JP3824013B2 - refrigerator - Google Patents

Description

  The present invention relates to a refrigerator in which a compressor is loaded on the top surface of the refrigerator.

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

  Conventional refrigerators generally have a machine room disposed at the lower rear of the refrigerator body, and house high-pressure components of a refrigeration cycle such as a compressor in the machine room. In recent years, refrigerators have become easier to use. From the standpoints of goodness and space saving, improved storage properties and from the viewpoint of the global environment are demanded to improve energy savings. The method of installing in the surface or the back upper part of a refrigerator main body is proposed (for example, refer patent document 1).

  FIG. 15 shows a configuration of a conventional refrigerator described in Patent Document 1. As shown in FIG.

  The box body 1 of the refrigerator is composed of a refrigerator compartment 2, a vegetable compartment 3, and a freezer compartment 4 from the top. The refrigerator compartment 2 has a refrigerating compartment rotary door 5, and the vegetable compartment 3 has a vegetable compartment drawer door 6, a freezer compartment. The chamber 4 has a freezer compartment drawer door 7.

  The cooling unit 10 including the internal fan 8 and the evaporator 9 has a rear surface of the freezer compartment 4 that is substantially the same height as the opening of the freezer compartment 4 that forms a storage portion as the lowermost storage compartment. It installs in the rear part, and installs in the recessed part 12 dented in the refrigerator compartment 2 side over the top | upper surface 11a and the back surface 11b of the box main body 1 of the refrigerator box 1 which is not convenient to use.

  The refrigerator compartment 2 is provided with a plurality of shelves 12b for storing food and the like, and the box main body 1 extends between the uppermost storage space 12c and the second storage space 12d partitioned by the uppermost shelf 12b. The recessed part 12 provided in the back upper part of is traveling as a convex part 12e.

In such a configuration, as the compressor 11 moves, the freezer compartment 4 and the vegetable compartment 3 are reduced in height by the storage volume of the compressor 11, so that the partition wall that partitions the refrigerator compartment 2 and the vegetable compartment 3 The position can be lowered downward, and the stored items in the vegetable room 3 can be easily taken out.
JP-A-11-183014

  However, in the above-described conventional configuration, even if the storage property of the lower stage of the refrigerator is improved, the convex portion 12e formed in the upper corner portion of the refrigerator is poorly designed and the storage property is also reduced. In order to reduce the height of the concave portion 12, it is necessary to lower the concave portion 12, and there is a problem of reducing the height of the compressor 11, which is the maximum factor for determining the height of the concave portion 12.

  Further, in order to reduce the height of the concave portion 12 in which the compressor 11 is installed as much as possible, a horizontal rotary compressor having a rotary compressor mechanism can be an effective means in terms of the type and form of the compressor 11.

  However, in general, a rotary compressor has a structure in which a machine part is directly fixed to an inner surface of a compressor shell, which is a container, in order to realize downsizing, and vibrations during operation are easily transmitted to the outside. For this reason, in the compressor upper arrangement type refrigerator in which vibration is likely to be transmitted to the refrigerator box main body 1, the position of the compressor 11 is closer to the user's ear than the conventional refrigerator of the compressor lower installation type. Therefore, there is a problem that the resonance sound due to the vibration of the compressor 11 and vibration transmission is likely to be uncomfortable, and the improvement of the usability and the appearance quality by the reduction of the compressor installation space and the reduction of vibration and noise are achieved. There was a problem that it was difficult.

  In addition, the top surface 11a, which is difficult to reach in the refrigerator and is not easily stored, is effectively used for purposes other than storage, and it is a problem to improve the convenience of the refrigerator without reducing the substantial storage capacity.

  That is, it is a problem relating to the entire refrigerator to increase the internal volume in the warehouse as much as possible to the external volume determined by the external dimensions of the box body 1 in order to improve the storage of food and the like with the transfer of the compressor. But it was.

  On the other hand, in the upper corner portion of the refrigerator, when the protrusion to the interior by the recess 12 protrudes downward from the shelf bottom of the uppermost storage space 12c, it is in the vicinity of the height of the user's eyes. The appearance design of the inside deteriorates the quality of the refrigerator, which is not preferable.

  Also, when storing food etc. by hand in the second storage space, the depth on the back side is lower than the height of the frontage. When taking out food, etc., there was a problem that it would not come out if it was tilted.

  Furthermore, as a problem in terms of cooling performance, it was necessary to efficiently cool the compressor 11 installed in the recess 12 across the top surface 11a and the back surface 11b.

  The present invention solves the above-described conventional problems, and aims to provide a refrigerator that achieves both storage efficiency and usability, and can achieve these without impairing the appearance design and the quality of cooling performance. To do.

In order to solve the above problems compression refrigerators of the present invention, which is housed a box body having a storage compartment having a door on the front is arranged, in a recess recessed across the top surface and the back surface of the box body The compressor includes an electric element composed of a stator and a rotor and a compression element driven by the electric element in a hermetic container having an upper container and a lower container by a support member. while supporting the vessel, there is installed in the recess via an elastic member by a leg fixed to the lower container, as the top portion of the compressor is lower than the top surface of the box body, the The electric element of the compressor is an inverter-driven electric motor that is operated at a plurality of revolutions, and a permanent magnet is used for the rotor of the electric element to reduce the height of the compressor, and to the lower container Is curved from the outer periphery of the sealed container. A convex hump portion formed in a small convex shape and a concave shape. The convex hump portion has a support hump portion to which a lower end surface of the support member is fixed and a leg of the compressor fixed. Each of which is shifted from each other, and the concave bump portion is continuously formed on the support bump portion .

  As a result, the storage capacity of the lower part of the refrigerator is improved, and the protrusion (convex part) of the concave part to the storage space side is reduced to improve the appearance, so that the effective space is not infringed. The storage space becomes larger and the storage performance can be greatly improved.

  In addition, by this, if there is a flat curved surface close to the flat surface portion by reducing the height of the compressor, the portion becomes less rigid, and even if it is susceptible to noise and vibration, The hump portion can improve the rigidity around the hump portion, and can provide a compressor with reduced vibration and noise.

  The refrigerator of the present invention has improved usability by increasing the inner volume of the lower stage of the refrigerator, and has a small protrusion to the inner side of the compressor housing space arranged in the upper part of the refrigerator, in harmony with the internal structure. It is possible to provide a refrigerator with good appearance and improved storage.

  Moreover, the refrigerator which reduced the vibration and noise more can be provided by reducing the vibration transmission from a compressor.

According to a first aspect of the present invention includes a box body that storage compartment having a door on the front is disposed, a compressor is accommodated in the top surface and recesses recessed over the back of the box body has the compressor, a compression element driven stator in a sealed container having an upper container and the lower container and the electromotive element consisting of a rotor by the electric element to the lower vessel by a support member while supporting the be one that is installed in the recess via an elastic member by a leg fixed to the lower container, as the top portion of the compressor is lower than the top surface of the box body, the compressor The electric element is an inverter-driven electric motor that is operated at a plurality of rotational speeds, and the height of the compressor is reduced by using a permanent magnet for the rotor of the electric element. The curvature is smaller than the outer periphery of the sealed container The convex-shaped bump portion includes a support bump portion to which a lower end surface of the support member is fixed and a leg bump to which a leg of the compressor is fixed. And the concave bump portion is continuously formed on the support bump portion .

As a result, the cylinder capacity of the compression element can be made compact by guaranteeing the refrigeration capacity at high load by varying the frequency, and an inverter motor using a permanent magnet eliminates the need for an excitation current necessary for generating rotational torque. The thickness of the stator and rotor can be reduced, and as a result, the height of the compressor and electric elements of the compressor can be reduced to reduce the overall height of the compressor, and the recess where the compressor is installed Since the height of the refrigerator can be reduced, the storage capacity of the lower part of the refrigerator is improved, and the protrusion (convex part) of the recess to the storage space side in the storage is reduced to improve the appearance, and the storage space in the storage is If the flat curved surface close to the flat surface is reduced by reducing the height of the compressor, the rigidity becomes weak and noise and vibration are reduced. Influenced by Even if Kunar, the Cobb unit, it is possible to improve the rigidity of the peripheral Cobb unit, also, by continuously forming small irregularities of curvature complicated shape, improve the rigidity of the Cobb unit By doing so, a compressor with reduced vibration and noise can be provided.

The invention described in claim 2 is the invention according to claim 1, the contact surface between the legs and the elastic member of the compressor is arranged above the lowermost portion of the compressor, the elastic member The height is made larger than the distance between the installation surface of the compressor in the recess and the lowest part of the compressor.

  As a result, it becomes a bulge in the refrigerator cabinet, which impairs the design and storage properties, and is effective for reducing vibration transmission from the compressor while reducing the height of the recess for storing the compressor. Since the height of the elastic member can be increased and the vibration can be further attenuated, it is possible to provide a high-quality refrigerator by reducing unpleasant vibration and generation of noise caused by the vibration.

The invention according to claim 3 of the present invention is the invention according to claim 1 or 2 , wherein the distance between the center of gravity of the compressor in the vertical direction and the contact surface between the leg of the compressor and the elastic member is This is shorter than the distance between the center of gravity of the compressor in the vertical direction and the lower end surface of the support member.

  As a result, the amplitude of the vibration of the compressor is less than the vibration of the lower surface of the support member that supports the mechanical unit, because the entire compressor vibrates around the center of gravity where the vibration near the center of gravity is the smallest and increases as the distance from the center of gravity increases. However, since the vibration amplitude of the contact surface between the leg closer to the center of gravity and the elastic member becomes smaller, vibration transmission to the refrigerator can be further reduced, and there is no unpleasant vibration or generation of noise due to vibration. A high-quality refrigerator can be provided.

According to a fourth aspect of the present invention, in the invention according to any one of the first to third aspects, the contact surface between the leg of the compressor and the elastic member is located above the lower end surface of the support member. It is what is located.

  As a result, the vibration of the compressor is transmitted downward through the support member from the mechanical part which is the vibration generation source, and then the direction is changed upward and transmitted to the elastic member through the leg part. Therefore, since the vibration transmission path becomes complicated, the vibration is further attenuated in the transmission path, and further, the distance from the support member to the contact surface between the leg of the compressor and the elastic member can be increased. The vibration transmission in the high area is attenuated, and the amplitude of the vibration of the contact surface between the leg and the elastic member is reduced. Further, vibration transmission to the refrigerator can be reduced, resulting in unpleasant vibration or vibration. A high-quality refrigerator that does not generate noise can be provided.

According to a fifth aspect of the present invention, in the invention according to any one of the first to fourth aspects, the legs of the compressor are fixed surfaces that are fixed to the sealed container, bent portions that rise upward, and elastic members. It has an elastic member arrangement lower surface which latches.

  As a result, the legs can be positioned on the lower side of the closed container with good workability such as joining, and the surface on which the elastic member is disposed can be the lower surface of the elastic member disposed closer to the center of gravity, and the bent portion can be formed. It can be formed by simple leg bending and is very easy to manufacture.

  Further, by forming the bent portion, it is possible to increase the distance from the surface where the leg is fixed to the sealed container to the lower surface where the elastic member is disposed, and the distance of vibration transmission from the surface is increased. In particular, transmission in a high frequency region is attenuated, and vibration transmission to the refrigerator can be further reduced. Therefore, manufacture is easy and vibration transmission to the refrigerator can be reduced, and providing a high-quality refrigerator free from unpleasant vibration and noise generation due to vibration can be achieved at low cost.

The invention according to claim 6 of the present invention is the invention according to claim 5 , wherein the leg is provided with ribs extending over at least two places of the fixing surface, the bent portion, and the elastic member arrangement lower surface. .

  As a result, the rigidity of the leg increases, the eigenvalue of the leg itself increases, and the leg itself hardly vibrates, so that the elastic member placement bottom surface of the leg, the elastic member, the refrigerator main body, Vibration transmission can be further reduced. Further, the rib can be formed by a press that is easy to manufacture, and the strength of the leg is increased. Therefore, another problem that is caused when the leg is deformed by the transport impact of the refrigerator can be improved.

  Therefore, manufacture is easy and vibration transmission to the refrigerator can be reduced, and providing a high-quality refrigerator free from unpleasant vibration and noise generation due to vibration can be achieved at low cost.

The invention described in claim 7 is the invention according to claim 1, provided with a recess in the compressor installation surface of the recess, by disposing the elastic member in the recess, the elastic member The compressor is mounted so that the height is larger than the distance between the installation surface of the compressor and the lowest part of the compressor.

  Thereby, the height of the elastic member effective for transmitting the vibration from the compressor to the refrigerator can be increased. On the other hand, the wall thickness of the installation surface is a factor that determines the size of the convex part into the refrigerator compartment, but a certain amount of thickness is necessary as a structure that supports the compressor in order to obtain the cooling characteristics of the refrigerator. However, with the formation of the recess, it is possible to reduce vibration transmission by increasing the height of the elastic member, ensure cooling characteristics by ensuring the thickness of the installation surface, and ensure the strength as a structure that supports the compressor. Since the height of the elastic member effective for transmitting the vibration from the compressor can be increased, unpleasant vibration and noise generation due to the vibration can be greatly reduced, and the refrigerator Therefore, it is possible to maintain the characteristics by securing the heat insulating property of the steel and to maintain the transport resistance by securing the strength of the structure, and to provide a high-quality refrigerator.

According to an eighth aspect of the present invention, in the invention according to the seventh aspect, at least the lower side of the elastic member is fitted and fixed using the entire circumference or a part of the recess provided on the compressor installation surface. Is.

  As a result, it is possible to fix the position of the elastic member without adding extra parts, eliminate the displacement of the compressor, reduce the vibration transmission change due to the change of the support surface of the elastic member, and the refrigerator installation surface of the elastic member It is possible to provide a high-quality refrigerator that greatly reduces the generation of unpleasant vibrations and noise caused by vibrations at low cost and with improved transport resistance.

According to a ninth aspect of the present invention, in the invention according to any one of the first to eighth aspects, the compression element is elastically supported with respect to the sealed container, and reciprocates between the compression chamber and the compression chamber. It is equipped with a reciprocating compressor equipped with a moving piston.

  This makes it easier to reduce the vibration of the compressor as compared to a horizontal rotary compressor, etc., but the height of the compressor is large due to the structure, so there is a limitation in application to the refrigerator with the compressor placed on top. Even if it is a reciprocating compressor, the overall height of the compressor can be reduced, and vibration that becomes a big problem when the compressor is placed on the top can be reduced. Even in refrigerators with an upper compressor arrangement where vibrations may be transmitted, a user-friendly refrigerator that improves the storage capacity of the lower stage of the refrigerator by reducing the height of the recess where the compressor is installed while removing the user's discomfort Can be provided.

According to a tenth aspect of the present invention, in the invention according to any one of the first to ninth aspects, the compression element is provided in a shaft having a main shaft portion and an eccentric portion, and the main shaft portion. The rotor has a bearing portion that pivotally supports the main shaft portion, has a rotor recess on the compression element side of the rotor, and the bearing portion extends into the rotor recess.

  Thus, in the reciprocating compressor, the length of the main bearing is shortened according to the present invention, while securing the bearing length for pivotally supporting the shaft, which is one of the major problems in reducing the height. By arranging the electric element and the compression element so as to overlap each other on the projection surface in the height direction, the overall height of the machine part including the electric element and the compression element can be greatly reduced. The height of the compressor can be further reduced without lowering the reliability.

According to an eleventh aspect of the present invention, in the invention according to any one of the first to tenth aspects, the compressor is an internal low-pressure type, and the electric element is disposed below the sealed container. The compression element is elastically supported via a support member with respect to the sealed container, and the compression element is disposed on an upper portion of the electric element and is provided with a high-pressure pipe having an elastic shape with respect to the sealed container. Is connected through the network.

  Thereby, since the compression element which is a vibration source of the compressor is arranged via the electric element portion with respect to the elastic support portion in the hermetic container, the elastic support portion can be compared with the case where the compression element is directly elastically supported. The vibration generated by the compression element is further attenuated when passing through the stator of the highly rigid electric element and then transmitted from the elastic support portion of the compressor to the outside of the compressor. Therefore, vibration of the compressor can be reduced. For this reason, even in the compressor top-position type refrigerator where the compressor position is close to the user's ear, the height of the recessed portion in which the compressor is installed is reduced while removing the user's discomfort, and the lower storability of the refrigerator An easy-to-use refrigerator with improved quality can be provided.

  In addition, the high-pressure piping of the compression element is made of an elastic shape, so that the vibration of the compression element is sufficiently attenuated by the high-pressure piping and then transmitted to the outside of the compressor, so that the vibration of the compressor can be further reduced. it can.

According to a twelfth aspect of the present invention, in the invention according to any one of the first to eleventh aspects, the uppermost storage of the storage chamber located at the uppermost position among the storage chambers provided in the box body. The shelf bottom portion of the space and the indoor side bottom wall surface of the concave portion are substantially the same horizontal plane.

  As a result, the compressor can be stored in the predetermined recess in a state in which the shelf of the uppermost storage space and the bottom wall surface on the indoor side of the compressor storage recess are substantially continuously connected in appearance.

  Furthermore, when storing or taking out food, etc. in the second storage space from the top of the refrigerator, the height of the frontage is the same as far as it goes, so food is not caught on the way and can be taken in and out. This makes it easier to use and improves usability.

The invention according to claim 13 of the present invention is the invention according to claim 12 , wherein the height of the uppermost storage space is such that a 350 ml can beverage standard product can be made and stored.

  As a result, the compressor is installed at the rear of the uppermost part, and while digging into the inside of the cabinet, it balances the appearance with the uppermost storage space and is usually unusable. The rear space, which is particularly inconvenient to use, is placed in the compressor housing recess, and the canned beverage that is often stored in the refrigerator in the front space is relatively easy to use. Therefore, the total number of storages in the refrigerator compartment increases, and the uppermost storage space can be used effectively.

The invention according to claim 14 of the present invention is the refrigerator of the invention according to any one of claims 1 to 13, wherein the height of the top surface of the box body from the floor surface is 1800 mm or less. .

  In this way, considering the ease of use in the cabinet so that women of standard Japanese height are easy to use, the height of the compressor 11 is made as compact as possible within this height range, so that the inside of the warehouse is effective. Space infringement can be suppressed and storage efficiency can be maximized.

  Embodiments of a compressor according to the present invention will be described below with reference to the drawings. The present invention is not limited to the embodiments.

(Embodiment 1)
1 is a schematic sectional view of a refrigerator according to Embodiment 1 of the present invention, FIG. 2 is a schematic rear view of the refrigerator according to the embodiment, and FIG. 3 is a schematic exploded view of components of the refrigerator according to the embodiment. 4 is a longitudinal sectional view of the compressor of the refrigerator in the embodiment, FIG. 5 is a horizontal sectional view of the compressor of the refrigerator in the embodiment, and FIG. 6 is an induction of the compressor of the refrigerator in the embodiment. FIG. 7 is a plan view of the salient pole concentrated winding stator of the refrigerator compressor in the embodiment. FIG. 8 is a perspective view of a leg portion of the compressor of the refrigerator in the same embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS. In addition, about the same structure as background art, the same code | symbol is attached | subjected and detailed description is abbreviate | omitted.

  1 to 3, a box body 1 includes a heat insulator 15 that foams and fills a space formed by an inner box 13 formed by vacuum forming a resin body such as ABS and an outer box 14 using a metal material such as a pre-coated steel plate. It is equipped with a heat insulating wall. As the heat insulator 15, for example, a hard urethane foam, a phenol foam, a styrene foam, or the like is used. As the foam material, it is better to use hydrocarbon-based cyclopentane from the viewpoint of preventing global warming.

  The box body 1 is divided into a plurality of heat insulating sections, and a door 15a is provided on the front surface. The door 15a is configured such that the upper part is a revolving door type and the lower part is a drawer type. The heat-insulated storage room 15b is a refrigerator room 2, a drawer-type switching room 16 and an ice making room 17, a drawer-type vegetable room 3, and a drawer-type freezer room 4 provided side by side. Each heat insulation section is provided with a door 15 a having heat insulation properties via a gasket 18. From the top are the refrigerating room rotary door 5, the switching room drawer door 19, the ice making room drawer door 20, the vegetable room drawer door 6, and the freezer compartment drawer door 7.

  The refrigerator compartment revolving door 5 is provided with a door pocket 21 as a storage space, and a plurality of storage shelves 22 are provided in the warehouse.

  Next, details of the box body 1 will be described. The outer box 14 of the box body 1 has a U-curved outer shell panel 24 cut out from the top surface 23, a bottom panel 25, a back panel 26, and a machine room panel 28 that forms a recess 27 to ensure sealing performance. And is constructed by assembling. The assembled box body 1 has a recess 27 formed in a portion extending over the top surface 23 and the back surface 28a. The concave portion 27 is convex on the uppermost storage space 29a defined by the uppermost shelf 29 and the inner box 13 and the second shelf storage space 30a defined by the second shelf 30 and the uppermost shelf 29. I am on a business trip as 30b. More preferably, the indoor side bottom wall surface 30c of the convex portion 30b and the shelf bottom portion 30d of the uppermost shelf 29 are substantially the same horizontal plane.

  In addition, the bottom panel 25 and the back panel 26 are provided with handles made of depressions that can be hooked with fingertips.

  Further, the inner box 13 is slightly smaller than the outer box 14, and the back portion of the inner box 13 is recessed inward, and a space in which the heat insulating body 15 is foam-filled by being incorporated in the outer box 14 is a box body. 1 is formed. Therefore, the left and right parts of the machine room panel 28 are also filled with the heat insulator 15 to form heat insulating walls, and the strength is also ensured.

  Next, the refrigeration cycle will be described. In the refrigeration cycle, the compressor 11 disposed on the installation surface 28 b of the recess 27, the discharge pipe 31 connected to the compressor 11, the top surface 23 and the side surface of the outer shell panel 24, the condensation provided on the recess 27 and the bottom panel 25. A vacuum chamber (not shown), a capillary 32 as a decompressor, a dryer (not shown) for removing moisture, an evaporator 9 having an internal fan 8 disposed in the vicinity of the back of the vegetable compartment 3 and the freezing compartment 4 The suction pipe 33 is connected in a ring shape.

  The recess 27 is provided with a top cover 34 fixed with screws or the like. The compressor 11 and the machine room fan 34a, the condenser (not shown), and the dryer (not shown) provided in the recess 27 are provided. A part of the discharge pipe 31 and the suction pipe 33 are accommodated. The upper portion of the top cover 34 is substantially flush with the top surface 23, and the top 34 b of the compressor 11 is located at a position lower than the top surface 23.

  The capillary 32 and the suction pipe 33 are copper pipes having substantially the same length, and are soldered so as to allow heat exchange with the end portion remaining. The capillary 32 is a small-diameter steel pipe having a large internal flow resistance for decompression. The inner diameter of the capillary 32 is about 0.6 mm to 1.0 mm, and the amount of decompression is designed by adjusting with the length. The suction pipe 33 uses a large-diameter copper pipe to reduce pressure loss, and its inner diameter is about 6 mm to 8 mm. Further, the capillary 32 and the suction pipe 33 are arranged in a compact manner by meandering the back surface of the refrigerator 2 in order to ensure the length of the heat exchanger section 35, and are located between the inner box 13 and the back panel 26. It is embedded in the heat insulator 15. One end of the capillary 32 and the suction pipe 33 protrudes from the vicinity of the rear of the vegetable compartment 3 of the inner box 13 and is connected to the evaporator 9, and the other end is connected to the edge of the installation surface 28 b of the machine room panel 28. It protrudes upward from the provided cutout and is connected to a dryer (not shown), a condenser (not shown), and the compressor 11.

  In addition, the suction pipe 33 and the discharge pipe 31 are provided with a U-turn portion 36 in the vicinity of the connection portion with the compressor 11 for providing connection flexibility, and are accommodated in the recess 27. Furthermore, with the aim of improving assembly workability and serviceability, in order to reduce the density of piping and to make the piping connection portion visible from the rear, the piping connection portion faces the back side of the compressor 11. Thus, the compressor 11 is arranged on the left and right sides of the compressor 11.

  Next, details of the compressor 11 will be described.

  4 to 8, a mortar-shaped lower container 101 formed by deep drawing a rolled steel plate having a thickness of 2 to 4 mm is engaged with an inverted mortar-shaped upper container 102, and the engagement portion is welded all around. The sealed container 103 is formed by joining, and the refrigerant 104 and the refrigerating machine oil 105 are stored inside the sealed container 103 at the bottom. A leg 106 is fixed to the lower side of the airtight container 103, and a hole 109 of the elastic member 107 is loosely connected to a pin 108 provided in the recess 27 of the refrigerator via an elastic member 107 locked to the leg 106. The position is fixed by fitting.

  Further, the leg 106 is elastically supported in the hermetic container 103 via a support portion 113a as a support member and a spring 114, and the vertical center of gravity A of the compressor 11, the leg 106 of the compressor, the elastic member 107, and the like. The distance B with the contact surface 106a is shorter than the distance C between the vertical center of gravity A of the compressor 11 and the lower end surface 113b of the support member.

  As in the present embodiment, when the center of gravity A in the height direction of the compressor is above the contact surface 106a between the leg 106 of the compressor and the elastic member 107, a support member inside the compressor The contact surface 106a between the leg 106 of the compressor and the elastic member 107 is located above the lower end surface 113b of the compressor.

  Moreover, the height of the elastic member 107 is made larger than the distance F between the installation surface D in the concave portion of the compressor and the lowest end E of the compressor.

  The leg 106 has a fixing surface 106b that is fixed to the closed container, a bent portion 106c that rises upward, and an elastic member arrangement lower surface 106d that locks the elastic member. The fixing surface 106b, the bent portion 106c, and the elastic member arrangement lower surface 106d. Ribs 106e extending across at least two of them are provided.

  The electric element 110 includes a rotor 111 and a salient pole concentrated winding stator 112. The compression element 113 is constructed above the electric element 110 and is driven by the electric element 110.

  The electric element 110 and the compression element 113 are both housed in the hermetic container 103 and elastically supported on the bottom of the lower container 101 and the lower end of the stator 112 via a support part 113a as a support member and a spring 114.

  A support portion 113a and a spring 114 provided at the lower end of the stator 112 are support members that elastically support the mechanical portion.

  A terminal 115 constituting a part of the lower container 101 is for communicating electricity (not shown) inside and outside the sealed container 103, and supplies electricity to the electric element 110 through a lead wire 116. Further, the sealed container 103 has a discharge tube 120 for connection to the discharge pipe 31 of the refrigeration system, a suction tube 121 for connection to the suction pipe 33, and a refrigerant 104 enclosed in the refrigeration system, and then the system is closed. A sealing tube 122 is provided.

  By the operation of the compression element 113, the refrigerant 104 is sucked into the sealed container 103 through the suction pipe 33 and the suction tube 121 and discharged from the discharge tube 120 to the discharge pipe 31.

  The discharge pipe 31 elastically connects the compression element 113 and the discharge tube 120 of the sealed container.

  Next, details of the compression element 113 will be described below.

  The shaft 130 has a main shaft portion 131 in which the rotor 111 is fixed by press-fitting or shrink fitting, and an eccentric portion 132 formed by being eccentric with respect to the main shaft portion 131. The cylinder block 133 has a substantially cylindrical compression chamber 134 and a bearing portion 135 for supporting the main shaft portion 131 of the shaft 130, and is formed above the electric element 110.

  At this time, a rotor recess 111a is formed on the compression element side of the rotor 111, and a bearing portion 135 extends into the rotor recess 111a.

  The piston 136 is loosely fitted in the compression chamber 134 and connected to the eccentric portion 132 of the shaft 130 by the connecting means 137, and the rotational motion of the shaft 130 is converted into the reciprocating motion of the piston 136. The refrigerant 104 in the sealed container 103 is sucked from the suction port 141 of the suction muffler 140 by enlarging and reducing the pressure, and is formed in the cylinder block 133 via a valve (not shown) provided in the cylinder head 142. The discharged muffler 143, the discharge pipe 144, and the discharge tube 120 are discharged to the discharge pipe 31 outside the sealed container 103.

  The discharge pipe 144, which is a high-pressure pipe, is a steel pipe having an inner diameter of 1.5 mm to 3.0 mm, and is formed so as to be flexible by using L-shaped or U-shaped bending. The tube 120 is connected with elasticity.

  Next, details of the electric element 110 will be described below.

  The rotor 111 includes a main body 150 in which silicon steel plates of 0.2 mm to 0.5 mm are stacked, a hole 152 that houses the permanent magnet 151 provided in the main body 150, and an end plate that closes the hole 152 after inserting the permanent magnet 151. 153 and is integrally fixed by caulking pins 154.

  The stator 112 includes a stator core 161 in which silicon steel plates having a thickness of 0.2 mm to 0.5 mm are stacked, and a winding 162 that is a copper wire having an insulation coating of 0.3 mm to 1 mm. The stator iron core 161 has salient pole portions 171 formed in an annular shape at a predetermined interval, and windings 162 are wound around the salient pole portions 171 (referred to as salient pole concentrated windings). They are connected together by a line 172.

  Next, the inverter motor and the induction motor will be compared and described.

  For easy understanding, FIG. 6 shows a comparison of the cross section of the induction motor on the left side and the cross section of the inverter motor on the right side with the center line as a boundary. Each electric motor is used for a compressor having approximately the same maximum refrigerating capacity. The height L1 of the stator core 161 of the stator 112 of the inverter motor is significantly lower than the height H1 of the stator core 181 of the stator 180 of the induction motor. The height L4 of the rotor 111 of the inverter motor is also lower than the height H4 of the rotor 182 of the induction motor. Further, in the inverter motor using salient pole concentrated windings, the coil end height at which the winding 162 protrudes from the stator core 161, and L2 and L3 are H2 of the coil end height of the winding 183 of the induction motor. , Much lower than H3. Further, by using a rare earth magnet as the permanent magnet 151, the height L5 of the permanent magnet 151, the height L1 of the stator iron core 161 of the inverter motor, and the height L4 of the rotor 111 can be further reduced.

  About the refrigerator comprised as mentioned above, the operation | movement and an effect | action are demonstrated below.

  First, the temperature setting of each heat insulation section will be described. The refrigerator compartment 2 is usually set at 1 to 5 ° C. with the lower limit of the temperature at which it does not freeze for refrigeration. The switching chamber 16 can be changed in temperature setting according to user settings, and can be set to a desired temperature range from the freezer temperature range to the refrigeration and vegetable room temperature ranges. The ice making chamber 17 is an independent ice storage chamber and is set at a relatively high temperature of -18 to -10 ° C.

  The vegetable room 3 is often set to 2 to 7 ° C., which is a temperature setting equal to or slightly higher than that of the refrigerator room 2. The freezer compartment 4 is usually set at −22 to −18 ° C. for frozen storage, but may be set at a lower temperature, for example, −30, in order to improve the storage state.

  Each chamber is divided by a heat insulating wall in order to efficiently maintain different temperature settings. The heat insulating wall is formed by foaming and filling the heat insulating body 15 between the inner box 13 and the outer box 14. . The heat insulator 15 has sufficient heat insulating performance and ensures the strength of the box body 1.

  Next, the operation of the refrigeration cycle will be described. The cooling operation is started and stopped by signals from a temperature sensor (not shown) and a control board (not shown) in accordance with the set temperature in the cabinet. In response to the instruction to start the cooling operation, the compressor 11 discharges the high-temperature and high-pressure refrigerant 104. The discharged refrigerant 104 passes through the discharge pipe 31 to dissipate heat in a condenser (not shown) to be condensed and liquefied, and is depressurized by the capillary 32 to become a low-temperature and low-pressure liquid refrigerant, reaches the evaporator 9, and reaches the evaporator 9. The refrigerant in the inside is evaporated and the low-temperature cold air subjected to heat exchange is distributed by a damper (not shown) to cool each chamber.

  Next, the operation of the compressor 11 will be described.

  When the compressor 11 is energized, electricity is supplied to the stator 112 of the electric element 110 through the terminal 115 and the lead wire 116, and the rotor 111 is rotated by the rotating magnetic field generated by the stator 112. Due to the rotation of the rotor 111, the eccentric portion 132 of the shaft 130 connected to the rotor performs a rotational motion that is eccentric from the axis of the shaft 130. The eccentric motion of the shaft 130 is converted into a reciprocating motion by the connecting means 137 connected to the eccentric portion 132 and becomes a reciprocating motion of the piston 136 connected to the other end of the connecting means 137, and the piston 136 is compressed into the compression chamber 134. The refrigerant 104 is sucked and compressed while changing the internal volume.

  The capacity of the piston 136 that is sucked and discharged during one reciprocation in the compression chamber 134 is referred to as a cylinder volume, and the ability to cool the cylinder volume changes.

  In the refrigerator that performs the operation as described above, the compressor 11 supported by the elastic member 107 and the legs 106 is mounted in a recess 27 formed across the top surface 23 and the back surface 28a of the refrigerator. The depth (height) of the recess is at least the minimum gap between the bottom of the lower container 101 of the compressor 11 and the installation surface 28b, the height of the compressor 11, and the minimum gap between the upper container 102 and the top cover 34, The thickness of the top cover 34 is necessary. In order to avoid contact between the compressor 11 and the installation surface 28b or the top surface cover 34, a minimum clearance is required, and the minimum thickness of the top surface cover 34 is determined from the strength surface. ) Is determined by the height of the compressor 11.

  On the other hand, the convex portion 30b is on a business trip by the concave portion 27 in the refrigerator. When the convex portion 30b is large, the storage property is deteriorated, and when the refrigerating chamber rotating door 5 is opened and the inside of the refrigerator compartment 2 is viewed, the appearance of the convex portion 30b is deteriorated. Therefore, a technique for reducing the height of the compressor 11 is required.

  The height of the compressor 11 will be specifically described. The compressor 11 uses steel plates of 2 to 4 mm for the lower container 101 and the upper container 102, and the total is about 7 mm. The lower container 101 and the upper container 102 each have a shape with a curvature in the vertical direction. This is because a specification with low noise is desired to make the living space where the refrigerator is installed comfortable. By giving the container a curvature, the rigidity and eigenvalue of the container are increased, and noise due to resonance is suppressed. The curvature is approximately R100 mm to R150 mm in radius, and in order to obtain this curvature, a little over 13 mm is required on one side.

  Next, refrigerating machine oil 105 is stored at the bottom of the sealed container 103. The refrigerating machine oil 105 is sealed in an amount of about 200 to 250 ml in order to guarantee the operation of the compressor 11 under various conditions, and occupies about 20 mm in height. Further, when the refrigerating machine oil 105 and the electric element 110 come into contact with each other, an abnormal increase in input occurs, so that a spatial distance of about 9 mm is necessary to prevent contact.

  In the refrigerator in which the compressor 11 is loaded on the top surface 23 of the refrigerator, since the compressor 11 approaches the position of the user's ear, it is more important to keep the noise of the compressor 11 small. Improvement is important, and securing the refrigerating machine oil 105 is also important from the viewpoint of improving reliability. For these reasons, the plate thickness is 7 mm, the curvature is 13 mm, the curvature and the oil are 20 mm, and 9 mm necessary for securing the clearance is required to be 49 mm. It is not appropriate in terms of characteristics to reduce this dimension.

  Therefore, the height of the compressor 11 is largely determined by the electric element 110 and the compression element 113. The compression element 113 can make the piston 136, the connecting means 137, the shaft 130, and the bearing portion 135 compact by reducing the cylinder volume. However, when the cylinder volume is reduced, the refrigerating capacity is reduced. In the present embodiment, in order to obtain a large capacity with a small cylinder volume, the compression element 113 is made compact by operating at a rotational speed higher than the commercial power supply frequency (50 Hz or 60 Hz in Japan). More specifically, since the cylinder volume can be reduced by about 30%, the diameter of the piston 136 can be reduced, and the load acting on the shaft 130 can be reduced. Therefore, the length of the bearing portion 135 that supports the shaft load is also reduced. Therefore, the electric element 110 can be configured close to the compression element 113. By making good use of the high rotation by the inverter, the inventor's design has been able to make it 5 to 10 mm compact.

  The setting of the plurality of rotation speeds of the electric element 110 by the inverter method does not necessarily include a rotation speed corresponding to a frequency higher than the commercial power supply frequency (50 Hz or 60 Hz) in Japan.

  That is, a combination of settings that does not exceed the upper limit of a plurality of determined frequencies exceeding the commercial power supply frequency (not limited to Japan) is expected to save energy and reduce noise. There is also a combination that corresponds to the effect and does not dare to make the cylinder volume of the compression element 113 compact.

  Next, as shown on the left side of the center line in FIG. 6, the electric element 110 has an torque required for the operation of the compressor 11 unless the thicknesses H1 and H4 of the stator 180 and the rotor 182 are large. Does not occur. On the other hand, the use of an inverter motor using permanent magnets 151 for the rotor 111 eliminates the need for an excitation current necessary for generating rotational torque, so the stack thickness L1 of the stator 112 and the stack thickness of the rotor 111 are eliminated. L4 can be lowered, and the electric element 110 can be made compact. More specifically, the induction motor has to pass a current to the rotor side (secondary side), and in order to obtain this exciting current, a high thickness is required. Since there is a magnet, no exciting current is required to generate torque, and the thickness can be reduced.

  Furthermore, the dimension of the winding 162 of the stator 112 of the electric element 110 protruding from the stator core 161 is larger than the protruding dimensions H2 and H3 of the winding 183 in the distributed winding. Since it does not cross between distant slots and is concentrated and densely wound around each salient pole part, the winding does not rise due to the winding crossing between the slots, and as shown in L2 and L3 The overall height of the stator 112 is reduced, and the electric element 110 can be made more compact.

  Furthermore, when a rare earth magnet is used for the permanent magnet 151 of the inverter motor, the magnetic properties are about 4 times that of a general ferrite magnet, and the energy product is about 10 times that of the magnetic product. Sufficient characteristics can be obtained. Therefore, the height L5 of the permanent magnet 151 and the height of the stator L1 can be further reduced, and the electric element 110 can be further compacted.

  Further, in the present embodiment, a rotor recess 111a is formed on the compression element 113 side of the rotor 111, and a bearing portion 135 extends into the rotor recess 111a. By arranging the electric element 110 and the compression element 113 so as to overlap each other on the projection surface in the height direction without shortening the length of the bearing part 135, the entire mechanical part including the electric element 110 and the compression element 113 can be obtained. The height can be greatly reduced, and the height of the compressor can be further reduced without reducing the reliability of the compressor.

  More specifically, in the design of the inventor, in the induction motor, the stack thickness of the stator 180 is 42 mm, the coil end heights H2 and H3 of the winding 183 are 25 mm, and the height H4 of the rotor 182 is 65 mm. On the other hand, in the inverter motor, when the stator L has a stack thickness L1 of 26 mm, and a rare earth magnet is used, the lower L1 is 16 mm, and the coil end heights L2 and L3 of the winding 162 of the stator 112 are When salient pole concentrated winding is used, L2 and L3 are 9 mm. Further, the rotor 111 has a thickness of 35 mm and can be reduced to 20 mm when a rare earth magnet is used, and can be reduced by a maximum of 58 mm compared to a compressor using an induction motor.

  Further, as described above, the rotor recess 111a is formed on the compression element 113 side of the rotor 111 at a depth of more than half of the height of the rotor, and the bearing portion 135 is formed in the rotor recess 111a. Since the extension of the rotor 111 is 35 mm and the rare earth magnet is used, the height of the machine part can be further reduced to about 10 mm, which is the extension of the bearing part 135. Therefore, the height of the entire machine part can be reduced by about 25 mm in total.

  Thus, by extending the extension allowance of the bearing portion 135, the sliding length between the shaft 130 and the bearing portion 135 can be increased without increasing the overall height, and the compression load applied to the shaft 130 can be reduced. As a result, the reliability of the compressor can be improved.

  However, as the extension length of the bearing portion 135 is increased, the depth of the rotor recess 111a is increased, so that the fixing margin of the rotor 111 to the shaft 130 is shortened.

  In particular, in a compressor arranged such that the compression element 113 is at the upper part and the electric element 110 is located at the lower part as in the present embodiment, the rotor provided in the lower electric element 110 is a shaft. For example, an induction motor such as an induction motor that obtains a magnetic force by flowing current inside the rotor, such as an induction motor, uses the rotor 111 during operation. Since there is a possibility that the rotor 111 is detached from the shaft 130 due to thermal expansion and thermal expansion, there is a problem in reliability to significantly reduce the fixing allowance of the rotor 111 to the shaft 130. However, according to the inventor's study, when the permanent magnet 151 is used, heat is generated because the magnetic force is obtained by the permanent magnet without current flowing through the rotor 111. Has become much smaller, and further compared with the induction motor, the weight by height lowered is lighter, it is possible to hold the rotor 111 also greatly shorten the sticking margin. For example, even if the fixing allowance is reduced to about 6 mm, which is 20% or less with respect to the total height of 35 mm of the rotor 111, the fixing force is sufficient, and the rotor 111 is caused by heat generated during operation, vibration or impact due to transportation, etc. There is no possibility of falling off the shaft 130, and it is possible to improve the reliability by increasing the sliding length of the shaft 130 and the bearing portion 135 and to secure the fixing force between the rotor 111 and the shaft 130. The overall height of the mechanical unit composed of the compression element 113 and the electric element 110 can be reduced.

  In addition, since the fixing allowance of the rotor 111 is shortened, the oil supply capability by an oil supply mechanism (not shown) provided inside the shaft 130 can be improved. This is a lift in which the distance between the bearing portion 135 and the lowermost sliding end of the shaft 130 and the refrigerating machine oil 105 is raised to the spiral groove for refueling the shaft 130, and this lift is significantly shortened. Because. As a result, the oil supply capability to the sliding portion between the shaft 130 and the bearing portion 135, the sliding portion of the compression element 113 via the shaft 130, and the like can be improved, thereby improving the reliability.

  In particular, when the compressor 11 is operated at a lower speed by mounting the inverter motor as in the present embodiment, the improvement in the oil supply capability is obtained by increasing the centrifugal force of the shaft in proportion to the decrease in the rotational speed. However, even if the compressor 11 is operated at a lower speed, the refrigerating machine oil to the sliding portion is improved by improving the oil supply capacity. 105 can be stably supplied.

  Thus, in order to achieve downsizing in the height direction while achieving both prevention of falling off of the rotor 111 and improvement of oil supply reliability, a permanent magnet is used for the rotor 111 having a total height of 35 mm, and rotation at 50 Hz. An experiment for confirming the oil supply amount was performed by changing the fixing margin between the rotor 111 and the shaft 130 in terms of the number.

  As a result, when the fixing allowance between the rotor 111 and the shaft 130 is 50% compared to 80% of the total height of the rotor, the oil supply amount is improved by about 3%, and a certain effect on the oil supply amount improvement is obtained. In the case of 30%, the amount of oil supply was improved by about 5%, and in the case of 15%, the amount of oil supply was improved to about 8%.

  Furthermore, in order to confirm the improvement of the oil supply reliability at the time of low rotation by the inverter compressor, as a result of an experiment for confirming the oil supply amount at 20 HZ, the fixing allowance between the rotor 111 and the shaft 130 is 80% of the total height of the rotor. Compared to the above case, when 50%, the oil supply amount is improved by about 5%, and a certain effect for improving the oil supply amount starts to be obtained, and when it is further 30%, the oil supply amount is improved by about 10%. However, in the case of 15%, the amount of oil supply was improved to about 15%.

  In this way, by extending the bearing into the rotor, the lift for raising the refrigerating machine oil 105 to the spiral groove for refueling is shortened, improving the refueling reliability, and during normal rotation and low rotation When both are set to 50% or less, an effect starts to be obtained, and when the content is desirably set to 30% or less, a certain effect margin is obtained. Further, when the fixing allowance is further shortened and reduced to about 15%, the effect is further enhanced, but there is a case where the influence of reliability of the rotor holding starts to appear, and it is necessary to sufficiently confirm the adoption. Therefore, it is desirable that the adhering allowance should not be less than 15% as much as possible, and if it is 10% or less, the reliability of holding the rotor is greatly lowered and should be avoided.

  In particular, at the time of low rotation, shortening the head for raising the refrigerating machine oil 105 to the spiral groove for oil supply is very effective for improving the oil supply amount. In recent years, energy saving of refrigerators has been promoted, and operation of a compressor with low rotation that is effective for energy saving is becoming mainstream. However, at this low speed, the amount of oil supply inevitably decreases, so that various improvements have been made in the oil supply structure inside the compressor to improve the amount of oil supply. The focus of improving the oil supply amount by shortening the cost is a technology that has multiple beneficial effects such as reducing the overall height of the compressor and lowering the center of gravity, as well as improving the oil supply amount at low rotation .

  As described above, the inverter drive that operates the electric element 110 of the compressor 11 at a plurality of rotation speeds including at least a frequency higher than the commercial power supply frequency so that the top of the compressor 11 is lower than the top surface 23 of the box body 1. By using the permanent magnet 151 for the rotor 111 of the electric element 110, the compressor 11 can be made smaller, and the height of the recess 27 in which the compressor 11 is installed can be reduced, so that the lower storability of the refrigerator is improved. In addition, the protrusion of the concave portion 27 toward the storage space in the storage space can be reduced to improve the appearance, the storage space in the storage space can be widened, and the storage performance can be greatly improved.

  Further, a salient pole concentrated winding type in which a plurality of salient pole portions 171 of a stator iron core 161 constituting the stator 112 of the compressor 11 are wound with a winding 162 via an insulator, or a rare earth element is provided on the permanent magnet 151. By using a magnet, the compressor 11 can be further reduced, and the height of the concave portion 27 in which the compressor 11 is installed can be reduced, so that the storage property of the lower stage of the refrigerator is improved and the concave portion 27 is moved to the storage space side in the cabinet. The protrusion of the convex portion 30b can be made small to improve the appearance, the storage space in the warehouse can be widened, and the storage performance can be greatly improved.

  On the other hand, in the compressor 11 of the present embodiment, in particular, the compression element 113 employs a reciprocating type including a compression chamber 134 and a piston 136 that reciprocates within the compression chamber 134. The compression element 113 and the electric element 110 are elastically supported via a spring 114.

  As described above, by reducing the height of the compressor 11 with elements other than the support structure portion of the compression element 113 and the electric element 110, the vibration can be reduced as compared with a rotary compressor or the like. In addition, the height of the compressor can be reduced even if it is a reciprocating compressor that has a limitation of application in a refrigerator with an upper arrangement type compressor. Since it becomes possible to reduce the vibration which becomes a big subject when arrange | positioning in the upper part, even if it is a compressor top arrangement type refrigerator with a possibility that a vibration may transmit to the box main body 1, removing a user's discomfort It is possible to provide an easy-to-use refrigerator in which the height of the concave portion 27 in which the compressor 11 is installed is reduced and the storage property of the lower stage of the refrigerator is improved.

  The reciprocating compressor is an internal low-pressure type, and the electric element 110 is disposed below the sealed container 103 and supports the sealed container 103 via a support portion 113a and a spring 114. It is elastically supported, and the compression element 113 is disposed on the electric element 110 and connected to the sealed container 103 via a discharge pipe 144 that is a high-pressure pipe having an elastic shape. Since the compression element 113 that is a vibration source of the compressor is disposed via the electric element portion 110 with respect to the support member in the hermetic container 103, the compression element 113 is more elastic than the case where the compression element 113 is directly elastically supported. The distance from the support portion can be further increased, and the vibration generated in the compression element 113 is attenuated when passing through the stator of the electric element 110 having high rigidity, and then the support portion of the compressor. For transmitting from outside the compressor, it is possible to reduce the vibration of the compressor.

  Further, since the discharge pipe 144 which is a high-pressure pipe in the compression element 113 has an elastic shape, the vibration of the compression element 113 is attenuated by the discharge pipe 144 and transmitted to the outside of the compressor. Can be further reduced.

  Further, the leg 106 is elastically supported in the hermetic container 103 via a support portion 113a as a support member and a spring 114, and the vertical center of gravity A of the compressor, the leg 106 of the compressor, and the elastic member 107 are The distance B with the abutment surface 106a is shorter than the distance C between the center of gravity A in the vertical direction of the compressor and the lower end surface 113b of the support member, so that the vibration amplitude of the compressor is near the center of gravity A. Since the whole compressor vibrates around the center of gravity where the vibration is the smallest and the vibration increases as it moves away from the center of gravity, the contact surface between the leg 106 and the elastic member 107 closer to the center of gravity than the lower surface of the support member that supports the mechanical unit. Since the amplitude of vibration becomes small, vibration transmission to the refrigerator can be further reduced.

  Moreover, the permanent magnet 151 is used for the rotor 111, the height of the rotor 111 is made low, and the height of the stator 112 is made low by making the stator 112 into a salient pole concentrated winding type. The overall center of gravity can be lowered.

  Further, when the stator 112 is distributed winding, since the winding protrudes upward from the attachment portion of the cylinder block 133 to the stator 112, the dimension of the leg of the cylinder block 133 is larger than the protruding dimension of the winding. However, if the stator 112 is a salient pole concentrated winding type, it is possible to shorten the leg of the cylinder block 133 that is the attachment portion of the cylinder block 133 to the stator 112, and the compression element The center of gravity can also be lowered.

  Further, by extending the extension allowance of the bearing portion 135 of the cylinder block 133 to the rotor recess 111a, the cylinder block 133 can be lowered further and the center of gravity can be lowered.

  As described above, the center of gravity A of the mechanical portion inside the compressor is lowered, and the contact surface 106 between the leg 106 and the elastic member 107 provided in the sealed container 103 outside the compressor is positioned further upward. By doing so, the distance B between the center of gravity A, the contact surface of the leg 106 and the elastic member 107 is further reduced, and vibration transmission from the compressor to the refrigerator can be further reduced.

  This is especially important for refrigerators with a compressor placed at the top, where it is necessary to reduce the overall height of the compressor as much as possible, while at the same time achieving both low vibration and low noise. While various elements for downsizing the compressor are conceivable, in the internal configuration surface, by using the permanent magnet 151 for the rotor 111, while maintaining the holding effect of the rotor 111 by the shaft 130, The bearing portion 135 is further extended into the rotor to reduce the internal height, and on the external configuration surface, the mounting surface of the leg 106 on the elastic member 107 is raised, and the overall height can be increased even when installed in the refrigerator. A low-vibration compact compressor with low center of gravity and high support stability can be realized.

  Further, according to the present embodiment, the contact surface 106a between the leg of the compressor and the elastic member is located above the lower end surface 113b of the support member, whereby the vibration of the compressor generates vibration. After being transmitted downward through the support member from the mechanical part as the source, the direction changes upward and is transmitted to the elastic member 107 via the leg 106. Therefore, since the vibration transmission path becomes complicated, the vibration is further attenuated in the transmission path, and further, the distance from the support member to the contact surface 106a between the leg 106 of the compressor and the elastic member 107 can be increased. In particular, the vibration transmission in a high frequency region is attenuated, and the amplitude of vibration of the contact surface 106a between the leg 106 and the elastic member 107 is reduced. Further, vibration transmission to the refrigerator can be reduced, and unpleasant vibration or It is possible to provide a high-quality refrigerator that does not generate noise due to vibration.

  Further, the leg 106 has a fixing surface 106b that is fixed to the sealed container 103, a bent portion 106c that rises upward, and an elastic member disposing lower surface 106d that locks the elastic member. It is located on the fixed surface 106b of the lower portion of the closed container 103, and the surface on which the elastic member is arranged can be the elastic member arrangement lower surface closer to the center of gravity, by forming the bent portion by simple leg bending, It is very easy to manufacture.

  Further, the fixing surface 106b fixed to the closed container 103 of the leg 106 is below the lower end surface 113b that is the fixing surface of the support member 113a of the lower container 101, and the vibration of the compression element 113 that is the vibration source of the compressor. Is transmitted to the fixing surface of the support member 113a located farthest from the excitation source in the sealed container 103 through the electric element 110 and also through the spring 114 supported by the support member 113a. Therefore, the vibration is greatly damped.

  Further, the leg 106 extends from the fixing surface in a substantially horizontal direction, rises vertically upward by the formation of the bent portion 106c, and bends in the substantially horizontal direction again, and then the elastic member disposition lower surface 106d is formed. The vibration transmission path becomes complicated and long up to the contact surface 106a with the member 107, and the vibration transmission is attenuated. Further, the elastic member 107 has a lower elastic member arrangement lower surface 106d closer to the center of gravity A in the vertical direction of the compressor, and the elastic member 107 has a sufficient length. Therefore, vibration transmission to the refrigerator can be sufficiently reduced, and a high-quality refrigerator free from unpleasant vibration and noise caused by vibration can be provided.

  In the present embodiment, the vertical rising height is 24 mm. This is about 16% of the total height of the compressor.

  The vertical rising height is above the lower end surface 113b of the support portion 113a, but the lower end portion of the spring 114 engaged with the support portion 113a is fitted to the support portion 113a. In addition, since it is fixed to the sealed container without having elasticity, it is more desirable that it be above the lower end portion of the spring having elasticity with respect to the sealed container.

  Also, as the vertical rise height increases, the distance of the rising portion becomes longer, so it becomes difficult to obtain high rigidity at the rising portion. In such a case, a vibration phenomenon occurs in which the vertical direction is twisted back and forth around the contact surface 106a between the leg 106 and the elastic member 107, and stress concentration occurs around the rising portion of the leg 106. In view of the external impact force, it is considered desirable for the reliability of the compressor to be about 30% or less with respect to the total height of the compressor.

  Further, the formation of the bent portion 106c makes it possible to increase the distance from the surface where the leg 106 is fixed to the sealed container 103 to the lower surface where the elastic member 107 is disposed, and transmission of vibration from the fixing surface 106b. Since the distance becomes long, transmission in a particularly high frequency region is attenuated, and vibration transmission to the refrigerator can be reduced. Therefore, manufacture is easy and vibration transmission to the refrigerator can be reduced, and providing a high-quality refrigerator free from unpleasant vibration and noise generation due to vibration can be achieved at low cost.

  Furthermore, by providing the leg 106 with the rib 106e extending over the bent portion 106c and the elastic member arrangement lower surface 106d, the rigidity of the leg 106 is increased, the eigenvalue of the leg 106 itself is increased, and the leg 106 itself vibrates. Therefore, it is possible to further reduce vibration transmission from the fixing surface of the sealed container 103 to the elastic member and the refrigerator main body through the legs. Further, the rib can be formed by a press that is easy to manufacture, and the strength of the leg is increased. Therefore, another problem that the leg is deformed by the transport impact of the refrigerator can be improved.

  Therefore, manufacture is easy and vibration transmission to the refrigerator can be reduced, and providing a high-quality refrigerator free from unpleasant vibration and noise generation due to vibration can be achieved at low cost.

  As described above, the downsizing element in the height direction of the compressor 11 can be broadly distinguished from the viewpoint corresponding to the electric element 110 and the viewpoint corresponding to the compression element 113. Whether to keep it in any one of the elements may be selected based on a balance between a required value for height reduction and other characteristics and quality.

  For example, a method of mainly configuring a height reduction element that is combined with the electric element 110 that does not require relatively high-precision durability and reliability and is not likely to cause significant noise and vibration is a configuration in which the compressor 11 is disposed above. Is advantageous in that it can be downsized while suppressing the effects on noise and vibration.

  On the other hand, when trying to achieve the purpose by downsizing the compression element 113, it is possible to expect a reduction in size by reducing the cost, which is advantageous in terms of cost performance.

  In addition, as described above, the compressor 11 is arranged on the upper part of the box body 1 of the refrigerator so that it is closer to the user's ear, so that it is necessary to consider noise and vibration more than the conventional refrigerator, and the compression Miniaturization by reducing the height of the machine 11 is important in combination with miniaturization elements that do not affect the noise and vibration of the refrigerator, and the structure for supporting the electric element 110 and the compression element 113 and the sealed container 103 are provided. It is also effective to incorporate ingenuity to reduce the height while suppressing noise and vibration in the supporting structure, or to not incorporate a simple height reduction design that adversely affects noise and vibration.

  Next, focusing on the top storage space 29a and the second storage space 30a of the refrigerator, the back of the top storage space 29a is a hard-to-reach place, and the back of the top storage space 29 is closed by the convex portion 30b. Even if it is peeled off, the depth of use becomes shallow, and since there are stored items such as food within the reachable range, it can be prevented from being left behind after the expiration date, and the usability is improved. On the other hand, when the convex portion 30b travels to the second-stage storage space 30a side, the convex portion 30b becomes noticeable when the refrigerating chamber revolving door 5 is opened, and the appearance is deteriorated. There is an inconvenience that food or the like is difficult to put in and take out when storing or taking out the food, but the horizontal surface of the shelf bottom portion 30d of the uppermost storage space 29a and the convex portion 30b that is the indoor side bottom wall surface of the concave portion 27 Are substantially the same horizontal plane, and the compressor 11 can be accommodated in the predetermined recess 27 in a state where the external appearance is almost continuously connected and the protrusion of the protrusion 30b is not felt and the appearance is good. .

  Further, the protruding portion 30b does not feel the protrusion and the appearance is improved, and the stored items such as foods which are lower than the height of the opening of the second stage storage space 30a can be smoothly put in and out, and there is no inconvenience.

  Looking more specifically at the dimensions, the distance from the top surface 23 to the shelf bottom 30d of the uppermost storage space 29a is that the heat insulation wall thickness between the top surface 23 and the interior is 25 mm, and the height of the uppermost storage space 29a. Is 140 mm (because it is the uppermost part in the cabinet, the thickness is determined to be 140 mm when taking into consideration that the standard product of a 350 ml can drink with a height of 123 mm and a diameter of 66 mm is tilted and pulled out is 140 mm). Is 10 mm, it is 175 mm. The uppermost housing is provided with the thickness of the installation surface 28b of the compressor 11 of the recess 27 being 20 mm, the clearance between the compressor 11 and the installation surface 28b and the clearance between the inner surface of the top cover 34 being 3 mm each, and the thickness of the top cover 34 being 2 mm. If the shelf bottom 30d of the space 29a and the indoor side bottom wall surface 30c of the recess 27 are substantially the same horizontal plane, the maximum height of the compressor 11 that can be accommodated in the recess 27 is 147 mm.

  On the other hand, when the dimensions of the compressor 11 are seen more specifically, the total thickness of the lower container 101 and the upper container 102 of the sealed container 103 is 7 mm, and the height for obtaining the curvature of the upper container 102 is 14 mm. The upper part of the cylinder block 133 with the compression chamber 134 is 39 mm, the dimension to the stator 112 mounting surface on the side with the bearing portion 135 is 20 mm, the height of the stator 112 is 26 mm, the lower end of the stator 112 to the rotor 111 9 mm, the distance from the lower end of the rotor 111 to the refrigerating machine oil 105 is 9 mm, and the height of the refrigerating machine oil 105 is 20 mm. The total of these is 144 mm. 27 can be accommodated in a height space.

  Thus, since the height dimension of this type of compressor in a refrigerator with a standard capacity is generally 190 mm or more, a large height dimension can be reduced. In particular, by using an inverter motor using a permanent magnet 151 for the rotor 111 that is operated at a plurality of rotation speeds including frequencies higher than those of the commercial power supply, the compression element 113 and the electric element 110 of the compressor 11 can be appropriately dimensioned. The compressor 11 can be accommodated in the predetermined recess 27 while maintaining the rigidity for keeping the noise of the airtight container 103 good, and the convex portion which is the bottom wall surface on the indoor side of the recess 27. By making the horizontal plane of 30b substantially the same horizontal plane, it is possible to provide a refrigerator that is substantially continuous in appearance and does not feel the protrusion of the convex portion 30b and has a good appearance.

  Further, by incorporating the downsizing element in the height direction as the main component of the improvement of the electric element 110, the problem of ensuring the reliability of the noise and the vibration surface associated with the specification change of the compression element 113 is reduced. 11 can be an effective means for reducing the height while solving the problems of noise and vibration for a refrigerator in which noise and vibration are concerned by arranging 11 at the top of the refrigerator.

  In the present embodiment, the ground height of the box body 1, that is, the height of the top surface 23 from the floor surface is set to 1800 mm or less. This height is set based on the maximum height that can be reached by a Japanese woman of standard height reaching up.

  If the height of the top surface 23 from the floor surface is higher than 1800 mm, the height of the compressor 11 can be easily accommodated in the recess 27 without making the height dimension large and compact. Usability becomes even worse, making it difficult to achieve both storage efficiency and usability as a whole refrigerator.

  In the present embodiment, the height of the top surface 23 from the floor surface is suppressed to 1800 mm or less, so that the user-friendliness is first taken into consideration, and then the height of the compressor 11 is made as compact as possible within this height range. This makes it possible to maximize the merit of suppressing the invasion of the effective space inside the warehouse and maximize the storage efficiency.

  In the present embodiment, the rib 106e extending across the bending portion 106c and the elastic member disposing lower surface 106d is provided. The rib 106e is formed of the fixing surface 106b, the bending portion 106c, and the elastic member disposing lower surface 106d. Since it is desirable to provide the rib 106e extending over at least two places, the rib 106e may extend to the leg portion on the horizontal plane of the fixing surface 106b and the bent portion 106c.

  Furthermore, when extending over the three surfaces of the fixing surface 106b, the bent portion 106c, and the elastic member arrangement lower surface 106d, the rigidity can be further improved. In particular, the elastic member arrangement lower surface 106d is arranged significantly upward. In this case, the distance from the fixing surface 106d to the elastic member disposition lower surface 106d is greatly increased. By thus forming ribs across the three surfaces, improving the rigidity of the legs can reduce vibration and noise. It is very effective for the purpose of reduction.

(Embodiment 2)
Fig.9 (a) is a schematic sectional drawing of the refrigerator in Embodiment 2 of this invention, FIG.9 (b) is principal part sectional drawing of the refrigerator in Embodiment 2 of this invention.

  In addition, about the same structure as FIG. 1, the same code | symbol is attached | subjected and detailed description is abbreviate | omitted.

  In addition, although configurations and operational effects common to the first embodiment will not be described one by one, it is assumed that the same contents are included unless they are unreasonable when applied to the present embodiment.

  In FIG. 9A, a ventilation duct 201 communicating with the recess 27 is provided immediately below the top surface 200 of the box body 1, and the compressor 11 is located at a position higher than the lower surface 202 of the ventilation duct 201 and lower than the top surface 200. The compressor 11 is installed on the installation surface 28b of the recess 27 so that the top 203 comes. A condenser 204 is disposed above the ventilation duct 201, and the condenser 204 communicates with the discharge pipe 31. The top surface 200 of the ventilation duct 201 is configured to be substantially the same horizontal plane as the surface of the recess 27 on the top surface cover 34 or integrally. The ventilation duct 201 sucks air from the intake port 205, passes through the concave portion 27 in which the condenser 204 and the compressor 11 are installed, and exhausts the air from the discharge port 206 of the top cover 34.

  In the configuration as described above, the top portion of the compressor 11 is disposed at a position lower than the top surface 200 of the box body 1 and higher than the lower surface 202 of the ventilation duct 201, so the inside of the recess 27 that accommodates the compressor 11. The overhanging margin, that is, the protruding margin of the convex portion 30b is reduced, and the internal space can be utilized more effectively.

  In addition, since the compressor 11 may be designed so that the height of the compressor 11 is within the height range in which the height of the ventilation duct 201 and the height of the recess 27 are combined, for example, a large refrigerator can be used. Even if various elements are incorporated, if a compressor having a relatively large refrigerating capacity must be employed, the degree of freedom in design can be expanded, and the compressor 11 can be used even in a large refrigerator. It becomes easy to provide a refrigerator with high storability that is stored behind the top.

  On the other hand, the ventilation duct 201 necessary for cooling the compressor 11 is disposed on the top surface 200 that is difficult to reach in the refrigerator, so that the vicinity of the top surface 200 can be effectively used for purposes other than storage. Further, since the top 203 of the compressor 11 is disposed at a position lower than the top surface 200 of the box body 1 and higher than the lower surface 202 of the ventilation duct 201, the top of the compressor 11 is projected in the ventilation direction of the ventilation duct 201. By being arranged in the plane, the top portion 203 having the highest temperature in the compressor 11 is efficiently cooled, and the characteristics and reliability of the compressor 11 are also improved. Furthermore, by configuring the condenser 204 inside the ventilation duct 201, the heat dissipation effect of the condenser 204 is enhanced, and the efficiency of the system can be improved.

  Next, focusing on the uppermost storage space 29a and the second storage space 30a of the refrigerator, the back of the uppermost storage space 29a is a place that is difficult to reach, and the back side of the uppermost storage space 29a is closed by the convex portion 30b. Even if it is peeled off, the depth of use becomes shallower, and stored items such as foods are within the reach of the hand. Therefore, it is possible to prevent the product from being left behind after the expiration date, and the usability is improved. On the other hand, when the convex portion 30b travels to the second-stage storage space 30a side, the convex portion 30b becomes noticeable when the refrigerating compartment revolving door 5 is opened, the appearance looks worse, and food or the like is behind the second-stage storage space 30a. There is an inconvenience that food or the like is difficult to put in and take out when storing or taking out, but the shelf bottom portion 30d of the uppermost storage space 29a and the inner bottom wall surface 30c of the recess 27 are substantially omitted. By adopting the same horizontal plane, the compressor can be accommodated in the predetermined recess 27 in a state where the external appearance is almost continuously connected and the protrusion of the protrusion 30 b is not felt and the appearance is good.

  The substantially identical horizontal plane refers to the case where the indoor side bottom wall surface 30c of the recess 27 and the shelf bottom portion 30d of the uppermost storage space 29a are substantially the same horizontal plane, or the indoor side bottom wall surface 30c of the recess 27 and the uppermost stage The upper side of the shelf, which is the lower end of the storage space 29a, is substantially the same horizontal plane. For example, the uppermost shelf 29 is inserted into the lower surface of the interior bottom wall surface 30c of the recess, so 30c may be avoided, and the shelf that forms the uppermost storage space 29a is positioned in the vicinity of the bottom wall surface 30c on the indoor side of the recess 27 so that the appearance is almost continuously connected. The effect that the compressor can be accommodated in the predetermined concave portion 27 is obtained in a state where the protrusion of the convex portion 30b is not felt and the appearance is good.

  In addition, stored items such as food that are lower than the height of the frontage of the second-stage storage space 30a can be smoothly put in and out, and there is no inconvenience.

  In addition, since the uppermost storage space 29a is located at a high position and is difficult to store, the minimum height at which a 350 ml canned beverage standard product (123 mm in height) can be stored in order to reduce the height of the storage portion as much as possible. If this is the case, setting the height of the storage portion of the uppermost storage space 29a to 125 mm with a gap of 2 mm in the upper part can be used most efficiently.

  More specifically, in the refrigerator shown in the figure, the distance from the shelf bottom 30d of the uppermost storage space 29a to the top surface 200 including the ventilation duct 201 and the top surface of the top cover 34 is determined by the ventilation duct 201. The thickness of the top surface 200 to be formed is 2 mm, the inner height of the ventilation duct 201 is 18 mm, the heat insulation wall thickness between the lower surface 202 of the ventilation duct 201 and the interior is 25 mm, and the height of the uppermost storage space 29a is 350 ml. If the standard height of 125 mm where a can beverage standard product enters is 125 mm and the shelf board thickness is designed to be 10 mm, the thickness is 180 mm. The uppermost housing is provided with the thickness of the installation surface 28b of the compressor 11 of the recess 27 being 20 mm, the clearance between the compressor 11 and the installation surface 28b and the clearance between the inner surface of the top cover 34 being 3 mm each, and the thickness of the top cover 34 being 2 mm. If the shelf bottom portion 30d of the space 29a and the indoor side bottom wall surface 30c of the concave portion 27 are substantially the same horizontal plane, the maximum height of the compressor 11 that can be accommodated within the combined height of the concave portion 27 and the ventilation duct 201 is 152 mm. Yes, the compressor 11 having a height dimension of 144 mm shown in the first embodiment can be sufficiently designed for housing and can easily meet the demand for increasing the size of the compressor in response to the increase in size of the refrigerator. It becomes.

  That is, the balance between the storage space cut into the compressor 11 and the uppermost storage space is harmonized in appearance, and is usually unusable. The rear space, which is particularly inconvenient, is applied to the compressor housing recess 27, and the can beverages that are often housed in a refrigerator are arranged vertically in the front space that is relatively easy to use. Since it can be stored, the number of storage in the entire refrigerator compartment increases, and the uppermost storage space 29a can be effectively utilized.

  As described above, the ventilation duct 201 communicating with the recess 27 is provided to be the top surface 200 of the box body 1, and the top portion 203 of the compressor 11 is lower than the top surface 200 of the box body 1, and the bottom surface 202 of the ventilation duct 201. Since the ventilation duct 201 necessary for cooling the compressor 11 and the like is arranged near the top surface 200 which is difficult to reach and is not easy to use, the vicinity of the top surface 200 is stored. It can be used effectively for other purposes, and the storage in the cabinet is also improved. Moreover, since the top 203 of the compressor 11 is disposed at a position lower than the top surface 200 of the box body 1 and higher than the lower surface 202 of the ventilation duct 201, the top 203 having the highest temperature in the compressor 11 is efficiently cooled. Also, the characteristics and reliability of the compressor 11 are improved.

  In the present embodiment, the top cover 34 that covers the ventilation duct 201 extends to the front side of the refrigerator as shown in FIG. 9A, but the ventilation duct 201 is formed as shown in FIG. 9B. The top cover 34 that covers the upper surface of the recess 27 may be covered. In this case, air is sucked from the intake 205 provided in the front opening of the ventilation duct 201, so that the user can see the intake 205. Therefore, dust and the like adhering to the intake 205 is not directly visible to the user, and the appearance design of the refrigerator can be improved. In particular, when the top surface portion is not provided with a condenser, a shape that does not extend the top surface cover forward is desirable.

(Embodiment 3)
FIG. 10 is a schematic cross-sectional view of a refrigerator compressor according to Embodiment 3 of the present invention.

  FIG. 11: is a schematic sectional drawing of the compressor of the refrigerator in Embodiment 3 of this invention.

  In addition, the configuration and operational effects common to the first and second embodiments will not be described one by one. However, the same contents are included unless they are unreasonable when applied to the present embodiment. is there.

  In the drawing, the compression element 209 includes a main bearing 220 and a sub-shaft portion 210c, which are bearing portions that support the main shaft portion 210b, the sub-shaft portion 210c, and the main shaft portion 210b coaxially with the eccentric portion 210a of the shaft 210 interposed therebetween. The auxiliary bearing 221 that supports the shaft is provided.

  In addition, the eccentric portion 210 a is provided with a piston 232 that reciprocates in the compression chamber 231 via the connecting member 230.

  Further, as shown in the figure, the sealed container 250 includes an upper container 251 and a lower container 252, and a plurality of legs 260 fixed to the lower container 252 are installed in the recess through the elastic member 270, and the compression of the recess is performed. The machine installation surface 280 is provided with a recess 281 in the heat insulating wall, and the elastic member 270 is disposed in the recess 281 so that the height of the elastic member 270 is the distance between the compressor installation surface 280 and the lowest part of the compressor. It is equipped with a compressor so that it becomes larger. Further, the lower side of the elastic member 270 is fitted and fixed in the recess 281.

  The operation and action of the compressor configured as described above will be described below.

  Since the refrigerant is compressed to a high pressure in the compression chamber 231 while the compressor is in operation, this compression load is transmitted to the eccentric portion 210 a via the piston 232 and the connecting member 230.

  When the compressive load received by the eccentric portion of the shaft 210 is transmitted to the entire shaft 210, a large surface pressure is applied to the sliding portion between the main shaft portion 210b of the shaft and the main bearing 220.

  This surface pressure increases as the sliding length between the main shaft portion 210b of the shaft 210 and the main bearing 220 becomes shorter. In this embodiment, in addition to the main shaft portion 210b of the shaft 210 and the main bearing 220, the surface pressure increases. Since the shaft 210 is pivotally supported at two locations, that is, the minor shaft portion 210c of the shaft 210 and the subsidiary bearing 221 that pivotally supports the shaft 210, the piston 232 as a vibration source can be supported from both sides, and the shaft can be further bent. And the reliability of the sliding surface of the shaft 210 can be improved. Further, even if the sliding length of the main bearing 220 is shortened compared to the conventional case, the sliding length of the entire shaft 210 can be secured by complementing the sliding length of the auxiliary bearing 221, so that the reliability of the compressor The height of the compressor can be further reduced without lowering the performance.

  Therefore, in the reciprocating compressor, the piston 232 that reciprocates according to the present invention is provided for securing the bearing length that supports the shaft 210, which is one of the major problems in reducing the height. Since the main bearing 220 and the auxiliary bearing 221 are provided on both sides of the eccentric portion 210a, the piston 232 as a vibration source can be supported from both sides, and the shaft 210 can be prevented from being bent and the shaft can slide. Since the reliability of the surface can be improved, the reliability of the compressor can be ensured even if the sliding length of the main bearing is shorter than the conventional one, so that the reliability of the compressor is not lowered. The height of the compressor can be further reduced.

  In this embodiment, the auxiliary bearing 221 is provided on the opposite side of the main bearing 220 with the eccentric portion 210a interposed therebetween. However, even if the auxiliary shaft portion is provided coaxially with the main shaft portion 210b with the rotor 240 interposed therebetween, Similarly, the bearing length for supporting the shaft 210 can be ensured, and the reliability of the compressor can be ensured even if the sliding length of the main bearing is shorter than the conventional one. The height of the compressor can be further reduced without lowering.

  In addition, in the compressor installation surface 280 of the recess, the recess 281 is provided in the heat insulating wall, and the elastic member 270 is disposed in the recess 281 so that the height of the elastic member 270 is increased. By becoming larger than the distance of the compressor installation surface 280 and the lowest part of a compressor, the height of the elastic member 270 effective in order to transmit the vibration from the compressor to a refrigerator can be made high. On the other hand, the wall thickness of the installation surface is a factor that determines the size of the convex part into the refrigerator compartment, but a certain amount of thickness is necessary as a structure that supports the compressor in order to obtain the cooling characteristics of the refrigerator. However, with the formation of the recess, it is possible to reduce vibration transmission by increasing the height of the elastic member, ensure cooling characteristics by ensuring the thickness of the installation surface, and ensure the strength as a structure that supports the compressor. Since the height of the elastic member effective for transmitting the vibration from the compressor can be increased, unpleasant vibration and noise generation due to the vibration can be greatly reduced, and the refrigerator Therefore, it is possible to maintain the characteristics by securing the heat insulating property of the steel and to maintain the transport resistance by securing the strength of the structure, and to provide a high-quality refrigerator.

  In this way, by reducing the vibration by increasing the height of the elastic member by forming a recess as an external support structure that supports the compressor, the reliability of the compressor is reduced while further reducing the height of the compressor Without causing the noise, the unpleasant vibration caused by the compressor and the noise generation caused by the vibration can be greatly reduced, and the convex part inside the refrigerator of the type in which the compressor is mounted on the top of the refrigerator Can be reduced in size.

  In addition, by fitting and fixing the lower side of the elastic member, it is possible to fix the position of the elastic member without adding extra parts, eliminating the displacement of the compressor, and transmitting vibrations due to changes in the support surface of the elastic member. It is possible to reduce the change, and to provide a high-quality refrigerator that greatly reduces the generation of unpleasant vibration on the refrigerator installation surface of the elastic member and the noise caused by the vibration, while being inexpensive and improving transport resistance.

(Embodiment 4)
FIG. 12 is a schematic cross-sectional view of a refrigerator compressor according to Embodiment 4 of the present invention. FIG. 13 (a) is a schematic perspective view of a sealed container of a refrigerator compressor in Embodiment 4 of the present invention, and FIG. 13 (b) is from the bottom surface of the sealed container of the refrigerator compressor in Embodiment 4 of the present invention. FIG. FIG. 14 is a schematic cross-sectional view of an airtight container of a compressor according to an example of Embodiment 4 of the present invention.

  In addition, the configuration and operational effects common to the first and second embodiments will not be described one by one. However, the same contents are included unless they are unreasonable when applied to the present embodiment. In the present embodiment, a description will be given of the sealed container of the compressor described in the first and second embodiments.

  In the figure, a plurality of bumps 410 are provided at the bottom of the sealed container 403.

  The plurality of bump portions 410 are formed in a convex shape that is mainly convex from the inside of the sealed container to the outside, and a concave shape that is concave from the outside of the sealed container 403 to the inside. There is a concave bump.

  As the convex bump portion, a leg bump portion 410 a is provided in the vicinity of the connecting portion 420 between the compressor leg 406 and the closed vessel 403 provided in the closed vessel 403. The leg-cove portion 410a is a convex cove portion in which the periphery of the connection portion 420 is formed with a curvature that is clearly smaller than the curvature of the outer periphery of the sealed container.

  In addition, the support member 413 that supports the mechanical part including the electric element and the compression element inside the sealed container includes a support part 413 a that is a support member and a spring 414 that is an elastic member, and is hermetically sealed at the lower end surface of the support part 413. A support bump 410b is provided in the vicinity of the container. The support bump portion 410b is a convex bump portion having a vertically lower periphery of the support portion formed with a curvature that is clearly smaller than the curvature of the outer periphery of the sealed container.

  Further, the sealed container 403, the leg 406, and the support part 413a below the spring 414 are fixed by spot welding, that is, the leg 406 and the lower end part of the support part 413 are welded to the convex hump part.

  Further, the closed container is formed with a concave bump 411 that is recessed inwardly from the outer periphery of the closed container, and is formed with a curvature that is clearly smaller than the curvature of the outer periphery of the closed container. It is formed continuously.

  The operation and action of the compressor configured as described above will be described below.

  As in the present embodiment, by providing a plurality of bumps 410 especially in the lower part of the sealed container 403, the top and bottom surfaces of the sealed container are placed, for example, from the center of the compressor in order to reduce the height direction of the compressor. It becomes difficult to provide a substantially spherical curved surface, and there is a tendency that the upper surface and the lower surface of the sealed container have a curved surface close to a flat surface.

  Thus, if there is a flat curved surface that is close to a flat surface in the shape of the sealed container 403, the rigidity of the portion is weakened and it is easy to be affected by noise and vibration.

  Therefore, in the present embodiment, the support bump portion 410b is provided in the vicinity of the hermetic container located at the lower end surface of the support part 413 of the mechanical part that is a vibration source and the hermetic container. The lower end of the support portion is provided with the support bump portion 410b having a small curvature in the vicinity of the fixing surface between the lower end portion of the support portion 413a and the closed vessel 403 when propagating to the closed vessel via the spring 414. Since the rigidity in the vicinity of the portion can be improved, vibration and noise propagating from the compressor to the sealed container can be reduced.

  Furthermore, by providing a leg cove portion 410a in the vicinity of the connecting portion 420 between the compressor leg 406 and the sealed container 403, which is the external support of the compressor on the lower surface side of the sealed container, such as the sealed container 403, Since the rigidity in the vicinity of the connection portion 420 can be improved, vibration and noise that propagate from the sealed container to the refrigerator main body via the legs 406 can be reduced.

  In this way, a curved surface having a large curvature such that the lower surface side of the hermetic container is close to a flat surface in order to reduce the overall height of the compressor by providing a bump-like convex part in the vicinity of the support part on the inner side and the outer side of the compressor. Even in such a case, a refrigerator with reduced vibration and noise can be provided by using a compressor in which the rigidity of the sealed container, particularly in the vibration transmission path, is improved.

  Further, in the present embodiment, the concave bump portion 411 is formed continuously in the closed container, and the concave portion having a small curvature is continuously formed in a complicated shape. By doing so, there is an effect of further improving the rigidity of the hump portion.

  Further, in addition to the hump portion having a small curvature centering on the vibration transmission path of the sealed container 403 as in the present embodiment, the compressor leg and the elasticity as described in the first and second embodiments are also provided. When a type in which the contact surface 106a with the member is located above the lower end surface 113b of the support member is used, the vibration of the compressor is directed downward from the mechanical part that is the source of vibration. After transmitting through the support member, the direction changes upward and the rigidity of the transmission path when transmitting to the elastic member 107 via the leg 106 can be further increased and the transmission path can be complicated. Vibration can be further reduced.

  Further, in addition to the hump portion having a small curvature centering on the vibration transmission path of the sealed container 403 as in the present embodiment, the concave portion of the compressor installation surface 280 as described in the third embodiment is provided. Is provided with a recess 281 in the heat insulating wall and an elastic member 270 is disposed in the recess 281 so that the height of the elastic member 270 is larger than the distance between the compressor installation surface 280 and the lowest part of the compressor. In addition to the effect of reducing the vibration transmission from the mechanical part to the leg part of the compressor, the elastic member can be made larger, and the vibration and noise of the refrigerator can be further reduced. .

  Further, in addition to the provision of the bump portion 410 having a small curvature around the vibration transmission path of the sealed container 403 as in the present embodiment, the fixing surface 456a of the leg 456 is provided on the bump portion as shown in FIG. In the case where the fixing portion to the closed container of the leg portion is used as the hump portion even if the bent portion rising upward from the fixing surface as described in the first embodiment is not provided, Since it is possible to reduce the vibration in the vibration transmission path of the compressor by the portion, even if the bending portion that rises upward from the fixing portion with the closed container is not necessarily provided, the leg 456 of the compressor and the elastic member 457 Since the abutting portion 458 can be disposed closer to the center of gravity A in the vertical direction of the compressor, the vibration amplitude of the compressor is the smallest in the vicinity of the center of gravity A, and the vibration increases as the distance from the center of gravity increases. Since the entire compressor vibrates around the center of gravity, the amplitude of vibration of the contact surface 458 between the leg 456 and the elastic member 457 closer to the center of gravity is smaller than the lower surface of the support member that supports the mechanical unit. Vibration transmission to the refrigerator can be reduced.

  Therefore, manufacture is easy and vibration transmission to the refrigerator can be reduced, and providing a high-quality refrigerator free from unpleasant vibration and noise generation due to vibration can be achieved at low cost.

  As described above, since the refrigerator according to the present invention can be used effectively and conveniently, the refrigerator can be applied to equipment using a cooling device such as a refrigerator for home use or business use.

Schematic sectional view of the refrigerator in the first embodiment of the present invention. Schematic rear view of the refrigerator of the embodiment Schematic component development view of the refrigerator of the same embodiment Vertical sectional view of the compressor of the refrigerator of the same embodiment Horizontal sectional view of the refrigerator compressor of the embodiment Comparison diagram of induction motor and inverter motor of refrigerator compressor of same embodiment Top view of salient pole concentrated winding stator of refrigerator compressor of the embodiment The perspective view of the leg part of the compressor of the embodiment (A) Schematic sectional view of the refrigerator in the second embodiment of the present invention (b) Main part sectional view of the refrigerator in the second embodiment of the present invention Schematic sectional view of a refrigerator compressor according to Embodiment 3 of the present invention. Schematic sectional view of a refrigerator compressor according to Embodiment 3 of the present invention. Schematic sectional view of a refrigerator compressor according to Embodiment 4 of the present invention. (A) The schematic perspective view of the airtight container of the compressor of the refrigerator in Embodiment 4 of this invention (b) The top view seen from the lower surface of the airtight container of the compressor of refrigerator in Embodiment 4 of this invention Schematic sectional view of a sealed container of a refrigerator compressor according to Embodiment 4 of the present invention. Schematic sectional view of a conventional refrigerator

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Box main body 11 Compressor 15a Door 15b Storage room 23,200 Top surface 27 Recessed part 28a Back surface 29a Uppermost storage space 30c Indoor side bottom wall surface 30d Shelf bottom part 34b, 203 Top part 101 Lower container 102 Upper container 103,403 Sealed container 106 Leg 106b Adhering surface 106c Bending portion 106d Elastic member arrangement lower surface 107,270 Elastic member 110 Electric element 111,240 Rotor 111a Rotor concave portion 112 Stator 113,209 Compression element 130,210 Shaft 131,210b Main shaft portion 132,210a Eccentricity Portions 134, 231 Compression chamber 135 Bearing portion 136, 232 Piston 151 Permanent magnet 161 Stator core 171 Salient pole portion 201 Ventilation duct 202 Lower surface 210c Sub shaft portion 220 Main bearing 221 Sub bearing 280 Compressor installation surface 281 Depression 06 leg 410 Cobb units 410a leg Cobb unit 410b supporting Cobb portion 411 recessed nubs 413 supporting member 420 connected portion 456 leg 456a fixed surface

Claims (14)

A box body having a storage chamber with a door on the front surface, and a compressor housed in a recess recessed over the top and back surfaces of the box body, the compressor comprising an upper container and In a closed container provided with a lower container, an electric element composed of a stator and a rotor and a compression element driven by the electric element are supported by the lower container by a support member, and by legs fixed to the lower container be those through the elastic member is disposed in the recess, so that the top portion of the compressor is lower than the top surface of the box body, it is operated the electric element of the compressor at a plurality of rotational speed Inverter-driven electric motor, and using a permanent magnet for the rotor of the electric element reduces the height of the compressor, and the lower container has a convex shape with a smaller curvature than the outer periphery of the hermetic container and Repetitive coins formed in a concave shape The convex hump portion is provided such that a support hump portion to which a lower end surface of the support member is fixed and a leg hump portion to which a leg of the compressor is fixed are shifted from each other, and The refrigerator which formed the said concave-shaped bump part continuously in the support bump part . The interval between the contact surfaces of the legs of the compressor and the elastic member is disposed above the lowermost part of the compressor, and the height of the elastic member is set so that the installation surface of the compressor in the recess and the compressor The refrigerator according to claim 1 , wherein the refrigerator is larger than a distance from the lowest part. And vertical center of gravity of the compressor, the distance between the contact surface between the legs and the elastic member of the compressor, according to claim 1 which is shorter than the distance between the lower end face of the vertical center of gravity and the supporting member of the compressor Or the refrigerator of 2 . The refrigerator according to any one of claims 1 to 3, wherein the contact surface between the leg of the compressor and the elastic member is located above the lower end surface of the support member. The refrigerator according to any one of claims 1 to 4, wherein the legs of the compressor have a fixing surface that is fixed to the sealed container, a bent portion that rises upward, and an elastic member disposition lower surface that locks the elastic member. The refrigerator according to claim 5 , wherein the leg is provided with a rib extending over at least two portions of the fixing surface, the bending portion, and the elastic member arrangement lower surface. A recess is provided on the compressor installation surface of the recess, and an elastic member is disposed in the recess, so that the height of the elastic member is larger than the distance between the compressor installation surface and the lowest part of the compressor. The refrigerator according to any one of claims 1 to 6 , further comprising a compressor. The refrigerator according to claim 7 , wherein at least the lower side of the elastic member is fitted and fixed using the entire circumference or a part of the depression provided on the compressor installation surface. 9. The compressor according to claim 1 , wherein the compression element is elastically supported with respect to the hermetic container and includes a compression chamber and a reciprocating compressor including a piston that reciprocates in the compression chamber. Refrigerator. The compression element has a shaft having a main shaft portion and an eccentric portion, a rotor provided in the main shaft portion, and a bearing portion that pivotally supports the main shaft portion, and on the compression element side of the rotor The refrigerator according to any one of claims 1 to 9, wherein the refrigerator has a rotor recess, and the bearing portion extends into the rotor recess. The compressor is an internal low-pressure type, and the electric element is disposed below the sealed container and is elastically supported via a support member with respect to the sealed container. The refrigerator as described in any one of Claims 1-10 arrange | positioned via the high voltage | pressure pipe | tube which is arrange | positioned at the upper part and consists of an elastic shape with respect to the said airtight container. The shelf bottom part of the uppermost storage space of the storage room located in the uppermost part among the storage rooms provided in the box body and the indoor side bottom wall surface of the concave part are substantially the same horizontal plane . The refrigerator according to one item . The refrigerator according to claim 12 , wherein a height of the uppermost storage space is set to a height at which 350 ml of can beverage standard product can be made and stored. The refrigerator according to any one of claims 1 to 13, wherein a height of the top surface of the box body from the floor surface is set to 1800 mm or less.

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