The present invention relates to a hermetic compressor used in a refrigerating cycle of a Refrigerator Freezer, etc.
Recently, reduction in power consumption of this kind of hermetic compressors has been strongly demanded. In a hermetic compressor disclosed in International Publication WO 02/02944, by improving an outer shape of a piston, sliding loss between the piston and a cylinder is reduced so as to achieve efficiency.
Hereinafter, a conventional hermetic compressor is described with reference to drawings.
As shown in
Crankshaft 10 includes main shaft 11 to which rotor 3 is press-fitted and fixed and eccentric shaft 12 formed eccentric to main shaft 11. Inside main shaft 11, oil pump 13 is housed and an opening portion of oil pump 13 is disposed in oil 6. Block 20 provided at the upper side of motor element 4 has cylinder 21 having a substantially cylindrical shape and bearing 22 for supporting main shaft 11. Piston 30 is inserted into cylinder 21 of block 20 capable of reciprocating sliding and coupled to eccentric shaft 12 via connecting means 41.
Next, a conventional piston is described with reference to
Removed portion 36 is a concave portion that is not brought into close contact with the inner circumferential surface of cylinder 21. Furthermore, an angle made by lines respectively connecting between central axis 37 of cylindrical piston 30 and two boundary edges 35a and 35b of guide surface 35 in the direction of the radius of piston 30 is generally 40° or less and preferably 30° or less.
Next, an operation of a conventional hermetic compressor shown in
During operation, piston 30 reciprocates in the horizontal direction in the drawing. In the vicinity of the bottom dead center, a part of the skirt side of piston 30 is protruded to the outside of cylinder 21. From this state, when piston 30 enters cylinder 21, that it is to say, when piston 30 moves in the right direction of
However, in a conventional hermetic compressor, inclination in the vertical direction of piston 30 with respect to cylinder 21 is regulated by space between outer circumferential surface 33 and cylinder 21 only in short section 34A between the edge of top surface 31 and the edge of seal surface 34. Therefore, piston 30 is likely to be inclined in the vertical direction. In particular, during the compression stroke from the bottom dead center to the top dead center (movement in the right direction in
In particular, when low-density refrigerant Isobutane (R600a) was used, the outer diameter of piston 30 was increased and leakage of refrigerant was likely to occur, and therefore the efficiency was lowered remarkably.
In order to solve the above-mentioned problems with a prior art, a hermetic compressor of the present invention includes an under cut that does not communicate with at least a top surface of a piston on an outer circumferential surface of the piston excluding a sliding surface provided in the axis direction and in the perpendicular direction of the piston pin, in which the under cut communicates with space inside a housing at least in the vicinity of the bottom dead center. This configuration makes it possible to reduce sliding loss due to the reduction in a sliding area. Furthermore, by the sliding surface provided in the parallel and in the perpendicular direction of the piston pin, the inclination of the piston with respect to the cylinder is suppressed, thus suppressing the leakage of refrigerant. Furthermore, by supplying the sliding portion with oil through the under cut, the sealing property can be improved. With the above mentioned effect, a hermetic compressor with high efficiency can be provided.
Hereinafter, an exemplary embodiment of the present invention is described with reference to drawings. Note here that the present invention is not limited by the exemplary embodiment.
As shown in FIGS. 1 to 6, housing 101 houses motor element 104 and compression mechanism 105 driven by motor element 104, and moreover contains oil 106. Motor element 104 includes stator 102 and rotor 103, and enables inverter driving by using a control circuit, etc. controlled at plural operational frequencies including operation frequency that is not higher than power supply frequency.
The hermetic compressor of this exemplary embodiment uses hydrocarbon-based refrigerant Isobutane (or R600a). Refrigerant R600a is a natural refrigerant with low global warming potential.
Crankshaft 110 includes main shaft 111 and eccentric shaft 112 and is disposed in substantially the vertical direction. Herein, rotor 103 is press-fitted and fixed to main shaft 111 and eccentric shaft 112 is disposed eccentric to main shaft 111.
Oil supplying structure 120 includes centrifugal pump 122, vertical hole 123, and lateral hole 124. One end of centrifugal pump 122 formed inside of crankshaft 110 is opened in oil 106 with another end connected to viscosity pump 121. One end of vertical hole 123 is connected to one end of viscosity pump 121 with another end opened in space inside housing 101.
Block 130 includes substantially cylindrical cylinder 131, main bearing 132 for supporting main shaft 111 and collision-portion 134 provided on the upper side of cylinder 131. Cylinder 131 includes notch 135 provided on the upper side of the edge at the side of crankshaft 110.
Piston 140 is inserted into cylinder 131 capable of reciprocating sliding. Piston 140 has piston pin hole 141 formed in parallel to the center axis of eccentric shaft 112. Into piston pin hole 141, hollow cylindrical piston pin 142 is fitted. Piston pin 142 is fixed to piston 140 by hollow cylindrical lock pin 143. Piston pin 142 is connected to eccentric shaft 112 via connecting rod 146.
Hollow part 144 of piston pin 142 communicates with space inside housing 101 via vent hole 145.
On outer circumferential surface 150 of piston 140, under cut 153 is formed. Under cut 153 does not reach top surface 151 of piston 140 but reaches skirt surface 152.
Furthermore, as shown in
Furthermore, as shown in
As shown in
Furthermore, on circumferentially formed land 190, two annular grooves 191 are provided in the outer circumferential direction of the piston. Furthermore, on outer circumferential surface 150 of the piston, at both end portions of top surface 151 side and skirt surface 152 side, minute tapers 201 and 202 are provided.
In this exemplary embodiment, as shown in
Next, the operation and action of the hermetic compressor of the exemplary embodiment are described.
When rotor 103 of motor element 104 rotates crankshaft 110, the rotation movement of eccentric shaft 112 is transmitted to piston 140 via connecting rod 146 and piston pin 142 as a connecting portion, and thereby piston 140 reciprocates in cylinder 131. When piston 140 reciprocates, a refrigerant gas is sucked from a cooling system (not shown) into cylinder 131, compressed and then discharged into the cooling system, again.
Next, an operation of oil supplying structure 120 is described. By the rotation of crankshaft 110, centrifugal pump 122 is rotated so as to generate centrifugal force. By the centrifugal force, oil 106 moves upwardly in centrifugal pump 122 to reach viscosity pump 121. Oil 106 which reached viscosity pump 121 further moves upwardly in viscosity pump 121 and are scattered in housing 101 via vertical hole 123 and lateral hole 124.
Oil 106 scattered in housing 101 collides with collision-portion 134 and moves along notch 135 so as to be attached to outer circumferential surface 150 of the piston. Attached oil 106 moves around outer circumferential surface 150, under cut 153, annular groove 191 and minute tapers 201 and 202 in accordance with the reciprocating movement of piston 140, and works as a lubricant between outer circumferential surface 150 and cylinder 131.
In the hermetic compressor of this exemplary embodiment, as shown in
As shown in
Furthermore, since angle θ made by edge 180 and outer circumferential surface 150 of the piton is made to be an acute angle, in accordance with the movement of piston 140, oil 106 is efficiently drawn into between cylinder 131 and outer circumferential surface 150 of the piston.
In this exemplary embodiment, since four under cuts 153 are provided in the axial direction of piston 140, through under cut 153, oil 106 is supplied to the wide range of outer circumferential surface 150 of the piston.
With the synergistic effect of them, the lubricant property of piston 140 is improved, and extremely high sealing property can be obtained so as to suppress leakage of refrigerant. Therefore, high efficiency can be realized.
In general, when piston 140 is in the vicinity of the top dead center, the inside of cylinder 131 becomes high pressure due to a compressed refrigerant, so that a refrigerant gas is about to leak from between cylinder 131 and outer circumferential surface 150 of the piston. At this time, by compression load generated inside cylinder 131, via piston pin 142 and connecting road 146, crankshaft 110 is pressed toward the opposite direction to the piston and may be inclined. When crankshaft 110 is inclined, piston 140 may be inclined in the vertical direction with respect to cylinder 131, thereby forming a part in which space between cylinder 131 and outer circumferential surface 150 of the piston may be broadened. As a result, leakage of a refrigerant gas from the part may be accelerated. Furthermore, the inclination of piston 140 may deteriorate the lubricant state between piston 140 and cylinder 131 and may increase a sliding noise.
However, in this exemplary embodiment, since upper sliding surface 154 and lower sliding surface 155 of piston 140 are provided over the full length of piston 140 from top surface 151 to skirt surface 152 as shown in
Furthermore, the sliding loss generated when piston 140 reciprocates in cylinder 131 is in a state of fluid lubricant in which the loss is reduced in proportion to reduction of the sliding area. In this exemplary embodiment, since the area of under cut 153 is set to not less than one half of the area of outer circumferential surface 150 of the piston, sliding loss of piston 140 is about one half. Thus, high efficiency by remarkable input reduction can be realized.
Furthermore, during the compression stroke, a high pressure gas inside cylinder 131 leaks out to under cut 153. However, since under cut 153 always communicates with space inside housing 101 at skirt surface 152 side, leaked refrigerant gas is not accumulated in under cut 153. Therefore, jet noise is not generated when the under cut comes out from the cylinder and a high pressure gas is released into low pressure space inside housing 101 at once in the case of a piston having a structure in which an under cut does not communicates with space inside housing 101. Furthermore, a high pressure gas accumulated in the under cut does not backflow into cylinder 131 to increase re-expansion loss during the suction stroke.
Note here that, in this exemplary embodiment, under cut 153 always communicates with skirt surface 152. However, another configuration mentioned below can provide the same effect because a high pressure gas is released into space inside housing 101. That is to say, without allowing under cut 153 to communicate with skirt surface 152, under cut 153 may be allowed to communicate with space inside housing 101 only in the vicinity of the bottom dead center, or under cut 153 may be allowed to communicate with piston pin hole 141.
Furthermore, when circumferentially formed land 190 is provided with annular groove 191 and oil 106 is allowed to be brought into direct contact with annular groove 191 in the vicinity of the bottom dead center in which piston 140 is protruded from cylinder 131, attached oil 106 is spread over the entire part of annular groove 191 by the capillary phenomenon. Thereafter, during the movement of piston 140 from the bottom dead center to the top dead center, when a refrigerant gas reaches annular groove 191 and is joined together with oil 106 in groove 191, great viscosity resistance acts on the refrigerant gas. Furthermore, joined oil 106 and the refrigerant gas are expanded and contracted repeatedly, so that the pressure is reduced, whereby a so-called labyrinth seal effect is generated and the sealing property with respect to the leakage of refrigerant from cylinder 131 is improved. From the effect mentioned above, oil supply to the circumferentially formed land is further promoted, the lubricant property can be more improved, and furthermore, high efficiency can be achieved.
Next, the role of minute tapers 201 and 202 provided at the end portions both at top surface 151 side and skirt surface 152 side of piston 140 is described. When the piston moves from the bottom dead center to the top dead center, by the wedge effect of minute taper 201 at top surface 151 side of piston 140, oil 106 moves around circumferentially formed land 190 of piston 140 so as to improve the lubricant property of piston 140 and to also improve the sealing property. On the other hand, when piston 140 moves from the top dead center to the bottom dead center, by the wedge effect of minute taper 202 at the skirt surface 152 side, oil 106 enters minute taper 202 so as to form an oil film and lubricant property and sealing property are improved. That is to say, the presence of minute tapers 201 and 202 suppresses the leakage of refrigerant and reduces the sliding loss. Furthermore, high efficiency can be achieved.
Furthermore, in the case where the motor element is inverter driven at plural operation frequencies including operation frequency that is not more than power supply frequency, reciprocating movement speed of piston 140 is reduced during low speed operation. Furthermore, since an amount of oil 106 scattered in housing 101 is reduced, leakage of refrigerant from space between outer circumferential surface 150 of the piston and cylinder 131 is likely to be increased. On the other hand, in the hermetic compressor of this exemplary embodiment, since oil 106 can be accumulated in under cut 153 and inclination in the vertical direction of piston 140 can be suppressed, high efficiency can be maintained also during the low speed operation.
The density of refrigerant R600a used in the hermetic compressor of this exemplary embodiment is smaller than the density of refrigerant R134a (1,1,1,2-tetrafluoroethane), which has been conventionally used in refrigerators. Therefore, when refrigerating ability that is the same as in a hermetic compressor using refrigerant R134a is intended to be obtained by using refrigerant R600a, cylinder capacity is increased and the outer diameter of piston 140 may be increased. Necessarily, the flow passage area for a refrigerant is increased and the amount of refrigerant leaking into housing 101 from cylinder 131 is likely to increase. However, in the hermetic compressor of this exemplary embodiment, since the inclination of piston 140 with respect to cylinder 131 can be suppressed, the efficiency can be improved.
Note here that crankshaft 110 may be provided with secondary axis which is provided on the same axis as main shaft 111 and opposed to main shaft with eccentric shaft 112 therebetween, and at the same time, a secondary bearing for supporting the secondary axis may be provided. With such a configuration, since crankshaft 110 is supported at both ends with eccentric shaft 112 sandwiched therebetween, resulting in effectively suppressing the inclination of piston 140 in the vertical direction with respect to cylinder 131. Consequently, since the behavior of piston 140 becomes stable, sliding loss can be reduced and the increase in noise can be suppressed, it is possible to realize a hermetic compressor with high efficiency and low noise property.
As mentioned above, since a hermetic compressor according to the present invention yields high productivity, and can increase efficiency and reliability, it can be widely applied to an application of a hermetic compressor of, for example, an air conditioner, a vending machine, and the like.
Number | Date | Country | Kind |
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2004-159165 | May 2004 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP05/09006 | 5/11/2005 | WO | 10/20/2005 |