DE112009001435T5 - Variable Displacement Compressor - Google Patents

Abstract

A variable displacement compressor having a housing in which an output chamber, a suction chamber, a crank chamber and cylinder bores are defined therein, pistons are provided in the cylinder bores, a drive shaft is rotatably supported in the housing and a conversion mechanism includes a swash plate whose inclination angle can be changed for converting a rotation of the drive shaft into a reciprocating motion of the pistons, which adjusts the stroke of the pistons by varying a pressure difference between the crank chamber and the suction chamber, compresses a fluid sucked into the cylinder bore from the suction chamber, and a compressed fluid in the discharge chamber, characterized in that there are provided a plurality of urging means each having an end brought into contact with the swash plate and urging the swash plate in a direction of increasing an inclination angle of the swash plate, and the Meh The number of pressing means is such that a number of pressures is increased, while the angle of inclination of the ...

Description

Technical field of the invention

The present invention relates to a variable displacement swash plate type compressor, and more particularly, to a variable displacement compressor in which the structure of a portion of a pressing means for pressing a swash plate in a direction of increasing inclination angle is improved and which is suitable for use in an air conditioning system for vehicles.

Background of the invention

In a swash plate type variable displacement compressor, a structure is known for returning the inclination angle of a swash plate from a state of minimum inclination angle to a direction of increasing inclination angle and increasing the displacement for the output of the compressor in which a pushing means (a spring for enlarging the tilting angle or a return spring) for pressing the swash plate in the direction of the increasing inclination angle near the position of the minimum inclination angle is provided (for example, Patent Document 1).

Documents of the prior art

Patent documents

• Patent Document 1: JP 2000-2180A

Summary of the invention

Problems to be solved by the invention

As described above, although the spring for increasing the inclination angle is aimed to easily return the displacement from the minimum inclination angle, e.g. For example, by the appearance of a clutchless compressor, since the pressing force for increasing the tilt angle affects the power consumption in a state where the operation of the compressor is stopped (in a state near the minimum tilt angle), the adjustment of the pressing force becomes important.

However, in the spring for increasing the inclination angle (in particular, a spring for increasing the inclination angle such as a return spring 27 described in Patent Document 1), its pressing force changes proportionally (evenly) according to an amount of its displacement, the urging force of the spring increases the inclination angle relative to the swash plate changes according to the inclination angle of the swash plate, but only in this structure in which the pressing force changes proportionally, it is difficult to finely adjust the pressing force according to the inclination of the swash plate.

Accordingly, it is an object of the present invention, by paying attention to the above-described problems in the conventional technology, to provide a variable displacement compressor having the freedom of adjusting the urging force due to the urging means for increasing a tilting angle of a swash plate simple structure can increase and the fine pressing force can adjust according to the inclination angle of the swash plate.

Means of solving the problems

To achieve the above-described object, a variable displacement compressor according to the present invention comprises a housing in which an output chamber, a suction chamber, a crank chamber and cylinder bores are defined therein, pistons are provided in the cylinder bores, a drive shaft is rotatably supported in the housing and a conversion mechanism includes a swash plate whose inclination angle can be changed to convert a rotation of the drive shaft into reciprocation of the pistons, which adjusts strokes of the pistons by varying a pressure difference between the crank chamber and the suction chamber, compresses a fluid discharged from the Suction chamber is sucked into the cylinder bores, and outputs a compressed fluid into the discharge chamber, and characterized in that a plurality of pressing means is provided, each having an end which is brought into contact with the swash plate and the swash plate in a direction of increasing an inclination angle of the swash plate presses, and the plurality of pressing means is constructed so that a number of pressures is increased, while the inclination angle of the swash plate is reduced.

In such a variable-displacement compressor, the number of pressures of the urging means is increased while the inclination angle of the swash plate is reduced, thereby increasing the urging force relative to the swash plate, and the freedom of adjusting the urging force according to the inclination angle of the swash plate is increased , By this, the adjustment of the pressing force due to the pressing means for pressing the swash plate in the direction of increasing the inclination angle can be optimized. Although the plurality of pressing means press the swash plate parallel to each other, since each pressing means of a simple structure, even the entirety of the plurality of pressing means may be formed as a simple structure. Further, since the plurality of urging means pushes the swash plate parallel to each other, the length of the pressing means in the axial direction of the compressor can be small, and by providing the plurality of pressing means, the axial length of the compressor itself is not increased.

For example, in the above-described variable displacement compressor according to the present invention, a structure may be used in which each of the plurality of urging means is constructed so as to proportionally increase a pressing force as the inclination angle of the swash plate is reduced, and by enlarging In the number of pressures as described above, a gradient of the increase of the pushing force due to the plurality of pressing means is increased. With such a structure, since the pressing force is proportionally increased, the adjustment of the pressing force is facilitated. At the same time, since the gradient of the increase of the pressing force can be made large, fine adjustment of the pushing force becomes possible.

Further, a structure may be used in which a connecting means for connecting the plurality of pressing means is integrally provided. With such a structure, since the plurality of pressing means are integrally connected by the connecting means, these pressing means can be treated as an integrated single part, and therefore the assembly is facilitated and the productivity improved.

Further, a structure may be used in which a positioning structure for positioning the above-described connecting means in an axial direction of the drive shaft is formed on the connecting means and the drive shaft, and at least two of the plurality of pressing means are set to be different from each other are different in height in an axial direction from the connecting means. With such a structure, the position in the axial direction of the connecting means is decided by the above-described positioning structure, and because the heights in the axial direction of the at least two of the plurality of pressing means are set different from each other with reference to the positioned connecting means a base position, the number of depressions of the pressing means can be changed more accurately and surely according to the inclination angle of the swash plate.

Further, a structure may be used in which the above-described plurality of pressing means are formed, for example, as flat springs, the flat springs are made of a material for forming a flat spring by pressing, and the connecting means is a remaining part the material for forming the flat spring is formed unlike the flat springs. With such a structure, since the flat springs and the connecting means can be formed as a single part, it becomes possible to substantially simultaneously form the flat springs and the connecting means by pressing, and the manufacture can be simplified and that can be reduced to contribute to the costs.

Further, a structure may be used in which the above-described connecting means and the plurality of urging means are formed so as to surround the drive shaft, the plurality of urging means are arranged at a predetermined interval, and corresponding tip portions thereof are the swash plate in the direction press the enlarged slope and corresponding base portions thereof are integrally connected to the connecting means. With such a structure, since the connecting means is formed so as to surround the drive shaft, and the plurality of pressing means can be provided around the drive shaft at predetermined intervals, even if there are a plurality of pressing means, they can be made compact , Therefore, it becomes possible to make the entirety of the section of the pressing means small in size and to simplify the structure.

Further, a structure may be used in which at least two of the above-described plurality of pressing means are set so that spring constants thereof are different from each other. In particular, when this structure is applied to a case where the plurality of pressing means are formed as flat springs, the freedom of adjusting the spring characteristics of the flat springs can be increased, and the optimization of the setting of the pressing force can be facilitated.

Further, a structure may be used in which a minimum inclination angle regulating means for regulating a minimum mechanical inclination angle of the swash plate is provided, and the minimum inclination angle regulating means is integrally connected with the above-described connecting means. With such a structure, it becomes possible to manage the pressing force of the pushing means by taking the minimum inclination angle as a standard, and to reduce the dispersion of the pressing forces between the urging means. Further, the minimum inclination angle regulating agent also acts as a regulating agent In order to regulate excessive bending of the urging means, it becomes possible that excessive tension does not act on the urging means, and this can contribute to ensuring the reliability of the urging means.

The variable displacement compressor according to the present invention is particularly suitable for a case where the fluid to be compressed is a refrigerant, and is particularly suitable as a compressor used in an air conditioning system for a vehicle.

Effect according to the invention

In the variable displacement compressor according to the present invention, since a plurality of urging means for urging the swash plate in the direction of the increased inclination angle and the number of pressures is increased while decreasing the inclination angle of the swash plate, the freedom of adjusting the urging force the pressing means for increasing the inclination angle of the swash plate can be increased while using a simple and compact structure, and a fine adjustment of the pressing force can be performed according to the inclination angle of the swash plate. Consequently, the setting of the urging force due to the pressing means for urging the swash plate in the direction of the increasing inclination angle can be optimized, and the swash plate can perform a desired operation near the minimum inclination angle.

Brief explanation of the drawings

1 FIG. 4 is a vertical sectional view of a variable displacement compressor according to an embodiment of the present invention (FIG. 1 (A) ) and a sectional view of a displacement control valve for controlling a displacement thereof ( 1 (B) ).

2 is a vertical sectional view of the in 1 shown displacement control valve.

3 shows flat springs in the in 1 shown variable displacement compressor, 3 (A) is an outline of the flat feathers and 3 (B) is a side view of 3 (A) ,

4 is an enlarged partial sectional view of the in 1 a variable displacement compressor, which shows a state in which a swash plate comes into contact with a stopper.

5 is a diagram showing a relationship between a displacement of a spring and a spring force of the in 3 shown flat spring shows.

6 FIG. 15 is a graph showing a relationship between a resultant force of a coil spring and a flat spring and a tilting angle of a swash plate in a case where the in. FIG 3 shown flat spring is used.

7 Fig. 15 is a diagram showing a relationship between a resultant force of a coil spring and flat springs and a tilting angle of a swash plate in a case where the flat spring portion uses two flat springs.

8th FIG. 12 is a diagram showing a relationship between a resultant force of a coil spring and flat springs and a tilting angle of a swash plate in a case where the flat spring portion uses four flat springs.

Embodiments for carrying out the invention

Hereinafter, desirable embodiments of the present invention will be explained with reference to the figures.

1 shows a variable displacement compressor according to an embodiment of the present invention ( 1 (A) ) and a displacement control valve for controlling a displacement of the compressor ( 1 (B) ). In 1 has a compressor 100 variable displacement of the swash plate type as the variable displacement compressor, a cylinder block 101 with a plurality of cylinder bores 101 , a front housing 102 on one end of the cylinder block 101 is provided, and a rear housing 104 on the other end of the cylinder block 101 via a valve plate 103 is provided on.

A drive shaft 106 is provided so that it is the inside of a crank chamber 105 that crosses the cylinder block 101 and the front housing 102 is defined. A swash plate 107 is with a rotor 108 connected to the drive shaft 106 about a connecting part 109 is fixed, and is rotatable together with the drive shaft 106 stored and in a state in which their inclination angle relative to the drive shaft 106 can change. A coil spring 110 that the swash plate 107 to press a direction to reduce the inclination angle is between the rotor 108 and the swash plate 107 intended. On one side of the swash plate 107 opposite the side of the coil spring 110 is a flat spring 111 intended for pressing the swash plate 107 that is in a state of the minimum inclination angle, in a direction of increasing the inclination angle. As described later is, is the flat spring 111 as a part constructed with flat spring sections 111a1 . 111a2 . 111a3 acting as a plurality of pressing means for pushing the swash plate 107 are provided in the direction of increasing the inclination angle in the present invention.

One end of the drive shaft 106 extends to the outside of the housing through a projection portion 102 of the front housing 102 , and it is connected to a drive source such as a vehicle engine (not shown) through a belt and the like via a power transmission (not shown). A shaft sealing device 112 is between the drive shaft 106 and the protrusion portion 102 intended. The drive shaft 106 is going through warehouse 113 . 114 . 115 . 116 supported in the radial direction and in the printing direction.

piston 117 are in cylinder bores 101 provided, and a pair of shoes 118 that in a recessed section 117a in an end portion of each piston 117 are included, carry the outer peripheral part of the swash plate 107 in a relative sliding state. The rotation of the drive shaft 106 gets into a reciprocating motion of the pistons 117 over the swash plate 107 and the shoes 118 changed.

A suction chamber 119 and an output chamber 120 are in the rear housing 104 educated. The suction chamber 119 communicates with the cylinder bore 101 over a suction hole 103a that in the valve plate 103 is formed, and a suction valve (not shown), and the discharge chamber 120 communicates with the cylinder bore 101 via an output valve (not shown) and an ejection hole 103b that in the valve plate 103 is formed. The suction chamber 119 is with an evaporator of an air conditioning system for a vehicle (not shown) via a suction port 104a connected.

The front housing 102 , the cylinder block 101 , the valve plate 103 and the rear housing 104 cooperate to form a housing that houses a compression mechanism that is driven by the drive shaft 106 , the rotor 108 , the connecting part 109 , the swash plate 107 , the shoes 118 , the pistons 117 , the cylinder bores 101 , the intake valves, the output valves, etc. is formed.

A damper 121 is outside the cylinder block 101 intended. The damper 121 is achieved by connecting a cup-like cylindrical cover part 122 acting as a separate part of the cylinder block 101 is provided with a cylindrical wall 101b placed on the outer surface of the cylinder block 101 is formed by a sealing member. A delivery opening 122a is in the lid part 122 educated. The dispensing opening 122a is connected to a condenser of an air conditioning system for a vehicle (not shown).

A communication path 123 that's the damper 121 with the output chamber 120 communicates is over the cylinder block 101 , the valve plate 103 and the rear housing 104 educated. The damper 121 and the communication path 123 form an output path that extends between the output chamber 120 and the dispensing opening 122a extends, and the damper 121 forms an enlarged space, which is provided on the way of the output path. Then there is a check valve 200 for opening / closing the inlet of the damper 121 in the damper 121 intended.

The front housing described above 102 , the cylinder block 101 , the valve plate 103 , and the rear housing 104 are adjacent to each other via a seal (not shown) and integrally assembled using through bolts.

A displacement control valve 300 is on the rear housing 104 appropriate. The displacement control valve 300 represents an opening path of the communication path 124 between the output chamber 120 and the crank chamber 105 and controls an amount of the discharged refrigerant gas, which is in the crank chamber 105 is introduced. The refrigerant gas in the crank chamber 105 flows into the suction chamber 119 through a gap between the camps 115 . 116 and the drive shaft 106 , a room 125 in the cylinder block 101 is formed, and an opening 103c in the valve plate 103 is formed.

The internal pressure of the crank chamber 105 is controlled by the displacement control valve 300 changed, which variably the displacement to output the compressor 100 variable displacement is controlled by the swash plate type. The displacement control valve 300 adjusts the amount of electricity sent to the built-in solenoid based on an external signal, variably controls the displacement for the compressor 100 variable displacement of the swash plate type so that the internal pressure of the suction chamber 119 placed in a pressure chamber of the displacement valve 300 through the communication path 146 is introduced, becomes a predetermined value, forcibly opens the communication path 124 by switching the electric current to the built-in solenoid to OFF, thereby controlling the displacement for the output of the compressor 100 Variable displacement of the swash plate type, so that it is a minimum. The displacement control valve 300 Can the suction pressure on one control optimal value according to an external environment.

As in 2 is shown, the displacement control valve 300 a first pressure detection chamber 302 in a valve body 301 is formed and with the crank chamber 105 communicates through a communication hole 301 , a valve hole 301c one end of which is the first pressure chamber 302 opens and the other end to a valve chamber 303 opens with the output chamber 120 through a communication hole 301b communicates a cylindrical valve body 304 whose one end section is in the valve chamber 303 is provided and the valve hole 301c opens / closes, and the other end portion slidably on a support hole 301d is stored, a bellows arrangement 305 that in the first pressure chamber 302 is provided, which is a crank chamber pressure through the communication hole 301 receives and works as a pressure detecting means, the inner side is evacuated and in which a spring is provided, a connecting part 306 , with one end of the bellows assembly 305 is connected in a state such that it can be brought into contact / disconnected therewith, and the other end at one end of the valve body 304 is attached, and a second pressure detection chamber 307 in which the other end of the valve body 304 is provided, and with the suction chamber 119 through a communication hole 301e communicates, on.

The carrying hole 301d sliding the other end portion of the valve body 304 carries is in the valve body 301 formed and by a state in which the valve body 304 sliding through the support hole 301d Carries over a fine gap, the other end of the valve body 304 from the valve chamber 303 interrupted.

The displacement control valve 300 further has a solenoid rod 304a that is integral with the valve body 304 is formed and attached to the a movable iron core 308 is adjusted and at the end away from the valve body 304 is attached, a solid iron core 309 into the solenoid bar 304a is introduced, and the opposite the movable iron core 308 is provided with a predetermined gap, a spring 310 between the solid iron core 309 and the movable iron core 308 is provided and the the movable iron core 308 in a direction to open the valve presses, a cylindrical part 312 which is made of a non-magnetic material attached to a solenoid housing 311 is fixed in a state in which the solid iron core 309 and the movable iron core 308 are introduced, and an electromagnetic coil 313 which is the cylindrical part 312 surrounds and in the solenoid housing 311 is included on.

Ps:

Druck der Ansaugkammer

Sb:

effektive Balgenfläche (= Druckaufnahmefläche (Sv) des Druckes der Kurbelkammer, der den Ventilkörper betätigt = Druckaufnahmefläche (Sr) des Druckes der Ansaugkammer, der den Ventilkörper betätigt)

f:

drückende Kraft der Feder 310F

F:

drückende Kraft des Galgens

F(i):

elektromagnetische Kraft.

In the operation of this displacement control valve 300 as an effective gallows surface Sb of the gallows arrangement 305 , a pressure receiving area Sv of the pressure of the crank chamber 105 of the valve body 304 operated and from the side of the valve hole 301c is received, and a pressure receiving area Sr of the suction pressure of the valve body 304 at the second pressure detection chamber 307 operated, set to approximately the same values, therefore, the force that is the valve body 304 operated, determined by the following equation (1). Ps = [- (1 / Sb) × F (i) + (F + f) / Sb] (1) in which

ps:

Pressure of the suction chamber

sb:

effective bellows area (= pressure receiving area (Sv) of the pressure of the crank chamber actuating the valve body = pressure receiving area (Sr) of the pressure of the suction chamber actuating the valve body)

f:

pressing force of the spring 310F

F:

oppressive power of the gallows

F (i):

electromagnetic force.

Further expands in the displacement control valve 300 when the pressure of the suction chamber Ps is lower than the value determined by the above-described equation (1), the bellows 305a , the valve body 304 goes away from the valve seat to open the valve hole 301c , the first pressure chamber 302 and the valve chamber 303 communicate with each other through the valve hole 301c , and the communication path 124 between the output chamber 102 and the crank chamber 105 it is open. The coolant in the dispensing chamber 120 becomes the crank chamber 105 through the communication path 124 delivered, the pressure of the crank chamber increases, the inclination angle of the swash plate 107 decreases, and the displacement of the compressor 100 variable displacement to the output decreases, and the pressure of the suction chamber disappears. When the pressure of the suction chamber is higher than the value determined by the above-described equation (1), the bellows of the gallows assembly contracts 305 , the valve body 304 comes in contact with the valve seat to close the valve hole 301c , the communication between the first pressure chamber 302 and the valve chamber 303 through the valve hole 301c is interrupted, and the communication path 124 between the output chamber 120 and the crank chamber 105 will be closed. The refrigerant gas in the crank chamber 105 flows out into the suction chamber 119 through the gaps between the camps 115 . 116 and the drive shaft 106 , the room a25, which is in the cylinder block 101 is formed, and the opening hole 103c that in the valve plate 103 is formed, and the pressure of the crank chamber is reduced, the inclination angle of the swash plate 107 is increased and the displacement to the output of the compressor 100 is increased, and the pressure of the suction chamber is reduced. The pressure sensing mechanism passing through the bellows assembly 305 , the connecting part 306 and the valve body 304 is formed, automatically controls the pressure of the suction chamber to the value determined by the equation (1). The electromagnetic actuator that passes through the solenoid rod 304a , the movable iron core 308 , the solid iron core 309 , the feather 310 , the solenoid housing 311 , the cylindrical part 312 and the electromagnetic coil 313 is formed changes the operating point of the pressure detecting mechanism according to the value "I" of the electric current flowing in the electromagnetic coil 313 flows. In the displacement control valve 300 can, if the electric current "I", to the electromagnetic coil 313 is delivered, a control property can be achieved, so that the pressure of the suction decreases. In the displacement control valve 300 The aforementioned pressure-sensing mechanism and the electromagnetic actuator drive the valve body 304 , Due to the structure in which the displacement control valve 300 having the pressure detecting mechanism, the control accuracy of the suction chamber pressure is improved, and by the structure in which the electromagnetic actuator is provided for changing the operating point of the pressure detecting mechanism, it becomes possible to clearly control the suction chamber pressure to be controlled relative to the electric control current "i "To decide.

Further, when the supply of the electricity to the solenoid is turned OFF, the valve body opens 304 the valve hole 301c by the oppressive force of the spring 310 , the coolant in the dispensing chamber 120 becomes the crank chamber 105 through the communication path 124 supplied, the pressure of the crank chamber is increased, and the inclination angle of the swash plate 107 is reduced, and the displacement to the output of the compressor 100 variable displacement becomes a minimum.

With reference to 3 to 6 becomes the flat spring 111 explained.

In this embodiment, the flat spring 111 constructed as in 3 and 4 it is shown that the flat spring sections 111a1 . 111a2 . 111a3 which are provided at three positions in the circumferential direction, the stoppers 111b which are provided at three positions and a connecting portion 111c , which is annular for connecting the three flat spring sections 111a1 . 111a2 . 111a3 and the three stoppers 111b is formed, are integrally connected. This flat spring 111 is namely constructed as a part that the flat spring sections 111a1 . 111a2 . 111a3 at three positions acting as a plurality of pushing means for pushing the swash plate 107 are provided in a direction of increasing the inclination angle in the present invention, and the stoppers 111b at three positions acting as a minimum inclination angle regulating means for regulating the mechanical minimum inclination angle of the swash plate 107 are provided in the present invention, integrally with each other by a connecting portion 111c , which is provided as a connecting means in the present invention, connects. This flat spring is formed of a flat spring-forming material (a flat spring-forming plate) by pressing, and the stoppers 111b and the connecting section 111c are on the remaining part unequal to the corresponding flat spring sections 111a1 . 111a2 . 111a3 educated. Where, the three flat spring sections 111a1 . 111a2 . 111a3 are provided at approximately the same intervals around the drive shaft.

At the flat spring 111 is how in 4 is shown, the inner diameter section 111d (in 3 (A) ) of the connecting section 111c on the drive shaft 106 fitted, the flat spring 111 is positioned in the axial direction by being in contact with a stepped portion resting on the drive shaft 105 is formed and brought by a snap ring 150 is fixed. By a state in which the swash plate 107 in contact with the tips of the stoppers 111b comes is the mechanically regulated minimum angle of inclination (Θmin) of the swash plate 107 Are defined. For example, as in 6 is shown when the angle of the swash plate 107 is denoted as 0 ° in a state in which the plane of the swash plate 107 perpendicular to the axis of the drive shaft 106 is, the minimum inclination angle (Θmin) is set to about 0 ° (an angle near 0 °), and the height of the three stoppers 111b is set by aiming for this minimum inclination angle (Θmin).

Although a pressing force to push the swash plate 107 in the direction of increasing the inclination angle by a condition in which the tips of the respective flat spring portions 111a1 . 111a2 . 111a3 in contact with the swash plate 107 come, are still the inclination angle of the swash plate 107 at the tips of the corresponding flat spring sections 111a1 . 111a2 . 111a3 in contact with the swash plate 107 come set so that they differ from each other depending on the corresponding flat spring sections. As in 3 (B) This can be achieved safely by Adjusting the heights in the axial direction of the tips of the corresponding flat spring sections 111a1 . 111a2 . 111a3 from the connecting section 111c at heights different from each other (h1>h2> h3).

There continue the tips of the stoppers 111b also with the heights of the connecting section 111c are regulated, the dispersion of the pressing forces of the flat spring 111 reduced from the minimum inclination angle. Because the stoppers 111c also as a regulating means for regulating excessive bends of the flat spring sections 111a1 . 111a2 . 111a3 work, excessive tension will not affect the flat spring sections 111a1 . 111a2 . 111a3 exercised.

The oppressive force of the flat spring 111 will be like In 5 is shown. For example, if the flat spring 111 by a sliding body having a sliding surface with an outer diameter of the flat spring 111 or more (the displacement when the sliding body is in contact with the flat spring portion 111a1 is referred to as 0), although up to a state where the displacement of the flat spring section 111 = x1, only the flat spring section works 111a1 as a spring, and the pushing force increases proportionally, if it exceeds x1, also comes the flat spring section 111a2 in contact, and the pressing force of the flat spring section 111a2 is added, and therefore the inclination (gradient) of the increase of the pressing force becomes larger. If further the displacement x2 exceeds, also comes the flat spring section 111a3 in contact, and the pressing force of the flat spring section 111a3 is added, and therefore the gradient of the increase of the pressing force becomes even larger. Namely, by increasing the number of depressions due to the flat spring portions, there is a characteristic that the spring constant becomes larger at an upshift condition. Therefore, by setting x1, x2 at appropriate positions, the load property can be adjusted, and the pressing force can be optimized.

When the inclination angle of the swash plate 107 becomes smaller than the predetermined angle Θ ₁ , the swash plate became 107 through the coil spring 110 and the flat spring 111 clamped, and the resulting force of the two springs is as in 6 is shown. In 6 only the flat spring works 111a1 as a spring in a zone between Θ ₁ and Θ ₂ , the flat springs 111a1 and 111a2 work as springs in a zone between Θ ₂ and Θ ₃ , and all flat feathers 111a1 . 111a2 and 111a3 work as feathers in a zone between Θ ₃ and Θmin. Here, Θ _{4 is} an angle at which the resultant force of both springs becomes 0, in a zone below Θ ₄ is a pushing force for pushing the swash plate 107 acting in the direction of increasing the inclination angle, and in a zone greater than Θ ₄ is a pushing force for pressing the swash plate 107 working in the direction of reducing the inclination angle.

Thus, the pointed sides of the flat spring sections come 111a1 . 111a2 . 111a3 whose heights from the connecting section 111c are different from each other, in contact with the swash plate 107 in order, and by using a structure in which the number of pushes in the order increases, a finely set desired property of the spring 111 as the oppressive force to push the swashplate 107 be given in the direction of increasing the inclination angle.

In the above-described embodiment, although the heights of the respective flat spring portions are set to be different from each other, a structure in which the heights of the respective flat spring portions are set equal to one step may be provided on one side of the swash plate, with which the corresponding flat spring portions are brought into contact, and the number of depressions of the respective flat spring portions is increased in order, as the inclination angle of the swash plate decreases. In such a structure, the formation of the flat spring portions is facilitated.

Further, in the embodiment described above, although a case where the number of the plurality of pushing means 3 is as shown, any number of pushing means is available as long as it is 2 or more. For example, with respect to a property of a resulting spring force shows 7 an example of two oppressive means, and 8th shows an example of four pressing means, and thus the number of pressures can be decided with a view to optimizing the setting of the pressing force.

Further, in the embodiment described above, although the lengths of the arms of the plurality of flat spring portions 111a1 . 111a2 . 111a3 are set equal and the heights thereof are changed, a structure can be used in which the lengths of the arms of the respective flat spring portions are set different from each other and the corresponding spring constants are set different from each other. By thus setting, the freedom of adjusting the spring characteristic of the flat spring 111 can be further increased, and the optimization of the setting of the pressing force can be facilitated.

Further, the plurality of pressing means is not limited to flat springs. For example, a structure may be used in which compression coil springs are provided around the drive shaft with one ends thereof brought into contact with the swash plate and the other ends connected by a connecting portion. Alternatively, a structure may be used in which a drive shaft is inserted into a plurality of compression coil springs provided concentrically with the one ends of the coil springs brought into contact with the swash plate and the other ends connected by a connecting portion.

Further, in the embodiment described above, although the plurality of flat spring portions 111a1 . 111a2 . 111a3 is formed to the circumferential direction of the drive shaft, as in 3 (A) is shown, the forming of the flat spring sections not limited thereto. For example, a structure may be used in which the tip portions of the respective flat spring portions are formed so as to be directed to an axis of the drive shaft or formed to a direction separate from the drive shaft.

Further, a structure may also be used in which a rotation preventing mechanism is provided so that the flat spring 111 not relative to the drive shaft 106 is rotated, z. B. wherein a groove is defined on the drive shaft and a part of the flat spring 111 engaged with the groove.

Further, in a case of a structure in which a supporting part of a swash plate such as a sleeve, a joint ball, etc., between the swash plate 107 and the drive shaft 106 is provided, the supporting part of the swash plate by the flat spring sections 111a1 . 111a2 . 111a3 be pressed.

Further, the present invention can also be applied to a variable displacement compressor to which an electromagnetic clutch is attached, or to a clutchless compressor, and the present invention can be applied to a variable displacement compressor driven by a motor, for example a variable displacement compressor with built-in motor.

Further, in the embodiment described above, although a case has been explained in which the fluid to be compressed is a refrigerant, another fluid to be compressed may be used. Further, the kind of the refrigerant as the fluid to be compressed is not particularly limited, the present invention can be applied in common to variable displacement compressors for which carbon dioxide or another new refrigerant can be used, unlike a case where R134a is used as the refrigerant ,

Industrial applications of the invention

The variable displacement compressor according to the present invention can be applied to any compressor having a swash plate whose inclination angle can be changed, and in particular, it is suitable as a variable displacement compressor used in an air conditioning system for a vehicle.

LIST OF REFERENCE NUMBERS

100

Variable Displacement Compressor

101

cylinder block

101

bore

102

front housing

103

valve plate

104

rear housing

105

crank chamber

106

drive shaft

107

swash plate

108

rotor

109

connecting part

110

coil spring

111

flat spring with a plurality of pressing means

111a1, 111a2, 111a3

a flat spring portion as pressing means for pressing a swash plate in a direction of increasing the inclination angle

111b

A stopper as a minimum inclination angle regulating means for regulating a mechanical minimum inclination angle of a swash plate

111c

connecting portion as a connecting means between a regulating means of a minimum inclination angle and a pressing means

111d

Section of the inner diameter of the connecting section

117

piston

118

shoe

119

suction

120

dispensing chamber

121

damper

122

cover part

123

communication path

150

snap ring

200

check valve

300

Displacement control valve

301

valve housing

302

first pressure chamber

303

valve chamber

304

valve body

304a

solenoid rod

305

bellows assembly

307

second pressure chamber

308

movable iron core

309

solid iron core

311

solenoid

313

electromagnetic coil

SUMMARY

A variable displacement compressor having a swash plate whose inclination angle can be changed to convert the rotation of a drive shaft into the reciprocating motion of pistons has a plurality of urging means each having an end brought into contact with the swash plate and presses the swash plate in the direction of increasing an inclination angle of the swash plate, wherein the plurality of pressing means is constructed so that the number of pressures is increased as the inclination angle of the swash plate becomes smaller. The freedom of adjusting the pressing force due to the pressing means for increasing the inclination angle of the swash plate can be increased by a simple structure, and the pressing force can be finely adjusted according to the inclination angle of the swash plate. Consequently, the adjustment of the urging force due to the urging means for urging the swash plate in the direction of inclination angle increase can be optimized, and the swash plate can be made to perform in a desirable operation near the minimum inclination angle.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• JP 2000-2180A [0002]

Claims (11)

A variable displacement compressor having a housing in which an output chamber, a suction chamber, a crank chamber and cylinder bores are defined therein, pistons are provided in the cylinder bores, a drive shaft is rotatably supported in the housing and a conversion mechanism includes a swash plate whose inclination angle can be changed for converting a rotation of the drive shaft into a reciprocating motion of the pistons, which adjusts the stroke of the pistons by varying a pressure difference between the crank chamber and the suction chamber, compresses a fluid sucked into the cylinder bore from the suction chamber, and a compressed fluid in the discharge chamber, characterized in that there is provided a plurality of urging means each having an end brought into contact with the swash plate and urging the swash plate in a direction of increasing an inclination angle of the swash plate, and the me The number of pressing means is designed so that a number of pressures is increased while the inclination angle of the swash plate is reduced. The variable displacement compressor according to claim 1, wherein each of the plurality of urging means is constructed so as to proportionally increase a pressing force while decreasing the inclination angle of the swash plate, and increasing the number of depressions, a gradient of the increasing force due to the pressing force Majority of oppressive means is increased. A variable displacement compressor according to claim 1, wherein connecting means is provided for integrally connecting said plurality of urging means. The variable-displacement compressor according to claim 3, wherein a positioning structure for positioning the connecting means in an axial direction of the drive shaft is formed on the connecting means and the drive shaft, and at least two of the plurality of pressing means are set to be different from each other of the height in an axial direction from the connecting means. A variable displacement compressor according to claim 3, wherein said plurality of urging means are formed as flat springs, said flat springs being made of a flat springing material by pressing, and said connecting means being formed on a remaining part of said flat springing material other than said flat springs , A variable displacement compressor according to claim 5, wherein at least two of said urging means are set so that the spring constants thereof are different from each other. A variable displacement compressor according to claim 3, wherein said connecting means and said plurality of urging means are formed so as to surround said drive shaft, said plurality of urging means are arranged at predetermined intervals, and said respective tip portions thereof rotate said swash plate in the direction of Press enlargement of the inclination, and corresponding base portions thereof are integrally connected to the connecting means. A variable displacement compressor according to claim 7, wherein at least two of said urging means are set so that the spring constants thereof are different from each other. A variable displacement compressor according to claim 3, wherein a minimum inclination angle regulating means for regulating a minimum mechanical inclination angle of the swash plate is provided, and the minimum inclination angle regulating means is integrally connected to the connecting means. A variable displacement compressor according to claim 1, wherein the fluid to be compressed is a refrigerant. A variable displacement compressor according to claim 1, wherein said compressor is used in an air conditioning system for a vehicle.

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