JP2011208909A - Cooling device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cooling device which improves heat exchange efficiency in a condenser.SOLUTION: The condenser 19 of the cooling device 10 includes a plurality of juxtaposed radiation fins 30, a meandering refrigerant piping 31 passing through the respective radiation fins, pipe plates 21 positioned on both sides in a ventilating direction by a blower for the condenser to retain the refrigerant piping, with the lower ends fixed in a unit base 9, and an upper surface plate 37 attached across the upper ends of the respective pipe plates to block the upper part of the radiation fins. A refrigerant is made to flow through the refrigerant pipe from top to bottom, and moreover, an air inflow hole 37A is formed on the inflow side of air by the blower for the condenser of the upper surface plate.

Description

  The present invention relates to a cooling device having a refrigerant circuit composed of a compressor, a condenser, an evaporator, and the like, and air-cooling the condenser with a condenser blower.

  Conventionally, cooling storages such as commercial refrigerators and freezers are installed in restaurant kitchens, supermarket stores, etc., and a refrigerant circuit is composed of a compressor, a condenser, a decompression device, a cooler, and the like. A cooling device is provided, and the cool air exchanged with the cooler is circulated into the storage chamber by a blower to cool and store food and the like at a set temperature.

  Cooling devices such as a compressor, a condenser, and a condenser fan are installed in a machine room provided outside the storage room. Here, in the cooling device shown in Patent Document 1, the condenser is a plate fin type heat exchanger that includes a plurality of heat radiation fins arranged in parallel and includes meandering refrigerant pipes that penetrate the heat radiation fins. In addition, it is disposed corresponding to the rear side of the outside air inlet formed in the panel that defines the machine room.

  And the steel plate fan casing is attached to the tube sheet located in this both sides. The fan casing includes an upper wall that covers the upper surface of the condenser and is fixed to the tube plate, and a rear wall that descends substantially vertically from the rear end of the upper wall. A grill is formed on the rear wall. The condenser blower is fixed in correspondence with the grill.

  As a result, by operating the condenser blower, air is sucked from the front of the condenser, and passes between the heat radiation fins of the condenser to exchange heat with the refrigerant piping constituting the condenser, thereby promoting the heat radiation of the condenser. Blow out the air after heat exchange.

2000-258038

  In the above, the refrigerant flows from the top to the bottom through the refrigerant piping constituting the condenser. Therefore, the temperature of the refrigerant flowing in the refrigerant pipe in the upper part of the condenser is higher than the temperature of the refrigerant flowing in the lower part. However, in the conventional configuration, air is uniformly sucked from the front of the condenser by the operation of the condenser blower, and thus there is a problem that the heat exchange efficiency in the upper part of the condenser is particularly bad.

  Therefore, it has been desired to develop a condenser that can achieve higher heat exchange efficiency in a condenser having the same dimensions.

  The present invention has been made to solve the conventional technical problem, and provides a cooling device capable of realizing improvement in heat exchange efficiency in a condenser.

  In order to solve the above problems, the cooling device of the present invention has a refrigerant circuit composed of a compressor, a condenser, an evaporator, and the like, and is formed by air-cooling the condenser with a condenser fan. The condenser is located on both sides of the ventilation direction by the condenser fan, and the lower end is the unit base. And a top plate that is attached across the upper end of each tube plate and closes the upper side of the heat radiating fins, and the refrigerant is flowed from the top to the bottom in the refrigerant pipe. An air inflow hole is formed on the air inflow side of the face plate by the condenser blower.

  The invention of claim 2 is characterized in that, in the above, an anti-vibration material is interposed between the tube plate and the unit base.

  The invention of claim 3 is characterized in that, in each of the above inventions, an anti-vibration material is interposed between the tube plate and the upper surface plate.

  According to the present invention, in a cooling device having a refrigerant circuit composed of a compressor, a condenser, an evaporator, and the like, in which the condenser is air-cooled by a condenser fan, a plurality of condensers are arranged in parallel. Radiating fins, meandering refrigerant pipes penetrating each radiating fin, tube plates that are located on both sides in the direction of ventilation by the condenser fan, hold the refrigerant pipes, and have lower ends fixed to the unit base, and each pipe An upper surface plate that is mounted across the upper end of the plate and closes the upper side of the radiating fin, and the refrigerant is flowed from the top to the bottom of the refrigerant pipe, and the air inflow side by the condenser blower on the upper surface plate Since the air inflow holes are formed, in addition to the ventilation of the condenser in the direction of ventilation by the condenser blower, the air gap between the radiating fins can also be seen from above the condenser through the air inflow holes formed in the top plate. Allow air to flow into To become.

  Therefore, the upper part of the refrigerant flowing from the top to the bottom can be efficiently cooled by the air flowing between the heat radiating fins through the air inflow hole, and high heat radiation efficiency can be realized.

  According to the invention of claim 2, in addition to the above, a vibration isolator is interposed between the tube plate and the unit base, so that the vibration from the compressor traveling along the unit base is caused by the vibration isolator. Can be absorbed. Thereby, the noise by the vibration of a tube sheet and a unit base can be reduced.

  According to a third aspect of the present invention, in the above inventions, a vibration isolator is interposed between the tube plate and the top plate, so that the vibration from the compressor traveling along the unit base is absorbed by the vibration isolator. be able to. Thereby, the noise by the vibration of a tube plate and an upper surface plate can be reduced.

It is a vertical side view of the cooling storehouse to which the present invention is applied. It is a perspective view of a cooling device. It is a top view of a cooling device. FIG. 4 is a sectional view taken along line AA in FIG. It is a front view of a compressor and its attachment apparatus. It is a perspective top view of a silicon vibration isolator. It is a see-through | perspective side view of a silicon anti-vibration material. It is a partial expanded sectional view of an electrical equipment box.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a vertical side view of a cooling storage R to which the present invention is applied. The cooling storage R in the present embodiment is a commercial cooling storage installed in a restaurant kitchen or the like, for example, and the main body is constituted by the heat insulating box 1 opened to the front. This heat insulating box 1 is made of polyurethane which is filled with an outer box 2 made of a steel plate such as stainless steel, an inner box 3 incorporated in the outer box 2, and inner and outer boxes 2, 3 by an in-situ foaming method. It is comprised from the heat insulating material 4. And the storage chamber 5 is comprised in this heat insulation box 1 (inner box 3), and the front opening 22 of the storage chamber 5 is obstruct | occluded by two sets of double doors 6 so that opening and closing is possible. Reference numeral 7 denotes a shelf installed in the storage room 5.

  On the other hand, a rectangular window hole 8 is formed in the top wall 1A of the heat insulation box 1, and a unit base 9 composed of a heat insulating plate is attached in a manner to close the window hole 8 from above. An evaporator 11 constituting the cooling device 10 and a blower 12 for circulating cold air are attached to the lower surface of the unit base 9, and the evaporator 11 and the blower 12 are located in the upper part of the storage chamber 5. ing. And the partition plate 13 which divides the cooling chamber 14 to which this evaporator 11 is attached, and the storage chamber 5 side is arrange | positioned under the evaporator 11. FIG. A suction port 15 is formed in the partition plate 13 corresponding to the blower 12, and a discharge port 16 is formed in the rear end of the partition plate 13.

  On the other hand, a machine room 17 is formed on the ceiling wall 1A (ceiling) of the heat insulation box 1, and an openable / closable front panel 21 is attached and concealed in front of the machine room 17. A gap 23 is formed between the lower edge of the front panel 21 and the heat insulating box 1.

  Here, with reference to FIG. 2 thru | or FIG. 6, the cooling device 10 arrange | positioned in the machine room 17 is demonstrated. 2 is a perspective view of the cooling device 10, FIG. 3 is a plan view of the cooling device 10, FIG. 4 is a cross-sectional view taken along line AA of FIG. 3, FIG. 5 is a front view of the compressor 18 and its mounting device, and FIG. 7 is a perspective side view of the silicon materials 48 and 49, and FIG. 8 is a partially enlarged sectional view of the electrical equipment box 28, respectively.

  On the upper surface of the unit base 9 that closes the window hole 8 on the top wall 1A of the heat insulation box 1 from above, a compressor 18, a condenser 19 and a condenser blower 20 that constitute the cooling device 10 together with the evaporator 11 are provided. Furthermore, an electrical equipment box 28 is installed and these are located in the machine room 17.

  The cooling device 10 forms a well-known refrigerant circuit 24 by pipe-connecting the compressor 18, the condenser 19, an expansion valve as a decompression unit, and the evaporator 11 in order. A predetermined amount of refrigerant is sealed in the refrigerant circuit 24.

  The condenser 19 in this embodiment includes a plurality of heat radiation fins 30 arranged in parallel, a meandering refrigerant pipe 31 penetrating each heat radiation fin 30, tube plates 32 and 32, and an upper surface plate 37. Arranged at the front of the base 9. The condenser blower 20 is disposed in the vicinity of the condenser 19, in the present embodiment, behind the evaporator 19. The direction of the heat dissipating fins 30 of the condenser 19 is set so that air flows from the front (front panel 21 side) to the rear by the operation of the condenser blower 20.

  The tube plates 32 and 32 are arrange | positioned and located in the both sides of the ventilation direction by the said air blower 20 for condensers. Each tube plate 32 has a plurality of holding holes 32 </ b> A for holding the refrigerant pipe 31. Therefore, the refrigerant pipes 31 arranged in a meandering shape are held in the tube plates 32 and 32 by being inserted into the holding holes 32A. In the refrigerant pipe 31, the refrigerant flows from top to bottom.

  The tube plate 32 has a fixing piece 33 bent at a substantially right angle toward the outside at the lower end thereof. The fixing piece 33 is fixed on the unit base 9 by fixing means 34 such as a bolt. Is done. In this embodiment, a vibration isolator 35 is interposed between the fixed piece 33 of the tube plate 32 and the unit base 9 (see FIG. 4).

  The vibration isolator 35 is made of an elastic material such as a rubber plate, that is, a material that can absorb vibrations due to its properties. Therefore, vibration from the compressor 18 disposed on the same unit base 9 can be absorbed by the vibration isolator 35. Thereby, the noise by the vibration of the tube sheet 32 (fixed piece 33) and the unit base 9 can be reduced.

  On the other hand, an upper surface plate 37 that closes the upper side of the heat radiation fin 30 is attached across the upper ends of the tube plates 32 and 32. An air inflow hole 37A is formed on the air inflow side of the upper surface plate 37 by the condenser blower 20, in this embodiment, on the front side. The air inflow hole 37A is formed to extend in the direction in which the heat dissipating fins 30 are juxtaposed, and at least the refrigerant disposed in a meandering manner on the air inflow side of the condenser blower 20 The dimensions correspond to the first to second rows of the piping 31.

  Therefore, when the condenser blower 20 is operated, air flows from the front of the condenser 19 between the heat radiating fins 30, and from above the condenser 19 through the air inflow holes 37 </ b> A formed on the front side of the top plate 37. In addition, air flows between the radiating fins 30.

  Thereby, the refrigerant flowing through the meandering refrigerant pipe 31 penetrating each radiation fin 30 is cooled by the air flowing between the radiation fins 30 from the front of the condenser 19. In particular, in the present embodiment, air can be introduced between the radiation fins 30 from the air inflow holes 37 </ b> A formed on the front side of the upper surface plate 37 that closes the upper side of each radiation fin 30. The upper part of the refrigerant flowing from the top to the bottom in the refrigerant pipe 31 can be efficiently cooled by the inflowing air. As a result, high heat dissipation efficiency can be realized.

  Since the air inlet hole 37A is formed only on the front side of the upper surface plate 37, the heat radiation fins 30 are blocked on the portions other than the front side, so that the inflow of air from above the condenser 19 is restricted to the front side. And positive air flow into the condenser 19 is promoted.

  Furthermore, in this embodiment, a vibration isolator 38 is interposed between the upper surface plate 37 and each tube plate 32 (see FIG. 4). Like the vibration isolator 35, the vibration isolator 38 is made of an elastic material such as a rubber plate, that is, a material that can absorb vibration due to its property. Therefore, vibration from the compressor 18 disposed on the same unit base 9 can be absorbed by the vibration isolator 38. Thereby, the noise by the vibration of the tube plate 32 and the upper surface plate 37 can be reduced.

  Next, the compressor 18 in this embodiment is a rotary compressor as an example, and a driving element and a compression element driven by the driving element are accommodated in a vertical sealed container 40. The sealed container 40 is configured by a substantially bowl-shaped end cap 40B that closes an upper end opening of a vertically long cylindrical container main body 40A that houses the driving element and the compression element. A discharge pipe 43 for discharging high-temperature and high-pressure refrigerant compressed by the compression element of the compressor 18 to the outside is connected.

  A suction pipe 42 for introducing a refrigerant into the compression element is connected to the side surface of the container body 40A. Further, in the present embodiment, a desuper heater 41 as a compressor cooling device is attached to the compressor 18. The desuperheater 41 is disposed at a position where the air that has passed through the condenser 19 is ventilated by the condenser blower 20 and air-cooled.

  A plurality (three in this embodiment, each having a spacing of approximately 120 °) of leg portions 45 are provided on the bottom of the container body 40A of the sealed container 40. The leg portion 45 is made of a thick steel plate and is formed to protrude outward.

  Next, the attachment device 44 for the compressor 18 will be described. An attachment device 44 for the compressor 18 includes a compressor base 47, a rubber vibration-proof material (hereinafter referred to as a rubber material) 46 provided on each leg 45, and is provided corresponding to each leg 45. First and second silicon anti-vibration materials (hereinafter referred to as first and second silicon materials) 48 and 49, and a bolt 50 for fixing them to the unit base 9. The compressor base 47 is disposed on the unit base 9 and has a plurality of bolt through holes (not shown) through which a plurality of bolts 50 for fixing the leg portions 45 pass.

  A bolt through hole (not shown) is formed at the tip end portion of each leg 45 that protrudes outward, and a rubber material 46 is provided below the tip portion. The rubber material 46 is constituted by a main body having elasticity, and a bolt through hole (not shown) that overlaps with the bolt through hole of the leg portion 45 is formed at the center in the axial direction.

  A first silicon material 48 is provided between each rubber material 46 and the compressor base 47, and a second silicon material is provided between the compressor base 47 and the unit base 9 at the corresponding positions. 49 is interposed.

  Each of the silicon materials 48 and 49 is made of a silicon material that is softer and more elastic than the rubber material 46, and a bolt through hole 52 that overlaps with the bolt through hole of the leg portion 45 is formed at the center in the axial direction. Has been.

  Here, as shown in the plan view of FIG. 6, the silicon materials 48 and 49 both extend radially outward from the bolt through holes 52 on the upper surface 51A (extend in the radial direction). A plurality of grooves 53 are formed. In this embodiment, four lines are formed with an interval of approximately 90 °.

  And, as shown by the broken line in FIG. 6, the lower surface 51B is radially outward from the bolt through hole 52 at a position that does not coincide with the grooves 53... Formed in the upper surface 51A in the vertical direction. A plurality of extending (radially extending) grooves 54 are formed. In this embodiment, four grooves 54 are formed at intervals of approximately 90 °, and are formed at positions rotated (shifted) by approximately 45 ° with the grooves 53.

  In this embodiment, each of the grooves 53 formed on the upper surface 51A and each groove 54 formed on the lower surface 51B has a depth smaller than ½ of the thickness dimension of the silicon material 48 or 49. Dimension. Moreover, although each groove | channel is formed four, it is not limited to this, Three or five or more may be sufficient.

  With this configuration, when the compressor 18 is fixed on the unit base 9, first, a plurality of bolt through holes (not shown) formed in the unit base 9 are respectively provided with the second silicon material 49 and the second silicon material 49 thereon. A compressor base 47 is placed. Then, a first silicon material 48 is placed at a position corresponding to each bolt through hole of the compressor base 47, and a rubber material 46 is placed thereon. In either case, the bolt through hole is polymerized.

  Then, the compressor 18 is placed from above, and each leg portion 45 is made to correspond to each rubber material 46. Then, from above the leg portions 45, the bolts 50 are inserted into the respective bolt through holes of the rubber material 46, the first silicon material 48, the compressor base 47, and the second silicon material 49. It is fixed by screwing with a nut (not shown) addressed to the lower side.

  Thereby, compared with the case where the compressor 18 is directly attached to the unit base 9, the displacement due to the vibration of the compressor 18 can be effectively absorbed by attaching the compressor 18 to the unit base 9 via the compressor base 47. It becomes possible.

  In particular, a rubber material 46 and a first silicon material 48 are interposed between each leg 45 and the compressor base 47, and further, between the compressor base 47 and the unit base 9, A second silicon material 49 is interposed. Therefore, the rubber material 46 and the silicon materials 48 and 49 can effectively absorb vibration caused by the operation of the compressor 18.

  Further, since each of the silicon materials 48 and 49 can be made thinner and softer than the rubber material 46, the vibration absorbing effect can be improved and noise can be prevented.

  In particular, since a plurality of grooves 53 and 54 are formed on the upper surface 51A and the lower surface 51B of each of the silicon materials 48 and 49, the vibrations can be absorbed softly by the grooves 53 and 54 of the silicon materials 48 and 49. Become.

  That is, the vibration caused by the operation of the compressor 18 can be effectively absorbed by expanding or restoring the grooves 53 and 54 by their elasticity. Therefore, the displacement of the discharge pipe 43 and the like connected to the compressor 18 can be suppressed, and damage to the pipe and the like can be prevented.

  Further, even if the compressor 18 has a relatively large vibration, by adopting the silicon materials 48 and 49, a high vibration absorbing effect can be realized with a thin vibration isolating material. It becomes possible to suppress the vibration and to attach it. Accordingly, it is possible to realize attachment to a device whose height is limited.

  Furthermore, in this embodiment, the silicon material is composed of a first silicon material 48 located on the rubber material 46 side and a second silicon material 49 located on the unit base 9 side, so that each silicon material A single body can be made thin, and molding becomes easy.

  Further, the grooves 53 and 54 of the silicon materials 48 and 49 employed in this embodiment are formed to extend radially outward from the bolt through holes 52 with an interval of approximately 90 °. Therefore, it is possible to effectively absorb the displacement in the rotational direction due to the operation of the compressor 18 in which the rotational motion is performed in the horizontal direction inside the sealed container 40.

  Since it forms radially outward from the bolt through hole 52, the workability of the grooves 53 and 54 is good.

  Further, since the grooves 53 formed on the upper surface 51A and the grooves 54 formed on the lower surface 51B are formed at positions that do not coincide with each other in the vertical direction, the grooves 53 on the upper surface 51A and the grooves 54 on the lower surface 51B are formed. It is possible to avoid an inconvenience that an extremely thin portion is formed as in the case where the positions match in the vertical direction. Therefore, the strength of the silicon materials 48 and 49 can be maintained.

  In this embodiment, the grooves are formed in each of the upper surface 51A and the lower surface 51B of the silicon material, but may be formed in only one of them. Moreover, the shape of each groove | channel 53,54 is not limited above, For example, the thing formed in multiple numbers concentric with the bolt through-hole 52 may be sufficient. Also in this case, it is more desirable that the upper surface 51A and the lower surface 51B are formed at positions where the positions of the grooves do not coincide with each other in the vertical direction. Also by this, the displacement by the vibration of the compressor 18 can be absorbed effectively.

  In addition to the above, the groove of the silicon material forms a plurality of parallel grooves on the upper surface 51A and a plurality of parallel grooves on the lower surface 51B, and the grooves on the upper surface 51A and the grooves on the lower surface 51B are approximately 90. It is also possible to form a grid that intersects at an angle.

  Thereby, since each groove | channel in each surface can be formed in the same direction, the improvement of workability can be aimed at. Vibration caused by displacement in the rotational direction of the compressor 18 is formed on each surface and can be absorbed in grooves orthogonal to each surface 51A, 51B at approximately 90 °, so that the vibration isolation effect can be improved.

  Next, the electrical box 28 disposed on the unit base 9 together with the condenser 19 and the compressor 18 as described above will be described. In the present embodiment, the electrical box 28 is disposed on one side of the front portion of the unit base 9 corresponding to the side of the condenser 19 disposed on the front portion of the unit base 9. The electrical box 28 is formed of a rectangular body made of, for example, a metal material, and has at least one side surface, in this embodiment, an exterior case 56 that opens on the side surface on the condenser 19 side, and a lid that closes and opens the opening. And a body 57. A through hole 58 is formed in the lid body 57.

  In the exterior case 56, electrical components such as a circuit board 60 and a transformer are accommodated. In particular, in this embodiment, the circuit board 60 includes a circuit for controlling the operation frequency of the compressor 18 as described above by an inverter. This circuit is provided with a switching element such as IGBT or MOS-FET as a switching circuit such as an inverter. The switching element is a heating element that generates significant heat by inverter control.

  The circuit board 60 is attached to the inner wall of the electrical equipment box 28 with a predetermined insulation distance. Specifically, it is attached to the electrical equipment box 28 via the mounting plate 61. The circuit board 60 is fixed to the mounting plate 61 by a plurality of holding members 62 on the inner surface of the electrical box 28. The holding member 62 ensures a predetermined insulation distance between the circuit board 60 and the mounting plate 61.

  The mounting plate 61 is formed to have a dimension capable of closing at least the through-hole 58, and a plurality of radiating fins 63 are attached to the position corresponding to the through-hole 58 at a predetermined interval. Yes.

  Further, on the inner surface side of the mounting plate 61 at a position corresponding to the heat radiating fin 63, a heat conductive material 65 is provided so that the circuit board 60 provided with an insulation distance and the mounting plate 61 are in a heat conductive relationship. .

  With this configuration, when the circuit board 60 is attached to the electrical box 28, the circuit board 60 is fixed to the attachment plate 61 to which the heat radiating fins 63 and the heat conducting material 65 are attached with the holding member 62 securing an insulation distance. Then, the mounting plate 61 is fixed to the lid body 57 of the electrical equipment box 28 by a fixing member 66 such as a screw.

  As a result, the mounting plate 61 is fixed to the electrical box 28, and the radiating fins 63 are exposed to the outside of the electrical box 28 from the through hole 58 in a state where the through hole 58 is closed by the mounting plate 61.

  Therefore, although the heat generation of the switching element (heating element) becomes remarkable due to the inverter control of the compressor 18, the heat generated on the circuit board 60 is caused by the heat conduction material 65 and the mounting plate 61 provided in the heat conduction relationship. It is conducted to the heat radiation fin 63 through. Since the heat radiating fins 63 are provided so as to face the outside of the electrical box 28 through the through holes 58, the heat generated in the circuit board 60 can be smoothly radiated to the outside of the electric box 28. Thereby, the effective discharge of the heat from the heating element can be realized by the radiation fins 63 facing the outside of the electrical box 28.

  Thereby, it is possible to effectively eliminate the inconvenience due to abnormally high temperature inside the electrical equipment box 28 without providing a special ventilation fan for the electrical equipment box. Therefore, smooth control of the cooling device 10 can be realized while reducing the number of parts.

  At this time, the mounting plate 61 closes the through hole 58 that allows the heat radiating fin 63 to face outside while ensuring the insulation distance between the circuit board 60 and the electric box 28, and therefore the electrical box 28 through the through hole 58. The inconvenience of dust entering the inside can be suppressed.

  In particular, in the present embodiment, the air sucked into the machine room 17 from the gap 23 between the front panel 21 and the heat insulating box 1 by the operation of the condenser blower 20 passes through the condenser 19 and then to the rear thereof. The compressor 18 is provided. Here, since the compressor 18 has a predetermined height dimension, a part of the air colliding with the front surface of the compressor 18 is distributed to the front side and is blown between the condenser 19 and the electrical box 28. The The radiating fins 63 provided in the electrical box 28 are arranged at positions where the air blown by the condenser blower 20 passes.

  Therefore, the heat from the heat generating element (circuit board 60) conducted to the heat radiating fins 63 can be radiated by the air blown by the condenser blower 20. Thereby, the improvement of the further heat dissipation performance can be aimed at.

R Cooling storage 1 Heat insulation box 5 Storage room 8 Window hole 9 Unit base (heat insulation plate)
DESCRIPTION OF SYMBOLS 10 Cooling device 11 Evaporator 17 Machine room 18 Compressor 19 Condenser 20 Condenser fan 23 Gap 24 Refrigerant circuit 28 Electrical box 30 Radiation fin 31 Refrigerant piping 32 Tube plate 32A Holding hole 33 Fixing piece 34 Fixing means (bolt)
DESCRIPTION OF SYMBOLS 35 Anti-vibration material 37 Top surface plate 37A Air inflow hole 38 Anti-vibration material 40 Airtight container 42 Suction piping 43 Discharge piping 44 Mounting apparatus 45 Leg part 46 Rubber material (rubber vibration-proof material)
47 Compressor base 48 First silicon material (silicon vibration-proof material)
49 Second silicon material (silicon anti-vibration material)
50 Bolt 51A Upper surface 51B Lower surface 52 Bolt through hole 53, 54 Groove 56 Exterior case 57 Cover body 58 Through hole 60 Circuit board 61 Mounting plate 62 Holding member 63 Radiation fin 65 Thermal conduction material 66 Fixing member

Claims (3)

In a cooling device comprising a refrigerant circuit composed of a compressor, a condenser, an evaporator, and the like, and the condenser is air-cooled with a condenser fan,
The condenser is provided with a plurality of heat radiation fins arranged side by side, a meandering refrigerant pipe penetrating each heat radiation fin, the refrigerant pipe located on both sides in the ventilation direction by the condenser blower, and a lower end thereof A tube plate fixed to the unit base, and an upper surface plate that is attached across the upper end of each tube plate and closes the upper side of the heat radiating fin;
The refrigerant flows in the refrigerant pipe from the top to the bottom, and an air inflow hole is formed on an air inflow side of the upper plate by the condenser blower.   The cooling device according to claim 1, wherein a vibration isolating material is interposed between the tube plate and the unit base.   The cooling device according to claim 1 or 2, wherein a vibration isolating material is interposed between the tube plate and the upper surface plate.

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