JP2011158176A - Refrigeration apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To relieve the problem that when a refrigeration apparatus is installed in a limited space, high temperature air exited from a machine room is resident and air temperature sucked in the machine room rises. <P>SOLUTION: The refrigeration apparatus includes: a second fan 20 that supplies external air to an air cooling condenser 14 apart from a first fan 15 that cools the air cooling condenser 14 and a compressor 16, thereby preventing rise of the air temperature sucked in by the cooling condenser 14 and efficiently radiating heat. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a refrigerator in which a condenser and a compressor are air-cooled by a fan and efficiently radiates heat while suppressing an increase in the temperature of air to be sucked.

  In a home refrigerator, a condenser that is air-cooled by a fan is used. However, in the refrigerator for home use, the size of the condenser main body and the air passage is restricted from the viewpoint of space saving, and there is a concern that the air passage is blocked due to dust adhering to the room.

  Therefore, a design of a machine room in consideration of sparseness and dust adhesion has been proposed.

  Hereinafter, a conventional refrigerator will be described with reference to the drawings.

  5 is a cross-sectional view of a machine room of a conventional refrigerator, FIG. 6 is a cross-sectional view taken along line AA in FIG. 5, and FIG. 7 is a cross-sectional view taken along line BB in FIG.

  5-7, 51 is a refrigerator, 52 is a machine room, 53 is a condenser, 54 is a fan, 55 is a compressor, and the machine room 52 in the lower part of the refrigerator 51 is connected to the condenser 53 in order from the windward side. A fan 54 and a compressor 55 are disposed. Reference numeral 56 denotes an air suction port for taking air into the machine chamber 52, 57 denotes an air discharge port for discharging the air heat-exchanged in the machine chamber 52, and 58 denotes the vicinity of the air suction port 56 and the vicinity of the air discharge port 57. It is a communication port that communicates.

  About the conventional refrigerator comprised as mentioned above, the operation | movement is demonstrated below.

  By driving the fan 54, the outside air at the lower and front sides of the refrigerator 51 is sucked from the air inlet 56 to cool the condenser 53, and then the heat exchanged air is supplied to the compressor 55 via the fan 54. The air is cooled and discharged from the air discharge port 57 to the outside of the machine room 52. Further, even when the air suction port 56 is blocked due to dust adhesion, air circulation is generated from the condenser 53 to the fan 54 and the compressor 55 through the communication port 58, so that the air cooling operation can be maintained.

Japanese Patent Laid-Open No. 2002-295554

  However, in the conventional configuration, since the air suction port 56 and the air discharge port 57 are in the vicinity, the high-temperature air discharged from the air discharge port 57 and the outside air are mixed and taken in from the air suction port 56. As a result As a result, the temperature of the air sucked into the machine chamber 52 is high, and the condenser 53 and the compressor 55 cannot be efficiently air-cooled. Similarly, it is difficult to maintain a sufficient heat dissipation capability even if high-temperature air is circulated through the communication port 58. As described above, since it is difficult to secure the distance between the air suction port 56 and the air discharge port 57 in the household refrigerator from the viewpoint of space saving, there is a problem of suppressing an increase in the temperature of the sucked air. It was. In particular, when installing a refrigerator in a limited space such as a system kitchen, the casing outline other than the front face that opens and closes the door is in close proximity to the wall. The increase in air temperature becomes more remarkable.

  SUMMARY OF THE INVENTION An object of the present invention is to solve the conventional problems and to provide a refrigerator that can efficiently dissipate heat by suppressing an increase in the temperature of the sucked air with a simple configuration.

  In order to solve the conventional problems, the refrigerator of the present invention has a second fan that supplies outside air to the condenser, separately from the first fan that is the main drive source of the blower circuit. As a result, it is possible to efficiently dissipate heat while suppressing an increase in the intake air temperature.

  The refrigerator of the present invention can efficiently dissipate heat while suppressing an increase in the intake air temperature, and the fan and the condenser can be reduced in size and energy can be saved by reducing the condensation temperature.

1 is a longitudinal sectional view of a machine room of a refrigerator according to Embodiment 1 of the present invention. The perspective view which removed the upper machine room cover of the refrigerator in Embodiment 1 of this invention The figure which shows the control pattern of the refrigerator in Embodiment 1 of this invention. The perspective view which mounted | wore with the ceiling duct of the refrigerator in Embodiment 1 of this invention Cross-sectional view of a conventional refrigerator machine room AA line sectional view of FIG. BB sectional view of FIG.

  The invention described in claim 1 is an air-cooled condenser, a first fan installed on the leeward side of the air-cooled condenser and serving as a main drive source of the blower circuit, and installed on the leeward side of the first fan. In the air path configuration having a compressor, the refrigerator has a second fan that is installed on the windward side of the air-cooled condenser and supplies outside air to the air-cooled condenser. Therefore, it is possible to efficiently dissipate heat while suppressing the air-cooled condenser from sucking again the exhaust air whose temperature has increased.

  The invention described in claim 2 is characterized in that, in the invention described in claim 1, it has a bypass air passage through which the outside air drawn directly by the first fan passes without passing through the air-cooled condenser. Since it is a refrigerator, even when the air-cooled condenser is blocked due to dust adhesion, the compressor can be cooled by the outside air sucked through the bypass air passage, and the durability of the compressor can be ensured.

  The invention according to claim 3 is the top mount type refrigerator in which the air-cooled condenser, the first fan, and the compressor are installed on the back upper part in the invention according to claim 1 or 2, And a second air fan formed in the rear corner portion, and a communication air passage that communicates the discharge side of the second fan and the suction side of the air-cooled condenser. When the outside air is supplied from below and the upper part of the refrigerator is an open space, it is possible to prevent the air-cooled condenser from inhaling again by discharging the exhaust air whose temperature has been increased through heat exchange upward. Efficient heat dissipation, and even when the refrigerator is installed in a limited space such as a system kitchen, the outside air near the bottom of the refrigerator, which is relatively cool, can be supplied to the air-cooled condenser. It is possible to Ku heat dissipation.

  The invention according to claim 4 is the invention according to claim 3, further comprising an evaporating dish that is installed in a blower circuit formed by the second fan and stores defrosted water in the warehouse. Since it is a refrigerator, it can also serve as a blower that promotes evaporation of defrosted water in the evaporating dish, and can supply air that has a temperature lower than that of the outside due to evaporation of defrosted water to the air-cooled condenser. It can dissipate heat.

  The invention according to claim 5 is the invention according to claim 3 or 4, wherein the second fan is driven in conjunction with the compressor at a predetermined outside air temperature or higher, and the compressor is operated at a temperature lower than the predetermined outside air temperature. Since the refrigerator is characterized in that the second fan is stopped during operation, the second fan is driven and efficiently cooled at a high outside temperature in which the temperature rise of the air-cooled condenser and the compressor is particularly problematic. At the same time, it is possible to save energy by stopping the second fan at a low outside air temperature at which the temperature rise of the air-cooled condenser and the compressor is not particularly problematic.

  A sixth aspect of the present invention is the refrigerator according to any one of the third to fifth aspects, further comprising a top surface duct that is provided on the top surface of the refrigerator and feeds and exhausts air from the front surface of the refrigerator. Therefore, when installing the refrigerator in a limited space such as a system kitchen, ensuring the distance between the discharge air passage and the intake air passage allows relatively high temperature discharge air and outside air near the top of the refrigerator. Can be prevented, and outside air having a relatively low temperature can be supplied to the air-cooled condenser, so that heat can be radiated efficiently.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings, but the same reference numerals are given to the same components as those of the conventional example, and detailed description thereof will be omitted. The present invention is not limited to the embodiments.

(Embodiment 1)
FIG. 1 shows a longitudinal sectional view of a machine room of a refrigerator according to Embodiment 1 of the present invention. In FIG. 1, 11 is a refrigerator, 12 is a housing of the refrigerator 11, 13 is an upper machine room installed at the upper back of the housing 12, 14 is an air-cooled condenser, 15 is a first fan, and 16 is a compressor. is there. In the upper machine room 13, an air-cooled condenser 14, a first fan 15, and a compressor 16 are installed in order from the windward side, and the air-cooled condenser 14 and the compressor 16 are driven by driving the first fan 15. Air cooled.

  Here, the first fan 15 is attached to the fan ring 17, and the fan ring 17 divides the air path in the upper machine chamber 13 into the windward side and the leeward side of the first fan 15. In addition, a bypass air passage 18 through which the outside air that is directly sucked into the first fan 15 without passing through the air-cooled condenser 14 passes is formed above the air-cooled condenser 14. The bypass air passage 18 supplies the outside air directly to the first fan 15 when the air-cooled condenser 14 is blocked due to dust adhesion or the like, and is about 3% to 15% of the height of the air-cooled condenser 14. A space of 5 to 15 mm corresponding to the height of is desirable. If the height of the bypass air passage 18 is less than 5 mm (3%), the air flow rate is significantly reduced when the air-cooled condenser 14 is completely blocked. If the height of the bypass air passage 18 is higher than 15 mm (15%), the air-cooled condenser The air volume which passes 14 falls and sufficient heat dissipation capability is not obtained.

  Further, 19 is a lower machine room installed at the lower back of the housing 12, 20 is a second fan, 21 is an evaporating dish for storing defrosted water in the cabinet (not shown), and 22 is the housing 12 This is a communication air passage provided in the back corner. In the lower machine room 19, a second fan 20 and an evaporating dish 21 are installed in order from the windward side. By driving the second fan 20, outside air near the lower part of the housing 12 is sucked and evaporated. While evaporating the defrost water stored in the tray 21, the outside air cooled by the evaporation of the defrost water is supplied to the air-cooled condenser 14 via the evaporation tray 21 and the communication air passage 22. In this way, the second fan 20 has both the function of cooling the air-cooled condenser 14 and the function of promoting the evaporation of the defrosted water accumulated in the evaporating dish 21, so that the defrosted water can be formed with a simple configuration. Air having a temperature lower than that of the outside air due to evaporation can be supplied to the air-cooled condenser, and heat can be efficiently radiated in the upper machine chamber 13.

In addition, since the compressor 16 and the air-cooled condenser 14 which are main heat sources are arranged in the upper machine chamber 13, the outside air near the lower portion of the housing 12 sucked by the second fan 20 is the outside air above the housing 12. However, it is desirable not to provide a main heat source in the lower machine chamber 19, but the defrost water in the evaporating dish 21 is sufficiently evaporated by only the evaporation promoting effect of the second fan 20. If this is not possible, a radiator (not shown) having a sufficiently smaller capacity than the air-cooled condenser 14 may be disposed in the evaporating dish 21.

  Here, the communication air passage 22 is formed by cutting out the vertical side of the back surface of the housing 12, and the refrigerator 11 is installed in a limited space such as a system kitchen, and the back surface and the side surface of the refrigerator 11 are close to the wall. In this case, the air flow path that communicates the lower machine room 19 and the upper machine room 13 is formed. At this time, both the outside air sucked from the upper side of the refrigerator 11 and the outside air sucked from the communication air passage 22 pass through the upper machine chamber 13, and the compressor 16 and the air-cooled condenser 14, which are main heat sources, Air-cool.

  Here, the air passage cross-sectional area of the communication air passage 22 is provided with substantially the same size as the sum of the cross-sectional areas of the portions that become the air passage of the suction side rear grille 33. As a result, air is appropriately sucked through the communication air passage 22 into the upper machine chamber.

  Further, by changing the ratio of the air volume between the first fan 15 and the second fan 20, it is possible to dissipate heat more efficiently. Here, the relative value of the air volume of the second fan 20 with respect to the first fan 15 is preferably set to 25 to 100%. By setting to 25 to 100%, air from below can be efficiently supplied upward, and a greater heat dissipation effect can be obtained. In addition, when the relative value of the air flow rate of the second fan 20 with respect to the first fan 15 is set to 25% or less, the cooling effect by the second fan 20 is hardly obtained, and the second value with respect to the first fan 15 is not obtained. When the relative value of the air volume of the fan 20 is 100% or more, even if a larger air volume than that of the first fan 15 is supplied from the second fan 20, the upper machine room 13 has a certain amount of outside air. Is not inhaled, so a cooling effect equal to or greater than 100% cannot be obtained. As a result, the amount of power of the second fan 20 only increases.

  Further, if the relative value of the air volume of the second fan 20 is set to 80 to 100%, a larger cooling effect can be obtained. By setting the relative value of the air volume of the second fan 20 to 80 to 100%, the amount of high-temperature exhaust discharged upward from the upper machine chamber 13 is reduced by reducing the amount of suction from the suction side top grill 32. The upper machine room 13 is not inhaled. Therefore, the influence of the high-temperature exhaust discharged upward from the upper machine room 13 can be almost eliminated, and the temperature of the air sucked into the upper machine room 13 can be lowered.

  FIG. 2 is a perspective view of the refrigerator according to the first embodiment with the upper machine room cover removed. In FIG. 2, reference numeral 31 denotes an upper machine room cover, 32 denotes a suction side top grill provided in the upper machine room cover 31 and sucks outside air from above the refrigerator 11, and 33 denotes a communication air passage 22 provided in the upper machine room cover 31. An intake-side rear grille 34 for sucking outside air from, and a discharge-side grill 34 for exhausting the refrigerator 11 upward. Here, the suction-side rear grille 33 has a shape recessed from the wall surface of the housing 12 above the communication air passage 22, so that even when the rear surface or side surface of the refrigerator 11 is close to the wall, You can communicate. As a result, as described above, when the refrigerator 11 is installed in a limited space such as a system kitchen, the outside air is sucked from the communication air passage 22 through the suction side rear grille 33, so that the upper machine room 13 is moved upward. It is possible to remarkably suppress the influence of the high-temperature exhaust discharged.

  About the refrigerator in Embodiment 1 of this invention comprised as mentioned above, the operation | movement is demonstrated below.

FIG. 3 is a diagram showing a control pattern of the refrigerator in the first embodiment. As shown in FIG. 3, the first fan 15 is controlled to be driven in conjunction with the driving of the compressor 16 regardless of the outside air temperature. On the other hand, the second fan 20 is driven to operate in conjunction with the drive of the compressor 16 at an outside air temperature equal to or higher than the reference value T, and is controlled to stop at an outside air temperature lower than the reference value T.

  When the refrigerator 11 is installed in a limited space such as a system kitchen and the wall is close to the upper side of the refrigerator 11, especially at the outside air temperature of the reference value T or more where the work of the compressor 16 increases. The high temperature air discharged upward from the machine room 13 is likely to flow around the upper portion of the housing 12, and the rise in the temperature of the air sucked from above the refrigerator 11 via the suction side top grill 32 is more remarkable. It becomes. On the other hand, by driving the second fan 20 in conjunction with the drive of the compressor 16, outside air having a relatively low temperature is sucked from the communication air passage 22 through the suction side rear grille 33, and the housing 12 The influence of the high-temperature air staying in the vicinity of can be remarkably suppressed. As a result, it is possible to efficiently dissipate heat while suppressing an increase in the intake air temperature, and the first fan 15 and the air-cooled condenser 14 can be reduced in size, and energy can be saved by reducing the condensation temperature. The reference value T is desirably set to 20 to 30 ° C. according to the indoor temperature in summer when the work of the compressor 16 increases.

  When the compressor 16 is a variable speed compressor, the speeds of the first fan 15 and the second fan 20 may be varied in accordance with the capacity of the compressor 16. When the compressor 16 has the maximum capacity, the heat dissipating capacity can be ensured by controlling the air volume of the first fan 15 and the second fan 20 to the maximum. On the other hand, when the compressor 16 is not at its maximum capacity, the drive power can be suppressed and energy saving can be achieved by controlling the air volume of the first fan 15 and the second fan 20 to be controlled. .

  At an outside air temperature less than the reference value T where the work of the compressor 16 is small, the second fan 20 can be stopped to reduce drive power. If the defrost water in the evaporating dish 21 cannot be sufficiently evaporated if the second fan 20 is always stopped, the second fan 20 may be driven for a predetermined time while the compressor 16 is stopped.

  As described above, the temperature rise of the air-cooled condenser and the compressor is particularly problematic, and at the time of high outside air temperature, the second fan is driven to efficiently cool, and the temperature rise of the air-cooled condenser and the compressor is not particularly problematic. When the outside temperature is low, the second fan can be stopped to save energy.

  FIG. 4 is a perspective view in which the top duct of the refrigerator according to the first embodiment is mounted. When the refrigerator 11 is installed in a limited space such as a system kitchen and hot air is likely to flow around the upper portion of the housing 12, a top duct 40 may be attached as shown in FIG. it can. The top duct 40 communicates the upper side of the discharge grill 34 and the front surface of the refrigerator 11, and discharges hot air forward from the upper machine room 13, so that hot air is generated around the upper part of the housing 12. It is intended to prevent stumbling. As a result, even if the lower limit value of the relative value of the air volume of the second fan 20 with respect to the first fan 15 is as small as 10%, the influence of the high-temperature exhaust exhausted from the upper machine chamber 13 can be almost eliminated.

  Similarly to the top surface duct 40, a duct that connects the upper side of the suction side top surface grill 32 and the front surface of the refrigerator 11 is provided, and outside air is sucked from the front surface of the refrigerator 11 through the suction side top surface grill 32. The influence of high-temperature exhaust discharged from the upper machine chamber 13 may be suppressed. However, when the outside air is sucked from the front surface of the refrigerator 11, dust adhering to the vicinity of the inlet of the suction portion is not preferable in appearance. Therefore, it is desirable to arrange the suction portion so as not to be seen from the front surface of the refrigerator 11.

In this way, by configuring the top surface duct 40 so as to ensure the distance between the discharge air passage and the intake air passage, the discharge air having a relatively high temperature and the outside air near the top surface of the refrigerator are mixed. Therefore, it is possible to supply outside air having a relatively low temperature to the air-cooled condenser, and to efficiently dissipate heat.

  As described above, the refrigerator according to the present invention has the second fan that supplies the outside air to the condenser separately from the first fan that is the main drive source of the blower circuit. As a result, it is possible to efficiently dissipate heat while suppressing an increase in the intake air temperature.

  As described above, the refrigerator according to the present invention can efficiently dissipate heat by suppressing an increase in the temperature of the air sucked in the refrigerator in which the condenser and the compressor are air-cooled by a fan. It can also be applied to frozen and refrigerated products.

DESCRIPTION OF SYMBOLS 11 Refrigerator 12 Case 13 Upper machine room 14 Air cooling condenser 15 1st fan 16 Compressor 18 Bypass air path 19 Lower machine room 20 2nd fan 22 Communication air path

Claims (6)

An air path configuration having an air-cooled condenser, a first fan installed on the leeward side of the air-cooled condenser and serving as a main drive source of the blower circuit, and a compressor installed on the leeward side of the first fan And a second fan that is installed on the windward side of the air-cooled condenser and supplies outside air to the air-cooled condenser. 2. The refrigerator according to claim 1, further comprising a bypass air passage through which outside air directly sucked by the first fan passes without passing through the air-cooled condenser. In a top mount type refrigerator in which an air-cooled condenser, a first fan, and a compressor are installed at the upper back, a second fan provided at the lower back and a rear corner portion are formed. The refrigerator according to claim 1 or 2, further comprising a communication air passage communicating the discharge side of the fan and the suction side of the air-cooled condenser. The refrigerator according to claim 3, further comprising an evaporating dish that is installed in a blower circuit formed by the second fan and stores defrosted water in the warehouse. 5. The second fan is driven in conjunction with the compressor at a predetermined outside air temperature or higher, and the second fan is stopped during compressor operation at a temperature lower than the predetermined outside air temperature. The refrigerator described. The refrigerator according to any one of claims 3 to 5, further comprising a top surface duct that is provided on the top surface of the refrigerator and feeds and exhausts air from the front surface of the refrigerator.