JPH0791376A - Valve device of compressor - Google Patents

Abstract

PURPOSE:To provide a compressor that is little loss and pulsation and high in performance and reliability by opening both inlet and discharge valves speedily. CONSTITUTION:In a compressor, where coolant gas is made to flow in or out by what each port is opened or closed by a reed valve 15a after a compression space Pb, an inlet space 12a and a discharge space 12b are interconnected with one another through an inlet port 13a and a discharge port 13b, a sealing surface of the reed valve 15a closing the port, 13b is inclined to a valve seat surface at a peripheral edge of the port 13b in the assembled state. Therefore, at the time of closing the port 13b, the reed valve 15a is elastically deformed, caning into contact with the valve seat surface, and at the time of opening the port 13b, this reed valve 15a is quickly separated from this seat surface by means of restoring force through the elastic deformation.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a compressor used for air conditioning of a vehicle, and more particularly to a valve structure of a suction valve and a discharge valve interposed between a compression chamber and a suction chamber and a discharge chamber. It is a thing.

[0002]

2. Description of the Related Art Conventionally, Japanese Patent Publication No.
As shown in Japanese Patent No. 2832, the refrigerant gas introduced from the external refrigeration circuit to the suction chamber is sucked from the suction chamber to the compression chamber via the suction port and the suction valve. Then, the refrigerant gas is compressed along with the volume change of the compression chamber, and then discharged from the compression chamber to the discharge chamber via the discharge port and the discharge valve,
It is led to an external refrigeration circuit. Normally, the suction valve and the discharge valve are elastically deformed by the pressure difference between the front and rear of the valve, that is, the pressure difference between the compression chamber and the suction chamber and the discharge chamber, and contact the valve seat surface at the peripheral portion of the suction port and the discharge port. , The ports are opened and closed by separating them. Normally, each valve is in a state where each port is closed in a state where it is not elastically deformed.

[0003]

The refrigerant gas contains mist-like lubricating oil, and when the port is closed by the valve, the valve seat surface at the peripheral portion of the port and the valve adhere to the lubricating oil. Tighten by force and seal the port. However, the adhesive force of this lubricating oil is unexpectedly large, and there is a problem that the valve becomes difficult to separate from the valve seat surface when the valve is opened. If the intake valve is hard to open, the suction pressure loss of the refrigerant gas occurs, and if the discharge valve is hard to open, the refrigerant gas over-compresses. In either case, extra drive torque is required for the compressor, resulting in power loss. Also,
When the valve is not opened easily, the differential pressure before and after the valve is increased when the valve is actually opened, so that the suction and discharge of the refrigerant gas are performed vigorously, so that the suction pulsation and the discharge pulsation are large. Become. At that time, the valve itself also vibrates greatly,
The vibration also contributes to the occurrence of pulsation.

A further problem caused by suction pressure loss and overcompression is that if the suction refrigerant pressure decreases the amount of refrigerant gas sucked into the compression chamber, the efficiency and performance of the compressor deteriorate. In addition, when the temperature of the refrigerant gas discharged due to overcompression rises, the seal rings of the rubber material used in various parts of the compressor deteriorate and the fatigue strength of the material of the compressor body decreases, so the durability of the compressor is reduced. Will be adversely affected.

The present invention has been made by paying attention to the problems existing in the above-mentioned prior art, and an object thereof is to provide a compressor having small performance loss and pulsation and high performance and reliability. is there.

[0006]

In order to achieve the above-mentioned object, the present invention is configured as follows.
That is, the compression chamber is connected to the suction chamber and the discharge chamber through the suction port and the discharge port, respectively, and at least one of the suction port and the discharge port is opened and closed by an elastically deformable reed valve, so that the refrigerant gas In a compressor that performs inflow and outflow, the reed valve sealing surface that closes the port is included in a surface that intersects the valve seat surface at the peripheral edge of the port in the assembled state before operation.

In the present invention, since the sealing surface of the reed valve that closes the port is plastically deformed in advance, a gap is created between the reed valve and the valve seat surface around the port in the assembled state before operation. It may be formed so as to occur. Further, in the present invention, it is effective that the valve seat surface at the peripheral edge of the port with which the reed valve abuts is an inclined surface that gives a torsional deformation to the reed valve in the abutting state, and particularly the inclined surface extends in the width direction of the reed valve. It is effective that the surface is parallel to the surface inclined with the center line as the axis.

[0008]

According to the valve structure having the above-described structure, during the suction stroke, the volume of the compression chamber is expanded in a sealed state, and the pressure in the compression chamber becomes lower than the pressure in the suction chamber. The pressure difference of the refrigerant gas from the side of the compression chamber, which is interposed between the two chambers, causes torsional deformation and closes the suction port, and the differential pressure between both chambers and the elastic restoring force due to the torsional deformation of the valve itself act on the suction valve. The intake valve is opened so as to be partially peeled off from the valve seat surface at the peripheral portion of the intake port. Also,
The discharge valve interposed between the compression chamber and the discharge chamber is twisted and deformed by the pressing force of the refrigerant gas from the discharge chamber side, and is brought into close contact with the valve seat surface at the peripheral portion of the discharge port to close the port. There is.

On the other hand, during the discharge stroke, the volume of the compression chamber is hermetically contracted and the pressure of the refrigerant gas in the compression chamber rises. Therefore, the pressure of the refrigerant gas in the compression chamber is applied to the discharge valve that has closed the discharge port. Also, the elastic restoring force due to the torsional deformation of the valve itself acts, and the discharge valve is opened so as to be partially peeled off from the valve seat surface at the peripheral portion of the discharge port, similarly to the above-mentioned suction valve. Further, the suction valve is twisted and deformed by the pressure of the refrigerant gas in the compression chamber and is brought into close contact with the valve seat surface at the peripheral portion of the suction port to close the port.

By repeating the intake stroke and the compression stroke as described above, the intake valve and the discharge valve are always smoothly opened at proper valve opening timings.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment in which the present invention is embodied in a double-headed piston swash plate type compressor will be described below with reference to FIGS. As shown in FIG. 1, a pair of front and rear cylinder blocks 1 and 2 that are fastened to each other are supported by a rotary shaft 4 to which a swash plate 3 is fixed. There are formed a plurality of cylinder bores 1a and 2a. A double-headed piston 5 is reciprocally housed in a pair of front and rear cylinder bores 1a and 2a, and a shoe 6 is interposed between the double-headed piston 5 and the swash plate 3. Therefore, when the swash plate 3 rotates, the double-headed piston 5 moves back and forth in the cylinder bores 1a and 2a.

A front housing 7 is joined to the end surface of the cylinder block 1 via a valve plate 8, a pair of valve forming plates 9 and 10 and a retainer forming plate 11, and the end surface of the cylinder block 2 is also connected to the rear housing 12. Are joined via a valve plate 13, a pair of valve forming plates 14 and 15 and a retainer forming plate 16.

A suction chamber 7 is provided in each of the housings 7 and 12.
a, 12a and discharge chambers 7b, 12b are formed.
The suction chambers 7a, 12a communicate with the cylinder bores 1a, 2a via the suction ports 8a, 13a on the valve plates 8, 13 and the discharge chambers 7b, 12b connect the discharge ports 8b, 13b on the valve plates 8, 13 with each other. It communicates with the cylinder bores 1a, 2a via the. Suction port 8a, 13
a is opened and closed by elastic deformation of the suction valves 9a and 14a formed in the reed valve shape on the valve forming plates 9 and 14, and the discharge ports 8b and 13b are connected to the valve forming plate 10 and
15 is a reed valve shaped discharge valve 10
It is opened and closed by elastic deformation of a and 15a.

When the head end surface 5a side of the double-headed piston 5 is the front side and the head end surface 5b side is the rear side in FIG. 1, the refrigerant gas in the suction chamber 7a pushes the suction valve 9a away during the suction stroke on the front side. It is sucked into the compression chamber Pa of the cylinder bore 1a, and during the discharge stroke, the compression chamber Pa
The refrigerant gas therein pushes out the discharge valve 10a and is discharged to the discharge chamber 7b. Similar suction and discharge are performed on the rear side, and the discharge valves 10a and 15a that are displaced along with the discharge of the refrigerant gas from the compression chambers Pa and Pb of the cylinder bores 1a and 2a to the discharge chambers 7b and 12b are retainer forming plates. 1
The retainers 11a and 16a on the terminals 1 and 16 come into contact with each other, and the opening degree is regulated.

2 and 3 show the discharge valve portion on the rear side in an enlarged manner, and show the shape of the discharge valve 15a in the assembled state before the compressor is in operation. The discharge valve 15a shown in FIG. 4 is integrally formed with the valve forming plate 15, and includes a seal portion 15b that closes the valve seat surface of the discharge port 13b so as to close the valve seat surface, and a valve forming plate 15 main body. Root part 1 connecting with the seal part 15b
It consists of 5c. By pressing the root portion 15c of the valve, as shown in FIGS. 2 and 3, the valve is formed into a twisted shape that is rotated about the center line Y in the width direction of the valve. There is. For example, as shown in FIG. 4, the above-described press working is performed so that a broken line S orthogonal to the center line Y is mountain-folded, and an oblique broken line T closer to the seal portion 15c than the broken line S is bent in a valley fold. It is good. By making the broken line S a mountain fold, the seal portion 15b above the broken line S is separated from the port peripheral portion, and by making the broken line T a valley fold, the seal portion 15c is twisted with respect to the valve seat surface of the port peripheral portion. And as a result valve 1
5a can be formed into a desired shape. For this reason,
The discharge valve 15a does not come into close contact with the valve seat surface of the peripheral portion of the discharge port 13b in a state where it is not elastically deformed, and the discharge port 15a
Do not close. The discharge valve 10a in the discharge valve portion on the front side also includes a seal portion 10b that closes the discharge port 8b, and a root portion 10c that connects the valve forming plate 10 main body and the seal portion 10b, like the discharge valve 15a. It is formed in a twisted shape as if it were rotated about the center line of the valve.

Next, the operation of the compressor having the discharge valve portion constructed as described above will be explained. When the rear side of the compressor is in the intake stroke, the pressure of the refrigerant gas in the compression chamber Pb of the cylinder bore 2a decreases, so the discharge valve 15a is sucked toward the compression chamber Pb side, and as shown in FIG. 1, the discharge port 13b. Discharge port 13b in close contact with the peripheral valve seat surface
To close. At this time, the discharge valve 15a elastically deforms from the twisted shape in the natural state and comes into close contact with the valve seat surface of the peripheral portion of the discharge port 13b. Since the discharge valve 15a is deformed so as to rotate about the center line Y of the valve, this elastic deformation is easily performed. Therefore, if the twisted shape of the discharge valve 15a in the natural state is properly formed, the seal portion 1
It is possible to close the discharge port 13b with good sealing property by closely bonding 5b to the valve seat surface at the peripheral portion of the discharge port 13b.

When the rear side is in the discharge stroke, the pressure of the refrigerant gas in the compression chamber Pb increases, so that the discharge valve 15a is pressed by the refrigerant gas in the cylinder bore 2a. At this time, the seal portion 15b is brought into close contact with the valve seat surface at the peripheral portion of the discharge port 13b by the mist-like lubricating oil contained in the refrigerant gas, but this close contact force is unexpectedly large. However, since the pressing force of the refrigerant gas and the restoring force due to the elastic deformation of the valve itself oppose the adhesion force due to the lubricating oil, the seal portion 15b is quickly removed from the discharge port 13b so as to be partially peeled off. Separate.

Even on the front side of the compressor, the discharge valve 10a is connected to the discharge valve 15 in the intake stroke and the discharge stroke.
The same operation as a is performed. In this example,
During the discharge stroke, the compression valves Pa,
Since the differential pressure between Pb and the discharge chambers 7b and 12b and the elastic restoring force due to the torsional deformation of the valve itself act, the discharge valve 10
The valves a and 15a are opened so as to be partially peeled off from the valve seat surface at the peripheral portion of the discharge port. Then, since the refrigerant gas is quickly discharged at an appropriate discharge timing, overcompression of the refrigerant gas is prevented and the power of the compressor is reduced. In addition, by preventing overcompression, the rise in temperature of the discharged refrigerant gas is suppressed, and along with that, the deterioration of the seal ring of the rubber material used in various parts of the compressor and the reduction of the fatigue strength of the constituent material of the compressor body. Is suppressed and the durability of the compressor is increased.

If the discharge valves 10a and 15a are difficult to open, the pressure difference between the front and rear of the valve increases when the valves are opened, and the discharge of the refrigerant gas is performed vigorously, so that discharge pulsation occurs. Further, at this time, the valve itself vibrates greatly due to the dynamic pressure of the refrigerant gas, so that pulsation due to the vibration also occurs. In this embodiment, since the discharge valves 10a and 15a are properly opened, the above-described discharge pulsation is reduced, and the vibration and noise of the compressor body are reduced.

In this embodiment, the suction valves 9a and 14a may be formed in the same twist shape as the discharge valves 10a and 15a. In this case, the suction valves 9a and 14a in the suction stroke are used.
The opening of the valve is also performed promptly like the opening of the discharge valves 10a and 15a in the discharge stroke. In this case, suction pressure loss in the suction stroke is prevented, so the power of the compressor is reduced. Also, since the refrigerant gas is sufficiently inhaled,
The refrigerant gas of the compressor is efficiently compressed, and the performance of the compressor is improved. Furthermore, since the differential pressure before and after the intake valve is opened does not increase too much, the intake pulsation is reduced,
Vibration and noise of the compressor body are reduced.

Next, a second embodiment embodying the present invention will be described with reference to FIGS. In this embodiment, the protrusion 17 is provided on the valve plate 13 at the peripheral edge of the discharge port 13b at the position where the root portion 15c of the discharge valve 15a abuts. On the other hand, the discharge valve 15a
Are formed in the same plane as the valve forming plate 15. Then, the protrusion 1 on the valve plate 13 during assembly
7 comes into contact with the root portion 15c, so that the discharge valve 1
5a is formed in a twisted shape. Discharge valve 1 on the front side
0a is also given a twisted shape by abutting on the protrusion provided on the valve plate 8.

Also in this embodiment, since the discharge valves 10a and 15a in the assembled state have a twisted shape, the same operation and effect as those of the above-described first embodiment can be obtained. Also in this embodiment, the intake valves 9a, 14a are formed in a twisted shape by providing a protrusion at a position where the root portions of the intake valves 9a, 14a abut on the peripheral portions of the intake ports 8a, 13a. It is possible to smoothly open the valves 9a and 14a.

In this embodiment, the valve plates 8 and 13 are
It is also possible to form the twisted shape of the discharge valves 10a and 15a by sandwiching the inclusion 9 between the valve plates 8 and 13 and the root portions 10c and 15c at the time of assembly without providing the protruding portion 17 on the upper side. . Next, a third embodiment of the present invention will be described with reference to FIGS. In this embodiment, the discharge valve 15a is pressed so that it can be bent in a mountain fold at the broken line S in FIG. Therefore, in the assembled state of the discharge valve 15a, all of the seal portion 15b is separated from the valve seat surface of the port peripheral portion as shown in FIGS. The front discharge valve 10a is also formed in the same shape.

The operation of the discharge valve 15a having such a configuration will be described. When the rear side of the compressor is in the intake stroke, the pressure in the compression chamber Pb decreases, so that the discharge valve 15a.
a is elastically deformed from a natural state in which it is separated from the peripheral portion of the port, and is closely attached to the valve seat surface of the peripheral portion of the discharge port 13b.
During the discharge stroke on the rear side of the compressor, a restoring force due to elastic deformation acts on the discharge valve 15a in addition to the pressing force of the refrigerant gas in the compression chamber Pb, so that the discharge valve 15a is partially sealed at the seal portion 15b. The valve is opened so that it can be peeled off. The discharge valve 10a also on the front side
Are performing similar operations.

In this embodiment, the discharge valves 10a and 15a are provided with compression chambers Pa and Pb and a discharge chamber 7 in the discharge stroke.
The discharge valve 10a, 15a is opened smoothly because the restoring force due to the differential pressure between b and 12b and the elastic deformation of the valve itself acts. As a result, the valve structure of this embodiment also has the same effects as those of the first and second embodiments. Also in this embodiment, the intake valves 9a and 14a are replaced by the discharge valves 10a and 15a.
In this case, the intake valves 9a and 14a can be opened quickly in the intake stroke as well as the discharge valves 10a and 15a in the discharge stroke. Also in this case, similarly to the above-described embodiment, the suction pressure loss in the suction stroke is prevented, the power and suction pulsation of the compressor are reduced, and the refrigerant gas is sufficiently sucked, so that the performance of the compressor is improved. And other effects.

Next, a fourth embodiment embodying the present invention will be described with reference to FIG. In this embodiment, the valve seat surface at the peripheral portion of the discharge port 13b is formed by the slope 19 as shown in FIG. On the other hand, the discharge valve 15a is formed in the same plane as the valve forming plate 15.
Therefore, when closing the discharge port 13b, the discharge valve 15a is twisted so as to rotate about the center line of the valve and comes into close contact with the slope 19. Further, since the valve seat surface at the peripheral portion of the discharge port 8b is also formed as a slope similar to the slope 19, the discharge valve 10a is twisted and deforms to come into close contact with the slope and close the discharge port 8b.

In the compressor having the discharge valve portion constructed as described above, in the discharge stroke, the elastic restoring force of the torsional deformation of the discharge valves 10a, 15a causes the discharge valves 10a, 15a to move in the same manner as in the above embodiment. The opening is done smoothly.
Also in this embodiment, the valve seat surfaces of the peripheral portions of the suction ports 8a and 13a are formed as slopes, and when the suction valves 9a and 14a close the suction ports 8a and 13a, they are twisted and deformed. , 13a may be closely attached to the valve seat surface at the peripheral edge. Also in this case, the opening of the intake valves 9a and 14a is smoothly performed by the elastic restoring force of the torsional deformation of the intake valves 9a and 14a.

In each of the above embodiments, the present invention has been described by embodying the swash plate type compressor having a double-headed piston.
INDUSTRIAL APPLICABILITY The present invention can be applied to any compressor as long as it has a reed valve-shaped discharge valve or suction valve in a single-headed piston swash plate type, wobble type, vane type, scroll type compressor or the like. is there. Further, the present invention can be applied to both fixed capacity and variable capacity compressors.

The present invention is not limited to the configuration of the above embodiment, and the valve seat surface of the port peripheral portion and the seal portion of the valve may not be parallel in the assembled state, that is, the valve Any structure may be used as long as it elastically deforms to close the port and the valve is opened by the restoring force of the elastic deformation. For example, a configuration is possible in which the valve is formed in a twisted shape and the valve seat surface at the peripheral portion of the port is formed as an inclined surface.

[0030]

As described above in detail, according to the present invention,
The simple effect of only changing the shapes of the intake valve and the discharge valve section has the excellent effect of reducing the power and pulsation of the compressor. In addition, since the intake chamber is sufficiently inhaled during the intake stroke, the efficiency and performance of the compressor are improved, and the temperature rise of the discharged refrigerant gas due to overcompression during the discharge stroke is suppressed, so the reliability of the compressor is improved. Is improved. Furthermore, since vibration and noise of the compressor are reduced as the pulsation is reduced, there is no need to provide a muffler or the like in the refrigerant gas passage, which has an advantage of cost reduction.

[Brief description of drawings]

FIG. 1 is a side sectional view of an entire compressor of an embodiment embodying the present invention.

FIG. 2 is an enlarged cross-sectional view of a discharge valve portion showing the valve structure of the first embodiment.

3 is a cross-sectional view taken along the line AA of FIG.

FIG. 4 is a diagram for explaining the shape of the discharge valve of the first embodiment.

FIG. 5 is an enlarged sectional view of a discharge valve portion showing a valve structure of a second embodiment.

6 is a sectional view taken along line BB of FIG.

FIG. 7 is an enlarged sectional view of a discharge valve portion showing a valve structure of a third embodiment.

8 is a sectional view taken along line CC of FIG.

FIG. 9 is a sectional view showing a valve structure according to a fourth embodiment.

[Explanation of symbols]

8a, 13a ... suction port, 8b, 13b ... discharge port, 9a, 14a ... suction valve, 10a, 15a ... discharge valve,
19 ... Slope

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Satoshi Konomura 2-chome, Toyota-cho, Kariya city, Aichi prefecture Toyota Industries Corporation

Claims (4)

[Claims] 1. A compression chamber is connected to a suction chamber and a discharge chamber through a suction port and a discharge port, respectively, and at least one of the suction port and the discharge port is opened and closed by an elastically deformable reed valve, In a compressor in which a refrigerant gas flows in and out, a reed valve sealing surface that closes a port is included in a surface that intersects a valve seat surface at a peripheral edge of the port in an assembled state. Valve device. 2. A compression chamber and a suction chamber and a discharge chamber communicate with each other through a suction port and a discharge port, and at least one of the suction port and the discharge port is opened and closed by an elastically deformable reed valve, In a compressor in which refrigerant gas flows in and out, the sealing surface of the reed valve that closes the port is plastically deformed in advance, so that the reed valve and the valve seat surface around the port periphery are in the assembled state. A valve device for a compressor, characterized in that a gap is created. 3. A compression chamber is connected to a suction chamber and a discharge chamber through a suction port and a discharge port, respectively, and at least one of the suction port and the discharge port is opened and closed by an elastically deformable reed valve, In a compressor in which a refrigerant gas flows in and out, a valve seat surface of a port peripheral edge with which a reed valve abuts is a slope that gives a torsional deformation to the reed valve in an abutting state, and a valve device for a compressor. . 4. The valve device for a compressor according to claim 3, wherein the valve seat surface at the peripheral edge of the port is a surface parallel to a surface inclined about the center line in the width direction of the reed valve as an axis.