CN218348777U - Air-conditioning smoke machine - Google Patents

Abstract

The utility model relates to an air conditioner cigarette machine includes air conditioner structure and cigarette machine structure. The air conditioning structure comprises a shell, a flow dividing piece, an evaporation assembly and a condensation assembly. The housing includes a front plate and a back plate disposed opposite to each other in a front-rear direction, and the front plate and the back plate are used together to define an inner space of the housing. The evaporation assembly and the condensation assembly are sequentially arranged in the inner space along the front-back direction. The flow dividing piece is arranged between the evaporation assembly and the condensation assembly and used for respectively guiding the air entering the inner space to the evaporation assembly and the condensation assembly. According to the air-conditioning range hood, the evaporation assembly and the condensation assembly of the air-conditioning structure are integrated in the same shell, and the air flow required by the evaporation assembly and the condensation assembly is formed by separating air entering the inner space of the shell under the action of the flow dividing piece. The design that integrates more can improve the utilization ratio of inner space effectively, improves the compactness of air conditioner structure, and then does benefit to the overall dimension of control air conditioner cigarette machine, makes it satisfy in wider mounting dimension requirement.

Description

Air-conditioning smoke machine

Technical Field

The utility model relates to a kitchen equipment technical field especially relates to an air conditioner cigarette machine.

Background

With the improvement of the requirements of people on living quality, the air-conditioning smoke machine is more and more widely used in kitchens. The air conditioner cigarette machine not only can be taken away the oil smoke that the culinary art produced, purifies the kitchen environment, can also adjust the temperature in kitchen, improves the culinary art of user in the kitchen and experiences.

In the conventional technology, a condenser and an evaporator of an air-conditioning structure in an air-conditioning range hood usually respectively need to occupy a certain installation space. However, limited to kitchen space, especially the space where the cooking bench is located, the space for installing the air conditioning cigarette machine is often very limited, and the limited space needs to accommodate both the air conditioning structure and the cigarette machine structure. Therefore, on the premise of not changing the structural size of the range hood, if the air conditioner is too large in structural size, the requirement on the installation condition of the air conditioner range hood can be improved, and the application range of the air conditioner range hood is reduced.

SUMMERY OF THE UTILITY MODEL

In view of the above, there is a need to provide an air-conditioning cigarette machine with a more compact structure.

An air-conditioned range hood, comprising:

a cigarette machine structure; and

the air conditioning structure comprises a shell, a flow dividing piece, an evaporation assembly and a condensation assembly, wherein the shell comprises a front plate and a back plate which are oppositely arranged along the front-back direction, and the front plate and the back plate are jointly used for defining the inner space of the shell; the evaporation assembly and the condensation assembly are sequentially arranged in the inner space along the front-back direction; the flow dividing piece is arranged between the evaporation assembly and the condensation assembly and used for respectively guiding the air entering the inner space to the evaporation assembly and the condensation assembly.

In one embodiment, the air conditioning structure further comprises a base for carrying the evaporation assembly, the base enclosing a cavity for guiding air to the condensation assembly.

In one embodiment, the base comprises a bearing plate and two supporting end plates, the bearing plate is used for bearing the evaporation assembly, the two supporting end plates are oppositely arranged at two ends of the bearing plate in the width direction intersecting with the front-back direction, and the bearing plate and the supporting end plates surround to form the cavity;

wherein, the support end plate is provided with an air inlet.

In one embodiment, the flow dividing member and the base are sequentially disposed between the evaporation assembly and the condensation assembly in a height direction intersecting the front-rear direction.

In one embodiment, the housing further comprises a top plate connected to top sides of the front plate and the back plate, the top plate having an air inlet portion through which air enters the inner space;

and an air outlet communicated with the inner space is formed in the front plate.

In one embodiment, the evaporation assembly comprises a cross flow wind wheel and an air duct shell, the cross flow wind wheel is installed in the air duct shell, and the air duct shell is communicated with the air outlet;

and the cross flow wind wheel forms cross flow wind flowing from the air inlet part to the air outlet in the air duct shell.

In one embodiment, the evaporation assembly further comprises an evaporation heat exchanger, and the evaporation heat exchanger is arranged on the peripheral side of the cross flow wind wheel and is positioned on the wind path of the cross flow wind between the air inlet part and the cross flow wind wheel.

In one embodiment, the evaporation assembly further comprises an outer cover, the outer cover is arranged on the surface of the evaporation heat exchanger, which is back to the cross-flow wind wheel, and is provided with an air inlet.

In one embodiment, the air conditioning structure further comprises a wind sweeping assembly, and the wind sweeping assembly is arranged at the wind outlet and used for controllably changing the direction of the airflow at the wind outlet.

In one embodiment, the cigarette machine structure is provided with a cigarette machine cavity channel and a centrifugal fan arranged in the cigarette machine cavity channel, the centrifugal fan is provided with an air suction port and an air exhaust port, and the top plate is further provided with a smoke exhaust hole communicated with the air exhaust port.

According to the air-conditioning range hood, the evaporation assembly and the condensation assembly of the air-conditioning structure are not completely separated from two independent components, but are integrated in a shell together, and the airflow required by the evaporation assembly and the condensation assembly is formed by separating air entering the inner space of the shell under the action of the flow dividing component. The more integrated design can effectively improve the utilization rate of the inner space and the compactness of the air-conditioning structure, thereby being beneficial to controlling the whole size of the air-conditioning range hood and meeting the requirement of the installation size in a wider range. In addition, compared with the mode that the evaporation assembly and the condensation assembly are arranged up and down, the mode of front and back arrangement can more effectively utilize the space of the air conditioner of the range hood in the front and back direction, namely the thickness direction of the machine body, and the height size of the whole machine is reduced. Compared with the left and right arrangement mode, the front and back arrangement mode can enable the evaporation assembly in front to obtain a wide outward blowing range under the same width size, so that the air outlet is more dispersed and soft.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the embodiments or the prior art descriptions will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a schematic structural view of an air-conditioning range hood according to an embodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of the air conditioning cigarette machine shown in FIG. 1;

FIG. 3 is a partial exploded view of the air conditioning structure of the air conditioning cigarette machine shown in FIG. 2;

fig. 4 is another angular structure diagram of the base of the air conditioning structure shown in fig. 3.

Description of reference numerals: 100. an air-conditioning smoke machine; 10. an air conditioning structure; 11. a housing; 111. a front plate; 112. a back plate; 113. a top plate; 114. a base plate; 115. a side plate; 12. a flow splitter; 13. an evaporation assembly; 131. a cross flow wind wheel; 133. an air duct housing; 1351. a motor; 1353. a motor fixing frame; 1355. a bearing; 137. an evaporative heat exchanger; 1371. evaporating fins; 1373. a housing; 1375. a fin fixing frame; 15. a condensing assembly; 151. a condensing heat exchanger; 153. a condensing fan; 17. a base; 171. carrying a plate; 173. supporting the end plate; 175. reinforcing ribs; 19. a wind sweeping assembly; 20. a cigarette machine structure; 21. a centrifugal fan; z, an interior space; J. an air inlet part; C. an air outlet; y, smoke machine cavity channel; p, smoke exhaust holes; K. an air passing port; q, a cavity; s, air inlet holes.

Detailed Description

In order to make the above objects, features and advantages of the present invention more comprehensible, embodiments of the present invention are described in detail below with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, as those skilled in the art will be able to make similar modifications without departing from the spirit and scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", and the like, indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or to implicitly indicate the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one of the feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless explicitly defined otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be interconnected within two elements or in a relationship where two elements interact with each other unless otherwise specifically limited. The specific meaning of the above terms in the present invention can be understood according to specific situations by those of ordinary skill in the art.

In the present application, unless expressly stated or limited otherwise, the first feature may be directly on or directly under the second feature or indirectly via intermediate members. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Referring to fig. 1 and 2, an embodiment of the present invention provides an air-conditioning range hood 100, which includes an air-conditioning structure 10 and a range hood structure 20, wherein the air-conditioning structure 10 is used to sweep cool air or hot air to adjust the temperature of the external environment, and the range hood structure 20 is located below the air-conditioning structure 10 for sucking the oil smoke generated by cooking below and condensing the sucked oil smoke into liquid oil drops or directly discharging the liquid oil drops to the outside. The air conditioning structure 10 and the range hood structure 20 are arranged in sequence in the height direction, and the air conditioning structure 10 is located above the range hood structure 20.

The air conditioning structure 10 includes a housing 11, a flow divider 12, an evaporation assembly 13, and a condensation assembly 15. The housing 11 includes a front plate 111 and a back plate 112 arranged oppositely in the front-rear direction, and the front plate 111 and the back plate 112 collectively define an internal space Z of the housing 11. The evaporation unit 13 and the condensation unit 15 are sequentially arranged in the inner space Z in the front-rear direction. The flow divider 12 is disposed between the evaporation assembly 13 and the condensation assembly 15, and is configured to guide the air entering the internal space Z to the evaporation assembly 13 and the condensation assembly 15, respectively.

The front-back direction is the thickness direction of the whole air-conditioning range hood 100, and corresponds to the X direction in fig. 1 and 2. Specifically, after the air-conditioning cigarette machine 100 is installed, the front panel 111 is located at an outer position, the outer surface of the front panel faces an indoor space, the back panel 112 is located further inward, and the outer surface of the front panel faces an inner structure such as a wall. The evaporation assembly 13 and the condensation assembly 15 are sequentially arranged in the internal space Z in the front-rear direction, wherein the evaporation assembly 13 is located in the front, and the condensation assembly 15 is located in the rear, and exchanges heat with the airflow guided by the flow dividing member 12. In addition, it is understood that the air conditioning structure 10 generally needs to include a compressor, a throttling device, etc. for normal functions, and will not be described herein.

In the air-conditioning cigarette machine 100, the evaporating component 13 and the condensing component 15 of the air-conditioning structure 10 are not completely separated to form two independent components, but are jointly integrated in the shell 11, and the airflow required by the evaporating component 13 and the condensing component 15 is formed by separating air entering the inner space Z of the shell 11 under the action of the flow dividing component 12. The more integrated design can effectively improve the utilization rate of the internal space Z and the compactness of the air-conditioning structure 10, thereby being beneficial to controlling the overall size of the air-conditioning range hood and meeting the requirement of the installation size in a wider range. In addition, compared with the way that the evaporation component 13 and the condensation component 15 are arranged up and down, the way of arranging front and back can more effectively utilize the space of the air conditioner smoke exhauster 100 in the front and back direction, namely the thickness direction of the machine body, and reduce the height size of the whole machine. Compared with the left-right arrangement mode, the front-back arrangement mode can enable the evaporation assembly 13 in front to obtain a wide outward blowing range under the same width size, and the air outlet is more dispersed and soft.

Referring to fig. 3, the housing 11 further includes a top plate 113 connected to the top sides of the front plate 111 and the back plate 112, and the top plate 113 is provided with an air inlet portion J through which air enters the inner space Z of the housing 11. An air outlet C communicating with the inner space Z is provided in the front plate 111. In addition, the housing 11 further includes a bottom plate 114 connected to the bottom sides of the front plate 111 and the rear plate 112. The bottom plate 114 is disposed opposite to the top plate 113 in the height direction.

The flow dividing member 12 is disposed near the air inlet portion J so as to guide the air entering from the air inlet portion J to the evaporation assembly 13 and the condensation assembly 15, respectively. The air inlet portion J is a plurality of apertures arranged on the top plate 113, so that on one hand, sufficient air inlet can be ensured when the number of the apertures is enough, and on the other hand, the apertures can also simply filter the air, thereby avoiding the large-volume sundries from entering the air-conditioning structure 10.

The surface of front bezel 111 is towards the interior space, and evaporation subassembly 13 also sets up in the position department that is close to front bezel 111 more, sets up air outlet C at front bezel 111 and can shorten evaporation subassembly's air-out journey as far as possible, is favorable to evaporation subassembly 13 air-out, reduces wind power loss. The air inlet portion J is disposed on the top plate 113, on one hand, since the two sides of the air-conditioning cigarette machine 100 are usually required to be matched or attached to a cabinet, a wall surface and the like after installation, sufficient air inlet is not easy to be realized, on the other hand, since the air inlet portion J on the top is far away from a smoke inlet of the cigarette machine structure 20, air is relatively clean, and smooth and continuous through-flow air is easy to form between the air inlet portion J on the top and the air outlet C on the front plate 111.

It is understood that the housing 11 should further include side panels 115 at two sides, and the front panel 111, the back panel 112, the top panel 113 and the bottom panel 114 together enclose an internal space Z of the housing 11, so that the internal space Z of the housing 11 can form a complete and relatively closed cavity for bearing and mounting various components.

Furthermore, the cigarette machine structure 20 is provided with a cigarette machine cavity Y and a centrifugal fan 21 arranged in the cigarette machine cavity Y, wherein the centrifugal fan 21 is provided with an air suction port and an air exhaust port, and air flow can be sucked in from the air suction port and then discharged from the air exhaust port during operation. Correspondingly, the top plate 113 is further provided with a smoke exhaust hole P communicated with the exhaust port of the centrifugal fan 21, and the oil smoke sucked by the centrifugal fan 21 through the air suction port is exhausted from the exhaust port through the smoke exhaust hole P.

Furthermore, the evaporation assembly 13 includes a cross flow wind wheel 131 and an air duct housing 133, the cross flow wind wheel 131 is installed in the air duct housing 133, and the air duct housing 133 is communicated with the air outlet C. The cross flow wind wheel 131 forms cross flow wind flowing from the wind inlet part J to the wind outlet C in the wind channel shell 133

When the cross flow wind wheel 131 rotates at a high speed, an eccentric vortex can be generated under the restriction of the air duct housing 133, and then cross flow wind is generated along a set route. The duct housing 133 is connected to the air outlet C, so that the cross-flow air flows toward the air outlet C along the air inlet portion J of the top plate 113.

The cross-flow wind wheel 131 can be used for generating a transverse airflow when rotating, and it can be understood that the cross-flow wind wheel 131 is transversely arranged in the inner space Z, that is, the longitudinal direction of the cross-flow wind wheel 131 is consistent with the width direction of the air conditioning structure 10. The cross flow wind generated by the cross flow wind wheel 131 can fully utilize the width of the air conditioning structure 10 in the transverse direction, and the cross wind with a wide coverage can be obtained only by arranging a proper air outlet C on the front plate 111. Compared with an ordinary fan, the coverage is greatly improved, the air outlet is more dispersed and soft, and the experience feeling is good.

Specifically, the evaporation assembly 13 further includes a motor 1351 and a motor fixing frame 1353, and the motor 1351 is in transmission connection with one end of the cross-flow wind wheel 131 and is fixedly connected to the air duct housing 133 through the motor fixing frame 1353. The other end of the cross flow wind wheel 131 is rotatably connected to the air duct housing 133 through a bearing 1355, and a buffer rubber ring is arranged between the bearing 1355 and the air duct housing 133.

The motor 1351 is controlled to drive the cross-flow wind wheel 131 to rotate around the axial direction of the cross-flow wind wheel, one end of the cross-flow wind wheel 131, far away from the motor 1351, can rotate relative to the air duct shell 133 through a bearing 1355, and vibration during rotation is reduced through a buffer rubber ring, so that operation noise is reduced. The cross flow wind wheel 131 can be provided with a shaft hole along the axis of the cross flow wind wheel, and the output shaft of the motor 1351 is arranged in the shaft hole to form transmission connection with the cross flow wind wheel.

In some embodiments, the evaporation assembly 13 further includes an evaporation heat exchanger 137, and the evaporation heat exchanger 137 is disposed on the peripheral side of the cross flow wind wheel 131 and on the wind path of the cross flow wind between the air inlet portion J and the cross flow wind wheel 131.

The evaporation heat exchanger 137 is composed of a plurality of evaporation fins 1371, the evaporation fins 1371 are circumferentially arranged on the periphery of the cross flow wind wheel 131, and when the cross flow wind wheel 131 rotates at a high speed to generate cross flow wind, the cross flow wind can flow through the evaporation fins 1371 arranged on the wind path, and perform sufficient heat exchange with the cross flow wind.

Further, the evaporation assembly 13 further includes an outer cover 1373 and a fin fixing frame 1375, the outer cover 1373 is covered on the surface of the evaporation heat exchanger 137 facing away from the cross flow wind wheel 131, and an air inlet J is formed in the outer cover. The fin fixing bracket 1375 is connected to one end of the evaporation heat exchanger 137, and is used to fix the evaporation heat exchanger 137.

The shape of the outer cover 1373 should match the shape of the evaporating heat exchanger 137, and there should be a gap between the outer cover and the evaporating heat exchanger 137, and there should be a one-to-one correspondence relationship between the air passing opening K and the evaporating fins 1371. Outside air gets into through air inlet portion J earlier, and the leading-in evaporation fin 1371 that carries out the heat transfer through wind gap K again, and through the guide of wind gap K, the air current can accurately flow to and pass evaporation fin 1371, reaches abundant heat transfer's purpose. The fixed frame is matched with the air duct shell 133, a bearing 1355 is reserved between the fixed frame and the air duct shell, and the fixed frame and the air duct shell compress the buffer rubber ring up and down.

Further, the condensing assembly 15 further includes a condensing heat exchanger 151 and a condensing fan 153, and under the action of the condensing fan 153, the air flow enters from the air inlet portion J of the top plate 113 and passes through the condensing heat exchanger 151 under the guidance of the splitter plate 12 to exchange heat with the air flow. The bottom plate is provided with a heat exhaust port communicated with a smoke machine cavity Y in the smoke machine structure, air flow after heat exchange with the condensing heat exchanger 151 is blown into the smoke machine cavity Y through the heat exhaust port by the condensing fan 153, sucked by an air suction port of the centrifugal fan 21 along with oil smoke in the smoke machine cavity Y and exhausted along the smoke exhaust hole P through an exhaust port. In this embodiment, the condensing fan 153 is a centrifugal fan, which also has an air inlet and an air outlet, and the air outlet is connected to an air outlet, and when the condensing fan operates, the condensing fan can drive airflow to enter the air inlet from the air inlet portion J, flow through the condensing heat exchanger 151, then enter the air inlet, and finally blow the airflow to the smoke machine cavity Y from the air outlet through the air outlet.

Referring also to fig. 4, in some embodiments, the air conditioning structure 10 further includes a base 17 for carrying the evaporation element 13, the base 17 enclosing to form a cavity Q for guiding air to the condensation element 15. The base 17 is disposed on the bottom plate 114.

The cavity Q can be used to guide air to the condensing assembly 15 for heat exchange therewith, so as to effectively improve the space utilization rate in the housing 11 and fully utilize part of the space occupied by the base 17. The condensing heat exchanger 151 is vertically disposed behind the base 17, and the air in the cavity Q can cool and dissipate the lower end of the condensing heat exchanger 151. In addition, the cavity Q may also be used for mounting other components.

Further, the base 17 includes a bearing plate 171 for bearing the evaporation assembly 13 and two supporting end plates 173, the two supporting end plates 173 are oppositely disposed at two ends of the bearing plate 171 in the width direction intersecting with the front-back direction, and the bearing plate 171 and the supporting end plates 173 surround to form a cavity Q.

The bearing plate 171 directly bears the air duct housing 133, which is located below the air duct housing 133 and has a shape matching the shape of the air duct housing 133. Since the duct housing 133 needs to form an airflow flowing to the air outlet C, it is arc-shaped. Accordingly, the carrier plate 171 is also arc-shaped. The cavity Q is formed below the bearing plate 171, and it is apparent that the cavity Q formed by the bearing plate 171 facing the air duct housing 133 and the support end plates 173 at both ends has an opening facing the condensing unit 15, through which air can flow toward the condensing unit 15.

Further, the support end plate 173 is opened with an air inlet hole S.

There is the clearance between support end plate 173 and the curb plate 115, and the air current can be under the traction of condensation fan 153 via getting into cavity Q by inlet port S in order to cool off the lower extreme of condensation heat exchanger 151 and dispel the heat, improves the radiating effect and the heat exchange efficiency of condensation heat exchanger 151, promotes condensation assembly 15 whole operating efficiency then.

Further, the surface of the bearing plate 171 facing the cavity Q is configured with at least one rib 175.

The bearing plate 171 has a bearing function, so that a certain requirement exists for the structural strength, and the reinforcing ribs 175 can effectively improve the structural strength of the bearing plate 171 on the premise that the size of the cavity Q is not influenced as much as possible.

In some embodiments, the flow dividing member 12 and the base 17 are sequentially arranged between the evaporation assembly 13 and the condensation assembly 15 in a height direction intersecting with the front-rear direction.

The flow dividing piece 12 is located above the condensation heat exchanger 137, the base 17 is located below the condensation heat exchanger 151, and the flow dividing piece 12 and the base 17 jointly separate the evaporation assembly 13 from the condensation assembly 15 in the front-back direction to form two relatively independent air ducts, so that the mutual interference between the air flow flowing to the evaporation heat exchanger 137 and the air flow flowing to the condensation heat exchanger 151 is avoided.

Further, the flow divider 12 is plate-shaped, a first end of the flow divider is fixed at the upper end of the base 17, a second end of the flow divider extends toward the top plate 113, and the air entering from the air inlet portion J of the top plate 113 is divided by the flow divider 12 to form two air flows blowing downward to the evaporation assembly 13 and the condensation assembly 15 along two sides of the flow divider 12.

In this embodiment, the first end of the flow divider 12 is connected to the housing 1373, the second end opposite to the first end in the height direction extends toward the top plate 113, and the second end is closer to the front plate 111 than the first end. The second end of the flow divider 12 is inclined near the front plate 111, which may increase the space at the upper end of the condensing heat exchanger 151, thereby facilitating heat dissipation thereof. The splitter 12 is located entirely above the duct housing 133 and the base 17 is located below the duct housing 133. It is understood that in other embodiments, the extension range of the splitter 12 can be adjusted adaptively, the first end is connected to the duct housing 133 or extends downward to be directly connected to the base 17, etc., and the distance between the second end and the top plate 113 can also be adjusted adaptively, so that only the air entering the inner space Z is respectively guided and prevented from interfering with each other, which is not limited herein.

Referring to fig. 1 again, in some embodiments, the air conditioning structure 10 further includes a wind sweeping assembly 19, and the wind sweeping assembly 19 is disposed at the wind outlet C and is used for controllably changing the direction of the airflow at the wind outlet C.

The direction of the air flow can be changed by the wind sweeping assembly 19, including but not limited to up-down direction, left-right direction, etc., which can be realized by being driven by a driver, or manually controlled and adjusted by a user, etc., and is not limited in detail herein. Sweep wind subassembly 19 and can change the air-out angle, enlarge air-out coverage, help improving user experience.

The air conditioning structure 10 is driven by the high-speed rotation of the cross flow wind wheel 131 and the condensing fan 153, respectively, and the airflow enters the inner space Z of the housing 11 from the air inlet portion J of the top plate 113, and is divided by the dividing member 12, so as to form two airflows blowing downward to the evaporation assembly 13 and the condensing assembly 15 along two sides of the dividing member 12, respectively. The airflow blowing to the evaporation assembly 13 forms through-flow wind flowing to the air outlet C under the action of the through-flow wind wheel 131, exchanges heat with the evaporation heat exchanger 137 in the flowing process, is finally blown to the indoor after being adjusted by the wind sweeping assembly 19, and adjusts the ambient temperature. The air flow blown to the condensing assembly 15 passes through the condensing heat exchanger 151 and exchanges heat therewith by the condensing fan 153. The air flow after heat exchange is blown to the smoke machine cavity channel Y by the condensing fan 153 through the heat exhaust port of the bottom plate, then flows to be sucked by the centrifugal fan 21 through the air suction port, and is exhausted outdoors through the exhaust port of the centrifugal fan 21 through the smoke exhaust hole P.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the concept of the present invention, several variations and modifications can be made, which all fall within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. An air-conditioned range hood (100), the air-conditioned range hood (100) comprising:

a range hood construction (20); and

air conditioning structure (10) comprising a casing (11), a flow divider (12), an evaporation assembly (13) and a condensation assembly (15), said casing (11) comprising a front panel (111) and a back panel (112) arranged opposite one another in a front-to-rear direction, said front panel (111) and said back panel (112) being jointly used to delimit an internal space (Z) of said casing (11); the evaporation component (13) and the condensation component (15) are sequentially arranged in the inner space (Z) along the front-back direction; the flow dividing piece (12) is arranged between the evaporation assembly (13) and the condensation assembly (15) and used for respectively guiding the air entering the inner space (Z) to the evaporation assembly (13) and the condensation assembly (15).

2. The range hood (100) of claim 1, wherein the air conditioning structure (10) further comprises a base (17) for carrying the evaporating assembly (13), the base (17) enclosing a cavity (Q) for directing air to the condensing assembly (15).

3. The range hood (100) of claim 2, wherein the base (17) comprises a carrying plate (171) for carrying the evaporating assembly (13) and two supporting end plates (173), the two supporting end plates (173) are oppositely arranged at two ends of the carrying plate (171) in the width direction intersecting with the front-back direction, and the carrying plate (171) and the supporting end plates (173) surround to form the cavity (Q);

wherein, the support end plate (173) is provided with an air inlet (S).

4. The range hood (100) of claim 2, wherein the diverter (12) and the base (17) are sequentially disposed between the evaporating assembly (13) and the condensing assembly (15) in a height direction intersecting the fore-aft direction.

5. The machine (100) according to any of the claims 1 to 4, wherein the outer housing (11) further comprises a top panel (113) connected to the top sides of the front panel (111) and the back panel (112), the top panel (113) being provided with air inlet portions (J) through which air enters the interior space (Z);

an air outlet (C) communicated with the inner space (Z) is formed in the front plate (111).

6. The air conditioner cigarette machine (100) as claimed in claim 5, wherein the evaporation assembly (13) comprises a cross flow wind wheel (131) and an air duct shell (133), the cross flow wind wheel (131) is installed in the air duct shell (133), and the air duct shell (133) is communicated with the air outlet (C);

and the cross-flow wind wheel (131) forms cross-flow wind flowing from the air inlet part (J) to the air outlet (C) in the air duct shell (133).

7. The machine (100) as claimed in claim 6, wherein the evaporating assembly (13) further comprises an evaporating heat exchanger (137), the evaporating heat exchanger (137) is disposed on the peripheral side of the cross-flow wind wheel (131) and is located on the wind path of the cross-flow wind between the air inlet portion (J) and the cross-flow wind wheel (131).

8. The machine (100) as claimed in claim 7, wherein the evaporating assembly (13) further comprises an outer cover (1373), the outer cover (1373) is covered on the surface of the evaporating heat exchanger (137) facing away from the cross-flow wind wheel (131), and is provided with an air passing opening (K).

9. The machine (100) according to claim 5, characterized in that said air conditioning structure (10) further comprises a wind sweeping assembly (19), said wind sweeping assembly (19) being provided at said outlet mouth (C) for controlled change of the direction of the air flow at said outlet mouth (C).

10. The air-conditioning cigarette machine (100) as claimed in claim 5, wherein the cigarette machine structure (20) has a cigarette machine cavity (Y) and a centrifugal fan (21) arranged in the cigarette machine cavity (Y), the centrifugal fan (21) has an air suction port and an air exhaust port, and the top plate (113) is further provided with a smoke exhaust hole (P) communicated with the air exhaust port.

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