Patent Grant
11143438
This application claims the benefit of an earlier filing date of and the right of priority to Korean Application No. 10-2018-0108544, filed on Sep. 11, 2018, which is herein expressly incorporated by reference in its entirety.
The present disclosure relates to a compressor having an aluminum shell and a refrigerator having the same.
A refrigerator is a device that can store objects such as food, beverage, and the like and keep the objects fresh for a certain period. For example, the refrigerator may store food items in a cavity at a freezing or refrigeration temperature according to the type of the food items.
The refrigerator may include a compressor and be operated by driving the compressor. For example, cool air supplied to the cavity of the refrigerator may be generated by the heat exchange function of refrigerant, where the cool air may be continuously or intermittently supplied to an inside of the refrigerator as the cavity temperature rises and falls based on repeatedly performing a cooling cycle including compression, condensation, expansion, and evaporation. In some cases, the supplied refrigerant is uniformly transferred to the inside of the cavity by convection to store food inside the refrigerator at a desired temperature.
In recent years, a demand for vehicle-mountable or movable small refrigerators has been increased due to an increased interest in leisure, where the small refrigerators may demand an improved cooling efficiency. For small refrigerators, supply of vehicle refrigerators which are fixedly mounted and used on a vehicle has also been increased. An increase in demand for small refrigerators is leading to an increase in demand for small compressors.
In some cases, a small compressor may have a compression mechanism that is the same as or substantially similar to that of a large compressor. In some cases, in the small compressor, heat may not be quickly discharged to an outside of the compressor due to a relatively reduced heat emission area. As a result, an internal temperature of the compressor may be increased, which may deteriorate the reliability of components in the compressor as well as a motor efficiency.
In some cases, a refrigerator with a small compressor may include a fan installed in a machine room of the refrigerator to discharge heat of the compressor. In such cases, an area of the machine room may be increased, which may reduce a storage space of the refrigerator compared to the refrigerator of the same capacity. In some cases, a manufacturing cost may increase as the number of parts increases due to the installation of the fan. In some cases, the efficiency of the refrigerator may decrease, and a noise level may increase as the operation time of the fan increases for emitting heat from the compressor.
One object of the present disclosure may be to provide a small compressor capable of rapidly emitting heat generated inside a shell.
In some implementations, a heat radiation fin may be installed on an outer surface of the shell, where the small compressor may have a reduced dead angle or dead volume generated by the heat radiation fin to minimize an area occupied by the compressor.
Another object of the present disclosure may be to provide a refrigerator that can reduce manufacturing cost as well as increase an area of storage space by excluding the fan when the compressor is applied to the refrigerator.
In some implementations, the refrigerator may increase the efficiency of the refrigerator and reduce noise by minimizing an operation time of the fan when the fan is installed.
According to one aspect of the subject matter described in this application, a compressor includes a shell that defines an enclosed space inside the shell, an electric motor unit located in the enclosed space of the shell and configured to generate a driving force, and a compression unit located in the enclosed space of the shell and configured to compress refrigerant. The compression unit includes a cylinder and a piston that is configured to reciprocate in the cylinder based on the driving force transmitted from the electric motor unit. The shell includes a plurality of heat radiation fins that are located at an outer circumferential surface of the shell and that are configured to emit heat generated inside the shell to an outside of the shell.
Implementations according to this aspect may include one or more of the following features. For example, at least a part of the outer circumferential surface of the shell may define a curved part, and each of the plurality of heat radiation fins may be located at the curved part of the outer circumferential surface of the shell. In some examples, the shell has a side central portion, an upper central portion located vertically above the side central portion, and a bottom central portion located vertically below the side central portion. In this example, a cross-section area of the upper central portion or the bottom central portion of the shell is less than a cross-section area of the side central portion of the shell, and each of the plurality of heat radiation fins is located between the upper central portion and the side central portion or between the bottom central portion and the side central portion.
In some implementations, each of the plurality of heat radiation fins may include a curved portion that is in contact with the outer circumferential surface of the shell, a vertical portion that extends in an axial direction for the shell from a first end of the curved portion, and a horizontal portion that extends from a second end of the curved portion in a direction perpendicular to the vertical portion. In some implementations, the shell may include a cover shell and a base shell that are coupled to each other to define the enclosed space, where the cover shell defines a first opening surface, and the base shell defines a second opening surface that faces the first opening surface of the cover shell, and the plurality of heat radiation fins are located at at least one of the cover shell or the base shell. In some cases, a surface area of the plurality of heat radiation fins located at the cover shell is greater than a surface area of the plurality of heat radiation fins located at the base shell.
In some examples, the cover shell and the base shell may include fastening protrusion portions that extend in a radial direction of the shell, that are configured to face each other, and that are located at positions corresponding to the first opening surface and the second opening surface, respectively. In this example, the base shell and the cover shell are configured to be coupled to each other by fastening bolts through the fastening protrusion portions of the cover shell and the based shell. In some examples, at least one of the cover shell or the base shell may include a stepped portion or a protrusion that is configured to couple the first opening surface and the second opening surface to each other.
In some implementations, the outer circumferential surface of the shell may include an upper side portion, a side wall portion, a lower side portion, and an edge portion that connects between the upper side portion and the side wall portion. In some examples, at least one of the plurality of heat radiation fins is located at the edge portion, and the plurality of heat radiation fins and the outer circumferential surface of the shell define a hexahedron shape comprising (i) one or more first planes defined by an end portion surface of the plurality of heat radiation fins and (ii) one or more second planes defined by the outer circumferential surface of the shell. In some examples, each of the plurality of heat radiation fins has a surface that extends in a direction parallel to at least one side of the hexahedron shape.
In some examples, each of the plurality of heat radiation fins extends in a plurality of directions that are parallel to orthogonal sides of the hexahedron shape, respectively. In some examples, each of the plurality of heat radiation fins extends radially with respect to a center of at least one side of the hexahedron shape. In some implementations, the shell may include a support portion that extends from a bottom portion of the shell and that is configured to support the shell. In some implementations, the shell is made of an aluminum material.
According to another aspect, a refrigerator includes a cavity configured to store one or more food items, a door configured to open and close at least a portion of the cavity, a machine room that is located at a side of the cavity, the machine room defining an air path that allows an inner space of the machine room to communicate with an outside of the machine room, a condenser located in the inner space the machine room, and a compressor located in the inner space of the machine room at a side of the condenser. The compressor includes a shell that defines an enclosed space and that is made of an aluminum material, an electric motor unit located in the enclosed space of the shell and configured to generate a driving force, and a compression unit located in the enclosed space of the shell and configured to compress refrigerant. The compression unit includes a cylinder and a piston that is configured to reciprocate in the cylinder based on the driving force transmitted from the electric motor unit. The shell includes a plurality of heat radiation fins that are located at an outer circumferential surface of the shell and that are configured to emit heat generated inside the shell to an outside of the shell.
Implementations according to this aspect may include one or more of the following features and the features described above with respect to the compressor. For example, each of the plurality of heat radiation fins may extend toward the condenser. In some examples, each of the plurality of heat radiation fins extends in a first direction perpendicular to a second direction extending toward the condenser.
In some implementations, the machine room may include an air inlet configured to receive air from the outside of the machine room, and an air outlet spaced apart from the air inlet and configured to discharge air to the outside of the machine room, the air path extending from the air inlet toward the air outlet, where the condenser and the compressor are located between the air inlet and the air outlet.
In some implementations, the refrigerator may further include a fan located between the condenser and the compressor. In some examples, the refrigerator may further include a controller that is configured to control the compressor, that is coupled to the shell of the compressor, and that is located between the fan and the shell of the compressor.
The accompanying drawings, which are included to provide a further understanding of the disclosure and are incorporated in and constitute a part of this specification, illustrate implementations of the disclosure and together with the description serve to explain the principles of the disclosure.
Hereinafter, a small compressor according to the present disclosure and a refrigerator to which the small compressor is applied will be described in detail based on an implementation illustrated in the accompanying drawings.
The implementations relate to a vehicle-mountable or movable refrigerator and a small compressor applied to the refrigerator, but the scope of application is not limited thereto. Hereinafter, a small compressor according to one or more implementations and a refrigerator to which the small compressor is applied will be described with reference to a refrigerator mounted on a vehicle for convenience of explanation.
The small refrigerator may be located in the console. However, the present disclosure is not limited thereto, and may be installed in various spaces. For example, it may be installed in a space between rear seats, a door, a glove box, and a center fascia. It is because a vehicle refrigerator in the implementation can be installed only when power is supplied and a minimum space is secured.
The console 3 has a console space 4 therein, and a console space 4 may be covered by a console cover 5. The console cover 5 may be fixedly fixed to the console 3. As a result, the console cover 5 makes it difficult for external foreign matter to enter the console through the console cover 5. A vehicle refrigerator 20 is placed inside the console space 4.
An air inlet 6 is provided on a right side of the console 3 to allow air inside the vehicle to flow into the console space 4. The air inlet 6 may be seen on the driver's side. An exhaust port 7 is provided on a left side of the console 3 to exhaust air warmed during the operation of the vehicle refrigerator inside the console space 4. The exhaust port 7 may be seen on the assistant driver's side. The air inlet 6 and the exhaust port 7 are provided with a grill so as to make it difficult for a user's hand to enter, thereby ensuring the user's safely, and the grill may prevent an object falling from above from entering thereinto, and direct the direction of wind to be exhausted downward so as not to direct to the person.
The refrigerator 20 is provided with a refrigerator bottom frame 21 for supporting the components, a machine room 22 provided on a left side of the refrigerator bottom frame 21, and a cavity 23 provided on a right side of the refrigerator bottom frame 21. The machine room 22 may be covered by a machine room cover 25, and an upper side of the cavity 23 may be covered by the console cover 5 and the door 24.
The machine room cover 25 may guide the flow path of cooling air as well as block foreign matter from entering the machine room. A refrigerator controller 30 is placed above the machine room cover 25 to control the entire operation of the small refrigerator 20.
As the refrigerator controller 26 is installed on an upper side of the machine room cover 25, the small refrigerator 20 may be operated without any problem in a proper temperature range in a narrow space inside the console space 4. In other words, the refrigerator controller 26 may be cooled by air flowing in a space between the machine room cover 25 and the console cover 5, and separated from an inner space of the machine room 22 by the machine room cover 25, and thus heat inside the machine room 22 may not have an effect thereon.
The console cover 5 may not only shield an open portion at an upper portion of the console space 4 but also shield an upper edge of the cavity 23. A door 24 may be further provided on the console cover 5 to enable the user to shield an opening allowing an article to be taken out of the cavity 23. The door 24 may open the console cover 5 and a back portion of the cavity 23 to the hinge point. Here, the console cover 5, the door 24 and an opening of the cavity 23 are horizontally placed when viewed by the user and positioned at a rear portion of the console 3 to allow the user to conveniently manipulate the door 24.
A condenser 27, a condensing fan 28, and a compressor 100 are sequentially installed inside the machine room 22 along the flow direction of cooling air. The condenser 27 may be fastened by a rear fastening element of a machine room bottom frame 221. Air suctioned through the condenser 27 cools the compressor 100 and then flows out to a right side or a lower right side of the compressor 100.
The aforementioned condensing fan 28 is provided between the condenser 27 and the compressor 100. The condensing fan 28 is unable to increase rotational speed infinitely due to the effect of noise. According to an experiment, it is seen that a level of about 2,000 rpm does not have an effect on the driver.
In some implementations, the condensing fan is not necessarily installed. For example, in the case of a refrigerator, the condensing fan 28 may not be installed when refrigerant can be condensed only by heat exchange due to convection without the condensing fan 28. However, the condensing fan 28 performs the role of not only condensing refrigerant passing through the condenser 27 but also emitting the heat of the compressor 100. Therefore, when the heat of the compressor 100 is efficiently emitted, it may not be required to install the condensing fan 28 or the operation time may be reduced even when the condensing fan 28 is installed. It will be described again later together with the compressor.
The flow process of air in the machine room of the small refrigerator is as follows. In other words, air suctioned into the machine room 22 by the condensing fan 28 may condense refrigerant while passing through the condenser 27. The air passes through a dryer and an expansion valve, and then cools the compressor 100 and is discharged to the outside. At this time, the flow of air is a flow from a rear side of the machine room 22 toward a front side thereof. Based on
The air that has cooled the compressor 100 may be discharged through the air outlet 22b provided on a side surface of the machine room or the machine room bottom frame 221. The air discharged through the air outlet 22b may be discharged to an outside of the vehicle refrigerator 20 through a flow guide provided in the refrigerator bottom frame 21.
In some implementations, as described above, the compressor may be a small compressor in which a surface area of the shell is reduced by about 70% as compared with a compressor applied to a domestic refrigerator in the related art. Accordingly, motor heat or compression heat generated inside the compressor cannot be efficiently and quickly emitted. As a result, it may reduce wear resistance on internal parts in the compressor or reduce the efficiency of the motor.
Furthermore, when the condensing fan is provided in consideration of this, manufacturing cost increases, and when the condensing fan is operated for a long period of time, power consumption increases and fan noise increases, thereby causing the passenger to feel uncomfortable. Thus, as illustrated in the present implementation, the shell of the small compressor may be made of an aluminum alloy having light weight and high heat transfer coefficient to enhance the heat radiation effect. A plurality of heat radiation fins may be formed on the surface of the shell to further enhance the heat radiation effect. Through this, it may be possible to minimize the fan operation time even when excluding or installing the condensing fan, thereby enhancing the efficiency of the refrigerator and increasing reliability.
The small compressor 100, which is one of the main elements of the refrigerator, may be divided into a reciprocating compressor, a rotary compressor, and a scroll compressor according to the driving method. In the present implementation, an example in which a connection type reciprocating compressor, which is a type of reciprocating compressor, is applied will be mainly described. However, the type of the compressor is not limited thereto.
The shell 110 forms an enclosed space therein to accommodate the electric motor unit 120 and the compression unit 130 in the enclosed space. The shell 110 is made of an aluminum alloy (hereinafter, abbreviated as aluminum) having light weight and high heat transfer coefficient, and includes the cover shell 111 and the base shell 112.
The cover shell 111 forms an enclosed inner space together with the base shell 112 and is formed in an approximately hemispherical shape like the base shell 112. The cover shell 111 is packaged with the base shell 112 on an upper side of the base shell 112 to form an enclosed space inside the shell 110.
The cover shell 111 and the base shell 112 may be welded and packaged, but the cover shell 111 and the base shell 112 may be bolt-fastened together as they are made of an aluminum material difficult to weld.
To this end, fastening protrusion portions 111a, 112a may be respectively protruded in a radial direction on the opening surfaces of the cover shell 111 and the base shell 112 so as to correspond to each other, and fastening holes for bolt assembly may be formed on the fastening protrusion portions 111a, 112a.
The base shell 112 is formed in a substantially hemispherical shape like the cover shell 111. A suction pipe 115, a discharge pipe 116 and a process pipe 117 are respectively mounted on the base shell 112. The suction pipe 115 allows refrigerant to flow into an inner space of the shell 110, and the discharge pipe 116 discharges compressed refrigerant in the shell 110, and the process pipe 117 is provided to fill refrigerant into the internal space of the shell 110 after sealing the internal space of the shell 110, and mounted through the base shell 112 like the suction pipe 115 and the discharge pipe 116.
In some implementations, an opening surface of the cover shell 111 and an opening surface of the base shell 112 may be respectively formed to be flat and closely coupled to each other, but the opening surface of the base shell 112 may be stepped, and thus the opening surface of the base shell 112 may be coupled to the opening surface of the cover shell 111 in a stepped manner as shown in
In some implementations, a sealing member such as a gasket or an O-ring may be further provided between an opening surface of the cover shell 111 and an opening surface of the base shell 112. As a result, a sealing force between the cover shell 111 and the base shell 112 may be further enhanced.
In some implementations, a plurality of heat radiation fins 1171, 1172 for radiating heat may be respectively formed on the outer circumferential surfaces of the cover shell 111 and the base shell 112. In some examples, the heat radiation fins may be formed only on an outer circumferential surface of the cover shell 111, not on an outer circumferential surface of the base shell 112, in consideration of the fact that heat is directed upward. In some examples, the heat radiation fins 1171, 1172 are respectively formed on the cover shell 111 and the base shell 112 such that a surface area of the heat radiation fin 1172 formed on the cover shell 111 is larger than that of the heat radiation fin 1172 formed on the base shell 112. The heat radiation fins 1171, 1172 are extended in a single body to the shell 110, and the heat radiation fins will be described later.
The electric motor unit 120 may include a stator 121 elastically supported and provided in an inner space of the shell 110, a rotor 122 rotatably provided at an inner side of the stator 121, and a crankshaft 123 coupled to the center of the rotor 122 to transmit a rotational force to the compression unit 130.
The compression unit 130 may include a cylinder block 131 forming a cylinder 131a, a piston 132 compressing refrigerant while reciprocating in a radial direction within the cylinder 131a, a connecting rod 133 an end of which is rotatably coupled to the piston 132 and the other end of which is rotatably coupled to the crankshaft 123 to convert the rotational motion of the electric motor unit 120 into a linear motion of the piston 132, a valve assembly 134 coupled to an end of the cylinder block 131 and provided with a suction valve and a discharge valve, a suction muffler 135 coupled to a suction side of the valve assembly 134, a head cover 136 coupled to accommodate a discharge side of the valve assembly 134, and a discharge muffler 137 communicated with the head cover 136 to attenuate discharge noise of refrigerant.
The foregoing small compressor operates as follows.
In other words, when power is applied to the electric motor unit 120, the rotor 122 rotates. When the rotor 122 rotates, the crankshaft 123 coupled to the rotor 122 transmits a rotational force to the piston 132 through the connecting rod 133 while rotating. The piston 132 reciprocates in a front-rear direction with respect to the cylinder 131a by the connecting rod 133.
For example, when the piston 132 is retracted from the cylinder 131a, an internal volume of the cylinder 131a is increased, and when the internal volume of the cylinder 131a is increased, refrigerant filled in an inner space of the shell 110 is suctioned into the cylinder 131a of the cylinder block 131 through the suction muffler 135.
In another, when the piston 132 is advanced in the cylinder 131a, an internal volume of the cylinder 131a is reduced, and when the internal volume of the cylinder 131a is reduced, refrigerant filled in the cylinder 131a is compressed to discharge the refrigerant to the head cover 136 through the discharge valve of the valve assembly 134. A series of processes of discharging the refrigerant through the discharge muffler 137 to the cooling cycle are repeated.
At this time, motor heat is generated in the electric motor unit 120 while generating a rotational force, and compression heat is generated in the compression unit 130 while compressing refrigerant. The motor heat and the compression heat are cooled while exchanging heat with refrigerant or oil suctioned into the inner space of the shell 110, and the refrigerant and the oil are cooled come into contact with an inner circumferential surface of the shell 110 while being in contact with an inner circumferential surface of the shell to exchange heat with the shell 110. Therefore, the heat generated in the inner space of the shell 110 is eventually emitted into an inside of the machine room 22 through a surface of the shell 110.
Accordingly, the heat radiation effect of the compressor may be determined by the material and surface area of the shell 110. As described above, though heat radiation effect can be enhanced as the shell 110 is formed of an aluminum material having a high heat transfer coefficient, since the compressor is miniaturized, heat emission area, that is, the surface area, is reduced by about 70% as compared with a compressor applied to a conventional household refrigerator. Due to this, even though the material of the compressor is changed to an aluminum material favorable to heat emission, the heat radiation effect of the compressor may be reduced as the heat emission area as a whole is reduced.
As a result, in the present implementation, as described above, a plurality of heat radiation fins are formed on an outer circumferential surface of the shell to enlarge the heat emission area, thereby securing a large heat emission area of the shell to enhance the heat radiation effect even when the compressor is miniaturized.
In some cases, when the heat radiation fins are uniformly formed on an entire outer circumferential surface of the shell, a size of an actual compressor defined by an end portion surface of the heat radiation fin is larger than the outer circumferential surface of the shell. Therefore, it may seriously undermine the advantages of miniaturizing the compressor. Therefore, in the present implementation, when forming the heat radiation fin, it can be preferable to reduce a dead angle or dead volume as much as possible not to increase the actual size of the compressor including the heat radiation fin.
Referring to
For example, a cross-sectional area of the shell 110 increases as it goes from the upper central region (A11) to the side central region (A12), and a cross sectional area thereof decreases as it goes from the side central region (A12) to the bottom central portion (A13). At this time, a figure (A) formed by connecting the upper central portion (A11), the side central region (A12), and the bottom central region (A13) together with the heat radiation fins 1171, 1172 substantially forms a hexahedron.
Therefore, an outer circumferential surface of the shell 110 has a curvature smaller than that of the corner area (A2) even when the central regions (A11, A12, A13) of each surface are substantially planar or curved when viewed based on the hexahedron. The eight corner regions (A2) may be curved.
Referring to
Referring to
Referring to
For example, as described above, an appearance of the cover shell 111 substantially forms an upper half of the hexahedron, and the edge portion forms a curved hemispherical shape. Accordingly, the upper central region of the cover shell 111 is formed with an upper side portion 111b1 having a flat or predetermined curvature, and the side central portion is formed with a side wall portion 111b2 having a substantially planar or predetermined curvature. A cover side edge portion 111c connecting the upper side portion 111b1 and the side wall portion 111b2 with a curved surface is formed at an edge of the cover shell 111. The cover side edge portion 111c is formed such that a transverse cross-sectional area of the shell 110 with respect to an inner space of the shell 110 becomes smaller as it goes from an opening surface of the cover shell 111 to an upper surface thereof.
The first heat radiation fin 1171 is formed on the cover side edge portion 111c of the cover shell 111, and the first heat radiation fin 1171 is formed only up to a point where the cover side edge portion 111c, the upper side portion 111b1 and the side wall portion 111b2 are connected. Here, when the cover shell 111 is formed in a hemispherical shape having a full circle, and an upper central portion of the cover shell 111 is formed as one point, the one point may be defined as an upper side portion 111b1.
As shown in
Furthermore, a height (H) of the horizontal portion 1171b and the vertical portion 1171c constituting an end portion surface of the first heat radiation fin 1171 is formed to extend to the same straight line L1, L2 as the upper side portion 111b1 and the side wall portion 111b2 of the cover shell 111 or formed lower than the upper side portion 111b1 and the side wall portion 111b2. Accordingly, the first heat radiation fin 1171 is not formed on the upper side portion 111b1 and the side wall portion 111b2, but formed only on the edge portion 111c. Therefore, a size of the actual compressor does not increase while forming the heat radiation fin.
In other words, when an outer surface of the cover shell 111 is formed in a substantially hemispherical shape, an edge portion is a type of dead angle area or dead volume area, and the first heat radiation fin 1171 is formed in an edge portion which is a dead angle area or dead volume area, and thus a new dead angle or dead volume is not generated due to the heat radiation fin.
Here, the dead angle area or dead volume area denotes a vacant space in the machine room, and when the heat radiation fins protrude from the upper side portion or the side wall portion, a substantially outer surface of the compressor becomes an end portion surface of the heat radiation fin. Therefore, the machine room must be enlarged by an area of the heat radiation fins formed to protrude from the upper side portion or the side wall portion, so that the shaded area B becomes a rectangular area or a carcass area. The present implementation is presented not to generate an additional dead angle area or dead volume area.
Accordingly, the compressor does not increase a substantial size of the compressor including a heat radiation fin while forming the heat radiation fin.
On the other hand, as shown in
However, the first heat radiation fin according to the present disclosure is not limited to the above-described arrangement shape.
For example, as shown in
In addition, as shown in
In addition, as shown in
In addition, the first heat radiation fins 1171 of the foregoing implementations are formed in a forward direction with respect to the flow direction of air. In some examples, the first heat radiation fins may be arranged in a direction intersecting with the flow direction of air.
Referring to
On the other hand, the case of the base shell 112 is similar. For example, the lower side portion 112b1 constituting a bottom central region of the base shell 112 and a base side wall portion 1122b constituting a side central region thereof may be formed substantially planar or formed to be smaller than the curvature of the edge portion 112c even when curved.
The edge portion 112c is a portion connecting the lower side portion and the side wall portion, and the second heat radiation fin 1172 is formed on the curved edge portion 112c.
The shape of the second heat radiation fin 1172 is the same as that of the first heat radiation fin 1171 described above. In other words, the second heat radiation fin 1172 is formed with a curved portion, a horizontal portion, and a vertical portion.
In some examples, for the heat radiation fins, a surface area of the first heat radiation fin 1171 formed on the cover shell 111 may be formed larger than that of the second heat radiation fin 1172 formed on the base shell 112. It is because heat generated in an inner space of the shell 110 moves to the upper side due to its characteristics, and thus heat is mainly exchanged with the cover shell 111. Accordingly, a surface area of the first heat radiation fins 1171 formed on the cover shell 111 may preferably be formed larger than that of the second heat radiation fins 1172 formed on the base shell 112 in order to enhance a heat radiation effect on the shell 110.
In some implementations, the second heat radiation fin 1172 may be formed in a vertical straight line manner, a horizontal straight line manner, a lattice shape, or a radial shape as the first heat radiation fin 1171.
In some implementations, a support portion 118 for supporting the shell 110 may be formed on the bottom portion of the base shell 112. The support portion 118 extends radially from the edge portion of the base shell 112, and an elastic member 1181 is inserted into and coupled to an end portion of the support portion 118.
The support portion 118 may be assembled and fixed to the bottom portion of the base shell 112, but as the base shell 112 is manufactured by a die casting method, the support portion 118 may be preferably formed into a single body together with the base shell 112.
As described above, the shell 110 is formed of an aluminum material having a high heat transfer coefficient. Accordingly, even when the surface of the shell 110 is formed significantly smaller than that of the shell of a compressor in the related art, heat generated in an inner space of the shell 110 may be rapidly emitted.
Furthermore, as a plurality of heat radiation fins 1171, 1172 are integrally formed on the surface of the shell 110, even when the surface area of the shell 110 is small, the overall heat emission area may be enlarged to rapidly emit heat generated in the inner space of the shell 110.
Furthermore, as the heat radiation fins 1171, 1172 formed on the surface of the shell 110 are formed in a dead angle area or dead volume area of the spherical shell 110, it may be possible to suppress a substantial size of the shell 110 from being increased while the heat radiation fins 1171, 1172 are protruded from the surface of the shell 110. Accordingly, it may be possible to prevent a volume of the machine room from increasing due to the heat radiation fins when the small compressor is installed in a small refrigerator. Through this, it may be possible to secure a large area of the storage space compared to the refrigerator of the same capacity.
On the other hand, as described above, the small compressor may be installed in a machine room in a small refrigerator. In this case, the small compressor may be arranged in the order of the condenser-condensing fan-compressor.
Here, the air inlet 22a is formed on a left side of the machine room 22, and the air outlet 22b is formed on a right bottom side of the machine room 22, respectively. Therefore, the condenser 27 and the compressor 100 may be arranged at a position in proximity to the air inlet 22a and at a position in proximity to the air outlet 22b of the machine room 22, respectively. In some examples, the compressor 100 may be less affected by air than the condenser 27 due to its characteristics, and thus the compressor 100 may not greatly affect the performance of the refrigerator even if it comes into contact with air at a higher temperature than the condenser 27. However, when the compressor 100 is small as in the present implementation, the heat emission area may be reduced to lower the heat radiating effect to the compressor, thereby increasing the operation time of the condensing fan 28.
In some implementations, when the shell 110 is made of an aluminum material and the heat radiation fins 1171, 1172 are formed on an outer circumferential surface of the shell 110 as in the present implementation, an area required for heat radiation of the compressor may be secured. Through this, the heat of the compressor 100 may be rapidly emitted without increasing the driving time of the condensing fan 28 in order to emit the heat of the compressor 100. Therefore, it may be possible to prevent power waste due to the long-time driving of the condensing fan 28, and reduce noise due to the driving of the condensing fan 28.
In some implementations, one longitudinal end of the heat radiation fins 1171 may be arranged to face the condenser 27. In this case, air that has passed through the condenser 27 may evenly come in contact with the heat radiation fins 1171, 1172 while passing through the heat radiation fins 1171, 1172. Furthermore, a flow resistance of air due to the heat radiation fins 1171, 1172 is reduced to allow fresh air to quickly flow into the machine room 22. As a result, the heat radiation effect of the condenser 27 and the compressor 100 may be further improved.
In some implementations, the heat radiation fins 1171, 1172 may be arranged in a direction horizontally and vertically orthogonal to a direction toward the condenser 27 as described above or may be arranged radially. In addition, the heat radiation fins 1171, 1172 may be arranged in a direction orthogonal to the flow direction of air.
In these cases, due to not only an enlarged area of the heat radiation fin but also a complicated shape of the heat radiation fin, air that has passed through the condenser 27 hits the heat radiations fins 1171, 1172 to form a turbulent flow. Then, air may form a complicated flow distribution in the machine room 22 to enhance contact between the air and the heat radiation fins 1171, 1172.
In some implementations, the small compressor may include a compressor controller 150 for controlling the electric motor unit 120 inside the shell 110.
Referring to
| Number | Date | Country | Kind |
|---|---|---|---|
| 10-2018-0108544 | Sep 2018 | KR | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 20050074354 | Ebara et al. | Apr 2005 | A1 |
| 20130045119 | Junior et al. | Feb 2013 | A1 |
| Number | Date | Country |
|---|---|---|
| 201162642 | Dec 2008 | CN |
| 201671795 | Dec 2010 | CN |
| 201812859 | Apr 2011 | CN |
| 102667157 | Sep 2012 | CN |
| 105464948 | Apr 2016 | CN |
| 105464948 | Apr 2016 | CN |
| 1033865 | Jul 1953 | FR |
| 1019970045516 | Jul 1997 | KR |
| 100190121 | Jun 1999 | KR |
| 100190121 | Jun 1999 | KR |
| 2020010002247 | Oct 2001 | KR |
| 1020180090057 | Aug 2018 | KR |
| WO2007107514 | Sep 2007 | WO |
| WO2018151493 | Aug 2018 | WO |
| Entry |
|---|
| Extended European Search Report in European Application No. 19151842.2, dated May 24, 2019, 11 pages. |
| CN Office Action in Chinese Appln. No. 201910636526.1. dated Jan. 8, 2021, 11 pages (with English translation). |
| CN Office Action in Chinese Appln. No. 201910636526.1, dated Jun. 25, 2021, 16 pages (with English translation). |
| Number | Date | Country | |
|---|---|---|---|
| 20200080752 A1 | Mar 2020 | US |
