JP2001050157A - Fixed displacement one side swash plate type compressor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress a neck part of a piston to deform by bending force of inertia force, and improve durability by forming each spherical seat surface in a single spherical shape, in a device wherein a pair of spherical seat surfaces are recessed on front and rear sides of a single head piston housed in a cylinder bore freely to perform reciprocating motion. SOLUTION: A piston 6 is provided with a pair of spherical seat surfaces 6a, 6b which are recessed face to face in front and rear directions on a driving shaft side of a neck part 6c. In this case, the spherical seat surfaces 6a, 6b are formed in a single sphere B shape around a point O. The point O is disposed in a center surface P of a swash plate 7. The piston 6 is also provided with a head 6e having a hollow part 6d for performing compressing action in a cylinder bore. A shoe is provided with a spherical surface 8a slidably housed in the spherical seat surfaces 6a, 6b, and an end surface 8c slide with the swash plate 7 facing to the spherical surface 8a. The neck part 6c of the piston 6 is shortened in an axial direction, and deformation of the neck part 6c caused by bending force of inertia force is suppressed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fixed displacement single-sided swash plate type compressor.

[0002]

2. Description of the Related Art A refrigerating circuit used in an air conditioning system for a vehicle incorporates a compressor for compressing a refrigerant gas. The compressor includes a fixed displacement type compressor and a variable displacement type compressor. More specifically, the fixed displacement compressor includes a one-side swash plate type and a double-head swash plate type. In addition, a variable displacement compressor includes a one-sided swash plate type and a double-headed swash plate type.

[0003] Among these compressors, a fixed capacity one-sided swash plate type has a cylinder bore, a crank chamber, a suction chamber and a discharge chamber defined inside a housing, and a single-headed piston reciprocates in each cylinder bore. Housed as possible. The drive shaft rotatably supported by the housing is driven by an external drive source such as an engine, and a swash plate is supported on the drive shaft so as to be synchronously rotatable at a fixed inclination angle. The swash plate is provided with a shoe for driving the piston. Here, the piston has a pair of spherical bearing surfaces recessed in the front and rear, and the shoe has a spherical surface slidably housed in the spherical bearing surface, and an end surface sliding on the swash plate facing the spherical surface. It is composed of

In such a fixed-capacity single-sided swash plate compressor,
When the drive shaft is driven by the external drive source, the swash plate rotates synchronously at a fixed inclination angle, so that the piston reciprocates in the cylinder bore via the shoe. Thereby, since the cylinder bore forms a compression chamber between the piston and the head of the piston, when the compression chamber is in the suction stroke, low-pressure refrigerant gas is supplied to the compression chamber from the suction chamber connected to the evaporator of the refrigeration circuit. When the compression chamber is in the compression stroke, high-pressure refrigerant gas is discharged from the compression chamber to the discharge chamber. The discharge chamber is connected to the condenser of the refrigeration circuit, and the refrigeration circuit is used for air conditioning of the vehicle as a vehicle air conditioning system. During this time, in the fixed-capacity single-sided swash plate type compressor, slidability between the spherical surface of the piston and the spherical surface of the shoe is ensured by the mist-like lubricating oil contained in the refrigerant gas. .

[0005]

However, in the conventional fixed-capacity single-sided swash plate compressor, each of the ball bearing surfaces forming a pair of pistons has a hemispherical shape and is independent, and has a single spherical shape. Absent. For this reason, in this compressor, there is a concern that the neck portion forming the ball seating surface of the piston is easily deformed and the reciprocation of the piston is hindered.

That is, if the compressor is of a double-headed swash plate type, whether it is a fixed-capacity type or a variable-capacity type, the piston of the compressor is a double-headed piston having heads on both sides. It is. The piston reciprocates in a cylinder bore where both heads face each other.
Here, the inertial force W acting in the front-rear direction of each piston is represented by M representing the mass of the piston, S representing the stroke of the piston, ω (rad) representing the angular velocity of the drive shaft per time t (second), and ω (rad) representing the rotational speed of the drive shaft. Assuming N (rpm), W = MS · 2 · si
n ² ωt = MS · 2 · sin ² (2π · N / 60). The inertial force W acts on the neck of the piston as a force in the bending direction. However, in such a piston, since the heads formed on both sides of the neck are supported by the cylinder bores, bending deformation of the neck does not occur. For this reason, even if each ball seat surface does not form a single spherical shape, such a piston does not hinder reciprocation and has no concern about durability.

On the other hand, if the compressor is a one-sided swash plate type, whether it is a fixed displacement type or a variable displacement type, the piston of the compressor has a single head having a head only on one side. It is a piston. One head of such a piston reciprocates in a cylinder bore. Here, also in such a compressor, the inertial force W acts on each piston as a force in the bending direction on the neck of the piston. However,
In a single-headed piston, one side of the neck is a free end, and the inertia force W tends to cause bending deformation of the neck of the piston. Therefore, in such a compressor, there is a concern that the inertia force W is large and the neck portion of the piston is easily deformed due to an increase in the rotation speed N, resulting in poor durability.
In addition, the spacing between the ball bearing surfaces increases with the bending deformation of the neck,
There is a concern that the clearance between the ball seat surface and the shoe is increased and noise is likely to be generated.

In particular, if the one-sided swash plate type compressor is of a fixed displacement type, the inclination angle of the swash plate can be changed in a variable displacement type compressor, while the inclination angle of the swash plate is always constant. Since the stroke S of the piston is constant, the inertial force W acting on each piston is always large. Therefore, a large inertial force W always acts on the neck of each piston,
The neck of the piston is easy to bend.

Here, if the pair of spherical bearing surfaces of the piston do not have a single spherical shape, the neck of the piston becomes longer in the axial direction, and the inertial force W makes the neck of the piston more bendable. Would.

When the neck of the piston becomes longer, the mass M of the piston becomes larger. If the mass M of the piston is large, the inertial force W is also large, so that the neck of the piston is also more likely to bend. In addition, an increase in the mass of the piston leads to an increase in the weight of the compressor.

The present invention has been made in view of the above circumstances, and an object of the present invention is to prevent the piston neck from being deformed by the force in the bending direction due to the inertial force W acting on the piston neck, and to provide excellent durability. An object of the present invention is to provide a fixed-capacity single-sided swash plate type compressor that can be used.

[0012]

SUMMARY OF THE INVENTION A fixed displacement single-sided swash plate type compressor according to the present invention has a housing defining therein a cylinder bore, a crank chamber, a suction chamber, and a discharge chamber, and is reciprocally housed in the cylinder bore. Single-headed piston,
A drive shaft driven by an external drive source and rotatably supported by the housing; and a piston supported via a pair of front and rear shoes rotatably supported at a fixed angle with respect to the drive shaft. The piston has a pair of spherical bearing surfaces recessed in the front and rear, each shoe is slidably housed in each spherical bearing surface, and the spherical surface A fixed-capacity single-sided swash plate type compressor having a swash plate and an end surface that slides facing the swash plate, wherein the piston has a single spherical shape in a pair of the ball bearing surfaces. .

Also in the compressor of the present invention, since it is a one-sided swash plate type, the inertial force W acts on the neck of the piston as a force in the bending direction. In particular, since the compressor of the present invention is of a fixed displacement type, the neck of the piston is easily bent by its inertia force W. However, in the compressor of the present invention, the pair of spherical bearing surfaces of the piston has a single spherical shape. For this reason, the neck of the piston is shortened in the axial direction, and the neck of the piston is less likely to bend due to its inertial force. In addition, a piston having a single spherical bearing surface as a pair has a single spherical shape, the overall axial length is shortened due to the shortened axial length of the neck, and the overall mass is also reduced. As a result, the inertia force is reduced, so that the neck of the piston is more difficult to bend.

Therefore, the fixed displacement single-sided swash plate type compressor of the present invention can exhibit excellent durability.

[0015] In the compressor of the present invention, it is preferable that the piston has a meat robbing portion excluding the head except for the head. In this case, the mass of the piston is reduced, and the inertial force is also reduced, so that the neck of the piston is more difficult to bend. Also, if the mass of the piston is reduced, the weight of the compressor can be reduced, and the fuel efficiency of the vehicle can be improved. For example, a hollow part formed inside the piston can be adopted as the meat steal part. Such a hollow portion may be either a completely hermetic type or a portion that communicates with the outside through a through hole or the like.

[0016]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a fixed displacement type single-sided swash plate type compressor according to an embodiment of the present invention.

In this compressor, as shown in FIG. 1, a front housing 2 is connected to a front end of a cylinder block 1, and a crank chamber 2a is formed in the cylinder block 1 and the front housing 2. Cylinder block 1
The rear housing 3 is connected to a rear end of the rear housing 3 via a suction valve 13, a valve plate 4, a discharge valve 14, and a retainer (not shown). A suction chamber 3a is formed in a central area of the rear housing 3, and an annular discharge chamber 3b is formed in an outer peripheral area.

The suction chamber 3a is connected by a pipe to an evaporator EV of an external refrigeration circuit, and the evaporator EV is connected to the expansion valve V by a pipe.
Is connected to the condenser CO. Further, the condenser CO is connected to the discharge chamber 3b by a pipe.

A drive shaft 5 is rotatably supported on the front housing 2 and the cylinder block 1 via bearing devices 2b, 1b. The drive shaft 5 is mounted on the cylinder block 1.
5 cylinder bores 1a are formed in parallel with the axis of, and a single-headed piston 6 is accommodated in each cylinder bore 1a so as to be able to reciprocate. A swash plate 7 is fixed to the drive shaft 5 so as to be rotatable in the crank chamber 2a via a bearing device 2c between the drive shaft 5 and the front housing 2, and a piston 6 is moored to the swash plate 7 via a pair of shoes 8. ing.

As shown in FIG. 2, the piston 6 has a pair of spherical bearing surfaces 6a and 6b which are recessed to face the drive shaft 5 side of the neck 6c in the front-rear direction. Such ball bearing surface 6
a and 6b have the shape of a single sphere B centered on the point O as a characteristic configuration of the present invention. The point O is located in the center plane P of the swash plate 7. A hollow portion 6d is formed inside the piston 6 as a robbery portion. Note that the piston 6 has a head 6e for performing a compressing action in the cylinder bore 1a, and the hollow portion 6d is formed in a portion excluding the head 6e.

The shoe 8 is provided with a ball seating surface 6 of the piston 6.
a and 6b are slidably housed, and an end face 8c facing the spherical surface 8a and sliding on the swash plate 7 is provided.

As shown in FIG. 1, the valve plate 4 is formed with a suction hole 4a and a discharge hole 4b for communicating the cylinder bore 1a with the suction chamber 3a and the discharge chamber 3b, respectively. The suction hole 4a is opened and closed by a suction valve 13 corresponding to the reciprocating movement of the piston 6, and the discharge hole 4b is similarly opened and closed by a discharge valve 14 corresponding to the reciprocating movement of the piston 6.

The compressor constructed as described above is incorporated into an air conditioning system of a vehicle together with the evaporator EV, the expansion valve V and the condenser CO of the external refrigeration circuit. In such a compressor, when the drive shaft 5 is driven by an engine (not shown), the swash plate 7 rotates synchronously at a fixed inclination angle.
The piston 6 reciprocates in the cylinder bore 1a via the shoe 8. As a result, the cylinder bore 1a is
When the compression chamber is in the suction stroke, low-pressure refrigerant gas is sucked into the compression chamber from the suction chamber 3a connected to the evaporator EV of the refrigeration circuit. When the compression chamber is in the compression stroke, high-pressure refrigerant gas is discharged from the compression chamber to the discharge chamber 3b. During this time, in this compressor, slidability between the spherical bearing surface 6a of the piston 6 and the spherical surface 8a of the shoe 8 is ensured by the mist-like lubricating oil contained in the refrigerant gas.

Also in this compressor, since it is a one-sided swash plate type, the inertial force W acts on the neck 6c of the piston 6 as a force in the bending direction. In particular, since this compressor is of a fixed displacement type, the neck 6c of the piston 6 is easily bent by its inertial force W. However, in this compressor, the piston 6 has a single spherical shape on each of the pair of spherical bearing surfaces 6a and 6b, so that the neck 6c of the piston 6 is formed.
Is shortened in the axial direction, and the neck portion 6c of the piston 6 is harder to bend even by the inertial force W.

In this compressor, since the piston 6 has a completely closed hollow portion 6d as a meat robbing portion,
Since the mass of the piston 6 is small and the inertial force W is also small, the neck 6c of the piston 6 is more difficult to bend.

Therefore, the compressor can exhibit excellent durability. Further, since the mass of the piston 6 is small, the weight of the compressor can be reduced, and the fuel efficiency of the vehicle can be improved. Furthermore, in a variable displacement compressor having a swash plate capable of changing the inclination angle, a spherical bearing surface formed by a pair of pistons in order to maintain a constant clearance between the piston and the shoe even when the inclination angle of the swash plate is changed. Is required to form a single spherical shape, so that a variable displacement compressor, a piston and a shoe can be used as common components.

[Brief description of the drawings]

FIG. 1 is an overall vertical sectional view of a compressor according to an embodiment.

FIG. 2 is an enlarged sectional view of a main part of the compressor according to the embodiment.

[Explanation of symbols]

1a: Cylinder bore 2a: Crank chamber 3a: Suction chamber 3b: Discharge chamber 1, 2, 3, ... Housing (1: cylinder block, 2 ...
Front housing, 3 Rear housing) 6 Piston 6a, 6b Ball seat surface 6c Neck 5 Drive shaft 8 Shoe 8a Spherical plate 7 Swash plate 8c End surface 6d Head robbing portion, hollow portion 6e Head

Claims (3)

[Claims] 1. A housing which internally defines a cylinder bore, a crank chamber, a suction chamber, and a discharge chamber, a single-headed piston reciprocally housed in the cylinder bore, and the housing driven by an external drive source. A drive shaft rotatably supported on the drive shaft, and a swash plate that is supported rotatably synchronously at a fixed inclination angle with respect to the drive shaft, and that drives the piston via a pair of front and rear shoes, The piston has a pair of spherical bearing surfaces recessed in front and back, and each of the shoes is
In a fixed-capacity single-sided swash plate type compressor having a spherical surface slidably housed on each of the ball seating surfaces and an end surface facing the spherical surface and sliding on the swash plate, the piston forms a pair. A fixed-capacity single-sided swash plate compressor characterized in that the ball seating surface has a single spherical shape. 2. The fixed-capacity single-sided swash plate type compressor according to claim 1, wherein the piston has a meat robbing portion excluding the head except for the head. 3. The fixed displacement single-sided swash plate type compressor according to claim 2, wherein the robbery portion is a hollow portion formed inside the piston.