WO2002040866A1 - Swash plate type compressor - Google Patents

Abstract

A swash plate type compressor, comprising a cylinder block (1) having a plurality of cylinder bores (6) formed therein, a shaft supported rotatably on the cylinder block (1) at the center part thereof, a swash plate (10) rotated according to the rotation of the shaft, and a plurality of pistons (7) connected to the swash plate (10) through shoes (50) rotating on the sliding surface (10a) of the swash plate (10) relative to each other and sliding inside the cylinder bores (6) according to the rotation of the swash plate (10), the shoe (50) further comprising a shoe disk (50a), a ball (50b), and a rod (50c) for connecting the shoe disk (50a) to the ball (50b) integrally with each other, wherein the shoe disk (50a) is brought into contact with the sliding surface (10a) of the swash plate (10), the ball (50b) is supported on a bottom part (7a) of the piston (7) so as to be rolled relative to each other, and a distance between an application point of a side load (F) and an application point of a resistance force (R2) acting on a top part (7b) of the piston (7) is shortened to remarkably reduce the resistance force (R2) acting on the top part (7b) of the piston (7).

Description

 Description Swash plate compressor Technical field

Inventions of this is related to the swash plate type compressor, concerning as a vehicle for the refrigerant compressor Ru physicians use with the C 0 ₂ and the refrigerant in JP Suitable swash plate type compressor. Scenery

 FIG. 5 is a longitudinal sectional view of a conventional swash plate type compressor. The swash plate type compressor has a cylindrical port 110 formed with a plurality of cylinder holes 106. And a shaft h105 supported rotatably at the center of the cylindrical opening 101, and a tiltable tiltable movable shaft 105. The swash plate 110 and the swash plate 110 are connected to the thrust flange 140 via a link mechanism 141 while being attached. Is connected to the swash plate 110 via a lug 150 that rotates relatively on the sliding surface 110a of the swash plate. A) A plurality of pistons 107 sliding in the inside 106 are provided.

 FIG. 6 is a partially enlarged view of FIG.

The shoe 150 supports the ball 111a at one end of the connecting rod 111 so as to be relatively rollable. Show 150 is the sliding surface of the swash plate 110 It is held by retainer 15 3.

 Radial bearings are provided on the boss section 110b of the swash plate 110.

55 is mounted, and the retainer 15 3 is rotatable relative to the swash plate 110. The radial bearing 15 is prevented from coming off by a stopper 154 fixed to the post portion 110b. Connecting port

Rod section 1 1 1b at the other end of V-d 1 1 1 is fixed to piston 107

 The shroud 150 is a dish-shaped shroud body 15 that supports the tip of the pole 11a of the connecting rod 1111 so that it can roll relatively. 1 and an annular disk 152 that supports the rear end face of the pole 1 11a of the connecting cut 11 1 1 so as to be relatively rotatable. ing .

 The swash plate compressor operates as follows.

 When the shaft 105 rotates, the rotating force is transmitted to the swash plate 110 via the storage flange 140 and the link mechanism 141. The swash plate 110 rotates. The rotation of the swash plate 110 causes the shoe 150 to rotate relative to the sliding surface 110a of the swash plate 110, and the rotational force from the swash plate 11 This is converted into a linear reciprocating motion of the tongue 107.

 As a result, the compression chamber 1 2 in the cylinder pore 10 6

2, the suction, compression, and discharge of the refrigerant gas are performed sequentially according to the change in the volume, and the refrigerant gas having a capacity corresponding to the inclination angle of the swash plate 110 is discharged. Issued In the compression process, a compression reaction force of the refrigerant gas acts on the piston 107, so that the side load (piston is tilted) according to the inclination angle of the swash plate 110. (Falling load) F (see Fig. 7 (a)) occurs.

In filtration come when, in the case of use physician Ru compressor and the C 0 ₂ refrigerant, the high-low pressure difference is rather come large in the emergency (up to 1 about 5 MP a), the compression reaction force of the refrigerant gas also conventional full Larger than a compressor that uses lon as a refrigerant.

 As a result, the large resistances R 1 and R 2 against the side load F (see Fig. 7 (a)) will act on the piston 107. However, wear of piston 107 and cylinder bore 106 occurs due to sliding friction. At this time, the amount of wear on the top side of the piston 107 is larger than that on the top side of piston 107.

 Further, when a thin film is formed on the outer peripheral surface of the piston 107 by surface treatment, it may be peeled off.

 The present invention provides a swash plate type compressor which improves the slidability of the piston by reducing the side load and which can improve the reliability. The purpose is. Disclosure of the invention

In order to solve the above-mentioned object, the present invention is directed to a cylinder block in which a plurality of cylinder pores are formed and a cylinder block in which the cylinder block is formed. A rotating shaft rotatably supported at the center and a rotation according to the rotation of the rotating shaft The swash plate is connected to the swash plate via a shaft that relatively rotates on a sliding surface of the swash plate, and the cylinder hole is rotated as the swash plate rotates. In a swash plate type compressor provided with a plurality of pistons sliding in the inside, a shudder that contacts the slide with a sliding surface of the swash plate. A sock, a spherical body rotatably supported by a bottom portion of the piston, and the shroud disk and the spherical body, which are integrally connected to each other. And the connecting part of.

 Fig. 7 (a) is an anti-chamber model diagram illustrating the anti-force added to the piston in the conventional example, and Fig. 7 (b) is the anti-piston model according to the present invention. FIG. 4 is an anti-chamber model diagram illustrating anti-mosquitoes added to a ton.

 In Fig. 7 (a) and Fig. 7 (b), F indicates side load, and R1 and R2 indicate resistance. The side load F is a force acting on spherical bodies (poles 11a, 50b), and the forces acting on each spherical body are equal. R 2 is a drag acting on the top side of the piston,

 1 is the drag acting on the piston at the opening edge of the cylinder bore.

 Let a be the distance between the action points of the anti-power R 2 and the anti-force R 1, and let b be the distance between the action points of the anti-force R 2 and the side load F. In view of this, the following force balance equation is established.

 F + R 1 + R 2 = 0 (1)

F-b + R l-a = 0 (2) '' The spherical body of the present invention (Fig. 7 (b)) is a conventional example (Fig. 7 (A) It is located closer to the rear. Therefore, in the present invention (FIG. 7 (b)), the distance between the point of action of the side load F and the point of action of the resistance R1, that is, the distance b, is reduced. In this case, since the distance a is equal to that of the conventional example, it can be seen from the equation (2) that the resistance R 1 is smaller than that of the conventional example. Further, when the resistance R1 is smaller than the conventional example, it is understood from the expression (1) that the resistance R2 is smaller than the conventional example.

 That is, the distance b between the point of action of the side load F and the point of action of the anti-force R 2 acting on the top side of the piston becomes shorter, and in particular, the distance of the piston The anti-power R 2 acting on the top side is greatly reduced.

 Therefore, the wear of the piston caused by the sliding friction between the piston and the cylinder pore and the peeling of the thin film on the outer peripheral surface thereof are reduced. The durability is slightly improved. In addition, since the friction loss when the piston slides in the cylindrical pore is reduced and the sliding characteristic of the piston is improved, the driving force of the compressor is reduced. And the performance and reliability are improved.

Preferably, the spherical body is supported by the bottom portion of the piston through a dasher. 'Since the spherical body is pressed onto the piston's bottom part via the dash, it is necessary to assemble the chassis into the piston beforehand. It is also good. For this reason, swash plate compression The machine can be easily manufactured. Brief explanation of drawings

 FIG. 1 is a longitudinal sectional view showing an entire swash plate type compressor according to a second embodiment of the present invention.

 FIG. 2 is a partially enlarged view of FIG.

 Fig. 3 (a) is a side view of the shoe, Fig. 3 (b) is a front view of the shower, and Fig. 3 (c) is a perspective view of the shower.

 FIG. 4 is a partially enlarged view of a swash plate type compressor according to a second embodiment of the present invention.

 FIG. 5 is a longitudinal sectional view of a conventional swash plate type compressor. FIG. 6 is a partially enlarged view of FIG.

 Fig. 7 (a) is an anti-chamber model diagram illustrating the anti-force added to the piston in the conventional example, and Fig. 7 (b) is the anti-piston model according to the present invention. FIG. 2 is an anti-chamber model diagram illustrating anti-mosquitoes added to the ton. The best form to carry out the invention

 An embodiment of the present invention will be described below with reference to the drawings.

 FIG. 1 is a longitudinal sectional view showing the whole of a swash plate type compressor according to a first embodiment of the present invention.

This swash plate compressor is C 0 ₂ Shi Li down da blanking lock one component and to this have found that Ru use in the swash plate type compressor of the refrigeration apparatus shall be the (carbon dioxide) the refrigerant 1 end face In this, a head 3 is arranged via a valve plate 2 and a front head 4 is arranged on the other end surface.

 The front head 4, the cylinder opening 1, the valve plate 2 and the rear head 3 pass through the port 31 and the shaft (rotation) (Shaft) 5 is integrally connected to the center axis direction

 A plurality of cylinder pores 6 are formed in the cylinder opening 1 at predetermined intervals along a circumference centered on the shaft 5. . A piston 7 is slidably inserted into each of the cylinder pores 6.

 The front head 4 has a crank chamber 8 for accommodating a swash plate 10 and a thrust flange 40, which will be described later.

 A suction chamber 13 and a discharge chamber 12 are formed in the lid head 3. The suction chamber 13 is located around the discharge chamber 12. The low pressure refrigerant gas sent to the compression chamber 22 is accommodated in the suction chamber 13.

 The discharge chamber 12 contains the high-pressure refrigerant gas discharged from the compression chamber 22. The discharge chamber 12 communicates with the discharge P3a via the communication passage 60.

A discharge port 16 for communicating the compression chamber 22 with the discharge chamber 12, and a suction port 15 for communicating the compression chamber 22 with the suction chamber 13. Valve plates 2 are provided at predetermined intervals along the circumferential direction, respectively. The discharge port 16 is opened and closed by the discharge valve 17, and the discharge valve 17 is pressed against the end face of the knob plate 2 on the rear head side 18 Both are fixed by Port 19.

 In addition, the suction port 15 is opened and closed by a suction valve 21, and the suction valve 21 is arranged on the front end face of the normal plate 2. .

 One end of the shaft 5 is rotatably supported on the front head 4 via a radial bearing 26, and the other end of the shaft 5 is radial. It is rotatably supported by the cylinder block 1 via the bearing 25 and the thrust bearing 24. .

 The swash plate 10 is attached to the shaft 5 so as to be inclined and slidable.

Further, the swash plate 10 is connected to the thrust flange 40 via a link mechanism 41, and rotates as the thrust flange 40 rotates. They rotate together.

 The thrust flange 40 fixed to the front end of the shaft 5 is connected to the front head 4 via a thrust bearing 33. It is rotatably supported on the inner wall. As described above, the thrust flange 40 and the swash plate 10 are connected via the link mechanism 41, and the swash plate 10 is at a right angle to the shaft 5. It can be tilted with respect to the virtual plane.

 The link mechanism 41 is connected to the front end face 1 of the swash plate 10.

A pair of protrusions 10 d provided at 0 c and a Between the arm 40a provided on the swash plate side end face 40c of the to flange 40 and the projecting portion 10d k: It is bridged and the arm 40 and a connecting pin 43 engaged with the elongated hole 40b of the a.

 A winding spring 47 is mounted between the thrust flange 40 and the swash plate 10, and the swash plate 10 is moved by the biasing force of the winding spring 47. The plate spring 48 is urged toward the side, and a countersink 48 is mounted between the thrust bearing 24 and the swash plate 10. 0 is biased to the front.

 FIG. 2 is a partially enlarged view of FIG.

 The table 50 is composed of a shadow disk 50a, a pole (spherical body) 50b, and a rod (connecting portion) 50c. .

 The new disk 50a contacts the sliding surface 10a of the swash plate 10 and is held by the retainer 53. A radial bearing 55 is mounted on the post portion 10b of the swash plate 10, and the retainer 53 can rotate relative to the swash plate 10. . Further, the radial bearing 55 is stopped by a stopper 54 fixed to the boss 10b.

 The pole 5 Ob is supported by the pot portion 7 a of the piston 7 so as to be able to relatively rotate. The port 50b is mounted on the bottom 7a of the piston 7.

Rod 50c is connected to the show disk 50a and the pole. 50 b and are connected.

 Figure 3 (a) is a side view of the show, and Figure 3 (b) is an excerpt.

Is a front view of the show, and FIG. 3 (c) is a perspective view of the show.

 丁 丁 内 内 内 内 内 内 内 内 内 内 内 内 51 内 51 内 内 内 51 内 内 内 内 内 51 内 51 内 51 51 51 内 51 51 51 It is installed at the center of the hole 50a and is connected to the body 50b via a cylindrical opening F50c.

 Next, when the rotating power of a mounting engine (not shown) for explaining the operation of the plate type compressor is transmitted to the shaft 5, the rotating force of the shaft 5 is changed to a thrust. The light is transmitted to the swash plate 10 through the storage flange 4 and the link mechanism 41, and the plate 10 rotates.

 The rotation of swash plate 0 causes the sh — 50 (new disk 50 a) to rotate relative to the sliding surface 10 a of swash plate 10, and the rotational force from swash plate 0 Is converted to the linear reciprocating motion of piston 7.

 When the piston 7 reciprocates in the cylinder pore 6, the volume of the compression chamber 22 in the cylinder 6 changes, and the suction and compression of the refrigerant gas are performed by this volume increase. Then, the refrigerant gas is discharged, and the refrigerant gas having a high volume corresponding to the inclination angle of the swash plate 10 is discharged.

At the time of suction, the suction valve 21 is opened, low-pressure refrigerant is sucked from the suction chamber 13 into the compression chamber 22 of the cylinder 6, and the discharge valve 17 at the time of discharge is opened. High-pressure refrigerant gas is discharged from the compression chamber 22 to the discharge 12. During compression, the compression reaction force of the refrigerant gas acts on the swash plate 10 via the pole 50b, the rod 50c and the shadow disk 50a. Since the refrigerant is CO ₂ , the compression reaction is greater than when the refrigerant is fluorinated as described above.

 However, in this embodiment, the pole 50b is force-strained relative to the bottom 7a of the piston 7 so that the pole 50b is rotatable, and the pole 50b is a conventional example. Because it is located on the rear side as compared to the top, the anti-power R1 and the piston 7 that act on the piston 7 at the opening edge of the cylinder 6 The anti-mouse R 2 acting on b is reduced.

 When the heat load decreases and the pressure in the crank chamber 8 increases, the inclination angle of the swash plate 10 decreases. The amount of discharge decreases as the amount of leak decreases. '

 On the other hand, when the heat load increases and the pressure in the crank chamber 8 decreases, the inclination angle of the swash plate 10 increases, so The stroke amount of the ton 7 is increased, and the discharge capacity is increased.

According to this embodiment, the distance b between the point of action of the side load F and the point of action of the drag R 2 is shorter than that of the conventional example (see FIG. 6), so that the pi The resistance R 2 acting on the top portion 7 b of the ton 7 is greatly reduced, and is caused by the sliding friction between the piston 7 and the cylinder 6. The wear and peeling of the thin film on the outer surface of the piston 7 are reduced, and the durability is improved. In addition, the friction loss when the piston 7 slides inside the cylinder 6 is reduced, and the sliding characteristic of the piston 7 is improved. Driving force can be reduced, and performance and reliability are improved.

 FIG. 4 is a partially enlarged view of a swash plate type compressor according to a second embodiment of the present invention. The same parts as those in the first embodiment are denoted by the same reference numerals and the description is given. Omitted.

 In this embodiment, when the port 50b of the shower 50 is attached to the port portion 97a of the piston 97, the port 50b is closed. It differs from the first embodiment in that the shaft 56 supports the piston 97 on the port portion 97a of the piston 97.

 According to this embodiment, the same effects as those of the first embodiment can be obtained, and it is not necessary to attach the shroud 50 to the piston 97 in advance. Manufacturing of swash plate compressors becomes easier

 In the second embodiment, the pedestal 56 is caulked and supported on the bottom part 97a of the piston 97, but the pedestal 56 A male screw is formed on the outer peripheral surface of the nut and a female screw is formed on the inner peripheral surface of the pot portion 977a, and the zipper 56 is screwed into the pot portion 977a. In this case, the pusher 56 may be supported by the bottom 97 a of the piston 97. Industrial applicability

As described above, the swash plate type compressor according to the present invention is C-type. 0 ₂ Ri Oh useful as the use of Medical Ru car dual-purpose refrigerant compressor as a refrigerant, if Re good to the call of the swash plate type compressor, the sliding of the bi-scan tons in Tsu by the reduction of side load It can improve the reliability and improve the reliability.

Claims

The scope of the claims

1. A cylinder block in which a plurality of cylinder pores are formed;

 A rotating shaft rotatably supported at the center of the cylinder block;

 A swash plate that rotates with the rotation of the rotation shaft and a swash plate that is connected to the swash plate via a shoe that relatively rotates on a sliding surface of the swash plate, and the swash plate rotates. In a swash plate type compressor provided with a plurality of pistons sliding in the cylinder pores,

 Eyes [j §

 A slidable disk that comes into contact with a sliding surface of the swash plate and a spherical body that is rotatably supported by a rubber member of the piston;

 A connecting portion for integrally connecting the shower disk and the spherical body;

 A swash plate compressor characterized by being composed of:

2. The swash plate type as set forth in claim 1, wherein said spherical body is supported by a pot portion of said piston via a bushing. Compressor.