner liner 118 .
- the end flange portion 78 of the wrapper 8 extends outwardly in a direction as indicated by arrow 79 A.
- the direction indicated by arrow 79 A of the end flange portion 78 of the wrapper 8 is parallel the top wall 50 of the wrapper 8 .
- the end flange portion 78 of the wrapper 8 extends outwardly in a straight line from the angled transverse portion 76 of the wrapper 8 .
- the end flange portion 84 of the refrigerator liner 16 extends outwardly in a direction as indicated by arrow 79 B.
- the direction indicated by arrow 79 B of the end flange portion 84 of the refrigerator liner 16 is parallel the top wall 18 of the refrigerator liner 16 .
- the end flange portion 84 of the refrigerator liner 16 extends outwardly in a straight line from the angled transverse portion 82 of the refrigerator liner 16 . It is contemplated that the configuration of the end flange portions 78 , 84 of the wrapper 8 and refrigerator liner 16 being parallel to the top walls 50 , 18 thereof is a common configuration along all walls of the wrapper 8 and refrigerator liner 16 around the openings 61 , 31 thereof. This configuration is also shown in FIG. 12 C , wherein the external wrapper 122 and the inner liner 118 include end flange portions extending outwardly in a straight and parallel manner with respect to the associated walls of the external wrapper 122 and the inner liner 118 shown in FIG. 12 C .
- the front edge 60 of the wrapper 8 is not only spaced-apart from the front edge 30 of the refrigerator liner 16 so as to be outside of or outboard from the front edge 30 of the refrigerator liner 16 (as indicated by arrow D 3 ), but is also offset laterally from the front edge 30 of the refrigerator liner 16 (as indicated by arrow D 2 ).
- This is generally due to the thermal bridge 10 having a staggered configuration for outer coupling portion 62 (and first channel 67 thereof) relative to the inner coupling portion 64 (and the second channel 69 thereof) for receiving the front edge 60 of the wrapper 8 and the front edge 30 of the refrigerator liner 16 , respectively.
- the first channel 67 is inset from the sealing surface a distance D 1 and is outboard of the second channel 69 a distance D 3 .
- the second channel 69 is inset from the sealing surface a distance D 2 , which, as noted above is greater than the distance D 1 defined between the sealing surface 72 and the first channel 67 .
- This staggered configuration is also present between the wrapper 8 and the freezer liner 32 , as further described below.
- the thermal bridge 10 includes a first portion defined by the sealing surface 72 with a first channel 67 disposed thereon.
- the thermal bridge 10 further includes a second portion defined by the inwardly projecting extension 74 which inwardly extends from the sealing surface 72 and includes a second channel 69 disposed at a distal end thereof.
- the first and second channels 67 , 69 are vertically and horizontally offset from one another such that the staggered configuration of the channels 67 , 69 is provided for around the entire upper opening 12 A of the thermal bridge 10 .
- the distances indicated in FIG. 5 may include specific parameters in the ranges noted below. However, the scope of the present concept is not limited to such ranges.
- the outer surface 72 A of the sealing surface 72 may be approximately 20 mm to provide a substantial surface for doors to seal against.
- the distance D 3 measuring the offset between the first channel 67 and the second channel 69 may be approximately 12 mm.
- the distance D 2 may be approximately 70 mm, such that the inwardly projecting extension 74 provides a substantial polymeric front portion 28 A for the refrigerator compartment 28 .
- the first channel 67 and the second channel 69 may be spaced-apart about 57 mm from one another in a direct path measured therebetween.
- the middle portion 10 B of the thermal bridge 10 is shown having inner coupling portion 64 disposed above inner coupling portion 66 .
- the inner coupling portion 64 is configured to receive the front edge 30 of the refrigerator liner 16 at channel 69 thereof, as shown in FIG. 6 .
- the inner coupling portion 66 is configured to receive the front edge 46 of the freezer liner 32 at channel 69 A thereof, as shown in FIG. 6 .
- the inner coupling portion 66 is interconnected with the inner coupling portion 64 by a trim component 72 C that may be a detachable trim component to the thermal bridge 10 that is used to seal lower portions of doors (such as doors 5 and 6 shown in FIG.
- the thermal bridge 10 includes an upper outwardly opening channel 65 A and a lower outwardly opening channel 65 B.
- the trim component 72 C includes inwardly turned upper and lower legs 72 D and 72 E that are received in the upper outwardly opening channel 65 A and the lower outwardly opening channel 65 B, respectively.
- the inner coupling portion 64 is disposed above the inner coupling portion 66 . Further, the inner coupling portion 64 is not staggered or offset relative to the inner coupling portion 66 , but rather they are aligned with one another.
- the refrigerator liner 16 includes the transverse portion 82 extending off of bottom wall 20 thereof, and leading to the end flange portion 84 which is received in the second channel 69 of the inner coupling portion 64 .
- the transverse portion 82 of the refrigerator liner 16 is disposed all the way around the opening 31 of the refrigerator liner 16 at top wall 18 , bottom wall 20 and opposed side walls 22 , 24 at front portions thereof.
- the end flange portion 84 is also disposed fully around the refrigerator liner 16 extending outwardly from transverse portion 82 , and defining a surface for adhering engagement with the second channel 69 of the inner coupling portion 64 of the thermal bridge 10 .
- the freezer liner 32 includes a transverse portion 92 extending off of top wall 34 thereof, and leading to an end flange portion 94 which is received in the inner coupling portion 66 .
- the transverse portion 92 of the freezer liner 32 is disposed all the way around the opening 47 of the freezer liner 32 at top wall 34 , bottom wall 36 and opposed side walls 38 , 40 at front portions thereof.
- the end flange portion 94 is also disposed fully around the freezer liner 32 extending outwardly from transverse portion 92 , and defining a surface for adhering engagement with the channel 69 A the inner coupling portion 64 of the thermal bridge 10 .
- the lower portion 10 C of the thermal bridge 10 is shown having the outer coupling portion 62 disposed below the inner coupling portion 66 .
- the outer coupling portion 62 is interconnected with the inner coupling portion 66 by the body portion 70 having the upright portion 72 and the horizontal portion 74 .
- the inner coupling portion 66 is staggered or offset relative to the outer coupling portion 62 by the distances indicated by arrows D 2 and D 3 .
- the inner coupling portion 66 is disposed inward and above the outer coupling portion 62 as disposed on an end of the inwardly projecting extension 74 of the body portion 70 of the thermal bridge 10 .
- the staggered configuration of the outer coupling portion 62 and the inner coupling portion 66 is akin to the staggered configuration of the outer coupling portion 62 and the inner coupling portion 64 shown in FIG. 5 .
- the front edge 60 of the wrapper 8 is not only spaced-apart from the front edge 46 of the freezer liner 32 so as to be outside of the front edge 46 of the freezer liner 32 , but is also offset laterally outward from the front edge 46 of the freezer liner 32 .
- the thermal bridge 10 includes a staggered configuration for outer coupling portion 62 relative to the inner coupling portion 66 for receiving the front edge 60 of the wrapper 8 and the front edge 46 of the freezer liner 32 .
- the end flange portions 84 and 94 of the refrigerator liner 16 and the freezer liner 32 are disposed inwardly of the end flange portion 78 of the wrapper 8 given the inwardly projecting extension 74 of the thermal bridge 10 .
- All of the end flange portions 78 , 84 and 94 include inner and outer surfaces which may include a plurality of engagement features, such as engagement features 90 shown in FIG. 7 disposed on end flange portion 78 of the wrapper 8 .
- the engagement features 90 shown in FIG. 7 are contemplated to be outwardly extending dimples and may be disposed on both sides of a front edge, such as front edge 84 of the refrigerator liner 16 shown in FIG.
- the dimples may also be positioned on the inner contours of the channels 67 and 69 A as well. Having such undulations positioned on the opposed contact surfaces of the end flange portions 78 , 84 and 94 provides for better engagement between the wrapper 8 , the liners 16 , 32 , and the thermal bridge 10 to ensure that a vacuum can be drawn and maintained in the vacuum cavity VC between the wrapper 8 , the liners 16 , 32 , and the thermal bridge 10 .
- the engagement features 90 also provide centering features for the front edges 78 , 84 and 94 of the wrapper 8 , the refrigerator liner 16 and the freezer liner 32 , to center the edges 78 , 84 and 94 within the channels 67 , 69 and 69 A.
- the thermal bridge 10 is shown along the upper portion 10 A thereof.
- a conduit 100 is shown positioned therein.
- the conduit 100 comprises a continuous loop of tubing 102 that is routed through the refrigerator 1 ( FIG. 1 ) as best shown in FIG. 11 .
- the conduit 100 may be referred to as a heat loop, a Yoder loop or a condenser loop, but is not meant to be limited to any one shape or configuration by the term “loop.”
- the conduit 100 circulates, or otherwise transports, a heated medium, such as heated refrigerant that is generated by the mechanical equipment 43 ( FIGS.
- the heated refrigerant contained and transported through the tubing 102 of the conduit 100 provides for an “anti-sweat” feature to help prevent condensation that can develop when the cold surfaces of the compartments 28 and 44 are exposed to ambient air in which the refrigerator 1 is disposed. This warm and humid air can cause condensation to develop along the sealing surface 72 of the thermal bridge 10 .
- the circulating warmed refrigerant of the conduit 100 provides a mitigating factor for combatting condensation buildup at the sealing surface 72 .
- the conduit 100 is positioned in the outwardly opening channel 68 which is configured to extend around an entire perimeter of the refrigerator 1 , as best shown in FIG. 11 .
- the conduit 100 can be retained in the outwardly opening channel 68 using an adhesive material.
- the placement of the conduit 100 in the outwardly opening channel 68 is provided, such that the conduit 100 can circulate heated refrigerant near the opening 12 A into the refrigerator compartment 28 . It is contemplated that the outwardly opening channel 68 and the conduit 100 thereof are positioned about 12 mm from the opening 12 A into the refrigerator compartment 28 .
- the scope of the present concept is not limited to such an embodiment.
- the conduit 100 is positioned in the outwardly opening channel 68 along the side of the refrigerator 1 .
- An intermediate portion 104 of the tubing 102 of the conduit 100 loops through the mullion portion 14 of the thermal bridge 10 along trim piece 72 C which is connected to the upper and lower outwardly opening channels 65 A, 65 B.
- the openings 12 A, 12 B of the thermal bridge 10 are fully surrounded by the conduit 100 , as best shown in FIG. 11 .
- the conduit 100 is positioned in the outwardly opening channel 68 which, as noted above, is configured to extend around an entire perimeter of the refrigerator 1 , as best shown in FIG. 11 .
- the conduit 100 is also shown having a return portion 107 positioned in a raceway 108 formed in the lower portion 10 C of the thermal bridge 10 .
- the return portion 107 is contemplated to run the conduit 100 back to the spacing S of the refrigerator 1 where the cooling equipment 43 is housed, as best shown in FIG. 11 .
- the conduit 100 is positioned in the outwardly opening channel 68 (see FIGS. 8 - 10 ) of the thermal bridge 10 around the entirety of the refrigerator 1 .
- the intermediate portion 104 of the tubing 102 of the conduit 100 is shown covering the mullion portion 14 of the thermal bridge 10 .
- the conduit 100 fully surrounds the openings 12 A and 12 B of the thermal bridge 10 which open into the refrigerator compartment 28 and the freezer compartment 44 , respectively.
- the return portion 107 is illustrated as running the conduit 100 back to the spacing S of the refrigerator 1 where the cooling equipment 43 , that generates the heated refrigerant for circulation within the conduit 100 , is housed.
- a refrigerator 110 includes a cabinet 114 having an inner liner 118 and an external wrapper 122 .
- the inner liner 118 is positioned within the external wrapper 122 such that a gap 126 is defined between the external wrapper 122 and internal liner 118 .
- a first insulator 130 is positioned within the gap 126 and a second insulator 134 is positioned within the gap 126 .
- a pressure within the gap 126 may be below about 1000 Pa.
- the refrigerator 110 includes the cabinet 114 .
- the refrigerator 110 may take a variety of configurations including French door, side by side, top freezer, bottom freezer, counter depth, compact, built-in, and other types of refrigerators.
- the cabinet 114 includes the inner liner 118 , the external wrapper 122 and may optionally include a shell 142 .
- the inner liner 118 has a generally rectangular box shape, but may take a variety of shapes including a cube, prism, parallelepiped, etc. and combinations thereof.
- the inner liner 118 may have a liner flange 146 disposed around the inner liner 118 and connected to a plurality of liner walls 150 which define the inner liner 118 .
- the inner liner 118 may be formed from a polymeric material having high barrier properties (e.g., low gas permeation), metals and combinations thereof.
- the inner liner 118 may be formed via thermoforming, injection molding, bending and/or forming.
- the liner walls 150 of the inner liner 118 may have a thickness ranging from between about 0.1 mm to about 3.0 mm. In a specific embodiment, the liner walls 150 have a thickness of about 0.5 mm.
- the inner liner 118 is shaped and configured to mate, couple or otherwise be positioned within the external wrapper 122 .
- the external wrapper 122 includes a plurality of wrapper walls 158 to which a wrapper flange 162 is coupled.
- the wrapper flange 162 and the liner flange 146 are configured to be coupled when the cabinet 114 is in an assembled configuration.
- the coupling of the liner flange 146 and the wrapper flange 162 may be performed such that an airtight, or hermetic, seal is formed between the inner liner 118 and the external wrapper 122 .
- the hermetic seal of the wrapper flange 162 and the liner flange 146 may be achieved through use of adhesives, welding, an elastomeric gasket under compression and/or crimping.
- the coupling of the liner flange 146 to the wrapper flange 162 may be performed proximate a front flange area 164 ( FIG. 13 A ) of the cabinet 114 .
- the front flange area 164 may be configured to couple with a door which permits access to an interior of the cabinet 114 .
- the external wrapper 122 may be formed of and by any of the materials and processes listed above in connection with the inner liner 118 .
- the wrapper walls 158 of the external wrapper 122 may have a thickness ranging from between about 0.1 mm to about 3.0 mm. In a specific embodiment, the wrapper walls 158 have a thickness of about 0.5 mm.
- the wrapper walls 158 of the external wrapper 122 may define an injection port 166 and/or a vacuum port 170 .
- the external wrapper 122 may include one or multiple injection ports 166 and/or vacuum ports 170 .
- the injection ports 166 and/or vacuum ports 170 may be positioned as illustrated or in a variety of positions about the external wrapper 122 .
- the injection ports 166 and/or vacuum ports 170 may be disposed on both the external wrapper 122 and inner liner 118 , or solely on the inner liner 118 .
- the injection port 166 and the vacuum port 170 may be used to access (e.g., to inject an insulator, draw a vacuum and/or perform maintenance within) the gap 126 once the inner liner 118 and the external wrapper 122 are bonded.
- the injection port 166 and the vacuum port 170 may have a diameter of between about 10 mm and about 50 mm, or between about 12.5 mm and about 25 mm. In various embodiments, the injection port 166 and the vacuum port 170 may have different diameters than one another. Similarly, in embodiments utilizing more than one injection port 166 and vacuum port 170 , the sizes of the injection ports 166 and the vacuum ports 170 may vary.
- the trim breaker 172 may be formed of a plastic, a metal, a composite and/or insulating materials.
- the trim breaker 172 may define a liner joint 172 A configured to couple the inner liner 118 to the trim breaker 172 .
- the trim breaker 172 may also define a wrapper joint 172 B configured to couple the external wrapper 122 to the trim breaker 172 .
- the liner joint 172 A and the wrapper joint 172 B may be vibration welded, crimped, thermally bonded, adhesively bonded or otherwise coupled to render the gap 126 airtight.
- the trim breaker 172 may be used to hold the inner liner 118 and the external wrapper 122 together and in place. Use of the trim breaker 172 may provide advantages of resisting thermal bridging between the inner liner 118 and the external wrapper 122 and easing manufacturing.
- the first insulator 130 and the second insulator 134 may be dispensed into the gap 126 .
- the gap 126 may have a thickness of between about 12 mm to about 30 mm.
- the gap 126 may have an air pressure of less than about 1 atm (101,325 Pa, 1013.25 mbar), less than about 0.5 atm (50,662.5 Pa, 506.63 mbar), less than about 0.1 atm (10,132.5 Pa, 101.33 mbar), less than about 0.001 atm (101.325 Pa, 1.0133 mbar) or less than about 0.00001 atm (1.01 Pa, 0.01 mbar). Over the service life of the refrigerator 110 ( FIG.
- the air pressure within the gap 126 may rise more than about 0.001 atm (101 Pa, 1.01 mbar), greater than about 0.005 atm (506 Pa, 5.06 mbar) or greater than about 0.01 atm (1,013 Pa, 10.13 mbar) due to diffusion and/or permeation of gases into the gap 126 through the inner liner 118 and/or the external wrapper 122 .
- the first and second insulators 130 , 134 may be a material configured to have low thermal conductivity.
- the first and second insulators 130 , 134 may include precipitated silica, polyurethane foam, fumed silica, silica fume, beads (e.g., of glass, ceramic, and/or an insulative polymer), hollow organic micro/nano spheres, hollow inorganic micro/nano spheres, silica aerogel, nano-aerogel powder, rice husk ash, diatomaceous earth, cenospheres, perlite, glass fibers, polyisocyanurate, urea foam, rice hulls, polyethylene foam, vermiculite, fiberglass and combinations thereof.
- precipitated silica e.g., polyurethane foam, fumed silica, silica fume, beads (e.g., of glass, ceramic, and/or an insulative polymer), hollow organic micro/nano spheres, hollow inorganic micro/nano spheres, silica aerogel, nano-aerogel powder, rice husk ash, di
- an opacifier e.g., TiO2, SiC and/or carbon black
- materials configured to change the radiation conduction, flow properties and packing factor of the first and second insulators 130 , 134 may be introduced.
- one or more gas e.g., oxygen, hydrogen, carbon dioxide
- moisture getters may be included in the first and second insulators 130 , 134 .
- the first and second insulators 130 , 134 may include the same insulating material as one another, may be substantially the same material, or may be completely different materials.
- the organic spheres may include polystyrene, polythiophenes, polyethylene, rubber and/or combinations thereof.
- the spheres may include glasses, ceramics and combinations thereof.
- the beads or spheres may have an average outer diameter ranging from about 50 nm to about 300 ⁇ , or from about 1 ⁇ to about 300 ⁇ , or from about 50 nm to about 1000 nm. In various embodiments, the diameter size distribution of the spheres is low.
- first and/or second insulators 130 , 134 may be filled with a single gas (e.g., H2, O2, N2, noble gases, volatile organic compounds, CO2, SO, SO2) or a mixture of gases (e.g., atmosphere, noble gases, O2, SO2, SO).
- the spheres may be sealed and have a gas pressure within the spheres of between about 0.1 atm and about 1.0 atm, or between about 0.2 atm and about 0.5 atm, or between about 0.25 atm and about 0.35 atm.
- the first and/or second insulators 130 , 134 are positioned within the gap 126 and in contact with both the wrapper walls 158 and the liner walls 150 .
- the packing factor of the first and/or second insulators 130 , 134 within the gap 126 may be greater than about 60%, greater than about 62%, greater than about 65%, or greater than about 70%.
- the fumed silica may be hydrophobic and/or hydrophilic.
- the fumed silica may have a particle size ranging from less than about 0.005 ⁇ to greater than about 1.0 ⁇ .
- the fumed silica may have a density of between about 32 kg/m3 to about 80 kg/m3.
- the fumed silica When positioned within the gap 126 , the fumed silica may have a density between about 50 kg/m3 to about 300 kg/m3, or between about 80 kg/m3 to about 250 kg/m3 or between about 150 kg/m3 to about 200 kg/m3.
- the first and second insulators 130 , 134 are configured not only to thermally insulate the inner liner 118 from the external wrapper 122 , but also to resist the inward directed force of the atmosphere on the lower than atmosphere pressure of the gap 126 . Atmospheric pressure on the inner liner 118 and the external wrapper 122 may cause distortions which are unsightly and may lead to a rupture in either of the inner liner 118 or the external wrapper 122 thereby causing a loss of vacuum in the gap 126 . Further, drawing the vacuum in the gap 126 may cause an impact or shock loading of the first and second insulators 130 , 134 as the inner liner 118 and the external wrapper 122 contract around the first and second insulators 130 , 134 . Accordingly, the first and second insulators 130 , 134 should have sufficient crush resistance to resist deformation of the inner liner 118 and the external wrapper 122 due to a pressure gradient between the atmosphere and an air pressure of the gap 126 .
- the first insulator 130 may be positioned within, and proximate to, the front flange area 164 of the cabinet 114 and the second insulator 134 may fill the rest of the gap 126 .
- a filter 174 is positioned between the first insulator 130 and the second insulator 134 .
- the filter 174 may be made of paper, a polymeric material, a ceramic and/or a metal.
- the filter 174 may be porous, solid and/or coupled to the inner liner 118 and/or the external wrapper 122 . Use of the filter 174 may resist or prevent the migration and mixing of the first and second insulators 130 , 134 such that the first and second insulators 130 , 134 remain segregated.
- the front flange area 164 due to its thinner cross section and being surrounded by atmosphere on three sides, may suffer from a thermal, or heat, bridging effect. Such a thermal bridging across the front flange area 164 may result in an overall reduced efficiency of the refrigerator 110 . Accordingly, in various embodiments the first insulator 130 may have a higher insulating property than the second insulator 134 . In such an embodiment, the higher insulating property of the first insulator 130 may be sufficient to reduce, or eliminate any thermal bridging taking place through the front flange area 164 .
- the gap 126 within the cabinet 114 may undergo a pressure increase over the service life of the refrigerator 110 due to permeation and/or diffusion of gases.
- selection of the first and second insulators 130 , 134 may account for the expected change in pressure within the gap 126 .
- fumed silica undergoes the smallest increase in thermal conductivity over an expected pressure change range (e.g., between about 1 mbar and about 10 mbar), followed by precipitated silica.
- fumed silica as the first insulator 130 and precipitated silica and/or combinations of insulators (e.g., precipitated silica and spheres) as the second insulator 134 may not only reduce thermal bridging across the front flange area 164 while the gap 126 is at manufactured pressure, but also over the service life of the refrigerator 110 .
- the first method 180 includes step 184 , step 188 , step 192 , step 194 and step 196 .
- step 184 the inner liner 118 is positioned within the external wrapper 122 as explained in greater detail above.
- the liner flange 146 and the wrapper flange 162 may be bonded so as to make the gap 126 airtight.
- step 188 of drawing a vacuum may be performed. A vacuum, or negative pressure relative to atmospheric pressure, is generated within the gap 126 .
- the vacuum is created by drawing the air out of the gap 126 through the at least one vacuum port 170 .
- a pump or other suitable vacuum sources may be connected to the vacuum port 170 to facilitate drawing the vacuum.
- the first method 180 may be performed within a vacuum chamber 198 to provide the vacuum to the gap 126 .
- step 192 of injecting the first insulator 130 into the gap 126 is performed.
- Injection of the first insulator 130 into the gap 126 may be accomplished by feeding the first insulator 130 into a hopper 200 which in turn supplies the first insulator 130 to a transfer mechanism 204 .
- the transfer mechanism 204 may be a powder pump, a vacuum transfer device, pneumatic pump, flexible screw conveyor, auger feeder and/or other devices capable of transferring or moving the first and second insulators 130 , 134 .
- the transfer mechanism 204 pumps or otherwise injects the first insulator 130 into the gap 126 of the cabinet 114 ( FIG. 12 A ).
- the transfer mechanism 204 may utilize fluidization of the first insulator 130 to move the first insulator 130 into the gap 126 .
- the transfer mechanism 204 may dispense the first insulator 130 into the cabinet 114 with or without pressure. Use of the transfer mechanism 204 allows the first insulator 130 to be inserted into the gap 126 without any densification or compaction, while also providing an easy and efficient means of inserting the first insulator 130 . Once the first insulator 130 has sufficiently filled the front flange area 164 of the cabinet 114 and optionally been leveled off, the filter 174 may be placed on top of the first insulator 130 and optionally coupled to the inner liner 118 and external wrapper 122 . Next, step 194 of injecting the second insulator 134 is performed.
- Injection of the second insulator 134 may be performed in substantially the same manner as injection of the first insulator 130 is carried out in step 192 .
- the second insulator 134 may be dispensed or injected under different conditions that produce a different packing factor or density of the second insulator 134 relative to the first insulator 130 .
- step 196 of vibrating at least one of the inner liner 118 and the external wrapper 122 is performed. Vibration of the inner liner 118 and/or the external wrapper 122 may cause the first insulator 130 to increase its packing factor.
- the inner liner 118 and/or external wrapper 122 may be supported by one or more supports 206 such that relative motion between the inner liner 118 and the external wrapper 122 is minimized or prevented.
- the supports 206 may allow the thickness of the gap 126 to remain constant through filling and vibration.
- the second method 208 includes step 212 , step 216 , step 218 , step 220 and step 224 .
- the second method 208 begins with step 212 of positioning the inner liner 118 within the external wrapper 122 and sealing the gap 126 , as disclosed above.
- step 216 of dispensing the first insulator 130 within the gap 126 is performed.
- dispensing of the first insulator 130 into the gap 126 may be accomplished through a back aperture 232 .
- the back aperture 232 may take a variety of shapes (e.g., square, rectangular, circular, oblong, and combinations thereof) and sizes which are configured to allow the first insulator 130 to be poured or otherwise dispensed into the gap 126 .
- the first insulator 130 may be dispensed into the gap 126 between the inner liner 118 and the external wrapper 122 via the transfer mechanism 204 ( FIG. 14 A ), pouring the first insulator 130 , or manual application.
- the external wrapper 122 may not include the injection port 166 ( FIG. 14 A ).
- step 216 may be performed while at least one of the inner liner 118 and the external wrapper 122 are vibrated. Vibration of the inner liner 118 and/or the external wrapper 122 may facilitate in shaking or vibrating the first insulator 130 into its maximum packing factor and facilitate a more complete filling of the gap 126 .
- the filter 174 may be placed on the first insulator 130 as described above.
- step 218 of dispensing the second insulator 134 is performed. Dispensing of the second insulator 134 may be accomplished in a substantially similar manner to that described in connection with the first insulator 130 in step 216 .
- step 220 of positioning a back plate 242 over the back aperture 232 is performed.
- the back plate 242 may be constructed of the same or similar material as the external wrapper 122 , or a different material.
- step 224 of drawing a vacuum within the gap 126 is performed.
- the vacuum may be drawn through the vacuum port 170 ( FIG. 14 A ) of the external wrapper 122 .
- method 208 or individual steps thereof, may be performed within the vacuum chamber 198 such that drawing a vacuum may not be necessary, or less vacuum can be drawn.
- the second method 208 may utilize the supports 106 to resist relative motion of the inner liner 118 and the external wrapper 122 . It will be understood that steps of the first and second methods 180 , 208 may be omitted, combined, mixed and matched, or otherwise reordered without departing from the spirit of this disclosure.
- Use of the present disclosure may offer several advantages. For example, use of the present disclosure allows for the formation of vacuum insulated cabinets 114 , panels, and structures without noticeable deformation of the inner liner 118 and the external wrapper 122 . By filling the gap 126 , deformation of the inner liner 118 and the external wrapper 122 from the pressure differential between the atmosphere and the gap 126 is resisted by the first and second insulators 130 , 134 . Vacuum insulated cabinets 114 , panels and structures may provide enhanced insulative properties as compared to traditional foam filled insulating structures in addition to a reduced size (e.g., thickness decrease of greater than about 55%, 60% or 70%).
- first insulator 130 has a lower increase in thermal conductivity per unit pressure increase than the second insulator 134
- use of the first insulator 130 proximate the front flange area 164 allows for a greater resistance to thermal bridging as the pressure within the gap 126 increases over the service life of the refrigerator 110 .
- the disclosure was described in terms of a refrigerator, the disclosure may equally be applied to coolers, ovens, dishwashers, laundry applications, water heaters, household insulation systems, ductwork, piping insulation, acoustical insulation and other thermal and acoustical insulation applications.
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- Refrigerator Housings (AREA)
Abstract
A refrigerator includes a wrapper having an opening with a front edge. A liner includes an opening and a front edge. A thermal bridge interconnects the wrapper and the liner to form a vacuum insulated cavity therebetween. The thermal bridge includes an outwardly opening channel and first and second inwardly opening channels. The front edge of wrapper is received in the first inwardly opening channel, and the front edge of the liner is received in the second inwardly opening channel. The second inwardly opening channel is inset relative to the first inwardly opening channel on the thermal bridge. A conduit is disposed within the outwardly opening channel and is configured to circulate a heated medium. The wrapper and liner are contemplated to be comprised of conductive materials, such sheet metal, while the thermal bridge is comprised of a thermally resistant material, such as a polymeric material.
Description
- This application is a continuation of U.S. patent application Ser. No. 17/208,082, filed on Mar. 22, 2021, entitled VACUUM INSULATED STRUCTURE WITH THERMAL BRIDGE BREAKER WITH HEAT LOOP, the entire disclosure of which is hereby incorporated by reference, which is a continuation-in-part of U.S. application Ser. No. 16/757,790, filed on Apr. 21, 2020, entitled “VACUUM INSULATED STRUCTURE WITH THERMAL BRIDGE BREAKER WITH HEAT LOOP,” which is a National Stage Application under 35 U.S.C. § 371 of International Application No. PCT/US2017/063947, filed on Nov. 30, 2017, entitled “VACUUM INSULATED STRUCTURE WITH THERMAL BRIDGE BREAKER WITH HEAT LOOP.” This application is also a continuation-in-part of U.S. application Ser. No. 17/037,855, filed on Sep. 30, 2020, entitled “VACUUM INSULATION STRUCTURES WITH MULTIPLE INSULATORS,” which is a continuation of U.S. patent application Ser. No. 15/776,276 entitled “VACUUM INSULATION STRUCTURES WITH MULTIPLE INSULATORS,” filed May 15, 2018 (now U.S. Pat. No. 10,808,987) which is a national stage entry of PCT/US2016/063966, filed on Nov. 29, 2016, which claims the benefit under 35 U.S.C. § 119(e) to U.S. Provisional Patent Application No. 62/265,055 filed Dec. 9, 2015. The entire disclosures of each are incorporated herein by reference in their entireties.
- The present device generally relates to insulated structures, in particular, to a vacuum insulated refrigerator cabinet that includes a thermal bridge breaker that includes a heat loop and interconnects a wrapper and one or more liners and cooperates with the liners to define refrigerated storage compartments.
- Various types of insulated refrigerator cabinet structures have been developed. One type of insulated structure includes a wrapper and a liner. The wrapper and liner are generally spaced-apart to form a cavity therebetween that is filled with an insulating material. In a vacuum insulated refrigerator structure, this cavity may be filled with a vacuum insulated core material. In order to hold the vacuum, it is necessary to provide an airtight seal between the wrapper, one or more liners, and the thermal bridge breaker. Further, thermal conduction between component parts of a refrigerator is sought to be avoided to reduce condensation.
- In at least one aspect of the present concept, a refrigerator includes a wrapper having a wall portion and a flange portion with a transverse portion disposed therebetween. The flange portion of the wrapper extends outwardly in a forward direction from the transverse portion of the wrapper and is substantially parallel to the wall portion of the wrapper. A liner is spaced-apart from the wrapper to define a vacuum insulated cavity therebetween. The liner includes a wall portion and a flange portion with a transverse portion disposed therebetween. The transverse portion of the liner is an angled portion extending outwardly towards the wrapper, and the flange portion of the liner extends outwardly in a forward direction from the transverse portion of the liner and is substantially parallel to the wall portion of the liner. The transverse portion of the wrapper is an angled portion extending inwardly towards the liner. A thermal bridge includes a first channel, a second channel and a third channel. A portion of the flange portion of the wrapper is received in the first channel, and a portion of the flange portion of the liner is received in the second channel. A conduit is received in the third channel and is configured to circulate a heated medium around a perimeter of the refrigerator.
- In yet another aspect of the present concept, a refrigerator includes a liner received within a cavity of a wrapper to define a vacuum insulated cavity therebetween. The wrapper and the liner each include a wall portion and a flange portion with an angled transverse portion disposed therebetween. The transverse portion of the wrapper is angled inwardly towards the liner, and the transverse portion of the liner is angled outwardly towards the wrapper. The flange portion of the wrapper extends further in a forward direction than the flange portion of the liner. A thermal bridge interconnects the wrapper and liner and includes first and second channels. A portion of the flange portion of the wrapper is received in the first channel, and a portion of the flange portion of the liner is received in the second channel.
- These and other features, advantages, and objects of the present device will be further understood and appreciated by those skilled in the art upon studying the following specification, claims, and appended drawings.
- In the drawings:
-
FIG. 1 is isometric view of a refrigerator including a vacuum insulated cabinet structure; -
FIG. 2 is an exploded isometric view of a vacuum insulated cabinet structure; -
FIG. 3 is a rear isometric view of the vacuum insulated cabinet structure ofFIG. 2 as assembled; -
FIG. 4 is a cross-sectional view of the refrigerator ofFIG. 1 taken at line IV; -
FIG. 5 is a fragmentary cross-sectional view of the thermal bridge taken from location V ofFIG. 4 ; -
FIG. 6 is a fragmentary cross-sectional view of the thermal bridge taken from location VI ofFIG. 4 ; -
FIG. 7 is cross-sectional view of the thermal bridge taken from location VII ofFIG. 4 ; -
FIG. 8 is a fragmentary cross-sectional view of the thermal bridge ofFIG. 5 having a portion of a conduit coupled thereto; -
FIG. 9 is a fragmentary cross-sectional view of the thermal bridge ofFIG. 6 having a portion of a conduit coupled thereto; -
FIG. 10 is a is a fragmentary cross-sectional view of the thermal bridge ofFIG. 7 having a portion of a conduit coupled thereto; -
FIG. 11 is a top perspective view of the vacuum insulated cabinet structure ofFIG. 3 with portions thereof shown in phantom to reveal a conduit loop; -
FIG. 12A is a top perspective view of a refrigerator cabinet, according to one embodiment; -
FIG. 12B is an exploded top perspective view of the refrigerator cabinet ofFIG. 12A , according to one embodiment; -
FIG. 12C is a cross-sectional view taken at line IC-IC ofFIG. 12A , according to one embodiment; -
FIG. 13A is a cross-sectional view taken at line II-II ofFIG. 12A , according to one embodiment; -
FIG. 13B is a graph depicting the thermal conductivity of various insulator materials as a function of gas pressure; -
FIG. 14A is a schematic depiction of a refrigerator cabinet insulator filling system, according to one embodiment; -
FIG. 14B is a flow chart of a refrigerator cabinet insulator filling method, according to one embodiment; -
FIG. 15A is a schematic depiction of a refrigerator cabinet insulator filling system, according to one embodiment; and -
FIG. 15B is a flow chart of a refrigerator cabinet insulator filling method, according to one embodiment. - For purposes of description herein the terms “upper,” “lower,” “right,” “left,” “rear,” “front,” “vertical,” “horizontal,” and derivatives thereof shall relate to the device as oriented in
FIG. 1 . However, it is to be understood that the device may assume various alternative orientations and step sequences, except where expressly specified to the contrary. It is also to be understood that the specific devices and processes illustrated in the attached drawings, and described in the following specification are simply exemplary embodiments of the inventive concepts defined in the appended claims. Hence, specific dimensions and other physical characteristics relating to the embodiments disclosed herein are not to be considered as limiting, unless the claims expressly state otherwise. Further, the terms “substantial,” “substantially,” and variations thereof as used herein are intended to note that a described feature is equal or approximately equal to a value or description. For example, a “substantially planar” surface is intended to denote a surface that is planar or approximately planar. Moreover, “substantially” is intended to denote that two values are equal or approximately equal. In some embodiments, “substantially” may denote values within about 10% of each other, such as within about 5% of each other, or within about 2% of each other. - With reference to
FIG. 1 , arefrigerator 1 includes a vacuum insulatedcabinet structure 2 which, in the embodiment ofFIG. 1 , further includes arefrigerator compartment 28 positioned above afreezer compartment 44.Doors refrigerator compartment 28, while adrawer 7 is used to provide access to thefreezer compartment 44. The vacuum insulatedcabinet structure 2 is surrounded by anexterior wrapper 8 in assembly. The configuration of therefrigerator 1 is exemplary only and the present concept is contemplated for use in all refrigerator styles including, but not limited to, side-by-side refrigerators, whole refrigerator and freezers, and refrigerators with upper freezer compartments. - Referring now to
FIG. 2 , the vacuum insulatedcabinet structure 2 generally includes athermal bridge 10. In the embodiment shown inFIG. 2 , thethermal bridge 10, or thermal breaker, includes aframe 12 having anupper opening 12A and alower opening 12B with amullion portion 14 disposed therebetween. Thethermal bridge 10 further includes anupper portion 10A, amiddle portion 10B and alower portion 10C. A rear portion of theupper opening 12A of thethermal bridge 10 defines afront portion 28A of a refrigerator compartment 28 (FIGS. 3 and 4 ), as further described below, when the vacuum insulatedcabinet structure 2 is assembled. Similarly, a rear portion of thelower opening 12B of thethermal bridge 10 defines afront portion 44A of a freezer compartment 44 (FIGS. 3 and 4 ), as further described below, when the vacuum insulatedcabinet structure 2 is assembled. Thethermal bridge 10 may be referred to herein as a trim breaker, such as thetrim breaker 172 shown inFIG. 12C . Thus, the description of thethermal bridge 10 also describes thetrim breaker 172, as shown inFIG. 12C . - As shown in the embodiment of
FIG. 2 , the vacuum insulatedcabinet structure 2 further includes arefrigerator liner 16 having atop wall 18, abottom wall 20, opposed sidewalls 22, 24, and arear wall 26. Together, thewalls rear portion 28B of therefrigerator compartment 28 when the vacuum insulatedcabinet structure 2 is assembled (seeFIGS. 3 and 4 ). Therefrigerator liner 16 further includes afront edge 30 disposed on a front portion thereof. Thefront edge 30 is disposed along thetop wall 18, thebottom wall 20 and theopposed sidewalls refrigerator liner 16 may be referred to herein as an inner liner, such asinner liner 118 shown inFIG. 12C . Thus, the description of the refrigerator liner 16 (and thefront edge 30, thetransverse portion 82 and theflange portion 84 thereof) also describes theinner liner 118 shown inFIG. 12C . - As further shown in the embodiment of
FIG. 2 , afreezer liner 32 is provided and includes atop wall 34, abottom wall 36, opposed sidewalls 38, 40, and arear wall 42. Together, thewalls rear portion 44B of thefreezer compartment 44 when the vacuum insulatedcabinet structure 2 is assembled (seeFIGS. 3 and 4 ). Therear wall 42 is shown inFIG. 2 as being a contoured rear wall that provides a spacing S for housing mechanical equipment 43 (FIG. 4 ) for cooling both therefrigerator compartment 28 andfreezer compartment 44. Such equipment may include a compressor, a condenser, an expansion valve, an evaporator, a plurality of conduits, and other related components used for cooling the refrigerator andfreezer compartments FIG. 2 , thefreezer liner 32 includes afront edge 46 disposed on a front portion thereof. Thefront edge 46 is disposed along thetop wall 34, thebottom wall 36 and theopposed sidewalls front edge 30 of therefrigerator liner 16 and thefront edge 46 of thefreezer liner 32 define first andsecond openings lower openings thermal bridge 10, as further described below. - As further shown in
FIG. 2 , the vacuum insulatedcabinet structure 2 further includes theexterior wrapper 8 which, in the embodiment ofFIG. 2 , includes atop wall 50, abottom wall 52, opposed sidewalls 54, 56, and arear wall 58 which cooperate to define acavity 59. Thewrapper 8 further includes afront edge 60 which is disposed along anopening 61 of thecavity 59 which is further disposed along thetop wall 50, thebottom wall 52, and theopposed sidewalls frontmost edge 60 of theexterior wrapper 8 presented in a quadrilateral ring configuration. In assembly, thefront edge 60 of theexterior wrapper 8 is coupled to coupling portions of thethermal bridge 10 around theliners thermal bridge 10 interconnects theexterior wrapper 8 and therefrigerator liner 16 and thefreezer liner 32 when assembled. Further, therefrigerator liner 16 andfreezer liner 32 are received within thecavity 59 of theexterior wrapper 8 when assembled, such that there is a spacing VC (FIG. 3 ) between the outer surfaces of therefrigerator liner 16 and thefreezer liner 32 relative to the inner surfaces of theexterior wrapper 8. In this way, the spacing can be used to create a vacuum insulated cavity, as further described below. The spacing VC may be referred to herein as a gap 126 (FIG. 12C ) or a vacuum insulated cavity positioned between theexterior wrapper 8 andrefrigerator liner 16 and thefreezer liner 32. Theexterior wrapper 8 may be referred to herein as an external wrapper, such asexternal wrapper 122 shown inFIG. 12C . Thus, the description of the exterior wrapper 8 (and thefront edge 60, thetransverse portion 76 and theflange portion 78 thereof) also describes theexternal wrapper 122 shown inFIG. 12C . - The
wrapper 8 may be made from sheet metal, polymer materials, or other suitable materials. For purposes of the present concept, thewrapper 8 is contemplated to be made from a sheet metal material that is formed utilizing known steel forming tools and processes. Therefrigerator liner 16 and thefreezer liner 32 are also preferably made from a sheet metal material utilizing known steel forming tools and processes. - The
thermal bridge 10 may be formed from a material having a low thermal conductivity. For example, thethermal bridge 10 may be fabricated by thermoforming a sheet of thermoplastic polymer material. Thethermal bridge 10 may be constructed of a material that is substantially impervious, such that oxygen, nitrogen, carbon dioxide, water vapor, and/or other atmospheric gasses are sealed out of the vacuum cavity VC (FIG. 3 ) defined in the spacing or gap that is formed between thewrapper 8 andliners thermal bridge 10 may comprise a plurality of layers, wherein layers of polymeric material are selected to provide impermeability to gasses, such that thethermal bridge 10 provides for an air-tight connection between thewrapper 8 and theliners thermal bridge 10, thewrapper 8 and theliners FIG. 3 ). Thethermal bridge 10 may also be formed from any suitable material that is substantially impervious to gasses to maintain a vacuum in the vacuum cavity VC. The material used to comprise thethermal bridge 10 is also contemplated to have a low coefficient of thermal conductivity to reduce or prevent transfer of heat between themetal wrapper 8 and themetal liners thermal bridge 10 is preferably formed utilizing a molding process, and specifically, may include a reaction injection molding (RIM) process as further described below. In an RIM process, thethermal bridge 10 is likely formed in a mold using a polyurethane material. Other materials suitable for an RIM process may include, but are not limited to, polyureas, polyisocyanurates, polyesters, polyphenols, polyepoxides, thermoplastic elastomers, polycarbonate, and nylon materials. Using an RIM process of the present concept, thethermal bridge 10 could be overmolded to therefrigerator liner 16, thefreezer liner 32 and thewrapper 8 at the respective front edges 30, 46, 60 thereof. In this way, the vacuum insulatedcabinet structure 2 can be a unitary part after thethermal bridge 10 is cast onto thefront edges liners wrapper 8. Thus, thethermal bridge 10 can be comprised entirely of a material having a low thermal conductivity (such as glass, ceramic, or polymeric materials), or can by partially comprised of such materials. - As shown in
FIG. 2 , thefront edge 30 of therefrigerator liner 16 includes linear portions disposed around thetop wall 18,bottom wall 20 andopposed sidewalls front edge 30 of therefrigerator liner 16 is generally quadrilateral. As further shown inFIG. 2 , thefront edge 46 of thefreezer liner 32 includes linear portions disposed around thetop wall 34,bottom wall 36 andopposed sidewalls front edge 46 of thefreezer liner 32 is also generally quadrilateral. As depicted inFIG. 2 , and further shown inFIG. 3 , the profile of the combination of theliners wrapper 8. In this way, the vacuum cavity VC (FIG. 3 ) is formed within the spacing defined between theliners wrapper 8 when theliners cavity 59 of thewrapper 8. The vacuum cavity VC is configured to receive an insulating material (not shown) that may be described as a vacuum core material. The vacuum core material may comprise a plurality of preformed individual core panels that are preformed and positioned betweenwrapper 8 and theliners thermal bridge 10. Alternatively, the vacuum core material may comprise silica powder or other suitable loose filler material that is inserted (e.g. blown) into the vacuum cavity VC afterwrapper 8,liners thermal bridge 10 are formed into a unitary composite structure. - As configured in assembly, the
front edges liners bottom wall 20 of therefrigerator liner 16 and the linear portion disposed along thetop wall 34 of thefreezer liner 32. Further, thefront edges liners sidewalls liners top wall 18 of therefrigerator liner 16 and thebottom wall 36 of thefreezer liner 32 are spaced-apart from the linear portions defining thefront edge 60 of thewrapper 8 in assembly. - Referring now to
FIG. 3 , when the vacuum insulatedcabinet structure 2 is assembled, thethermal bridge 10 connects to thefront edge 60 of thewrapper 8, and further connects to thefront edge 30 of therefrigerator liner 16, and to thefront edge 46 of thefreezer liner 32, thereby interconnecting the components. In this way, thethermal bridge 10 interconnects thewrapper 8 and theliners FIG. 1 ) is in use, thewrapper 8 is typically exposed to ambient room temperature air, whereas theliners refrigerator compartment 28 or thefreezer compartment 44. With thethermal bridge 10 being made of a material that is substantially non-conductive with respect to heat, thethermal bridge 10 reduces transfer of heat from thewrapper 8 to theliners - The
thermal bridge 10 may include linear portions that are interconnected to form a ring-like structure having a quadrilateral perimeter orouter coupling portion 62 and quadrilateralinner coupling portions inner coupling portions lower openings openings front edges refrigerator liner 16, andfreezer liner 32 of thecabinet structure 2. In assembly, theouter coupling portion 62 is coupled to thefront edge 60 of thewrapper 8. Further, theinner coupling portions outer coupling portion 62 and set back therefrom, as further described below. In assembly, theinner coupling portions front edges refrigerator liner 16, andfreezer liner 32, respectively. It will be understood that thethermal bridge 10 may have various shapes and configurations as may be required for a particular application, and it is further contemplated that thethermal bridge 10 can be used in a refrigerator having multiple liners (as shown inFIG. 2 with arefrigerator liner 16 and a freezer liner 32) or in a refrigerator having a single liner for use as a refrigerator or freezer only. Theouter coupling portion 62 may be referred to herein as a wrapper joint, such as wrapper joint 172B shown inFIG. 12C . Thus, the description of the outer coupling portion 62 (and thefirst channel 67 thereof) also describes the wrapper joint 172B shown inFIG. 12C . Theinner coupling portion 64 may be referred to herein as a liner joint, such as liner joint 172A shown inFIG. 12C . Thus, the description of the inner coupling portion 64 (and thesecond channel 69 thereof) also describes the wrapper joint 172B shown inFIG. 12C . - Referring now to
FIG. 4 , therefrigerator 1 is shown in a cross-sectional view having therefrigerator liner 16 andfreezer liner 32 coupled to thethermal bridge 10 at upper andlower openings wrapper 8 is also coupled to thethermal bridge 10, such that thethermal bridge 10 interconnects thewrapper 8 with therefrigerator liner 16 andfreezer liner 32. Specifically, thethermal bridge 10 of the present concept is coupled to theliners wrapper 8 to hermetically seal the components together as a unitary whole as shown inFIG. 3 . In the cross-sectional view ifFIG. 4 , thethermal bridge 10 is shown as defining thefront portion 28A of therefrigerator compartment 28, with therefrigerator liner 16 defining therear portion 28B of therefrigerator compartment 28. A mating joint between therefrigerator liner 16 and thethermal bridge 10 is identified atreference numeral 29. Further, in the cross-sectional view ifFIG. 4 , thethermal bridge 10 is shown as defining thefront portion 44A of thefreezer compartment 44, with thefreezer liner 32 defining therear portion 44B of thefreezer compartment 44. A mating joint between thefreezer liner 32 and thethermal bridge 10 is identified atreference numeral 45. With thethermal bridge 10 providing thefront portions refrigerator compartment 28 and thefreezer compartment 44, respectively, the metal materials of the cooledliners metal wrapper 8 and a sealing surface of thethermal bridge 10. In this way, the configuration of thethermal bridge 10 insulates the highly conductive metallic materials of theliners thermal bridge 10 is further described below. - Referring now to
FIG. 5 , theupper portion 10A of thethermal bridge 10 is shown having abody portion 70 with a front forward facing sealingsurface 72 and an inwardly projectingextension 74. Thefront sealing surface 72 is a generally vertical forward facing sealing surface that provides a substantially planar surface for seal members of the doors, such asdoors FIG. 1 , to seal against when closed. The inwardly projectingextension 74 of thebody portion 70 of thethermal bridge 10 projects in a substantially horizontal manner at theupper portion 10A of thethermal bridge 10 and provides a substantially planar surface which defines thefront portion 28A of therefrigerator compartment 28, as shown inFIG. 3 . In this way, thebody portion 70 of thethermal bridge 10 includes a first portion (the upright outwardly facing sealing surface 72) and a second portion (the inwardly projectingextension 74 that extends orthogonally to the upright sealing surface 72) to provide an overall L-shapedbody portion 70. The inwardly projectingextension 74 is positioned around the entireupper opening 12A of thethermal bridge 10 to define thefront portion 28A of therefrigerator compartment 28 from all four sides thereof. Thus, theupper opening 12A of thethermal bridge 10 defines an opening into therefrigerated compartment 28 in assembly. The inwardly projectingextension 74 extends inwardly a distance D2 as shown inFIG. 5 from the sealingsurface 72. The sealingsurface 72 also extends around the entireupper opening 12A of thethermal bridge 10 to define a fully encircling sealingsurface 72 for therefrigerator compartment 28. - The configuration of the
body portion 70 of thethermal bridge 10 provides for theouter coupling portion 62 to be disposed outside of theinner coupling portion 64. Along theupper portion 10A of thethermal bridge 10,outer coupling portion 62 is specifically disposed above of theinner coupling portion 64. Theouter coupling portion 62 is positioned on arear side 72B of the sealingsurface 72 and includes afirst channel 67 which opens inwardly. As shown inFIG. 5 , thefront edge 60 of thewrapper 8 is received in thefirst channel 67. In the embodiment ofFIG. 5 , an outwardly openingchannel 68 is shown disposed on afront side 72A of the sealingsurface 72. The outwardly openingchannel 68 is configured to receive tubing for a heat loop, as further described below with specific reference toFIG. 8 . - As further shown in
FIG. 5 , theinner coupling portion 64 includes asecond channel 69 which, much likefirst channel 67, is disposed on therear side 72A and opens inwardly. As shown inFIG. 5 , thefront edge 30 of therefrigerator liner 16 is received in thesecond channel 69 of thethermal bridge 10. Thus, thethermal bridge 10, as shown in the embodiment ofFIG. 5 , extends across a gap or vacuum cavity VC between thewrapper 8 and therefrigerator liner 16 to interconnect thewrapper 8 and therefrigerator liner 16. Thebody portion 70 of thethermal bridge 10 includes first andsecond channels channel 68, which opens outwardly in a second direction that is opposed to or opposite from the first direction. The front edges 60, 30 of thewrapper 8 and therefrigerator liner 16 are disposed in the first andsecond channels - As further shown in
FIG. 5 , theouter coupling portion 62 is disposed along an upper portion of the sealingsurface 72 of thebody portion 70 of thethermal bridge 10 at theupper portion 10A of thethermal bridge 10. Thus, theouter coupling portion 62, and thechannel 67 thereof, is outboard of theinner coupling portion 64, and thechannel 69 thereof. Further, theinner coupling portion 64 is staggered or offset relative to theouter coupling portion 62. Specifically, in the embodiment shown inFIG. 5 , theinner coupling portion 64, and thechannel 69 thereof, is disposed inward and below theouter coupling portion 62, and thechannel 67 thereof, as theinner coupling portion 64 is disposed on an end of the inwardly projectingextension 74 of thebody portion 70 of thethermal bridge 10. - As further shown in
FIG. 5 , thefront edge 60 of thewrapper 8 may include an angledtransverse portion 76 and anend flange portion 78 that is received in thefirst channel 67 of theouter coupling portion 62 of thethermal bridge 10. The angle of thetransverse portion 76 of thewrapper 8 allows thetop wall 50 of thewrapper 8 to be flush with anouter surface 80 of thethermal bridge 10, when theend flange portion 78 is received in thefirst channel 67 of theouter coupling portion 62 of thethermal bridge 10. Theend flange portion 78 is contemplated to be part of thefront edge 60 of thewrapper 8 that is received in thefirst channel 67 for providing a surface for attachment of theouter coupling portion 62. This interconnection can include an adhesive or sealant medium disposed in thefirst channel 67 to adhere the components together in an airtight manner for retaining a vacuum between thethermal bridge 10 and thewrapper 8 andliner 16 in the vacuum insulated cavity VC. Similarly, therefrigerator liner 16 includes an angledtransverse portion 82 extending off oftop wall 18 thereof, and leading to anend flange portion 84 which is received in thesecond channel 69 of theinner coupling portion 64. The angle oftransverse portion 82 of therefrigerator liner 16 allows for the inner surface oftop wall 18 to align with the inwardly projectingextension 74 of thethermal bridge 10. With thefront edge 30 of therefrigerator liner 16 received in thesecond channel 69 of theinner coupling portion 64, theend flange portion 84 provides a surface for thethermal bridge 10 to adhere to therefrigerator liner 16. This interconnection can include an adhesive or sealant medium disposed in thesecond channel 69 to adhere the components together in an airtight manner for retaining a vacuum between thethermal bridge 10 and thewrapper 8 andliner 16 in the vacuum insulated cavity VC. As shown inFIG. 5 , thetransverse portion 82 of therefrigerator liner 16 extends inwardly towards the vacuum insulated cavity VC. In this way, thetransverse portion 82 of therefrigerator liner 16 extends towards thewrapper 8. Similarly, thetransverse portion 76 of thewrapper 8 extends inwardly towards the vacuum insulated cavity VC in an opposed direction as compared to the angle of thetransverse portion 82 of therefrigerator liner 16. In this way, thetransverse portion 76 of thewrapper 8 extends towards therefrigerator liner 16. This configuration is also shown inFIG. 12C , wherein theexternal wrapper 122 and theinner liner 118 include transverse portions extending into thegap 126 disposed between theexternal wrapper 122 and theinner liner 118. - As further shown in
FIG. 5 , theend flange portion 78 of thewrapper 8 extends outwardly in a direction as indicated byarrow 79A. The direction indicated byarrow 79A of theend flange portion 78 of thewrapper 8 is parallel thetop wall 50 of thewrapper 8. Thus, theend flange portion 78 of thewrapper 8 extends outwardly in a straight line from the angledtransverse portion 76 of thewrapper 8. Similarly, theend flange portion 84 of therefrigerator liner 16 extends outwardly in a direction as indicated byarrow 79B. The direction indicated byarrow 79B of theend flange portion 84 of therefrigerator liner 16 is parallel thetop wall 18 of therefrigerator liner 16. Thus, theend flange portion 84 of therefrigerator liner 16 extends outwardly in a straight line from the angledtransverse portion 82 of therefrigerator liner 16. It is contemplated that the configuration of theend flange portions wrapper 8 andrefrigerator liner 16 being parallel to thetop walls wrapper 8 andrefrigerator liner 16 around theopenings FIG. 12C , wherein theexternal wrapper 122 and theinner liner 118 include end flange portions extending outwardly in a straight and parallel manner with respect to the associated walls of theexternal wrapper 122 and theinner liner 118 shown inFIG. 12C . - Thus, in the configuration of the
thermal bridge 10 shown inFIG. 5 , thefront edge 60 of thewrapper 8 is not only spaced-apart from thefront edge 30 of therefrigerator liner 16 so as to be outside of or outboard from thefront edge 30 of the refrigerator liner 16 (as indicated by arrow D3), but is also offset laterally from thefront edge 30 of the refrigerator liner 16 (as indicated by arrow D2). This is generally due to thethermal bridge 10 having a staggered configuration for outer coupling portion 62 (andfirst channel 67 thereof) relative to the inner coupling portion 64 (and thesecond channel 69 thereof) for receiving thefront edge 60 of thewrapper 8 and thefront edge 30 of therefrigerator liner 16, respectively. Thefirst channel 67 is inset from the sealing surface a distance D1 and is outboard of the second channel 69 a distance D3. Thesecond channel 69 is inset from the sealing surface a distance D2, which, as noted above is greater than the distance D1 defined between the sealingsurface 72 and thefirst channel 67. This staggered configuration is also present between thewrapper 8 and thefreezer liner 32, as further described below. Thus, thethermal bridge 10 includes a first portion defined by the sealingsurface 72 with afirst channel 67 disposed thereon. Thethermal bridge 10 further includes a second portion defined by the inwardly projectingextension 74 which inwardly extends from the sealingsurface 72 and includes asecond channel 69 disposed at a distal end thereof. The first andsecond channels channels upper opening 12A of thethermal bridge 10. - The distances indicated in
FIG. 5 may include specific parameters in the ranges noted below. However, the scope of the present concept is not limited to such ranges. For example, theouter surface 72A of the sealingsurface 72 may be approximately 20 mm to provide a substantial surface for doors to seal against. The distance D3 measuring the offset between thefirst channel 67 and thesecond channel 69 may be approximately 12 mm. The distance D2 may be approximately 70 mm, such that the inwardly projectingextension 74 provides a substantial polymericfront portion 28A for therefrigerator compartment 28. Further, thefirst channel 67 and thesecond channel 69 may be spaced-apart about 57 mm from one another in a direct path measured therebetween. - Referring now to
FIG. 6 , themiddle portion 10B of thethermal bridge 10 is shown havinginner coupling portion 64 disposed aboveinner coupling portion 66. As noted above, theinner coupling portion 64 is configured to receive thefront edge 30 of therefrigerator liner 16 atchannel 69 thereof, as shown inFIG. 6 . As further noted above, theinner coupling portion 66 is configured to receive thefront edge 46 of thefreezer liner 32 atchannel 69A thereof, as shown inFIG. 6 . Theinner coupling portion 66 is interconnected with theinner coupling portion 64 by atrim component 72C that may be a detachable trim component to thethermal bridge 10 that is used to seal lower portions of doors (such asdoors FIG. 1 ) and an upper portion of a drawer (such asdrawer 7 shown inFIG. 1 ) to thethermal bridge 10. At themiddle portion 10B, thethermal bridge 10 includes an upper outwardly openingchannel 65A and a lower outwardly openingchannel 65B. Thetrim component 72C includes inwardly turned upper andlower legs channel 65A and the lower outwardly openingchannel 65B, respectively. - As further shown in
FIG. 6 , theinner coupling portion 64 is disposed above theinner coupling portion 66. Further, theinner coupling portion 64 is not staggered or offset relative to theinner coupling portion 66, but rather they are aligned with one another. In the embodiment shown inFIG. 6 , therefrigerator liner 16 includes thetransverse portion 82 extending off ofbottom wall 20 thereof, and leading to theend flange portion 84 which is received in thesecond channel 69 of theinner coupling portion 64. Thus, thetransverse portion 82 of therefrigerator liner 16 is disposed all the way around theopening 31 of therefrigerator liner 16 attop wall 18,bottom wall 20 andopposed side walls end flange portion 84 is also disposed fully around therefrigerator liner 16 extending outwardly fromtransverse portion 82, and defining a surface for adhering engagement with thesecond channel 69 of theinner coupling portion 64 of thethermal bridge 10. - Similarly, the
freezer liner 32 includes atransverse portion 92 extending off oftop wall 34 thereof, and leading to anend flange portion 94 which is received in theinner coupling portion 66. Like therefrigerator liner 16, thetransverse portion 92 of thefreezer liner 32 is disposed all the way around theopening 47 of thefreezer liner 32 attop wall 34,bottom wall 36 andopposed side walls end flange portion 94 is also disposed fully around thefreezer liner 32 extending outwardly fromtransverse portion 92, and defining a surface for adhering engagement with thechannel 69A theinner coupling portion 64 of thethermal bridge 10. - Referring now to
FIG. 7 , thelower portion 10C of thethermal bridge 10 is shown having theouter coupling portion 62 disposed below theinner coupling portion 66. Theouter coupling portion 62 is interconnected with theinner coupling portion 66 by thebody portion 70 having theupright portion 72 and thehorizontal portion 74. As shown inFIG. 7 , theinner coupling portion 66 is staggered or offset relative to theouter coupling portion 62 by the distances indicated by arrows D2 and D3. Specifically, in the embodiment shown inFIG. 7 , theinner coupling portion 66 is disposed inward and above theouter coupling portion 62 as disposed on an end of the inwardly projectingextension 74 of thebody portion 70 of thethermal bridge 10. Thus, the staggered configuration of theouter coupling portion 62 and theinner coupling portion 66 is akin to the staggered configuration of theouter coupling portion 62 and theinner coupling portion 64 shown inFIG. 5 . In this way, thefront edge 60 of thewrapper 8 is not only spaced-apart from thefront edge 46 of thefreezer liner 32 so as to be outside of thefront edge 46 of thefreezer liner 32, but is also offset laterally outward from thefront edge 46 of thefreezer liner 32. Similarly, thethermal bridge 10 includes a staggered configuration forouter coupling portion 62 relative to theinner coupling portion 66 for receiving thefront edge 60 of thewrapper 8 and thefront edge 46 of thefreezer liner 32. - Thus, as shown in
FIGS. 5-7 , theend flange portions refrigerator liner 16 and thefreezer liner 32, respectively, are disposed inwardly of theend flange portion 78 of thewrapper 8 given the inwardly projectingextension 74 of thethermal bridge 10. All of theend flange portions FIG. 7 disposed onend flange portion 78 of thewrapper 8. The engagement features 90 shown inFIG. 7 are contemplated to be outwardly extending dimples and may be disposed on both sides of a front edge, such asfront edge 84 of therefrigerator liner 16 shown inFIG. 9 . The dimples may also be positioned on the inner contours of thechannels end flange portions wrapper 8, theliners thermal bridge 10 to ensure that a vacuum can be drawn and maintained in the vacuum cavity VC between thewrapper 8, theliners thermal bridge 10. The engagement features 90 also provide centering features for thefront edges wrapper 8, therefrigerator liner 16 and thefreezer liner 32, to center theedges channels - Referring now to
FIG. 8 , thethermal bridge 10 is shown along theupper portion 10A thereof. In the outwardly openingchannel 68 disposed along the sealingsurface 72 of thethermal bridge 10, aconduit 100 is shown positioned therein. Theconduit 100 comprises a continuous loop oftubing 102 that is routed through the refrigerator 1 (FIG. 1 ) as best shown inFIG. 11 . Theconduit 100 may be referred to as a heat loop, a Yoder loop or a condenser loop, but is not meant to be limited to any one shape or configuration by the term “loop.” Theconduit 100 circulates, or otherwise transports, a heated medium, such as heated refrigerant that is generated by the mechanical equipment 43 (FIGS. 4 and 11 ) when themechanical equipment 43 is cooling thecompartments tubing 102 of theconduit 100 provides for an “anti-sweat” feature to help prevent condensation that can develop when the cold surfaces of thecompartments refrigerator 1 is disposed. This warm and humid air can cause condensation to develop along the sealingsurface 72 of thethermal bridge 10. The circulating warmed refrigerant of theconduit 100 provides a mitigating factor for combatting condensation buildup at the sealingsurface 72. - As specifically shown in
FIG. 8 , theconduit 100 is positioned in the outwardly openingchannel 68 which is configured to extend around an entire perimeter of therefrigerator 1, as best shown inFIG. 11 . Theconduit 100 can be retained in the outwardly openingchannel 68 using an adhesive material. The placement of theconduit 100 in the outwardly openingchannel 68 is provided, such that theconduit 100 can circulate heated refrigerant near theopening 12A into therefrigerator compartment 28. It is contemplated that the outwardly openingchannel 68 and theconduit 100 thereof are positioned about 12 mm from theopening 12A into therefrigerator compartment 28. However, the scope of the present concept is not limited to such an embodiment. - Referring now to
FIG. 9 , theconduit 100 is positioned in the outwardly openingchannel 68 along the side of therefrigerator 1. Anintermediate portion 104 of thetubing 102 of theconduit 100 loops through themullion portion 14 of thethermal bridge 10 alongtrim piece 72C which is connected to the upper and lower outwardly openingchannels portion 104 of theconduit 100 extending across themullion portion 14, theopenings thermal bridge 10 are fully surrounded by theconduit 100, as best shown inFIG. 11 . - Referring now to
FIG. 10 , theconduit 100 is positioned in the outwardly openingchannel 68 which, as noted above, is configured to extend around an entire perimeter of therefrigerator 1, as best shown inFIG. 11 . Theconduit 100 is also shown having areturn portion 107 positioned in araceway 108 formed in thelower portion 10C of thethermal bridge 10. Thereturn portion 107 is contemplated to run theconduit 100 back to the spacing S of therefrigerator 1 where thecooling equipment 43 is housed, as best shown inFIG. 11 . - Referring now to
FIG. 11 , theconduit 100 is positioned in the outwardly opening channel 68 (seeFIGS. 8-10 ) of thethermal bridge 10 around the entirety of therefrigerator 1. Theintermediate portion 104 of thetubing 102 of theconduit 100 is shown covering themullion portion 14 of thethermal bridge 10. Thus, theconduit 100 fully surrounds theopenings thermal bridge 10 which open into therefrigerator compartment 28 and thefreezer compartment 44, respectively. Further, thereturn portion 107 is illustrated as running theconduit 100 back to the spacing S of therefrigerator 1 where thecooling equipment 43, that generates the heated refrigerant for circulation within theconduit 100, is housed. - Referring to
FIGS. 12A-15B , arefrigerator 110 includes acabinet 114 having aninner liner 118 and anexternal wrapper 122. Theinner liner 118 is positioned within theexternal wrapper 122 such that agap 126 is defined between theexternal wrapper 122 andinternal liner 118. Afirst insulator 130 is positioned within thegap 126 and asecond insulator 134 is positioned within thegap 126. A pressure within thegap 126 may be below about 1000 Pa. - Referring now to
FIGS. 12A and 12B , therefrigerator 110 includes thecabinet 114. Therefrigerator 110 may take a variety of configurations including French door, side by side, top freezer, bottom freezer, counter depth, compact, built-in, and other types of refrigerators. Thecabinet 114 includes theinner liner 118, theexternal wrapper 122 and may optionally include ashell 142. In the depicted embodiment, theinner liner 118 has a generally rectangular box shape, but may take a variety of shapes including a cube, prism, parallelepiped, etc. and combinations thereof. Theinner liner 118 may have aliner flange 146 disposed around theinner liner 118 and connected to a plurality ofliner walls 150 which define theinner liner 118. Theinner liner 118 may be formed from a polymeric material having high barrier properties (e.g., low gas permeation), metals and combinations thereof. Theinner liner 118 may be formed via thermoforming, injection molding, bending and/or forming. Theliner walls 150 of theinner liner 118 may have a thickness ranging from between about 0.1 mm to about 3.0 mm. In a specific embodiment, theliner walls 150 have a thickness of about 0.5 mm. - The
inner liner 118 is shaped and configured to mate, couple or otherwise be positioned within theexternal wrapper 122. Theexternal wrapper 122 includes a plurality ofwrapper walls 158 to which awrapper flange 162 is coupled. Thewrapper flange 162 and theliner flange 146 are configured to be coupled when thecabinet 114 is in an assembled configuration. The coupling of theliner flange 146 and thewrapper flange 162 may be performed such that an airtight, or hermetic, seal is formed between theinner liner 118 and theexternal wrapper 122. The hermetic seal of thewrapper flange 162 and theliner flange 146 may be achieved through use of adhesives, welding, an elastomeric gasket under compression and/or crimping. The coupling of theliner flange 146 to thewrapper flange 162 may be performed proximate a front flange area 164 (FIG. 13A ) of thecabinet 114. Thefront flange area 164 may be configured to couple with a door which permits access to an interior of thecabinet 114. - The
external wrapper 122 may be formed of and by any of the materials and processes listed above in connection with theinner liner 118. Thewrapper walls 158 of theexternal wrapper 122 may have a thickness ranging from between about 0.1 mm to about 3.0 mm. In a specific embodiment, thewrapper walls 158 have a thickness of about 0.5 mm. Thewrapper walls 158 of theexternal wrapper 122 may define aninjection port 166 and/or avacuum port 170. Theexternal wrapper 122 may include one ormultiple injection ports 166 and/orvacuum ports 170. Theinjection ports 166 and/orvacuum ports 170 may be positioned as illustrated or in a variety of positions about theexternal wrapper 122. It will be understood that in alternative embodiments, theinjection ports 166 and/orvacuum ports 170 may be disposed on both theexternal wrapper 122 andinner liner 118, or solely on theinner liner 118. Theinjection port 166 and thevacuum port 170 may be used to access (e.g., to inject an insulator, draw a vacuum and/or perform maintenance within) thegap 126 once theinner liner 118 and theexternal wrapper 122 are bonded. Theinjection port 166 and thevacuum port 170 may have a diameter of between about 10 mm and about 50 mm, or between about 12.5 mm and about 25 mm. In various embodiments, theinjection port 166 and thevacuum port 170 may have different diameters than one another. Similarly, in embodiments utilizing more than oneinjection port 166 andvacuum port 170, the sizes of theinjection ports 166 and thevacuum ports 170 may vary. - Referring now to
FIG. 12C , theinner liner 118 and theexternal wrapper 122 may be joined via atrim breaker 172. Thetrim breaker 172 may be formed of a plastic, a metal, a composite and/or insulating materials. Thetrim breaker 172 may define a liner joint 172A configured to couple theinner liner 118 to thetrim breaker 172. Thetrim breaker 172 may also define a wrapper joint 172B configured to couple theexternal wrapper 122 to thetrim breaker 172. The liner joint 172A and the wrapper joint 172B may be vibration welded, crimped, thermally bonded, adhesively bonded or otherwise coupled to render thegap 126 airtight. Thetrim breaker 172 may be used to hold theinner liner 118 and theexternal wrapper 122 together and in place. Use of thetrim breaker 172 may provide advantages of resisting thermal bridging between theinner liner 118 and theexternal wrapper 122 and easing manufacturing. - Referring now to
FIG. 13A , once theinner liner 118 and theexternal wrapper 122 have been joined and thegap 126 defined, thefirst insulator 130 and thesecond insulator 134 may be dispensed into thegap 126. Thegap 126 may have a thickness of between about 12 mm to about 30 mm. Thegap 126 may have an air pressure of less than about 1 atm (101,325 Pa, 1013.25 mbar), less than about 0.5 atm (50,662.5 Pa, 506.63 mbar), less than about 0.1 atm (10,132.5 Pa, 101.33 mbar), less than about 0.001 atm (101.325 Pa, 1.0133 mbar) or less than about 0.00001 atm (1.01 Pa, 0.01 mbar). Over the service life of the refrigerator 110 (FIG. 12A ), the air pressure within thegap 126 may rise more than about 0.001 atm (101 Pa, 1.01 mbar), greater than about 0.005 atm (506 Pa, 5.06 mbar) or greater than about 0.01 atm (1,013 Pa, 10.13 mbar) due to diffusion and/or permeation of gases into thegap 126 through theinner liner 118 and/or theexternal wrapper 122. The first andsecond insulators second insulators second insulators second insulators second insulators second insulators - In embodiments where the first and/or
second insulators second insulators second insulators second insulators second insulators gap 126 and in contact with both thewrapper walls 158 and theliner walls 150. The packing factor of the first and/orsecond insulators gap 126 may be greater than about 60%, greater than about 62%, greater than about 65%, or greater than about 70%. - In embodiments where the first and/or
second insulators gap 126, the fumed silica may have a density between about 50 kg/m3 to about 300 kg/m3, or between about 80 kg/m3 to about 250 kg/m3 or between about 150 kg/m3 to about 200 kg/m3. - The first and
second insulators inner liner 118 from theexternal wrapper 122, but also to resist the inward directed force of the atmosphere on the lower than atmosphere pressure of thegap 126. Atmospheric pressure on theinner liner 118 and theexternal wrapper 122 may cause distortions which are unsightly and may lead to a rupture in either of theinner liner 118 or theexternal wrapper 122 thereby causing a loss of vacuum in thegap 126. Further, drawing the vacuum in thegap 126 may cause an impact or shock loading of the first andsecond insulators inner liner 118 and theexternal wrapper 122 contract around the first andsecond insulators second insulators inner liner 118 and theexternal wrapper 122 due to a pressure gradient between the atmosphere and an air pressure of thegap 126. - The
first insulator 130 may be positioned within, and proximate to, thefront flange area 164 of thecabinet 114 and thesecond insulator 134 may fill the rest of thegap 126. In the depicted embodiment, afilter 174 is positioned between thefirst insulator 130 and thesecond insulator 134. Thefilter 174 may be made of paper, a polymeric material, a ceramic and/or a metal. Thefilter 174 may be porous, solid and/or coupled to theinner liner 118 and/or theexternal wrapper 122. Use of thefilter 174 may resist or prevent the migration and mixing of the first andsecond insulators second insulators front flange area 164, due to its thinner cross section and being surrounded by atmosphere on three sides, may suffer from a thermal, or heat, bridging effect. Such a thermal bridging across thefront flange area 164 may result in an overall reduced efficiency of therefrigerator 110. Accordingly, in various embodiments thefirst insulator 130 may have a higher insulating property than thesecond insulator 134. In such an embodiment, the higher insulating property of thefirst insulator 130 may be sufficient to reduce, or eliminate any thermal bridging taking place through thefront flange area 164. - Referring now to
FIGS. 13A and 13B , as explained above, thegap 126 within thecabinet 114 may undergo a pressure increase over the service life of therefrigerator 110 due to permeation and/or diffusion of gases. As such, selection of the first andsecond insulators gap 126. As can be seen inFIG. 13B , fumed silica undergoes the smallest increase in thermal conductivity over an expected pressure change range (e.g., between about 1 mbar and about 10 mbar), followed by precipitated silica. As such, use of fumed silica as thefirst insulator 130 and precipitated silica and/or combinations of insulators (e.g., precipitated silica and spheres) as thesecond insulator 134 may not only reduce thermal bridging across thefront flange area 164 while thegap 126 is at manufactured pressure, but also over the service life of therefrigerator 110. - Referring now to
FIGS. 14A and 14B , one embodiment of afirst method 180 of inserting the first andsecond insulators gap 126 is depicted. Thefirst method 180 includesstep 184,step 188,step 192,step 194 andstep 196. Instep 184, theinner liner 118 is positioned within theexternal wrapper 122 as explained in greater detail above. Theliner flange 146 and thewrapper flange 162 may be bonded so as to make thegap 126 airtight. Next, step 188 of drawing a vacuum may be performed. A vacuum, or negative pressure relative to atmospheric pressure, is generated within thegap 126. The vacuum is created by drawing the air out of thegap 126 through the at least onevacuum port 170. A pump or other suitable vacuum sources may be connected to thevacuum port 170 to facilitate drawing the vacuum. Additionally or alternatively, thefirst method 180, or any of its steps, may be performed within avacuum chamber 198 to provide the vacuum to thegap 126. - Next, step 192 of injecting the
first insulator 130 into thegap 126 is performed. Injection of thefirst insulator 130 into thegap 126 may be accomplished by feeding thefirst insulator 130 into ahopper 200 which in turn supplies thefirst insulator 130 to atransfer mechanism 204. Thetransfer mechanism 204 may be a powder pump, a vacuum transfer device, pneumatic pump, flexible screw conveyor, auger feeder and/or other devices capable of transferring or moving the first andsecond insulators transfer mechanism 204 pumps or otherwise injects thefirst insulator 130 into thegap 126 of the cabinet 114 (FIG. 12A ). Thetransfer mechanism 204 may utilize fluidization of thefirst insulator 130 to move thefirst insulator 130 into thegap 126. Thetransfer mechanism 204 may dispense thefirst insulator 130 into thecabinet 114 with or without pressure. Use of thetransfer mechanism 204 allows thefirst insulator 130 to be inserted into thegap 126 without any densification or compaction, while also providing an easy and efficient means of inserting thefirst insulator 130. Once thefirst insulator 130 has sufficiently filled thefront flange area 164 of thecabinet 114 and optionally been leveled off, thefilter 174 may be placed on top of thefirst insulator 130 and optionally coupled to theinner liner 118 andexternal wrapper 122. Next, step 194 of injecting thesecond insulator 134 is performed. Injection of thesecond insulator 134 may be performed in substantially the same manner as injection of thefirst insulator 130 is carried out instep 192. In other embodiments, thesecond insulator 134 may be dispensed or injected under different conditions that produce a different packing factor or density of thesecond insulator 134 relative to thefirst insulator 130. - Next, step 196 of vibrating at least one of the
inner liner 118 and theexternal wrapper 122 is performed. Vibration of theinner liner 118 and/or theexternal wrapper 122 may cause thefirst insulator 130 to increase its packing factor. Duringsteps inner liner 118 and/orexternal wrapper 122 may be supported by one ormore supports 206 such that relative motion between theinner liner 118 and theexternal wrapper 122 is minimized or prevented. Thesupports 206 may allow the thickness of thegap 126 to remain constant through filling and vibration. It will be understood that althoughmethod 180 was described in a specific order, the steps may be performed in any order or simultaneously without departing from the spirit of this disclosure. - Referring now to
FIGS. 15A and 15B , depicted is asecond method 208 of dispensing theinsulator 130 within thegap 126 between theinner liner 118 and theexternal wrapper 122. Thesecond method 208 includesstep 212,step 216,step 218,step 220 andstep 224. Thesecond method 208 begins withstep 212 of positioning theinner liner 118 within theexternal wrapper 122 and sealing thegap 126, as disclosed above.Next step 216 of dispensing thefirst insulator 130 within thegap 126 is performed. In thesecond method 208, dispensing of thefirst insulator 130 into thegap 126 may be accomplished through aback aperture 232. Theback aperture 232 may take a variety of shapes (e.g., square, rectangular, circular, oblong, and combinations thereof) and sizes which are configured to allow thefirst insulator 130 to be poured or otherwise dispensed into thegap 126. Thefirst insulator 130 may be dispensed into thegap 126 between theinner liner 118 and theexternal wrapper 122 via the transfer mechanism 204 (FIG. 14A ), pouring thefirst insulator 130, or manual application. In embodiments of the cabinet 114 (FIG. 12A ) where theexternal wrapper 122 includes theback aperture 232, theexternal wrapper 122 may not include the injection port 166 (FIG. 14A ). Optionally,step 216 may be performed while at least one of theinner liner 118 and theexternal wrapper 122 are vibrated. Vibration of theinner liner 118 and/or theexternal wrapper 122 may facilitate in shaking or vibrating thefirst insulator 130 into its maximum packing factor and facilitate a more complete filling of thegap 126. Optionally, once thefront flange area 164 is sufficiently filled with thefirst insulator 130 and optionally thefirst insulator 130 has been leveled off, thefilter 174 may be placed on thefirst insulator 130 as described above. - Once the
front flange area 164 of thegap 126 between theinner liner 118 and theexternal wrapper 122 is filled with thefirst insulator 130 and sufficiently packed with thefirst insulator 130, step 218 of dispensing thesecond insulator 134 is performed. Dispensing of thesecond insulator 134 may be accomplished in a substantially similar manner to that described in connection with thefirst insulator 130 instep 216. Next, step 220 of positioning aback plate 242 over theback aperture 232 is performed. Theback plate 242 may be constructed of the same or similar material as theexternal wrapper 122, or a different material. Once theback plate 242 is positioned over theback aperture 232, theback plate 242 is sealed to theexternal wrapper 122 to form an airtight, or hermetic, seal. Afterstep 220 is completed, step 224 of drawing a vacuum within thegap 126 is performed. The vacuum may be drawn through the vacuum port 170 (FIG. 14A ) of theexternal wrapper 122. Additionally or alternatively,method 208, or individual steps thereof, may be performed within thevacuum chamber 198 such that drawing a vacuum may not be necessary, or less vacuum can be drawn. Further, thesecond method 208 may utilize the supports 106 to resist relative motion of theinner liner 118 and theexternal wrapper 122. It will be understood that steps of the first andsecond methods - Use of the present disclosure may offer several advantages. For example, use of the present disclosure allows for the formation of vacuum insulated
cabinets 114, panels, and structures without noticeable deformation of theinner liner 118 and theexternal wrapper 122. By filling thegap 126, deformation of theinner liner 118 and theexternal wrapper 122 from the pressure differential between the atmosphere and thegap 126 is resisted by the first andsecond insulators insulated cabinets 114, panels and structures may provide enhanced insulative properties as compared to traditional foam filled insulating structures in addition to a reduced size (e.g., thickness decrease of greater than about 55%, 60% or 70%). Additionally, use of the disclosure may allow for the construction of a lessdense cabinet 114 while also providing increased rigidity due to the use of the first andsecond insulators first insulator 130 in more critical insulation areas (e.g., in thefront flange area 164, in corners and/or thin locations) and thesecond insulator 134 in the rest of thecabinet 114 may allow for a cost savings in embodiments where thefirst insulator 130 is more expensive (e.g., fumed silica) than the second insulator 134 (e.g., precipitated silica). Even further, in embodiments where thefirst insulator 130 has a lower increase in thermal conductivity per unit pressure increase than thesecond insulator 134, use of thefirst insulator 130 proximate thefront flange area 164 allows for a greater resistance to thermal bridging as the pressure within thegap 126 increases over the service life of therefrigerator 110. It will be understood that although the disclosure was described in terms of a refrigerator, the disclosure may equally be applied to coolers, ovens, dishwashers, laundry applications, water heaters, household insulation systems, ductwork, piping insulation, acoustical insulation and other thermal and acoustical insulation applications. - It will be understood that any described processes or steps within described processes may be combined with other disclosed processes or steps to form structures within the scope of the present device. The exemplary structures and processes disclosed herein are for illustrative purposes and are not to be construed as limiting.
- It is also to be understood that variations and modifications can be made on the aforementioned structures and methods without departing from the concepts of the present device, and further it is to be understood that such concepts are intended to be covered by the following claims unless these claims by their language expressly state otherwise.
- The above description is considered that of the illustrated embodiments only. Modifications of the device will occur to those skilled in the art and to those who make or use the device. Therefore, it is understood that the embodiments shown in the drawings and described above is merely for illustrative purposes and not intended to limit the scope of the device, which is defined by the following claims as interpreted according to the principles of patent law, including the Doctrine of Equivalents.
Claims (17)
1. A refrigerator comprising:
a wrapper having a wall portion and a flange portion with a transverse portion disposed therebetween, wherein the flange portion of the wrapper extends outwardly in a forward direction from the transverse portion of the wrapper and is substantially parallel to the wall portion of the wrapper;
a liner spaced-apart from the wrapper to define a vacuum insulated cavity therebetween, wherein the liner includes a wall portion and a flange portion with a transverse portion disposed therebetween, wherein the transverse portion of the liner is an angled portion extending outwardly towards the wrapper, and further wherein the flange portion of the liner extends outwardly in a forward direction from the transverse portion of the liner and is substantially parallel to the wall portion of the liner, and further wherein the transverse portion of the wrapper is an angled portion extending inwardly towards the liner;
a thermal bridge having a first channel, a second channel and a third channel, wherein a portion of the flange portion of the wrapper is received in the first channel, and further wherein a portion of the flange portion of the liner is received in the second channel; and
a conduit received in the third channel, wherein the conduit is configured to circulate a heated medium around a perimeter of the refrigerator.
2. The refrigerator of claim 1 , wherein the first and second channels of the thermal bridge are spaced-apart from one another.
3. The refrigerator of claim 2 , wherein the first and second channels are rearwardly opening channels.
4. The refrigerator of claim 3 , wherein the third channel is a forwardly opening channel.
5. The refrigerator of claim 4 , wherein the thermal bridge includes an upper opening and a lower opening with a mullion portion disposed therebetween.
6. The refrigerator of claim 5 , wherein the conduit surrounds the upper and lower openings of the thermal bridge.
7. The refrigerator of claim 4 , wherein the thermal bridge includes a sealing surface, and further wherein the third channel is disposed along the sealing surface.
8. The refrigerator of claim 7 , wherein the first channel is inset from the sealing surface a first distance and the second channel is inset from the sealing surface a second distance that is greater than the first distance.
9. A refrigerator comprising:
a liner received within a cavity of a wrapper to define a vacuum insulated cavity therebetween, wherein the wrapper and the liner each include a wall portion and a flange portion with an angled transverse portion disposed therebetween, wherein the transverse portion of the wrapper is angled inwardly towards the liner, wherein the transverse portion of the liner is angled outwardly towards the wrapper, and further wherein the flange portion of the wrapper extends further in a forward direction than the flange portion of the liner; and
a thermal bridge interconnecting the wrapper and liner and having first and second channels, wherein a portion of the flange portion of the wrapper is received in the first channel, and further wherein a portion of the flange portion of the liner is received in the second channel.
10. The refrigerator of claim 9 , wherein the first and second channels are rearwardly opening channels.
11. The refrigerator of claim 10 , wherein the thermal bridge includes a sealing surface, and further wherein the first channel is inset from the sealing surface a first distance and the second channel is inset from the sealing surface a second distance that is greater than the first distance.
12. The refrigerator of claim 11 , wherein the thermal bridge includes a third channel disposed along the sealing surface.
13. The refrigerator of claim 12 , wherein the third channel is a forwardly opening channel.
14. The refrigerator of claim 13 , including:
a conduit received in the third channel, wherein the conduit is configured to circulate a heated medium around a perimeter of the refrigerator.
15. The refrigerator of claim 9 , wherein the thermal bridge is comprised of a material having a lower coefficient of thermal conductivity as compared to the sheet metal material of the wrapper and the liner.
16. The refrigerator of claim 15 , including:
an adhesive disposed within the first channel to adhere the flange portion of the wrapper to the thermal bridge in an airtight manner for retaining a vacuum in the vacuum insulated cavity.
17. The refrigerator of claim 16 , including:
an adhesive disposed within the second channel to adhere the flange portion of the liner to the thermal bridge in an airtight manner for retaining the vacuum in the vacuum insulated cavity.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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US18/644,741 US20240271859A1 (en) | 2015-12-09 | 2024-04-24 | Vacuum insulated structure with thermal bridge breaker with heat loop |
Applications Claiming Priority (8)
Application Number | Priority Date | Filing Date | Title |
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US201562265055P | 2015-12-09 | 2015-12-09 | |
PCT/US2016/063966 WO2017100037A1 (en) | 2015-12-09 | 2016-11-29 | Vacuum insulation structures with multiple insulators |
PCT/US2017/063947 WO2019108204A1 (en) | 2017-11-30 | 2017-11-30 | Vacuum insulated structure with thermal bridge breaker with heat loop |
US201815776276A | 2018-05-15 | 2018-05-15 | |
US202016757790A | 2020-04-21 | 2020-04-21 | |
US17/037,855 US11555643B2 (en) | 2015-12-09 | 2020-09-30 | Vacuum insulation structures with multiple insulators |
US17/208,082 US11994336B2 (en) | 2015-12-09 | 2021-03-22 | Vacuum insulated structure with thermal bridge breaker with heat loop |
US18/644,741 US20240271859A1 (en) | 2015-12-09 | 2024-04-24 | Vacuum insulated structure with thermal bridge breaker with heat loop |
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US17/208,082 Continuation US11994336B2 (en) | 2015-12-09 | 2021-03-22 | Vacuum insulated structure with thermal bridge breaker with heat loop |
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US20240271859A1 true US20240271859A1 (en) | 2024-08-15 |
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US18/644,741 Pending US20240271859A1 (en) | 2015-12-09 | 2024-04-24 | Vacuum insulated structure with thermal bridge breaker with heat loop |
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