KR20080006027A - Hermetic compressor - Google Patents

Abstract

A hermetic compressor including a discharge valve system in a cylinder. Discharge valve system (114) includes discharge reed (127) having opening/closing portion (132) and discharge reed holding portion (131), spring reed (128) having movable portion (134) and spring reed holding portion (133), and stopper (129) having regulation portion (138) and stopper holding portion (137). Discharge reed (127), spring reed (128) and stopper (129) are fixed in this order to pedestal (125) of valve plate (113). At spring reed bending portion (135) provided in movable portion (134), movable portion (134) is bent toward the direction of valve seat (124) and tip portion (136) is brought into contact with plate contact portion (126). Space is provided between movable portion (134) of spring reed (128) and opening/closing portion (132) of discharge reed (127), and both are not brought into close contact with each other. Thus, delay in closing discharge reed (127) can be prevented. As a result, since it is possible to prevent discharge reed (127) and spring reed (128) from being brought into close contact with each other, the deterioration of the refrigerating capacity can be suppressed and high efficiency can be achieved.

Description

Hermetic compressor {HERMETIC COMPRESSOR}

The present invention relates to a hermetic compressor for use in a refrigeration apparatus.

Conventional hermetic compressors have a discharge valve device which improves energy efficiency by reducing noise during operation and reducing losses during opening and closing of the discharge lid, for example in Japanese Patent Laid-Open No. 2002-195160. Is disclosed.

Hereinafter, a conventional hermetic compressor will be described with reference to the drawings.

7 and 8 are a sectional view and a plan view, respectively, of a conventional hermetic compressor. 9 and 10 are side cross-sectional and exploded views, respectively, of a discharge valve device of a conventional hermetic compressor.

7 to 10, the sealed container 1 includes a discharge tube 2 and a suction tube 3 which are connected to a cooling device (not shown). The sealed container 1 also stores the oil 4 at the bottom and houses the transmission element 7 consisting of the stator 5 and the rotor 6 and the compression mechanism 8 driven therethrough. The inside of the sealed container 1 is filled with the refrigerant 9.

Next, the main structure of the compression mechanism 8 is demonstrated.

The cylinder 10 comprises a generally cylindrical compression chamber 11 and a bearing 12. The valve plate 13 includes a discharge valve device 14 outside the cylinder 10 and closes the compression chamber 11. The head 15 covers the valve plate 13. The suction muffler 16 opens one end into the sealed container 1 and communicates the other end into the compression chamber 11. The crankshaft 17 has a main shaft 18 and an eccentric shaft 19 and is axially supported by the bearing 12 of the cylinder. The rotor 6 is press-fitted to the crankshaft 17. The piston 20 is slidably inserted into the compression chamber 11 and connected to the single needle shaft 19 via the connecting rod 21.

Next, the discharge valve apparatus 14 provided in the compression mechanism 8 is demonstrated with reference to FIG.

The valve plate 13 has a yaw portion 22 on the outer side of the cylinder 10. The yaw portion 22 is provided with a discharge hole 23 communicating with the cylinder 10 and a valve seat 24 formed to surround the discharge hole 23. The valve plate 13 is provided with a pedestal 25 formed generally coplanar with the valve seat 24. The discharge lead 26, the spring lead 27, and the stopper 28 are fixed to the support part 25 by the rivet 29 in order.

The discharge lead 26 is a tongue-shaped leaf spring material. The discharge lead 26 includes a discharge lead support part 30 fixed to the support part 25 and an opening and closing part 31 for opening and closing the valve seat 24.

The spring lead 27 is a tongue-shaped leaf spring material. The spring lead 27 includes a spring lead support part 32 and a movable part 33 fixed to the supporting part 25, and the bent part 34 is provided near the root of the opening part 31 of the discharge lead 26. Have

The stopper 28 includes a stopper support part 35 fixed to the support part 25 and a restriction part 36 for restricting the movement of the discharge lead 26. The restricting portion 36 of the stopper 28 is formed substantially parallel to the plane comprising the valve seat 24 and the supporting portion 25 in cross section.

The movable part 33 of the spring lead 27 is adjusted by the bending angle of the bend part 34, and has a space | interval set with the control part 36 of the opening-and-closing part 31 of the discharge lead 26, and the stopper 28. As shown in FIG. .

The operation | movement is demonstrated about the hermetic compressor comprised as mentioned above.

When electricity is supplied to the transmission element 7, the rotor 6 rotates, and the crankshaft 17 is driven to rotate. At this time, the eccentric rotational movement of the eccentric shaft 19 is transmitted to the piston 20 via the connecting rod 21, whereby the piston 20 reciprocates in the compression chamber (11).

As the piston 20 reciprocates, the refrigerant 9 in the sealed container 1 is sucked into the compression chamber 11 from the suction muffler 16 and the refrigerant 9 of low pressure is cooled through the suction pipe 3. It flows into the closed container 1 from the apparatus (not shown). The refrigerant 9 sucked into the compression chamber 11 is compressed and discharged into the head 15 via the discharge valve device 14 of the valve plate 13. In addition, the high pressure gas discharged into the head 15 is discharged from the discharge pipe 2 to a cooling device (not shown).

However, the conventional hermetic compressor has a problem that the refrigeration capacity and efficiency easily change.

The present invention is directed to a hermetic compressor having a discharge valve device in a cylinder. The discharge valve device includes a discharge lead including an opening and closing portion and a discharge lead support portion, a spring lead including a movable portion and a spring lead support portion, and a stopper including a restricting portion and a stopper support portion. The discharge lead, spring lead and stopper are fixed in turn to the support of the valve plate. In the spring lead bent portion provided in the movable portion, the movable portion is bent toward the valve seat side, and the tip portion contacts the plate contact portion. Since the space is formed between the movable part of the spring lead and the opening / closing part of the discharge lead, the closing delay of the discharge lead can be prevented because both are not in close contact with oil. In addition, since the distance between the gaps is stable in the state where the tip portion and the plate contact portion are in contact, there is an effect of stabilizing the elastic characteristics of the discharge valve device.

The hermetic compressor of the present invention can provide a stable hermetic compressor with high energy efficiency because it prevents the discharge lead and the spring lead from being in close contact with each other and can stabilize the elastic characteristics of the discharge valve device.

The present inventors have found that in the conventional hermetic compressor, a phenomenon in which the state of low freezing capacity is maintained for a relatively long time as compared with the original refrigerating capacity immediately after the hermetic compressor is started, sometimes occurs. The above mechanism was successfully solved by analyzing the behavior of the discharge lead 26 and the spring lead 27. First, the above-described mechanism will be described with reference to FIGS. 7 to 10. In FIG. 9, the closing direction of the discharge lead is shown as the 'In' direction with respect to the cylinder 10, and the opening direction is shown as the 'Out' direction with respect to the cylinder 10.

At startup of the hermetic compressor, which tends to have a low freezing capacity phenomenon, the oil 4 is returned from the refrigeration cycle (not shown) together with the refrigerant 9. Since the oil 4 is also compressed and discharged together with the refrigerant 9, a large amount of oil 4 is interposed between the discharge lead 26 and the spring lead 27.

In general, at the start of the hermetic compressor, the suction pressure is high and the relatively dense refrigerant 9 is compressed and discharged until the pressure in the hermetic container 1 decreases, and a large load is applied to the discharge lead 26. It acts on the opening and closing part 31. On the other hand, since the displacement of the opening / closing portion 31 of the discharge lead 26 is controlled by the restricting portion 36 of the stopper 28, the opening / closing portion 31 of the discharge lead 26 is formed by the refrigerant 9 having a high density. The force is strongly applied toward the movable portion 33 of the spring lead 27 disposed between the restricting portion 36 of the stopper 28 and the opening / closing portion 31 of the discharge lead 26.

As a result of the large pressurization load as described above, the opening and closing portion 31 of the discharge lead 26 and the movable portion 33 of the spring lead 27 are brought into close contact with each other by the oil 4. That is, the discharge lead 26 and the spring lead 27 overlap like a single thick discharge lead to open and close.

Here, the movable portion 33 of the spring lead 27 is bent in the opening direction ('Out' direction) of the discharge lead 26 at the bent portion 34. As a result, the elastic force of the spring lead 27 acts in the opening direction ('Out' direction) opposite to the closing direction ('In' direction) of the discharge lead 26, and the discharge lead 26 is opened in the opening direction ( The timing of closing and pulling in the 'Out' direction is delayed.

As a result, when the piston 20 moves to the suction stroke through the top dead center in the compression chamber 11, the opening time of the discharge lead 26 becomes long. In the meantime, the high pressure refrigerant flows back in the compression chamber 11, and the stroke volume of the piston is substantially reduced, resulting in a low freezing capacity phenomenon.

While the low freezing capacity phenomenon occurs, the efficiency of the hermetic compressor is deteriorated, the power consumption is increased, and the cooling of the refrigerating device equipped with the hermetic compressor is delayed.

In addition, since the distance between the movable part 33 of the spring lead 27 and the opening-and-closing part 31 of the discharge lead 26 is adjusted by the bending angle of the bending part 34 of the spring lead 27, the spring lead 27 The distance between the movable part 33 of the () and the opening-closing part 31 of the discharge lead 26 tends to be different. When the discharge lead 26 is opened, the displacement is likely to change until the discharge lead 26 contacts the spring lead 27. That is, since the inflection point that is converted from the elastic force of the discharge lead 26 to the synthetic elastic force of the discharge lead 26 and the spring lead 27 is different, it causes variation in elastic characteristics.

Therefore, it is determined that the opening amount and the closing timing of the discharge lead 26 are easily changed, and as a result, the refrigerating capacity and efficiency can be changed.

The present invention is based on the above-mentioned explanation of the mechanism for the low freezing capacity phenomenon, and provides a stable hermetic compressor with high energy efficiency and little closing delay of the discharge lead.

The hermetic compressor of the present invention includes a valve plate having a discharge valve device on an outer side of a cylinder. The discharge valve device includes a discharge hole formed in the valve plate; A valve seat provided around the outer discharge hole of the valve plate; A support portion formed on the outer side of the valve plate at substantially the same height as the valve seat; A plate contact portion formed at a position higher than the valve seat on the valve plate outer side; A discharge lead of the leaf spring member having an opening and closing portion covering the discharge hole to be opened and closed; A spring lead of a leaf spring material provided on an outer side of the discharge lead; And a stopper provided on an outer side of the spring lead. The spring lead has a spring lead bent portion and a tip portion at the movable portion. At the spring lead bend the spring lead is bent in the valve seat direction and the tip of the spring lead is in contact with the plate contact.

Even when oil is interposed between the discharge lead and the spring lead at the start-up and an excessive load is applied to the discharge lead, a gap is formed with respect to the discharge lead at a position corresponding to the discharge lead opening and closing part, so that adhesion between the oil leads can be prevented. have. In addition, since the distance between the gaps is stabilized in contact with the plate contact portion, the elastic characteristics of the discharge valve device can be stabilized. Thus, a stable hermetic compressor with high energy efficiency is provided.

As described above, since the hermetic compressor according to the present invention can provide a stable hermetic compressor with high energy efficiency, which has almost no delay in closing the discharge leads even when the circulation amount of the refrigerant is relatively high, the refrigeration and air conditioning apparatus using the CO ₂ refrigerant It can also be applied to use.

Hereinafter, an embodiment of a compressor according to the present invention will be described with the drawings.

(Example 1)

1 and 2 are a cross-sectional view and a plan view, respectively, of a hermetic compressor according to Embodiment 1 of the present invention. 3 is a side cross-sectional view when the discharge valve device is closed according to the first embodiment, FIG. 4 is an exploded view of the discharge valve device, FIG. 5 is a side cross-sectional view when the discharge valve device is opened, and FIG. 6 is an elastic characteristic view of the discharge valve device. Respectively. In addition, in FIG. 1 and FIG. 2, the closing direction of the discharge lead is made into the "In" direction, and the opening direction is shown to the "Out" direction.

1 to 6, the sealed container 101 includes a discharge pipe 102 and a suction pipe 103 connected to a cooling device (not shown), and stores oil 104 at the bottom. In addition, the sealed container 101 accommodates a transmission element 107 consisting of a stator 105 and a rotor 106 and a compression mechanism 108 driven therefrom. The inside of the sealed container 101 is a refrigerant ( 109). The refrigerant 109 to be used is preferably a refrigerant that meets recent environmental standards and a refrigerant other than the designated Freon. For example, R134a or R600a, which is a natural refrigerant, is suitable as the refrigerant 109.

Next, the main configuration of the compression mechanism 108 will be described.

The cylinder 110 includes a generally cylindrical compression chamber 111 and a bearing 112. The valve plate 113 includes a discharge valve device 114 on the outer side ('Out' side) of the cylinder 110 to block the compression chamber 111. Head 115 covers valve plate 113. The suction muffler 116 opens one end into the sealed container 101 and communicates the other end into the compression chamber 111. The crankshaft 117 has a main shaft 118 and an eccentric shaft 119, and is supported by the bearing 112 of the cylinder 110 and press-fitted to the stator 105. The piston 120 is slidably inserted into the compression chamber 111 and is connected to the eccentric shaft 119 via the connecting rod 121.

Next, the discharge valve apparatus 114 provided in the compression mechanism 108 is demonstrated with reference to FIG.

The valve plate 113 has a yaw portion 122 on the outer side ('Out' side) of the cylinder 110. In the recess 122, a discharge hole 123 penetrating the valve plate 113 and communicating with the cylinder 110 is formed, and a valve seat 124 surrounding the discharge hole 123 is formed. The valve plate 113 is also provided with a support portion 125 and a plate contact portion 126 formed on the same plane as the valve seat 124 on the 'Out' side. The plate contact 126 is formed generally parallel to the plane comprising the valve seat 124 and the support 125 in cross section.

The discharge lead 127, the spring lead 128, and the stopper 129 are sequentially fixed to the support part 125 by the rivet 130. The discharge lead 127 (first leaf spring) is formed of a tongue-shaped leaf spring material, and includes a discharge lead support part 131 fixed to the support part 125 and an opening and closing part 132 that opens and closes the support part 124. do.

The spring lead 128 (the second leaf spring) is made of a tongue-shaped leaf spring, and includes a spring lead support 133 and a movable portion 134 fixed to the support 125. In the spring lead bent portion 135 provided in the movable portion 134, the movable portion 134 is bent toward the valve seat 124 side ('In' direction), and the tip portion 136 abuts against the plate contact portion 126 of the valve plate. All.

The stopper 129 includes a stopper support part 137 fixed to the support part 125 and a restricting part 138 for controlling the movement of the discharge lead 127. The restricting portion 138 of the stopper 129 is a side generally parallel to the plane including the valve seat 124 and the support portion 125. That is, the surface of the restricting portion 138 is generally parallel to the valve seat 124 and the supporting portion 125.

The side height dimension of the plate contact portion 126 provided in the valve plate 113 is that the movable portion 134 of the spring lid 128 is the opening and closing portion 132 of the discharge lid 127 and the restricting portion 138 of the stopper 129. It is set to have a stable interval with.

In the discharge lead 127, the opening and closing portion 132 side of the discharge lead bending portion 139 is bent toward the valve seat 124 side.

A deeper groove 140 is provided between the valve seat 124 and the support part 125 than the support part 125. The discharge lead bent part 139 is located in the outer region of the groove 140. That is, the recessed part formed in the valve plate 113 surface comprises the groove | channel 140, and the bottom face of the recessed part is formed lower than the height of the valve seat 124 and the support part 125. FIG.

The stopper contact part 141 formed in the surface bent toward the spring lead 128 side is provided at the end of the restricting part 138 of the stopper 129. The stopper contact 141 is formed generally parallel to the plane including the valve seat 124 and the support 125. That is, the stopper contact 141 is generally parallel with the plate contact 126.

Hereinafter, the operation and action of the hermetic compressor configured as described above will be described.

When electricity is supplied to the transmission element 107, the rotor 106 rotates and the crankshaft 117 is driven to rotate. At this time, the eccentric rotation of the eccentric shaft 119 is transmitted to the piston 120 via the connecting rod 121, the piston 120 reciprocates in the compression chamber 111.

The refrigerant 109 in the sealed container 101 is sucked from the suction muffler 116 into the compression chamber 111 by the reciprocating motion of the piston 120, and the refrigerant 109 of low pressure is cooled (not shown). It flows into the sealed container 101 through the suction pipe 103 from the inside. The refrigerant 109 sucked into the compression chamber 111 is compressed and discharged into the head 115 via the discharge valve device 114 of the valve plate 113. In addition, the high pressure gas discharged into the head 115 is discharged from the discharge pipe 102 to a cooling device (not shown).

Here, the oil 104 returns with the refrigerant 109 from a refrigeration cycle (not shown) at the start of the hermetic compressor. Since the oil 104 is also compressed and discharged together with the refrigerant 109, a large amount of oil 104 is interposed between the discharge lead 127 and the spring lead 128.

Also, in general, the suction pressure is high at the start of the hermetic compressor. Therefore, the relatively dense refrigerant 109 is compressed and discharged until the pressure in the sealed container 1 decreases, and a large load acts on the opening and closing portion 132 of the discharge lead 127.

On the other hand, since the displacement of the opening and closing portion 132 of the discharge lead 127 is controlled by the restricting portion 138 of the stopper 129, the opening and closing portion 132 of the discharge lead 127 has a high density of refrigerant 109. As a result, a strong force is applied toward the movable portion 134 of the spring lead 128 provided between the restricting portion 138 of the stopper 129 and the opening / closing portion 132 of the discharge lead 127. As a result, the opening / closing portion 132 of the discharge lead 127 and the movable portion 134 of the spring lead 128 tend to be in close contact with the oil 104.

However, in the first embodiment, since the spring lead bent part 135 is formed in the movable part 134 of the spring lead 128, even when the spring lead 128 is pressed toward the 'Out' side, A space 142 is formed between the opening and closing portion 132 and the movable portion 134 of the spring lid 128 as shown in FIG. 5. Since the space 142 is formed, the movable part 134 of the spring lead 128 and the opening / closing part 132 of the discharge lead 127 immediately fall, even if they are in close contact with each other. That is, since the close_contact | adherence does not last and the spring lead 128 and the discharge lead 127 do not operate integrally, the delay of closing can be prevented.

As a result, it is possible to prevent the occurrence of the low freezing capacity phenomenon caused by the backflow of the high pressure refrigerant in the compression chamber 111.

When the spring lead 128 is not pressed toward the "Out" side, as shown in FIG. 3, the front-end | tip part 136 of the spring lead 128 contacts the plate contact part 126 provided in the valve plate 113. As shown in FIG. Thus, the movable portion 134 of the spring lid 128 maintains a stable distance from the opening and closing portion 132 of the discharge lid 127. When the discharge lead 127 is opened in the 'Out' direction, the displacement until reaching the spring lead 128 is stable. That is, the variation of the inflection point from the elastic force of the discharge lead 127 to the synthetic elastic force of the discharge lead 127 and the spring lead 128 is suppressed to stabilize the elastic characteristics.

As a result, variations in the opening amount and closing timing of the discharge leads 26 can be reduced to stabilize the freezing capacity and efficiency.

Therefore, it is possible to provide a hermetic compressor having a low deviation and stable high energy efficiency.

Also, since the discharge lead 127 is bent toward the valve seat 124 side of the discharge lead bent portion 139 by the opening and closing portion 132, a force pushing the valve seat 124 against the opening and closing portion 132 of the discharge lead 127. This works.

Therefore, the opening / closing part 132 of the discharge lead 127 can be prevented from being lifted from the valve seat 124, and the better sealing property can be maintained. Therefore, it is possible to provide a hermetic compressor with higher energy efficiency.

In addition, a groove 140 is provided between the valve seat 124 and the support part 125 as a recessed portion deeper than the support part 125. Since the discharge lead bent part 139 is located at the 'out' side of the groove 140, the groove 140 may be prevented from being pressed by the elastic force of the support part 125 and the spring lead 128. As a result, the force which the opening / closing part 132 of the discharge lid 127 presses the valve seat 124 is obtained stably, and the sealing property of the opening / closing part 132 and the valve seat 124 is improved, and efficiency further improves.

In addition, according to the present exemplary embodiment, the stopper contact portion 141 bent toward the spring lead 128 is formed in the restricting portion 138 of the stopper 129. Therefore, the discharge lead 127 may continue to be deformed even after the spring lead 128 touches the stopper contact 141. As a result, the elastic characteristic of the discharge lead 127 has two inflection points as shown in FIG.

In FIG. 6, the first inflection point P1 corresponds to the point where the opening and closing portion 132 of the lid 127 is in contact with the movable portion 134 of the spring lid 128. From the first inflection point P1 to the second inflection point P2, the elastic composite force of the opening and closing portion 132 of the discharge lead 127 and the movable portion 134 of the spring lead 128 is obtained.

The second inflection point P2 corresponds to the point where the movable portion 134 of the spring lead 128 abuts on the stopper contact portion 141 of the stopper 129. After the second inflection point P2, since the support method of the spring lead is switched from one support to both supports, the elastic force is further increased.

Since the two inflection points and the three stages of characteristics are obtained as described above, the larger the opening of the discharge lead 127 is, the stronger the elastic force acts and the faster the closing speed becomes. Therefore, the closing delay hardly occurs even in the high circulation amount region in which the discharge lead 127 is largely open, and a hermetic compressor having high efficiency can be provided.

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

2 is a plan view of a hermetic compressor according to an embodiment of the present invention.

3 is a side cross-sectional view at the time of closing the discharge valve device according to the embodiment of the present invention.

4 is an exploded view of a discharge valve device according to an embodiment of the present invention.

5 is a side cross-sectional view at the time of opening the discharge valve device according to the embodiment of the present invention.

6 is an elastic characteristic diagram of a discharge valve device according to an embodiment of the present invention.

7 is a sectional view of a conventional hermetic compressor.

8 is a plan view of a conventional hermetic compressor.

9 is a side cross-sectional view of a discharge valve device of a conventional hermetic compressor.

10 is an exploded view of a discharge valve device of a conventional hermetic compressor.

Claims (9)

As a hermetic compressor, cylinder; A piston reciprocating in the cylinder; And A valve plate encapsulating the open end of the cylinder and having a discharge valve device on an outer surface of the cylinder, The discharge valve device A discharge hole formed in the valve plate; A valve seat provided around the discharge hole on a surface of an outer side of the valve plate; A support portion formed on the outer surface of the valve plate at substantially the same height as the valve seat; A plate contact portion formed at a position higher than the valve seat on the outer surface of the valve plate; A first leaf spring having one end fixed to the support part and the other end covering the discharge hole; A second leaf spring installed on an outer side of the first leaf spring, one end of which is fixed to the support portion, and an intermediate portion of which is bent in the valve seat direction between the valve seat and the support portion; A stopper covering the second leaf spring, When the first leaf spring is closed to block the discharge hole, the other end of the second leaf spring is in contact with the plate contact portion, and a space is formed between the other end of the first leaf spring and the second leaf spring. That is a hermetic compressor. The method according to claim 1, The first leaf spring is a discharge lead, The discharge lead is a hermetic compressor having a discharge lead support portion fixed to the receiving portion and the opening and closing portion for opening and closing the valve seat. The method according to claim 2, The second leaf spring is a spring lead, The spring lead is a hermetic compressor having a spring lead support and a movable part fixed to the support. The method according to claim 3, The movable portion is bent to the valve seat at a spring lead bent portion, The front end of the movable part is in the hermetic compressor contacting the plate contact when the discharge lead is closed. The method according to claim 2, The stopper is a hermetic compressor having a stopper support portion fixed to the support portion and a restriction portion for restricting the movement of the discharge lead. The method according to claim 3, The stopper is a hermetic compressor having a stopper support portion fixed to the support portion and a restriction portion for restricting the movement of the discharge lead. The method according to claim 2, The discharge lead has a discharge lead bent portion between the discharge lead support portion and the opening and closing portion, wherein the discharge lead is bent from the discharge lead bent portion to the valve seat side. The method according to claim 7, On the outer surface of the valve plate, and between the valve seat and the support portion, a lower surface is formed with a lower surface than the valve seat and the support portion, and the position of the discharge lead bent portion is Hermetic compressor, characterized in that it is located on the outer side with respect to the part. The method according to claim 6, And the stopper has a stopper contact portion bent toward the spring lead side in the restricting portion.

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