The present application claims priority from Japanese Patent application JP 2015-179641, filed on Sep. 11, 2015, and Japanese Patent application JP 2016-137898, filed on Jul. 12, 2016, the contents of which are hereby incorporated by reference into this application.
The present invention relates to a rotary compressor that is used in an air conditioner, a refrigerating machine, or the like.
For a purpose of suppressing noise caused by discharge of refrigerant, for example, a muffler member, in which two muffler outlets provided in the muffler member (end plate cover) are disposed in positions which are symmetrical sound sources with respect to an space on an outside of the muffler and nodes of a primary resonant mode and a flared portion of the muffler in a radial direction is an asymmetrical shape with respect to a y axis orthogonal to a rotation shaft, thereby being shifted from a position of a belly of a secondary resonant mode, is known.
As the related art, there is a configuration in which for a purpose of avoiding the positions of the bellies of the primary resonant mode and the secondary resonant mode, a muffler outlet is disposed adjacent to an outer peripheral portion of the boss portion (main bearing) of a front head (upper end plate). However, in such a configuration, in a case of a rotary compressor of a two-cylinder type, it becomes a muffler structure in which refrigerant that is compressed in a second compressing unit and refrigerant having a different pressure pulsation component, which is compressed in a first compressing unit and of which a pressure pulsation is reduced by a first muffler and a refrigerant path are easy to merge in a second muffler space. Therefore, the pressure pulsation is amplified and, as a result, there is a problem that noise is increased.
An object of the invention is to obtain a rotary compressor which suppresses a pressure pulsation of refrigerant being amplified and is able to suppress noise caused by discharge of refrigerant.
Hereinafter, an example (exemplary embodiment) for embodying the invention will be described in detail based on the drawings.
As illustrated in
A stator 111 of the motor 11 is formed in a cylindrical shape and is shrink-fitted and fixed in the inner circumferential surface of the compressor housing 10. A rotor 112 of the motor 11 is disposed inside the cylindrical stator 111 and is shrink-fitted and fixed to the rotation shaft 15 that mechanically connects the motor 11 with the compressing unit 12.
The compressing unit 12 includes a first compressing unit 12S and a second compressing unit 12T, and the second compressing unit 12T is disposed on an upper side of the first compressing unit 12S. As illustrated in
As illustrated in
The first vane groove 128S is formed in the first cylinder 121S over an entire region of a cylinder height in a radial direction from the first cylinder inner wall 123S. A planar first vane 127S is slidably fitted into the first vane groove 128S. The second vane groove 128T is formed in the second cylinder 121T over an entire region of a cylinder height in a radial direction from the second cylinder inner wall 123T. A planar second vane 127T is slidably fitted into the second vane groove 128T.
As illustrated in
When the rotary compressor 1 is started, the first vane 127S protrudes from the inside of the first vane groove 128S to the inside of the first cylinder chamber 130S by a repulsive force of the first vane spring and a distal end thereof abuts against an outer peripheral surface of the annular first piston 125S. As a result, the first cylinder chamber 130S is partitioned to a first inlet chamber 131S and a first compression chamber 133S by the first vane 127S. In addition, similarly, the second vane 127T protrudes from the inside of the second vane groove 128T to the inside of the second cylinder chamber 130T by a repulsive force of the second vane spring and a distal end thereof abuts against an outer peripheral surface of the annular second piston 125T. As a result, the second cylinder chamber 130T is partitioned to a second inlet chamber 131T and a second compression chamber 133T by the second vane 127T.
In addition, an outside of the first vane groove 128S in the radial direction communicates with the inside of the compressor housing 10 via an opening portion R (see
For a purpose of sucking the refrigerant from the outside to the first inlet chamber 131S, the first inlet hole 135S that causes the first inlet chamber 131S to communicate with the outside is provided in the first side-flared portion 122S of the first cylinder 121S. For a purpose of sucking the refrigerant from the outside to the second inlet chamber 131T, the second inlet hole 135T that causes the second inlet chamber 131T to communicate with the outside is provided in the second side-flared portion 122T of the second cylinder 121T. A cross-section of each of the first inlet hole 135S and the second inlet hole 135T is circular.
In addition, as illustrated in
A lower end plate 160S is disposed in a lower end portion of the first cylinder 121S and closes the first cylinder chamber 130S of the first cylinder 121S. In addition, an upper end plate 160T is disposed in an upper end portion of the second cylinder 121T and closes the second cylinder chamber 130T of the second cylinder 121T. The lower end plate 160S closes a lower end portion of the first cylinder 121S and the upper end plate 160T closes an upper end portion of the second cylinder 121T.
A sub-bearing unit 1615 is formed on the lower endplate 160S and a sub-shaft unit 151 of the rotation shaft 15 is rotatably supported in the sub-bearing unit 1615. A main-bearing unit 161T is formed on the upper end plate 160T and a main-shaft unit 153 of the rotation shaft 15 is rotatably supported in the main-bearing unit 161T.
The rotation shaft 15 includes a first eccentric portion 152S and a second eccentric portion 152T which are eccentric by 180° phase shift from each other. The first eccentric portion 152S is rotatably fit in the first piston 125S of the first compressing unit 12S. The second eccentric portion 152T is rotatably fit in the second piston 125T of the second compressing unit 12T.
If the rotation shaft 15 is rotated, the first piston 125S revolves in the counterclockwise direction of
As illustrated in
The lower muffler chamber 180S is a single chamber. The lower muffler chamber 180S is a part of a communication path through which a discharge side of the first compressing unit 12S communicates with the inside of the upper muffler chamber 180T by passing through a refrigerant path hole 136 (see
As illustrated in
The lower end plate cover 170S, the lower end plate 160S, the first cylinder 121S, and the intermediate partition plate 140 are inserted from the lower side and are fastened to the second cylinder 121T by a plurality (four or more) of penetrating bolts 175 that are screwed into female screws provided in the second cylinder 121T. The upper end plate cover 170T and the upper end plate 160T are inserted from the upper side and are fastened to the second cylinder 121T by the penetrating bolts 175 that are screwed into female screws provided in the second cylinder 121T. The lower end plate cover 170S, the lower end plate 160S, the first cylinder 121S, the intermediate partition plate 140, the second cylinder 121T, the upper end plate 160T, and the upper end plate cover 170T, which are integrally fastened by the plurality of penetrating bolts 175 and the like, configure the compressing unit 12. The outer periphery of the upper end plate 160T in the compressing unit 12 is joined to the inner peripheral surface of the compressor housing 10 by spot welding and the compressing unit 12 is fixed to the compressor housing 10.
First and second through holes 101 and 102 are provided in an outer periphery wall of the cylindrical compressor housing 10 at an interval in an axial direction in this order from a lower section thereof so as to communicate with first and second inlet pipes 104 and 105, respectively. In addition, outside the compressor housing 10, an accumulator 25 which is formed of a separate airtight cylindrical container is held by an accumulator holder 252 and an accumulator band 253.
A system connecting pipe 255 which is connected to an evaporator in a refrigerant circuit is connected at the center of the top portion of the accumulator 25. A first low-pressure communication tube 31S and a second low-pressure communication tube 31T are fixed to a bottom through hole 257 that is provided in a bottom portion of the accumulator 25. One ends of the first low-pressure communication tube 31S and the second low-pressure communication tube 31T are extended to an upper side on an inside of the accumulator 25. The other ends thereof are respectively connected to the other ends of the first inlet pipe 104 and the second inlet pipe 105.
The first low-pressure communication tube 31S, which guides a low-pressure refrigerant of the refrigerant circuit to the first compressing unit 12S via the accumulator 25, is connected to the first inlet hole 135S (see
A discharge pipe 107 as a discharge unit, which is connected to the refrigerant circuit (refrigeration cycle) and discharges a high-pressure refrigerant to a side of a condenser in the refrigerant circuit, is connected to the top portion of the compressor housing 10. That is, the first and second outlets 190S and 190T are connected to the condenser in the refrigerant circuit.
Lubricant oil is sealed in the compressor housing 10 substantially to a height of the second cylinder 121T. In addition, the lubricant oil is sucked up from a lubricating pipe 16 attached to the lower end portion of the rotation shaft 15, using a pump impeller (not illustrated) which is inserted into the lower section of the rotation shaft 15. The lubricant oil circulates through the compressing unit 12, lubricates sliding components (the first piston 125S and the second piston 125T), and seals a fine gap in the compressing unit 12.
Next, characteristic configurations of the rotary compressor 1 of Example 1 will be described with reference to
As illustrated in
The upper end plate cover 170T covers the upper ends of the second discharge valve unit 200TV and the refrigerant path hole 136 of the upper end plate 160T (see
A muffler outlet 183T is provided in each of the five flared portions 181T. The muffler outlet 183T causes the upper muffler chamber 180T to communicate with the inside of the compressor housing 10.
As illustrated in
In the rotary compressor 1 of Example 1, on the plane orthogonal to the rotation shaft 15, the upper muffler chamber 180T has a plurality of flared portions 181T which are radially flared between the penetrating bolts 175 (bolt holes 173T) from the center of the rotation shaft 15; and a plurality of small-diameter portions 182T, which connect between the flared portions 181T respectively, are apart from the penetrating bolts 175 so as not to interfere with the penetrating bolts 175 (bolt holes 173T), and are formed on the center side of the rotation shaft 15 from the penetrating bolts 175.
The muffler outlet 183T is provided in each of the plurality of flared portions 181T. The second outlet 190T of the second discharge valve unit 200TV of the upper end plate 160T and the refrigerant path hole 136 which are opened on the inside of the upper muffler chamber 180T are disposed in the flared portions 181T on sides which are opposite to each other with respect to the rotation shaft 15. Therefore, the refrigerant discharged from the second outlet 190T is discharged from the muffler outlet 183T disposed on the second outlet 190T side to the inside of the compressor housing 10. The refrigerant discharged from the refrigerant path hole 136 is discharged from the muffler outlet 183T disposed on the refrigerant path hole 136 side to the inside of the compressor housing 10.
Therefore, the refrigerant that is compressed by the second compressing unit 12T and the refrigerant having different pulsation component, which is compressed by the first compressing unit 12S, of which the pressure pulsation is reduced by the lower muffler chamber 180S and the refrigerant path hole 136 are unlikely to be merged on the inside of the upper muffler chamber 180T. Therefore, it is suppressed that the pressure pulsation of the refrigerant is amplified and it is possible to suppress an increase in noise caused by the amplification of the pressure pulsation.
The upper end plate cover 170T2 of Example 2 covers the upper ends of the second discharge valve unit 200TV and the refrigerant path hole 136 of the upper end plate 160T (see
A muffler outlet 183T2 is provided in each of the two flared portions 181T2. The muffler outlet 183T2 causes the upper muffler chamber 180T2 to communicate with the inside of the compressor housing 10.
The second outlet 190T (see
In the rotary compressor of Example 2, on the plane orthogonal to the rotation shaft 15, the upper muffler chamber 180T2 has a plurality (two) of flared portions 181T2 which are radially flared between the penetrating bolts 175 (bolt holes 173T2) from the center of the rotation shaft 15; and a plurality (two) of small-diameter portions 182T2, which connect between the flared portions 181T2 respectively, are apart from the penetrating bolts 175 so as not to interfere with the penetrating bolts 175 (bolt holes 173T2), and are formed on the center side of the rotation shaft 15 from the penetrating bolts 175. The muffler outlet 183T2 is provided in each of the plurality (two) of flared portions 181T2. The muffler outlet 183T2 is provided in each of the plurality (two) of flared portions 181T2. The second outlet 190T of the second discharge valve unit 200TV of the upper end plate 160T and the refrigerant path hole 136 which are opened on the inside of the upper muffler chamber 180T2 are disposed in the flared portions 181T2 on sides which are opposite to each other with respect to the rotation shaft 15. Therefore, the refrigerant discharged from the second outlet 190T is discharged from the muffler outlet 183T2 disposed on the second outlet 190T side to the inside of the compressor housing 10. The refrigerant discharged from the refrigerant path hole 136 is discharged from the muffler outlet 183T2 disposed on the refrigerant path hole 136 side to the inside of the compressor housing 10.
A length of the small-diameter portion 182T2 of Example 2 in a circumferential direction is longer than that of the small-diameter portions 182T of Example 1. Therefore, the refrigerant that is compressed by the second compressing unit 12T and the refrigerant having different pulsation component, which is compressed by the first compressing unit 12S, of which the pressure pulsation is reduced by the lower muffler chamber and the refrigerant path hole 136 are further unlikely to be merged on the inside of the upper muffler chamber 180T2 than the upper muffler chamber 180T of Example 1. The pressure pulsation of the refrigerant is unlikely to be amplified. Therefore, it is possible to suppress noise caused by the discharge of the refrigerant equal to or more greatly than the noise suppression effect in the rotary compressor 1 of Example 1 illustrated in
The rotary compressor of Example 3 includes, as illustrated in
The upper end plate cover 170T3 has a muffler outlets 183T3 communicating with the inside of the compressor housing 10 and forms the upper muffler chamber 180T3 by covering openings of the second outlet 190T and the refrigerant path hole 136N of the upper end plate 160T3.
As illustrated in
The muffler outlets 183T3 are respectively provided in the flared portions 181T3. The muffler outlets 183T3 are disposed in the vicinity of an inner wall of the upper endplate cover 170T3 on the outer periphery side on the inside of the flared portion 181T3.
On the plane orthogonal to the rotation shaft 15, the second outlet 190T and two refrigerant path holes 136N of the second discharge valve unit 200TV of the upper endplate 160T3 are positioned on an inside of one flared portion 181T3A of the plurality of flared portions 181T3. An opening area of the muffler outlet 183T3A (hereinafter, referred to as a main muffler outlet 183T3A) of one flared portion 181T3A is greater than an opening area of the muffler outlet 183T3B (hereinafter, referred to as a sub-muffler outlet 183T3B) of each of other flared portions 181T3B.
The main muffler outlet 183T3A is formed such that, for example, a diameter thereof is greater than a diameter of the sub-muffler outlet 183T3B substantially by two times. In addition, the diameter of the sub-muffler outlet 183T3B in Example 3 is formed smaller than the diameters of the muffler outlets 183T and 183T2 in Examples 1 and 2, for example, substantially by 25%. In addition, in each of Examples 1 to 3, for example, total opening areas of the muffler outlets 183T, 183T2, and 183T3 are set to be equal respectively.
In addition, the upper muffler chamber 180T3 in Example 3 has one main muffler outlet 183T3A and four sub-muffler outlets 183T3B, but the number of the sub-muffler outlets 183T3B is not limited to that in the example.
As illustrated in
As in Example 3, in a case of a configuration in which the refrigerant path holes 136N and the second outlet 190T are disposed in one flared portion 181T3 of the upper muffler chamber 180T3, a discharge amount of the discharge refrigerant intensively discharged to the inside of the one flared portion 181T3 is increased. Therefore, it is difficult to sufficiently discharge the discharge refrigerant from the muffler outlet 183T3 of the one flared portion 181T3. In the case of the configuration, the discharge refrigerant which is not discharged from the muffler outlet 183T3 among the discharge refrigerant discharged to the one flared portion 180T3 flows into another flared portion 181T3 and is discharged from each of the muffler outlets 183T3 of flared portions 181T3. However, since distances from the one flared portion 181T3 to the muffler outlets 183T3 of the other flared portions 181T3 are different respectively, frequency components of noise caused by the discharge of the refrigerant from the muffler outlets 183T3 of flared portions 181T3 are different from each other. Therefore, different frequency components of noise generated in each muffler outlet 183T3 are mixed and thereby there is a concern that it leads to a decrease in the effect of noise reduction.
Then, in Example 3, as described above, the opening area of the main muffler outlet 183T3A of the one flared portion 181T3A in which the refrigerant path holes 136N and the second outlet 190T are disposed is greater than the opening area of the sub-muffler outlet 183T3B of each of other flared portions 181T3B. Therefore, discharge property of the main muffler outlet 183T3A is properly raised and the discharge amount of the refrigerant from the sub-muffler outlet 183T3B of each of the other flared portions 181T3B is properly suppressed.
In addition, the opening area of the main muffler outlet 183T3A of the one flared portion 181T3A is equal to or greater than the opening area of the second outlet 190T of the upper end plate 160T3. Therefore, the discharge refrigerant discharged from the second outlet 190T and the refrigerant path holes 136N smoothly passes through the main muffler outlet 183T3A and is discharged to the inside of the compressor housing 10. Therefore, the flow rate of the discharge refrigerant flowing from the flared portion 181T3A to the sub-muffler outlets 183T3B of the other flared portions 181T3B is properly suppressed and the component of the pressure pulsation can be sufficiently reduced. Therefore, it is possible to further increase the effect of noise reduction.
In addition, the total opening area of the muffler outlets 183T3 (183T3A and 183T3B) provided in each of the plurality of flared portions 181T3 (181T3A and 181T3B) is equal to or less than the total opening area of each of the first outlet 190S of the lower end plate 160S and the second outlet 190T of the upper end plate 160T3. Therefore, it is possible to reduce the pressure pulsation of the discharge refrigerant by properly filling the inside of the upper muffler chamber 180T3 with the refrigerant discharged from the first and second outlets 190S and 190T to the inside of the upper muffler chamber 180T3.
As described above, according to Example 3, in a case where the second outlet 190T and the refrigerant path holes 136N of the upper end plate 160T3 are positioned in the one flared portion 181T3A among the plurality of flared portions 181T3 included in the upper muffler chamber 180T3, the opening area of the main muffler outlet 183T3A of the one flared portion 181T3A is greater than the opening area of the sub-muffler outlet 183T3B of each of the other flared portions 181T3B. Therefore, the refrigerant discharged to the flared portion 181T3A can be smoothly discharged from the main muffler outlet 183T3A and can also be properly discharged from each of the sub-muffler outlets 183T3B of the other flared portions. Therefore, in Example 3, it is possible to suppress noise caused by the discharge of the refrigerant from the upper muffler chamber 180T3.
In Example 3 illustrated in
As illustrated in
The examples have been described above, but the examples are not limited by the contents described above. In addition, those substantially identical, so-called equivalents are included in the constituent elements described above. Furthermore, the constituent elements described above can be appropriately combined. Furthermore, at least one of various omission, substitutions, and changes of the constituent elements can be performed without departing from the scope of the examples.
Number | Date | Country | Kind |
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2015-179641 | Sep 2015 | JP | national |
2016-137898 | Jul 2016 | JP | national |