KR100822577B1 - Hermetic compressor - Google Patents

Abstract

The hermetic compressor includes a suction container having an airtight container having an inner space, a cylinder housed in the airtight container and arranged to compress the refrigerant therein, a silencer space housed in the airtight container, and having a longitudinal silencer space therein; A communication tube communicating with the cylinder, and an end tube communicating with an inner space of the sealed container. The communication tube and the end tube each have a first opening end and a second opening end that open in the muffler space. The first opening end and the second opening end are located in a predetermined direction from the center of the silencer space along the longitudinal direction of the silencer space. The distance between the first opening end and the second opening end along the longitudinal direction is the distance between the first opening end and the center along the longitudinal direction and between the second opening end and the center along the longitudinal direction. Shorter than at least one of the distances. Hermetic compressors produce low noise and have stable performance.

Description

Hermetic compressor {HERMETIC COMPRESSOR}

The present invention relates to an inverter controlled hermetic compressor for use in a refrigeration cycle device such as an electric refrigerator.

The impact on the global environment is required to be reduced and therefore refrigeration cycle devices such as refrigerators are required to have higher operating efficiency while producing less noise.

5 is a sectional view of a conventional hermetic compressor 5001 disclosed in Japanese Laid-Open Patent Publication No. 2003-172265. Here, the sealed container 1 houses the power element 5 and the compressor element 6. The power element 5 comprises a stator 93 with a rotor 4 and a winding 3A. The compressor element 6 is driven by the power element 5. The airtight container 1 accommodates the lubricating oil 8 in the bottom part.

The crankshaft 10 includes a shaft portion 11 and an eccentric portion 12 having an axis line shifted from the axis line of the shaft portion 11. The rotor 4 is press-inserted into the shaft portion 11 and fixed. The oil pump 13 provided in the shaft portion 11 is opened in the oil 8. The cylinder block 20 has a compression chamber 22 having a substantially cylindrical shape and a shaft bearing 23 for supporting the shaft portion 11. The cylinder block is located above the power element 5.

The piston 30 is inserted into the compression chamber 22 to reciprocate in the compression chamber 22, and is coupled to the eccentric portion 12 by the coupler 31. The valve plate 32 seals the compression chamber 22. A movable valve 33 consisting of a strip spring is mounted on the valve plate 21. The suction port 34 communicates with the compression chamber 22. The movable valve 33 and the inlet 34 provide a suction valve 35. The head 36 provides a high pressure chamber and is attached to the side of the valve plate 32 opposite the compression chamber 22. The suction tube 39 is attached to the sealed container 1 and communicates with the low pressure side of the refrigerating cycle to introduce the refrigerant gas R134a into the sealed container 1.

The airtight container 1 is manufactured by press working a steel plate, and has a column resonant frequency of about 500 Hz when the refrigerant gas R134a is used.

6 is a front view of the suction muffler 40 of the hermetic compressor 5001. FIG. 7 is a cross-sectional view of the suction muffler 40 along line 7-7 shown in FIG. 6. The suction muffler 40 is made of a resin material having a silencer space 41. The silencer space 41 includes chambers 40A and 40B spaced apart from each other to the right and left, respectively, and a communication space 40C communicating between the chambers 40A and 40B. The communication path 42 communicates between the movable valve 33 and the silencer space 41. The communication path 42 is bent about 50 degrees to extend into the muffler space 41 and has an opening end 42A that opens in the muffler space 41. The communication path 43 communicates between the interior of the sealed container 1 and the silencer space 41. The communication path 43 has an opening end 43A that opens in the silencer space 41. Chamber 40A functions as a resonant muffler with a resonant frequency of about 500 Hz.

Operation of the hermetic compressor 5001 will be described below.

The rotor 4 of the power element 5 drives the crankshaft 10 to rotate the eccentric 12. The rotation of the eccentric portion 12 is transmitted to the piston 30 through the coupler 31, so that the piston 30 reciprocates in the compression chamber 22. Due to this reciprocating motion, the refrigerant gas flows from the refrigeration system to the sealed container 1 and flows into the sealed container 1 through the suction tube 39. The introduced refrigerant gas reaches the chamber 40B through the communication path 43. Thereafter, the refrigerant gas flows through the communication path 42 and the suction opening 34 and into the compression chamber 22 while the movable valve 33 is open. The refrigerant gas is compressed in the compression chamber 22 and returns to the refrigerant system.

The movable valve 33 is opened and closed when the refrigerant gas flows into the compression chamber 22. Upon opening and closing, the actuating valve 33 generates pressure pulses having various frequencies, which pulses are transmitted in a direction opposite to the flow direction of the refrigerant gas. Among the generated pulses, a pressure pulse having a frequency of 500 Hz in the resonant mode reaches the interior of the hermetic container 1 and increases the noise of 500 Hz of the host resonance of the hermetic container 1. However, chamber 40A provides a resonant muffler having a resonant frequency of 500 Hz, reducing the compression pulse of 500 Hz in chamber 40A.

In the conventional compressor 5001, the silencer space 41 of the suction muffler 40 essentially provides a resonant muffler having a specific resonance frequency, thereby suppressing miniaturization of the suction muffler 40.

When the silencer space 41 is reached, the refrigerant gas is decelerated, thereby separating oil from the refrigerant gas. The opening end 42A of the communication path 42 faces the opening end 43A, and this arrangement causes most of the refrigerant gas that reaches the muffler space 41 to be transferred into the communication path 42. Therefore, the refrigerant gas containing a large amount of oil flows into the compression chamber 22.

As described above, the suction muffler 40 may fail to reduce the noise caused by the pulses, and the refrigerant gas containing a large amount of oil flows into the compression chamber 22, thereby improving the performance of the compressor 5001. You can drop it.

Summary of the Invention

The hermetic compressor includes a hermetically sealed container having an inner space, a cylinder housed in the hermetic container and arranged to compress the refrigerant, a suction muffler having a silencer space contained in the hermetic container and having a longitudinal direction, and a communication tube communicating with the cylinder. And an end tube in communication with the interior space of the hermetically sealed container. The communication tube and the end tube have first and second opening ends, respectively, that open in the silencer space. The first and second opening ends are located in a predetermined direction from the center of the muffler space along the longitudinal direction of the muffler space. The distance between the first opening and the second opening in the longitudinal direction is shorter than at least one of the distance between the center and the first opening in the longitudinal direction and the distance between the center and the second opening in the longitudinal direction.

Hermetic compressors generate less noise and provide more stable performance.

1 is a cross-sectional view of a hermetic compressor according to an exemplary embodiment of the present invention;

2 is a cross-sectional view of the suction muffler of the hermetic compressor according to the embodiment;

3 is a cross-sectional view of the suction muffler along line 3-3 shown in FIG.

4 shows an acoustic profile of a suction muffler according to the embodiment;

5 is a cross-sectional view of a conventional hermetic compressor,

6 is a front view of a suction muffler of the conventional hermetic compressor,

7 is a sectional view of the suction muffler along line 7-7 shown in FIG.

1 is a cross-sectional view of a hermetic compressor 1001 in accordance with an exemplary embodiment of the present invention. The hermetic compressor 1001 includes a compressor body 104 and a hermetic container 101 containing the compressor body. The sealed container 101 accommodates the lubricating oil 102 at the bottom. The compressor body 104 includes a power element 110 and a compressor element 120 driven by the power element 110. Closed vessel 101 is filled with a hydrocarbon refrigerant, such as R600a, which has a low global warming potential. The power supply terminal 108 is mounted to the closed container 101 to connect the power element 110 to a power supply. The hermetic compressor 1001 has a height about 20 mm lower than that of the conventional hermetic compressor 5001 shown in FIG.

The power element 110 will be described in more detail below. The power element 110 includes a DC brushless motor of a projection-pole concentration winding type that includes a stator 112 and a rotor 114. The power element 110 is connected to the inverter drive circuit via the power supply terminal 108 with a conductor line.

Stator 112 includes a stator core having a stimulus tooth and a winding that winds around the stimulus tooth. The stator core is made of electronic iron material with small iron loss. The winding is wound directly onto an insulator coating that applies the magnetic pole teeth of the stator core as a whole. The rotor 114 includes a rotor core and a permanent magnet provided to the rotor core, and is fixed to the main shaft 122 of the crank shaft 121. The power element 110 is driven at a plurality of frequencies in the range of 18r / s to 81r / s by the inverter drive circuit.

Compressor element 120 will be described in detail below. Compressor element 120 is located above power element 110. The compressor element 120 includes a cylinder 130, a piston 128, a crankshaft 121, and a suction muffler 140.

The crankshaft 121 includes a main shaft 122 and an eccentric shaft 124. The lower end 122A of the main shaft 122 is immersed in the oil 102. The crank shaft 121 has a lubrication mechanism 125 extending from the lower end 122A of the main shaft 122 to the upper end 124A of the eccentric shaft 124. The block 126 includes a cylinder 130 and a bearing portion 127 supporting the main shaft 122 during rotation.

The piston 128 is received in the cylinder 130 to reciprocate in the cylinder. The piston 128 provides a compression chamber 134 with a valve plate mounted at one end of the cylinder 130. The piston 128 is coupled to the eccentric shaft 124 with a coupler 136.

The suction muffler 140 is made of a crystalline resin containing glass fiber or a synthetic resin material such as poly-butyrene terephthalic acid, and is interposed between the valve plate 132 and the cylinder head 138.

2 is a cross-sectional view of the suction muffler 140 of the hermetic compressor 1001. 3 is a cross-sectional view of the suction muffler 140 along line 3-3 shown in FIG. The suction muffler 140 has a silencer space 142 and includes a communication tube 150 and an end tube 152. The communication tube 150 has an opening end 154 open in the silencer space 142 and an opening end 156 in communication with the compression chamber 134 in the cylinder 130. The end tube 152 has an opening end 158 that opens in the muffler space 142 and an opening end 160 that communicates with the interior space 141 in the hermetically sealed container 101.

The opening end 154 of the communication tube 150 and the opening end 158 of the end tube 152 are longitudinally 1140 of the muffler space 142 from the center of the muffler space 142 along the longitudinal direction 1140. Spaced apart from the predetermined direction 1142. The opening ends 154 and 158 are arranged in close proximity to each other. More specifically, the distance L3 between the open end 154 of the communication tube 150 and the open end 158 of the end tube 152 along the longitudinal direction 1140 is a silencer along the longitudinal direction 1140. Opening end 158 of center 1141 and distal tube 152 along distance L2 and longitudinal direction 1140 between center 1141 of space 142 and opening end 154 of communication tube 150. Is shorter than either of the distances L1. Communication tube 150 and distal tube 152 extend along longitudinal direction 1140 and include a plane 1145 that is perpendicular to the longitudinal direction and includes a center 1141 of silencer space 142 along longitudinal direction 1140. Through)

The opening end 154 of the communication tube 150 has an extension length that is longer than the length of the opening end 158 of the end tube 152 in the muffler space 142. In other words, the distance L2 is longer than the distance L1. An opening end 154 of the communication tube 150 is located above the opening end 158 of the end tube 152.

Portion 212A of wall 212 of suction muffler 140 forming silencer space 142 provides distal tube 152. The portion 212A of the wall 212 of the suction muffler 140 that is part of the end tube 152 is connected with the extension 214. Extension 214 is inclined in direction 1143 so that silencer space 142 has a protrusion.

The operation of the hermetic compressor 1001 will be described below. When the inverter drive circuit applies energy to the power element 110, the stator 112 generates a magnetic field to rotate the rotor 114, thereby rotating the crankshaft 121. As the main shaft 122 of the crank shaft 121 rotates, the eccentric shaft 124 rotates eccentrically. This eccentric rotation is converted into reciprocating motion through the coupler 136. This causes the piston 128 to reciprocate in the cylinder 130. This reciprocating motion of the piston 128 introduces the refrigerant gas in the hermetic container 101 into the compression chamber 134 so that the gas is compressed (compression process).

Due to the compression of the refrigerant gas, the refrigerant gas in the sealed container 101 is intermittently introduced into the compression chamber 134 through the suction muffler 140. The refrigerant gas is compressed and then sent to the refrigerant cycle outside the hermetic container 101 through the exhaust tube. The suction muffler 140 reduces the pulse noise generated by the intermittent inflow of refrigerant gas. Suction muffler 140 consists of poly-butyrene terephthalic acid having much less heat transfer than metal and reduces the temperature rise of the refrigerant gas with a low temperature returning from the refrigerant cycle, thereby preventing a decrease in cooling performance of the refrigerant cycle.

The noise preventing effect of the suction muffler 140 will be described in detail below. 4 shows an acoustic profile of the muffler space 142 in the suction muffler 140. In FIG. 4, the horizontal axis represents frequency and the vertical axis represents the acoustic pressure level emitted from the open end 160 of the end tube 152 of the suction muffler 140. The smaller the sound pressure level, the greater the noise protection effect. 4 shows the acoustic profile 170 of the suction muffler 140 according to this embodiment as well as the acoustic profile 173 of the suction muffler of the comparative example. In the suction muffler of the comparative example, the open end 158 of the end tube 152 is located at the center 1141 along the longitudinal direction 1140 of the muffler space 142.

The main component of the pulse noise generated in the sealed container 101 is the resonance sound of the inner space 141 of the sealed container 101. In the suction muffler 140 according to this embodiment, the anti-resonant frequency 171 of the acoustic profile 170 is the same as the resonant frequency 162 of the interior space 141.

If the open end 158 of the end tube 152 is located further away from the open end 154 of the communication tube 150, it is located closer to the center of the muffler space 142, and the anti-resonant frequency ( 171 moves toward a higher frequency similar to anti-resonant frequency 174. The amount of reduced noise decreases as the anti-resonant frequency 171 reaches the resonance frequency 172, similar to the amount of noise reduced at the anti-resonant frequency 174.

Thus, the open end 158 of the distal tube 152 is preferably located further away from the center 1141 and closer to the open end 154 of the communication tube 150, so that the anti-resonant frequency ( Increase the amount of reduced noise at 171). The specific frequency of significant pulse noise produced in the hermetic compressor 1001 coincides with the anti-resonant frequency 171 to reduce the pulse noise around that frequency.

The vertices P1 and P2 of the acoustic profile 170 of the resonant frequency 172 are larger than the vertices P3 and P4 of the acoustic profile 173 at the resonant frequency 175 of the suction muffler of the comparative example. The resonant frequency 162 is spaced from a particular frequency of significant pulse noise, which is not amplified in the suction muffler 140 and is not emitted as loud noise from the hermetic compressor 1001.

Even if the muffler space 142 has a small volume, due to the reduction in the size of the hermetic compressor 1001 and thereby the noise suppression effect of the suction muffler 140, the muffler 140 is at a specific frequency. It has a large anti-noise effect.

The specific frequency of the pulse noise is determined by the resonant frequency 162 of the inner space 141 of the hermetic container 101 to reduce the pulse noise from the hermetic compressor 1001.

The oil 102 stored at the bottom of the airtight container 101 is pumped up according to the compression process, and the eccentric shaft 124 from the lower end 122A of the main shaft 122 by the lubrication mechanism 125 of the crankshaft 121. ) Is supplied to the upper end 124A. The oil is then sprayed and sprinkled onto the movable component of the closed container 101. Some of the oil becomes oil mist mixed with the refrigerant gas, while most of the oil falls off and is stored at the bottom of the closed container 101.

Refrigerant gas 200 having a portion of the mixed oil enters the silencer space 142 from the interior space 141 via the end tube 152 and is then sucked into the opening end 154 of the communication tube 150. Enter The open end 154 of the communication tube 150 and the open end 158 of the end tube 152 point in the same direction 1142. Most of the refrigerant gas 200 discharged from the open end 158 of the end tube 152 is sucked into the silencer space 142 while contacting the outer wall 154A of the open end 154 of the communication tube 150.

The oil mist mixed in the refrigerant gas 200 is attached to the outer wall 154A of the opening end 154 of the communication tube 150, allowing the oil 102 to be separated from the refrigerant gas 200. The separated oil 102 drops down to the bottom of the muffler space 142 in the suction muffler 140. The oil 102 then flows through the oil outlet 178, drains into the interior space 141 of the hermetic container 101, and is then stored at the bottom of the hermetic container 101. Thus, the refrigerant gas containing a small amount of oil mist is introduced into the cylinder 130, thereby ensuring a stable performance of the hermetic compressor 1001.

The open end 154 of the communication tube 150 extends longer than the open end 158 of the end tube 152. In other words, the open end 154 of the communication tube 150 extends further than the open end 158 of the end tube 152 in the muffler space 142. That is, distance L2 is longer than distance L1. This arrangement increases the area of the outer wall 154A of the opening end 154 with which the oil mist contacts, separating a large amount of oil from the refrigerant gas 200 and providing a hermetic compressor 1001 having high efficiency and stable performance. do.

An opening end 154 of the communication tube 150 is located above the opening end 158 of the end tube 152. This arrangement allows the outer wall 154A of the open end 154 of the communication tube 150 to face in the downward direction 1144. The oil 102 separated from the refrigerant gas and attached to the outer wall 154A of the communication tube 150 drops to the bottom of the muffler space 142 of the sealed container 101. The separated oil 102 is prevented from being sucked into the opening end 154 of the communication tube 150, so that refrigerant gas containing a small amount of oil mist is introduced into the cylinder 130. Thus, the hermetic compressor 1001 has high efficiency and stable performance.

A portion 212A of the wall 212 that provides the end tube 152 is also a portion of the wall 212 that forms the silencer space 142, and the extension 214 of the wall 212 is in the direction 1143. Can be tilted to expand the silencer space 142. This structure allows the refrigerant gas 200 containing the oil mist to flow directly along the portion 212A of the wall 212 and onto the portion 212A, thereby allowing the oil 102 to flow into the refrigerant gas ( 200, causing oil 102 to adhere to wall 212. Refrigerant gas 200 flows from the open end 158 of the end tube 152 and flows into the muffler space 142.

The oil 102 attached to the wall 212 is then supported on the extension 215 away from the refrigerant gas 200 and then falls from the extension 215 to the bottom of the muffler space 142. Accordingly, the refrigerant gas 200 introduced into the opening end 154 of the communication tube 150 contains a small amount of oil, has a high purity, thereby providing a hermetic compressor 1001 having high efficiency and stable performance.

The power element 110 of this embodiment includes a DC brushless motor with a central winding around the protruding pillar. The power element 110 may include a distributed winding induction motor that is associated with a suction muffler 140 that reduces noise generated from the compressor, providing a hermetic compressor with stable performance and miniaturization. have.

The power element 110 employing a motor including a rare earth magnet having a high magnetic strength can reduce the height, thus providing a hermetic compressor which generates low height and low noise.

The hermetic compressor 1001 of this embodiment can be driven over a wide range of rotations by an inverter drive circuit. The splashing state of oil 102 is mostly subject to rotation. When the compressor 1001 is driven at high rotation, a large amount of oil 102 splashes and is easily moved into the suction muffler 140. The high rotational operation of the hermetic compressor 1001 of this embodiment causes the refrigerant gas to flow directly along and on the wall 212 of the end tube 152, separating the refrigerant gas from oil. do. The hermetic compressor 1001 prevents oil 102 from entering the compression chamber 134 over a wide range of rotations, thereby ensuring high efficiency and stable performance.

As described above, the hermetic compressor 1001 according to the present embodiment enables the acoustic characteristics of the suction muffler 140 to be optimized and stably separates the refrigerant gas from the oil 102, thereby having a stable performance and less It will generate noise.

It should be understood that the present invention is not limited to the above embodiment.

The hermetic compressor according to the present invention generates little noise and has a stable performance, which is useful for refrigeration devices such as air conditioners and vending machines as well as electric refrigerators.

Claims (16)

An airtight container having an internal space, A cylinder housed in the sealed container and arranged to compress the refrigerant therein; A suction muffler accommodated in the sealed container and having a silencer space having a longitudinal direction therein; A communication tube having a first opening end opening in the muffler space and communicating with the cylinder; A terminal tube having a second opening end opening in said muffler space and in communication with an interior space of said hermetic container, The first opening end and the second opening end are located in a predetermined direction from the center of the muffler space along the longitudinal direction of the muffler space, The distance between the first opening end and the second opening end along the longitudinal direction is equal to the distance between the first opening end and the center along the longitudinal direction and between the second opening end and the center along the longitudinal direction. Shorter than at least one of The anti-resonant frequency in the silencer space of the suction muffler is equal to the resonant frequency in the interior space of the hermetic container. Hermetic compressor. delete The method of claim 1, The communication tube and the end tube extend in the longitudinal direction. Hermetic compressor. The method of claim 1, The distance between the first opening end and the center along the longitudinal direction is longer than the distance between the second opening end and the center along the longitudinal direction Hermetic compressor. The method of claim 1, The first opening end is located above the second opening end Hermetic compressor. The method of claim 1, The suction muffler comprises a wall defining the silencer space, The wall is A portion providing said end tube, An extension extending in a direction capable of expanding the silencer space Hermetic compressor. The method of claim 1, Oil is scattered in the inner space of the closed container Hermetic compressor. An airtight container having an internal space, A cylinder housed in the sealed container and arranged to compress the refrigerant therein; A suction muffler accommodated in the sealed container and having a silencer space having a longitudinal direction therein; A communication tube having a first opening end opening in the muffler space and communicating with the cylinder; A terminal tube having a second opening end opening in said muffler space and in communication with an interior space of said hermetic container, The first opening end and the second opening end are located in a predetermined direction from the center of the muffler space along the longitudinal direction of the muffler space, The distance between the first opening end and the second opening end along the longitudinal direction is equal to the distance between the first opening end and the center along the longitudinal direction and between the second opening end and the center along the longitudinal direction. Shorter than at least one of The distance between the first opening end and the center along the longitudinal direction is longer than the distance between the second opening end and the center along the longitudinal direction Hermetic compressor. The method of claim 8, The communication tube and the end tube extend in the longitudinal direction. Hermetic compressor. The method of claim 8, The first opening end is located above the second opening end Hermetic compressor. The method of claim 8, The suction muffler comprises a wall defining the silencer space, The wall is A portion providing said end tube, An extension extending in a direction capable of expanding the silencer space Hermetic compressor. The method of claim 8, Oil is scattered in the inner space of the closed container Hermetic compressor. An airtight container having an internal space, A cylinder housed in the sealed container and arranged to compress the refrigerant therein; A suction muffler accommodated in the sealed container and having a silencer space having a longitudinal direction therein; A communication tube having a first opening end opening in the muffler space and communicating with the cylinder; A terminal tube having a second opening end opening in said muffler space and in communication with an interior space of said hermetic container, The first opening end and the second opening end are located in a predetermined direction from the center of the muffler space along the longitudinal direction of the muffler space, The distance between the first opening end and the second opening end along the longitudinal direction is equal to the distance between the first opening end and the center along the longitudinal direction and between the second opening end and the center along the longitudinal direction. Shorter than at least one of The first opening end is located above the second opening end Hermetic compressor. The method of claim 13, The communication tube and the end tube extend in the longitudinal direction. Hermetic compressor. The method of claim 13, The suction muffler comprises a wall defining the silencer space, The wall is A portion providing said end tube, An extension extending in a direction capable of expanding the silencer space Hermetic compressor. The method of claim 13, Oil is scattered in the inner space of the closed container Hermetic compressor.

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