KR20140025909A - Swash plate type variable capacity compressor - Google Patents

Abstract

The present invention relates to a new-type swash plate type variable capacity compressor for reducing noise and vibration due to the excess of a suction pulse by attenuating the suction pulse while a refrigerant flows from a suction port to a suction chamber. According to the present invention for an effect above, a window formed at the valve case of a suction damping device includes: an exposed part positioned to communicate with the inside of a suction chamber; and an unexposed part positioned inside a suction flow path, wherein the whole area of the exposed part is equal to or larger than the area defined by the diameter of an inlet of the suction damping device into which the refrigerant flows.

Description

[0001] The present invention relates to a swash plate type variable capacity compressor,

The present invention relates to a variable displacement swash plate type compressor, and more particularly, to a reduction in suction pulsation during a refrigerant flow from a suction port to a suction chamber, thereby reducing noise and vibration due to excessive suction pulsation The present invention relates to a variable displacement swash plate type compressor according to a new type.

In general, the compressor used in the air conditioning system of the vehicle takes the refrigerant evaporated from the evaporator and transfers it to the condenser by making it easy to liquefy at high temperature and high pressure.

Among the compressors of the automotive air conditioning system, the swash plate type compressor has a structure in which the swash plate is rotated while the drive shaft is rotated by the driving force of the engine, and the piston is reciprocated in accordance with the rotation of the swash plate to compress the refrigerant. The swash plate of the swash plate type compressor is configured to be capable of changing the inclination angle according to the compression capacity.

1 is a cross-sectional view of a conventional variable displacement swash plate type compressor.

The conventional variable displacement swash plate type compressor includes a cylinder block 10 in which a plurality of cylinder bores 11 are radially formed and a crank chamber 21 formed in front of the cylinder block 10 A front housing 20 and a rear housing 30 coupled to the rear of the cylinder block 10 to form a suction chamber 31 and a discharge chamber 33. [

At this time, a piston 42 is accommodated in the cylinder bore 11, and a valve assembly 50 is installed between the cylinder block 10 and the rear housing 30 to control the flow of the refrigerant.

The suction chamber 31 formed in the rear housing 30 is configured to communicate with the suction port 37 through the suction passage 35.

A driving portion for reciprocating the piston 42 is installed in the crank chamber 21.

The drive unit is installed through the center of the front housing 20 and the cylinder block 10, the drive shaft 41 is rotated by receiving the driving force transmitted from the engine through the pulley (2) and in the crank chamber 21 The rotor 43 is coupled to the drive shaft 41 and rotates together with the drive shaft 41, and the swash plate 44 hinged to the rotor 43 and the inclination angle is variable.

At this time, the swash plate 44 is connected to each piston 42 through the shoe 45, so that each of the pistons 42 reciprocates in the cylinder bore 11 by the rotation of the swash plate 44 The refrigerant in the cylinder bore 11 is compressed.

In the variable capacity swash plate type compressor according to the related art described above, as the speed of the refrigerant flowing into the cylinder bore 11 from the suction chamber 31 during the compression operation of the refrigerant is irregular, the respective cylinder bores 11 The refrigerant pressure distribution in the suction chamber 31 becomes uneven at the time of the suction stroke to generate irregular waves, that is, suction pulsations. Therefore, during the compression operation of the compressor, noise due to the suction pulsation is continuously There is a problem that has occurred.

In addition, the pulsation generated in the above-described compressor is provided as a heat exchanger constituting an air conditioning system of an automobile through various pipes together with discharge pulsation generated in the earth, thereby causing additional problems such as tremble of the heat exchanger .

In the related art, the suction damping device 70 is additionally provided in the suction passage 35 through which the refrigerant is transferred from the suction port 37 to the suction chamber 31. 37) to prevent backflow and reduce noise and vibration.

As shown in FIG. 2, the suction damping device 70 is installed at a portion where the suction flow path 35 and the suction chamber 31 communicate with each other, and the valve case 71, the core 72, and the elasticity are provided. And a member 73 and a valve cap 74.

A window 75 is formed in the circumference of the valve case 71 so as to communicate with the inner and outer spaces of the valve case 71. The core 72 elastically moves in the valve case 71, (75).

However, the above-described suction damping device 70 serves only to substantially reduce noise and vibration due to the flow of the refrigerant discharged back from the suction chamber 31 toward the suction port 37 when the compressor is stopped. The noise and vibration reduction effect due to the suction pulsation during operation of the compressor was not provided, and thus, despite the additional provision of the suction damping device 70, the prevention of the problem due to the suction pulsation of the refrigerant was not sufficiently performed. It was.

The present invention has been made to solve the various problems according to the prior art described above, an object of the present invention is to provide a suction damping device through the structural improvement of the structure of the suction damping device and the suction flow path is installed the suction damping device; It is to provide a variable displacement swash plate compressor according to a new form that can reduce the suction pulsation of the refrigerant passing through, and thereby to reduce the noise.

According to the variable displacement swash plate type compressor of the present invention for achieving the above object, a suction passage for communicating the suction chamber and the suction port of the rear housing with each other is installed in a state in which the suction passage is disposed, and a refrigerant flows out on the circumferential surface thereof. A variable displacement swash plate type compressor including a valve case having a window formed therein and a suction damping device having a core for opening and closing the window while elastically moving in the valve case, wherein the window of the suction damping device is inside the suction chamber. And an exposed portion positioned in communication with the non-exposed portion positioned in the suction passage, and the total area formed by the exposed portion is equal to or wider than an area formed by a diameter of an inlet through which the refrigerant of the suction damping device is introduced. Characterized in that formed.

Here, the determination of the total area formed by the exposed portion of the window is characterized in that the refrigerant inlet side portion of the suction damping device is configured to be performed by adjusting the indentation depth pushed in from the rear of the rear housing.

In addition, the length of the non-exposed portion of the window is characterized in that it is determined to be smaller than or equal to 0.25 times the indentation depth.

As described above, the variable displacement swash plate compressor of the present invention can reduce the booming noise as much as possible without degrading the compression performance by determining the relationship between the exposed portion and the inlet of the suction damping device installed in the suction passage. Has the effect.

In particular, the installation according to the determined relationship between the exposed portion and the inlet of the suction damping device can be made through the adjustment of the indentation depth of the suction damping device has the effect that the precise installation is possible.

1 is a cross-sectional view illustrating an internal structure of a conventional variable capacity swash plate type compressor
FIG. 2 is an enlarged cross-sectional view illustrating a structure in which a refrigerant is sucked into a suction chamber of a conventional variable capacity swash plate type compressor
3 is a cross-sectional view illustrating an internal structure of a variable capacity swash plate type compressor according to a preferred embodiment of the present invention.
FIG. 4 is an enlarged cross-sectional view illustrating a structure in which a suction check valve of a variable capacity swash plate type compressor according to a preferred embodiment of the present invention is installed;
5 and 6 are enlarged cross-sectional views illustrating a refrigerant suction process of the variable capacity swash plate type compressor according to the preferred embodiment of the present invention.

Hereinafter, a preferred embodiment of the variable displacement swash plate compressor of the present invention will be described with reference to FIGS. 3 and 6.

Attached Figure 3 shows the internal structure of the variable displacement swash plate compressor of the present invention, according to the variable displacement swash plate compressor of the present invention largely the cylinder block 100, the front housing 200, the rear housing 300, a suction port 370, and a suction damping device 700.

This will be described in more detail below for each configuration.

First, the cylinder block 100 forms the outer appearance of the compressor together with the front housing 200 and the rear housing 300.

The cylinder block 100 has a plurality of cylinder bores 110 formed in a radial direction with respect to a center hollow portion of the cylinder block 100. The hollow portion of the cylinder block 100 is provided with a center bore 120 in which the drive shaft 410 is installed .

In each cylinder bore 110, a piston 420 is installed to be reciprocated linearly.

Next, the front housing 200 is coupled to the front of the cylinder block 100 to form a crank chamber 210. The rear housing 300 is coupled to the rear of the cylinder block 100, (310) and discharge chamber (330) are formed.

A suction port 370 for receiving a refrigerant from the outside is formed in the rear housing 300 and the refrigerant flows between the suction port 370 and the suction chamber 310 by the suction flow path 350, .

Next, the driving unit is installed inside the crank chamber 210 to linearly reciprocate the piston 420 in the cylinder bore 110.

The driving unit includes a driving shaft 410 rotated by receiving the driving force of the engine from the pulley 2 and a rotor 430 coupled to the driving shaft 410 in the crank chamber 210 and rotating together with the driving shaft 410. [ A swash plate hub 460 rotatably coupled to the driving shaft 410 and a swash plate 440 rotated together with the swash plate hub 460 so that the inclination angle of the swash plate hub 460 is variable, ).

A hinge arm 431 protrudes from a wall surface of the outer wall surface of the rotor 430 facing the swash plate 440 and a swash plate arm 431 overlapped with the hinge arm 431 is formed on the swash plate hub 460. [ The hinge arm 431 and the swash plate arm 461 are hinged to each other.

The valve assembly 500 controls the flow of refrigerant between the cylinder bores 200 of the cylinder block 100 and the suction chamber 310 and the discharge chamber 330 of the rear housing 300.

Next, the suction damping device 700 is provided in the suction passage 350 of the rear housing 300 to block the refrigerant in the suction chamber 310 from flowing back to the suction port 370.

The suction damping device 700 includes a valve case 710, a valve cap 740, a core 720, and an elastic member 730 as shown in FIG. 4.

Here, the valve case 710 is a portion constituting the body of the suction damping device 700, one end (right side in the drawing) is opened and the other end (left side in the drawing) is formed in a cylindrical shape having an empty space while the inside is closed. do.

The open end of the valve case 710 is positioned in a state of being press-fitted into the suction flow path 350 by a predetermined indentation depth H, and the closed other end of the valve case 710 is the suction flow path 350. It is installed so as to partially protrude into the suction chamber 310 through the.

A window 750 is formed through the circumference of the valve case 710 and the window 750 is connected to the inner space of the valve case 710 and the suction chamber 310 of the rear housing 300, So that the space inside the space is communicated with each other.

In particular, in the embodiment of the present invention, the window 750 is composed of an exposed portion 751 positioned to communicate with the inside of the suction chamber 310 and a non-exposed portion 752 positioned in the suction passage 350. The entire area formed by the exposed portion 751 is characterized in that it is formed to be the same as, or wider than the area formed by the diameter of the inlet 741 in which the refrigerant of the suction damping device 700 is introduced. That is, the total area formed by the exposed portion 751 and the total area formed by the non-exposed portion 752 can be determined based on the diameter of the inlet 741, thereby reducing the booming noise and reducing the performance of the compressor. It is to be prevented as much as possible.

Of course, since the non-exposed portion 752 of the window 750 performs a muffler function while the refrigerant introduced through the inlet 741 passes through the valve case 710, the non-exposed portion 752 has a large area. Larger results in a further reduction in booming noise. However, in this case, since there is a fear that the compression performance of the compressor is sharply lowered, the position of the non-exposed portion 752 and the exposed portion 751 can achieve the maximum reduction of the booming noise at the level of minimizing the degradation of the compression performance. Since it is more preferable to be able to determine the position, the exposure is based on the point where the area of the exposed portion 751 and the area of the inlet 741 are substantially the same as the reduction in performance compared to the efficiency of reducing the booming noise. The area of the portion 751 is determined to be equal to or larger than that of the inlet 741.

In particular, the determination of the total area formed by the exposed portion 751 of the window 750 is the indentation depth (H) in which the refrigerant inlet side portion of the suction damping device 700 is pressed from the back of the rear housing 300. It is preferable to configure to be carried out through the control of).

That is, when considering that the exposed portion 751 and the non-exposed portion 752 of the window 750 formed in the suction damping device 700 are located in the suction chamber 310 or the suction flow path 350, the suction damping device 700 In the installed state, the area of the exposed portion 751 of the window 750 may not be accurately determined whether the area of the exposed portion 751 is the same or larger than that of the inlet 741. Accordingly, by setting the area of the exposed portion 751 of the window 750 to be inferred based on the depth H at which the suction damping device 700 is press-fitted, an operator or an automated device sets the suction damping device 700. By adjusting the indentation depth (H) of the area of the exposed portion 751 is equal to the area of the inlet 741, or can be easily installed in a larger position.

To this end, the length L of the non-exposed portion 752 of the window 750 is set to be smaller than or equal to 0.25 times the indentation depth H. That is, the length L of the non-exposed portion 752 of the window 750 is equal to 0.25 times the indentation depth H, where the area of the exposed portion 751 and the inlet 741 are substantially the same. When the length L is smaller than 0.25 times the indentation depth H, the non-exposed part 752 is because the opening amount of the exposed part 751 is a point larger than the area of the inlet 741. If it is known that the length of the indentation depth (H) can be determined, the intake damping device 700 may be press-fitted by the indentation depth (H) thus determined.

In addition, the valve cap 740 constituting the suction damping device 700 is coupled to an open end of the valve case 710 while the core 720 in the valve case 710 opens the valve case 710. It prevents the departure to one end.

In this case, an inlet 741 is formed at the central portion of the valve cap 740 to guide the refrigerant sucked from the suction port 370 into the valve case 710.

The core 720 is configured to selectively open and close the window 750 formed in the valve case 710 while being elastically movably installed in the valve case 710 by the elastic member 730.

Hereinafter, the operation of the variable displacement swash plate type compressor according to the embodiment of the present invention described above will be described.

When the operation of the compressor is controlled, the driving shaft 410 is rotated by receiving the driving force of the engine. By rotating the driving shaft 410, the rotor 430 is rotated, 440 are rotated.

When the swash plate 440 is rotated, the rotation of the swash plate 440 is transmitted to each of the pistons 420 through the shoe 450, thereby causing the piston 420 to move in the cylinder bore 110 So that the refrigerant sucked into the cylinder bore 110 is compressed.

At this time, the refrigerant flows into the suction port 370 and then flows along the suction passage 350 and is supplied into the suction chamber 310 of the rear housing 300. Then, the refrigerant passes through the valve assembly 500, Bore < / RTI >

In particular, the refrigerant flowing along the suction passage 350 during the suction flow of the refrigerant passes through the suction damping device 700 provided in the suction passage 350, and in the process of the refrigerant Inhalation pulsation is attenuated.

That is, the coolant flows into the valve case 710 through the inlet hole 741 of the valve cap 740 constituting the suction damping device 700, and the core 720 is moved by the inlet pressure of the coolant. The window 750 is gradually opened as shown in FIG. 5 while being moved to the other end of the valve case 710, where the instantaneous flow fluctuation of the refrigerant is changed as much as the space provided by the non-exposed portion 752 constituting the window 750. FIG. Since it serves as a muffler to cause a gradual attenuation of the suction pulsation included in the refrigerant is made in the course of flowing the refrigerant introduced into the valve case 710.

6, the core 720 is completely moved to the other end of the valve case 710 and is opened to the exposed portion 751 of the window 750 positioned in the suction chamber 310 The refrigerant in the valve case 710 passes through the window 750 and is supplied into the suction chamber 310.

Of course, the refrigerant passing through the valve case 710 during the above process is attenuated by the suction pulsation due to the expansion of the flow path by the non-exposed part of the window 750. 310 is provided.

The refrigerant supplied into the suction chamber 310 is supplied into the cylinder bore 110 through the valve assembly 500 and is compressed by the operation of the piston 420 in the cylinder bore 110.

The refrigerant compressed in the cylinder bore 110 through the series of processes described above is discharged to the discharge chamber 330 of the rear housing 300 by the selective operation of the valve assembly 500, The suction, compression, and discharge processes of the refrigerant are sequentially and repeatedly performed, so that the compression operation of the continuous refrigerant is performed.

As a result, the variable displacement swash plate compressor of the present invention has suction damping through the setting of the relationship between the inlet 741 of the suction damping device 700 and the exposed portion 751 of the window 750 of the valve case 710. While it is possible to smoothly attenuate the suction pulsation of the refrigerant passing through the device 700, the degradation of the compression performance can be prevented.

In particular, the setting of the relationship between the inlet 741 and the exposed portion 751 can be performed by adjusting the indentation depth (H) of the suction damping device 700 to work by an operator or an automated device It also has the advantage that it is possible.

100. Cylinder block 110. Cylinder bore
120. Center bore 200. Front housing
210. Crankcase 300. Rear housing
310. Suction chamber 330. Discharge chamber
350. Suction flow path 351. Extension part
370. Suction port 410. Drive shaft
420. Piston 430. Rotor
431. Hinge arm 440. Swash plate
450. Shoe 460. Saffan hub
461. Swaff arm 500. Valve assembly
700. Suction damping device 710. Valve case
720. Core 730. Elastic member
740. Valve cap 741. Inlet ball
750. Windows 751. Exposed part
752.Non-exposed part H. Indentation depth
L. Length of Unexposed

Claims (3)

A suction passage 350 communicating the suction chamber 310 and the suction port 370 of the rear housing 300 with each other, and installed in a state in which the suction passage 350 is disposed, and a window through which the refrigerant flows out. Variable displacement type swash plate comprising a valve case 710 having a 750 and a suction damping device 700 having a core 720 that opens and closes the window 750 while elastically moving in the valve case 710. In the compressor,
The window 750 of the suction damping device 700 is composed of an exposed portion 751 positioned to communicate with the inside of the suction chamber 310 and a non-exposed portion 752 positioned in the suction passage 350.
The entire area formed by the exposed portion 751 is the same as or wider than the area formed by the diameter of the inlet 741 into which the refrigerant of the suction damping device 700 is introduced. Type compressor. The method of claim 1,
Determination of the total area formed by the exposed portion 751 of the window 750 is to adjust the indentation depth (H) in which the refrigerant inlet side portion of the suction damping device 700 is pressed from the back of the rear housing 300. Variable displacement swash plate compressor, characterized in that configured to be carried out through. The method of claim 1,
The length (L) of the non-exposed portion (751) of the window 750 is determined to be smaller than or equal to 0.25 times the indentation depth (H) of the variable displacement swash plate type compressor.

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