JP2005257210A - Refrigerator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a refrigerator comprising a stirling freezer capable of obtaining efficient cooling effect without needing a complex heat exchanging cycle. <P>SOLUTION: This refrigerator is composed of a cooling storage chamber 4 having a cold air circulating fan 18 in a duct 8 formed on an outer wall, the stirling freezer 12 mounted outside of the cooling storage chamber 4, and a heat exchanging fin 20 to be cooled mounted on a cold head 12a of the stirling freezer 12. The heat exchanging fin 20 is mounted in the duct 8 near a blowout port 6a to the cooling storage chamber 4, and an air blow fan 22 is mounted near the blowout port 6a to the cooling storage chamber 4 of the duct 8 mounted adjacently to the heat exchanging fin 20. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a refrigerator provided with a Stirling refrigerator.

  In a conventional refrigerator, the storage chamber is cooled by a refrigerant compression refrigeration cycle, and a chlorofluorocarbon refrigerant or a hydrocarbon refrigerant is mainly used in the refrigeration cycle. However, since chlorofluorocarbon refrigerants cause ozone layer destruction and global warming, their use is restricted worldwide due to consideration for the global environment. Hydrocarbon refrigerants have no impact on the ozone layer and have little impact on global warming. However, they are flammable, so if they leak from the refrigeration cycle, they will be ignited from sparks generated from the contact points of electrical components. And could develop into a fire.

  On the other hand, research and development of a Stirling refrigerator using a Stirling cycle and a refrigerator using the Stirling cycle are being promoted as an alternative to the refrigerant compression refrigeration cycle. Since this Stirling refrigerator uses an inert gas such as helium or nitrogen as the refrigerant, there is no problem with the above-mentioned Freon refrigerant or hydrocarbon refrigerant.

  The Stirling refrigerator has a structure in which a cylinder containing a piston and a displacer is filled with a refrigerant and sealed, and is operated so that the piston and the displacer reciprocate with a phase difference from each other by external power. The expansion of the refrigerant is repeated in the expansion space near the end, and the compression of the refrigerant is repeated in the compression space near the other end inside the cylinder, so that the expansion space becomes low temperature and the compression space becomes high temperature. The cold energy generated in the expansion space is obtained from the cold head through the regenerator.

  However, because of the structure of the Stirling refrigerator, the size of the heat transfer area of the cold head is limited. Therefore, when using a Stirling refrigerator as a refrigerator refrigerator, it is efficient to use cold heat from a cold head with a small heat transfer area. It is necessary to propagate well to the air in a refrigerator, and it is common to provide the heat exchanger using a secondary refrigerant as the means (for example, patent document 1).

FIG. 4 is a schematic configuration diagram showing a Stirling refrigeration cycle (50) provided with a heat exchanger (52) using a secondary refrigerant for a refrigerator, which is attached to the cold head (51a) together with the Stirling chiller (51). The cold head side heat exchanger (52a) to be connected to the internal heat exchanger (52b) for cooling the air in the storage is connected by a circulation pipe (52c), and a secondary refrigerant is sealed inside the circulation heat exchanger (52c). The secondary refrigerant is circulated by driving a circulation pump (52d) provided in the pipe (52c), the cold heat of the cold head (51a) is propagated to the internal heat exchanger (52a), and the storage chamber is cooled. It has a configuration.
JP 2003-314937 A

  However, in the Stirling refrigeration cycle (50) configured as described above, in order to efficiently transmit the cold heat from the cold head (51a) having a small heat transfer area to the internal air, a circulation pipe (52c) for circulating the secondary refrigerant, Since a heat exchange cycle such as a circulation pump (52d) is necessary and its structure becomes complicated, it causes a problem of cost increase.

  The present invention has been made in consideration of the above problems, and provides a refrigerator including a Stirling refrigerator that can obtain an efficient cooling effect without requiring a complicated heat exchange cycle. Objective.

  The refrigerator of the present invention is attached to a cooling storage room having a cooling air circulation fan in a duct formed on the outer wall, a Stirling refrigerator disposed outside the cooling storage room, and a cold head of the Stirling refrigerator. The heat exchange fins are arranged in a duct in the vicinity of the air outlet to the cooling storage chamber, and in the vicinity of the air outlet to the cooling storage chamber of the duct adjacent to the heat exchange fin. It is characterized by arranging a blower fan.

  According to the present invention, in addition to the circulation fan for circulating the cold air provided in the duct, by placing and operating the blower fan in the vicinity of the heat exchange fin, pressure loss in the duct can be eliminated, An efficient cooling effect can be obtained without requiring a complicated heat exchange cycle.

  Hereinafter, an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a longitudinal cross-sectional view of a refrigerator (1), and a cooling storage room (4), which is a storage space, is formed in the interior by a heat insulating box (2) having an open front surface. The front opening of the cooling storage chamber (4) is closed by a door (4a), and the rear of the cooling storage chamber (4) has an air outlet (6a) at the top and a suction port (6b) at the bottom. A duct (8) for circulating cold air is provided, and a machine room (10) is provided at an upper rear portion of the duct (8).

  As shown in FIG. 2, the Stirling refrigerator (12) includes a displacer (32) and a piston (33) disposed in a sealed cylinder (31), and an expansion space (34) and a compression space (35). And the regenerator (36) constitutes a closed space, and the closed space is filled with a refrigerant such as helium or nitrogen.

  The piston (33) slides in the axial direction of the cylinder (31) by external power such as a linear motor (37). A displacer rod (32a) penetrating the piston (33) is provided below the displacer (32), and the displacer rod (32a) is affected by pressure fluctuations in the bounce space (38) due to the operation of the piston (33). In response, the piston (33) reciprocates with a predetermined phase difference.

  Due to the reciprocating motion of the piston (33) and the displacer (32), the refrigerant moves back and forth between the expansion space (34) and the compression space (35) through the regenerator (36), and the expansion space (34) has a low temperature and expansion space (35). High temperature can be obtained.

  The cold heat thus obtained in the expansion space (34) is transmitted to the cold head (12a) via the low temperature side heat exchanger (39) provided in the expansion space (34), and is transmitted in the compression space (35). The obtained heat is transmitted to the worm head (12b) via the high-temperature side heat exchanger (40) provided in the compression space (35), and the cold and heat generated in the Stirling refrigerator (12) are transferred. It is taken out.

  The Stirling refrigerator (12) is arranged inside the machine room (10) in an upright state in which the axial direction of the cylinder (31) is orthogonal to the bottom surface of the refrigerator (1), and the duct (8) and the machine room (10) are arranged. The cold head (12a) is installed so as to protrude into the duct (8) from the through hole provided in the partition wall (14). The worm head (12b) and the control inverter board (not shown) are cooled by the heat radiating fan (16) disposed in the machine room (10).

  In the path of the duct (8), in order from the suction port (6b) side, a circulation fan (18), a heat exchange fin (20) attached to the cold head (12a), and a blower fan (22) are arranged, The circulation fan (18) is disposed in the vicinity of the upstream side of the heat exchange fin (20), and the blower fan (22) is a sirocco fan and is disposed immediately above the heat exchange fin (20).

  When the Stirling refrigerator (12) is driven, the temperature of the cold head (12a) decreases to -20 ° C to -50 ° C, and the heat exchange fin (20) that receives the cold heat is -10 ° C to -15 ° C. Simultaneously with cooling to temperature, the blower fan (22) and the circulation fan (18) rotate.

  The air that has exchanged heat with the cooled heat exchange fin (20) is discharged from the rotation center of the sirocco fan disposed in the vicinity of the upper portion of the heat exchange fin (20) to the outer periphery, and the air outlet (6a ) Is blown out into the cooling storage chamber (4) to cool the cooling storage chamber (4) and then taken into the duct (8) from the suction port (6b) provided at the lower back of the cooling storage chamber (4). By rising, the inside of the cooling storage chamber (4) is cooled.

  When changing the cooling capacity of the Stirling refrigerator (12) in order to change the cooling capacity of the cooling storage chamber (4), the rotational speeds of the blower fan (22) and the circulation fan (18) are changed in accordance with the change. To change. Specifically, when the cooling capacity of the cooling storage chamber (4) is increased, the linear motor (37) provided in the Stirling refrigerator (12) is controlled to increase the amplitude of the piston (33). In addition to lowering the temperature of the cold head (12a), the rotational speed of the blower fan (22) is increased to increase the wind passing through the heat exchange fin (20), thereby increasing the rotational speed of the blower fan (22). In order to compensate for the pressure loss inside the duct (8) due to this, an operation is performed to increase the rotational speed of the circulation fan (18). Moreover, when lowering | hanging cooling capacity, while controlling the amplitude of a piston (33) small, the driving | operation which reduces the rotation speed of a ventilation fan (22) and a circulation fan (18) is performed.

  FIG. 3 is a cross-sectional view of the heat exchange fin (20) used in the refrigerator of this embodiment. This heat exchange fin (20) has a cylindrical cap portion (20d) on the lower surface of a plate-like base portion (20a) formed of a good heat conductor such as copper, and on the upper surface of the base portion (20a). A fin portion (20b) in which a large number of aluminum fins are erected is attached by bolts or the like. The joint surface between the base part (20a) and the fin part (20b) is filled with silicon grease (20c) having a high thermal conductivity to keep the heat conduction between the base part (20a) and the fin part (20b) high. The cold head (12a) is inserted into and fixed to the cylindrical cap portion (20d) provided on the base portion (20a), so that the cold heat from the cold head is conducted to the heat exchange fin (20). Let In order to enhance thermal conductivity, the contact surface between the cap part (20d) and the cold head (12a) may be filled with silicon grease.

  Since the base part (20a) of the heat exchange fin (20) is made of copper having good heat conductivity, the base part (20a) that has received cold from the cold head (12a) having a small heat transfer area is quickly heated. Therefore, the heat of the base part (20a) can be efficiently transferred from the entire joining surface to the fin part (20b).

  Furthermore, since the fin part (20b) is made of aluminum with good heat conductivity, the entire fin part (20b) having a large heat transfer area can be uniformly cooled, and therefore flows down. The transmission efficiency of cold heat to cold air can be improved. Further, the base (20a) and the fin portion (20b) can be integrally formed of copper, but the fin portion (20b) is formed of aluminum as compared with the case of integrally forming with copper. Cost reduction can be achieved.

  By the way, when the Stirling refrigerator (12) is continuously operated at a high load, the tip temperature of the fin portion (20b) in the heat exchange fin (20) is -10 ° C to -15 ° C. When the operation of (12) is continued, moisture contained in the air circulating in the cooling storage chamber (4) adheres as frost to the surface of the fin portion (20b) of the heat exchange fin (20). In the case of frost formation, the gap between the fins is reduced, the flow of air blown from the blower fan (22) and the circulation fan (18) is deteriorated, and the contact area between the air and the fin portion (20b) is extremely small. Therefore, the heat exchange efficiency is lowered and the cooling performance is lowered. Therefore, the heat exchange fin (20) is defrosted as necessary.

  At the time of defrosting, the operation of the Stirling refrigerator (12) is stopped and the circulation fan (18) is rotated so that the air is directly applied to the heat exchange fin (20). Thereby, the frost adhering to the heat exchange fin (20) can be efficiently defrosted by heat exchange between the circulating cold air and the heat exchange fin (20), and the cold air having a low temperature by exchanging heat with the frost. However, since it discharges and circulates again to the cooling storage chamber (4), the temperature rise in the cooling storage chamber (4) can be effectively suppressed.

  The present invention is useful as a heat exchange cycle configuration of a refrigerator that employs a Stirling refrigerator.

It is a longitudinal cross-section figure of the refrigerator in one Embodiment of this invention. It is sectional drawing of the Stirling refrigerator used for FIG. It is sectional drawing of the heat exchange fin used for FIG. It is a schematic block diagram of the Stirling refrigerating cycle used for the conventional refrigerator.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Refrigerator 4 Cooling storage room 6a Outlet 6b Inlet 8 Duct 10 Machine room 12 Stirling refrigerator 12a Cold head 18 Circulating fan 20 Heat exchange fin 20a Base 20b Fin part 22 Blower fan

Claims (5)

  A cooling storage chamber having a cooling air circulation fan in a duct formed on the outer side wall, a Stirling refrigerator disposed outside the cooling storage chamber, and a heat exchange mounted on the cold head of the Stirling refrigerator and cooled. The heat exchange fin is arranged in a duct near the outlet to the cooling storage chamber, and a blower fan is arranged in the vicinity of the outlet to the cooling storage chamber of the duct adjacent to the heat exchange fin. A refrigerator characterized by that.   2. The refrigerator according to claim 1, wherein the Stirling refrigerator is provided with a sirocco fan which is made upright with the cold head at the top and directly sucks and discharges from the rotation center portion to the outer peripheral portion directly above the heat exchange fin attached to the cold head. .   2. The rotation speed of the blower fan is increased when the refrigeration capacity of the Stirling refrigerator is increased, and the cooling air circulation fan is also operated in proportion to the rotation speed of the blower fan. 2. The refrigerator according to 2.   The refrigerator according to claim 1 or 2, wherein the Stirling refrigerator and the blower fan are stopped and only the circulation fan is rotated during defrosting. The heat exchange fin is formed of a base portion and a fin portion, the base portion is made of copper, and the fin portion standing from the upper surface of the base portion is made of aluminum. Refrigerator.

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