KR20110136735A - Differential pressure valve - Google Patents

Abstract

PURPOSE: The number of component can be reduced, the set differential pressure can be adjusted after the assembly. CONSTITUTION: A differential pressure valve comprises a housing(10), a plug(20), and a pressure spring(30). The housing comprises a small-diameter portion(11), a large-diameter portion(12), and a valve seat(13). The small-diameter portion comprises a plurality of inlet ports(14) in the side the leading end is blocked. The large-diameter portion comprises an outlet port(15) the leading end is opened, bending a spring housing(16) and the large-diameter portion suspends the pressure spring. The plug comprises a valve body(21), a first guide(22), and a second guide(23). The first guide and the second guide are arranged in both end part of the axial direction. The pressure spring is accepted to the large-diameter portion of the housing in order to exert pressure upon the valve body to the direction of the valve seat.

Description

DIFFERENTIAL PRESSURE VALVE

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a differential pressure valve, and more particularly, to a differential pressure valve provided between two rooms having different pressures to maintain the pressure between the rooms at a predetermined differential pressure.

BACKGROUND ART A scroll compressor is known as a compressor constituting a refrigeration cycle of a vehicle air conditioner. The scroll compressor has a fixed scroll and a movable scroll supported by a hard plate disposed on an axially open side of the fixed scroll and driven by an electric motor or the like. By moving the movable scroll, the gas refrigerant is compressed by decreasing the volume of the compression chamber surrounded by the fixed scroll and the movable scroll in a spiral direction from the surroundings to the center.

In this compression operation, the hard disk of the movable scroll receives the force extruded in the direction axially spaced apart from the fixed scroll by the high pressure of the compression-generated compression chamber, and the drive source side receives an excessive thrust load. In order to avoid this, an intermediate pressure chamber is formed on the drive source side of the hard plate, and a high pressure compressed and generated is introduced into the intermediate pressure chamber to return the movable scroll to the fixed scroll side.

Since the intermediate pressure of the intermediate | middle pressure chamber is a load which presses a movable scroll to a fixed scroll, when it becomes high too much, the force to press becomes excessive, frictional force will become large and the power consumption of a compressor will become large. On the contrary, when the intermediate pressure is too small, the clearance between the movable scroll and the fixed scroll becomes large, resulting in a disadvantage such as deterioration of the compression performance.

Therefore, it is necessary to maintain the intermediate pressure of the intermediate pressure chamber at an appropriate value. Therefore, a structure is known in which a switching valve is provided between the high pressure chamber and the intermediate pressure chamber communicating with the compression chamber and between the intermediate pressure chamber and the low pressure chamber where the refrigerant gas is sucked in (see Patent Document 1, for example). When the pressure difference between the high pressure chamber and the low pressure chamber increases, the switching valve closes the passage from the high pressure chamber to the intermediate pressure chamber, opens the passage between the intermediate pressure chamber and the low pressure chamber, lowers the intermediate pressure in the intermediate pressure chamber, and reduces the pressure load. Doing. In addition, when the pressure difference between the high pressure chamber and the low pressure chamber decreases, the switching valve is reversed to raise the intermediate pressure of the intermediate pressure chamber to increase the pressing load.

In contrast, an orifice is provided between the high pressure chamber and the intermediate pressure chamber, and a differential pressure valve is provided between the intermediate pressure chamber and the low pressure chamber to maintain the pressure difference between the pressure in the intermediate pressure chamber and the pressure in the low pressure chamber at a predetermined differential pressure. It is also known (for example, refer patent document 2). The differential pressure valve includes a casing port having a valve seat, a valve body for opening and closing the valve seat, a connecting rod having one end coupled to the valve body, a damping piston screwed to the other end of the connecting rod, and a valve body. The valve closing spring which presses in the direction of a valve seat, and the valve main body which accommodates these are provided. In this configuration, since only the orifice and the downstream pressure valve are provided on the upstream side of the intermediate pressure chamber, the pressure adjustment of the intermediate pressure chamber can be realized at low cost.

Japanese Patent Application Laid-open No. Hei 8-21382 Japanese Patent Application Laid-open No. Hei 10-89179

However, the above-described differential pressure valve has a large number of parts, and since the valve closing spring for determining the set differential pressure is accommodated in the valve body whose opening is closed by the housing having the valve seat, there is a problem that the set differential pressure cannot be adjusted after assembly. there was.

This invention is made | formed in view of such a point, Comprising: It aims at providing the differential pressure valve which has few components and can adjust the set differential pressure after assembly.

In the present invention, in order to solve the above problems, the small diameter portion of the cylindrical shape, the tip is closed and the inlet port is perforated on the side, the large diameter portion of the cylindrical shape and the small diameter portion and the large diameter portion of which the tip is opened and forms the outlet port. A housing in which a valve seat composed of steps formed at a position is integrally formed, a valve body that can be contacted and detached with respect to the valve seat, and a piston shape extending from the valve body to a position beyond the inlet port and loosely fitted at the tip of the small diameter portion. The first guide and the valve body extending from the valve port to the side of the outlet port and having a polygonal outer shape and a portion of the ridge formed by axially connecting the vertices of the polygon having a curvature substantially equal to the inner wall of the large diameter portion; 2 A plug in which the guide is integrally formed, and one end is caught by the plug, and the other end is A differential pressure valve is provided, comprising a pressing spring which is caught by a plurality of spring receiving portions bent inwardly of a portion of the opening side edge of the expected diameter portion and presses the valve body in the direction of the valve seat.

According to such a differential pressure valve, it consists of three components, a housing, a plug, and a compression spring. Moreover, since the spring receiving part which hangs the pressing spring is in the open side edge of the large diameter part exposed, the latching position can be changed, and the fine adjustment of the setting differential pressure is attained.

The differential pressure valve of the above configuration has an advantage that the cost can be greatly reduced by having fewer components. Moreover, since the plug has the structure which supports the valve body with the 1st and 2nd guide part in the axial both ends, a valve body can operate | move without inclining with respect to a valve seat. Moreover, by making the 1st guide loosely fit in the small diameter part by which the front-end | tip of a housing was occluded, a damper effect can be made to a differential pressure valve, without increasing components.

Since the housing has a jig accommodation portion projecting outwardly in the axial direction from the spring accommodation portion on the opening side edge of the large diameter portion, the jig does not collide with the spring accommodation portion when the differential pressure valve is press-fitted using the jig in the passage. The differential pressure does not change.

The housing is provided with a fitting portion that is expanded radially outward on the opening end side of the large diameter portion, so that when the differential pressure valve is press-fitted into the passage having an inner diameter slightly smaller than the outer diameter of the fitting portion, the fitting portion is pressurized with the differential pressure valve and the passage inner wall. And a function of fixing the differential pressure valve in the passage.

BRIEF DESCRIPTION OF THE DRAWINGS The front view which shows the external appearance of the differential pressure valve which concerns on embodiment of this invention.
Fig. 2 is a diagram showing details of the differential pressure valve, (A) is a left side view of the differential pressure valve, and (B) is an AA arrow sectional view of (A).
3 is a perspective view showing an appearance of a plug;

Hereinafter, with respect to embodiment of this invention, the case where it installs in the channel | path between the middle pressure chamber and the low pressure chamber of the scroll compressor which comprises a refrigeration cycle, and uses a movable scroll as an adjustment valve of the intermediate pressure which presses a fixed scroll is taken as an example. It demonstrates in detail with reference to drawings.

BRIEF DESCRIPTION OF THE DRAWINGS The front view which shows the external appearance of the differential pressure valve which concerns on embodiment of this invention, FIG. 2 is a figure which shows the detail of a differential pressure valve, (A) is a left side view of a differential pressure valve, (B) is (A) AA arrow cross section of FIG. 3: is a perspective view which shows the external appearance of a plug.

The differential pressure valve has three parts of the housing 10, the plug 20, and the pressing spring 30, as shown in FIG. 2B, and the plug 20 and the pressing spring ( It is comprised by accommodating 30).

The housing 10 has the cylindrical small diameter part 11 and the large diameter part 12 arrange | positioned on the same axis and different outer diameters, and a step | step difference arises in these engagement positions, The inside is the valve seat of this differential pressure valve. We have function of (13). And this housing | casing 10 is a metal plate | board material, such as copper, stainless steel, and brass, for example, the small diameter part 11, the large diameter part 12, and the valve seat 13 by deep drawing processing, for example. It is formed integrally.

The tip of the small diameter part 11 is blocked, and the some inlet port 14 is perforated by the side surface. Four inlet ports 14 are provided in this embodiment, and are arranged evenly in the circumferential direction, respectively.

The large diameter part 12 has the open end, and comprises the exit port 15. As shown in FIG. As for the opening side edge of the large diameter part 12, as shown in FIG.2 (A), the spring accommodating part 16 and the jig accommodating part 17 are alternately arranged in the circumferential direction, and the spring accommodating part 16 ) Is formed at the boundary between the jig receiving portion 17 and the groove 18. The spring accommodating portion 16 extends straight outward in the axial direction before assembling the differential pressure valve, and is bent inward after accommodating the plug 20 and the pressing spring 30 in the housing 10. The base is deformed when the spring accommodating portion 16 is bent, but the groove 18 prevents the deformation from affecting other things. The jig accommodation portion 17 protrudes outward from the spring accommodation portion 16 in the axial direction. As a result, when the differential pressure valve is installed in the passage between the intermediate pressure chamber and the low pressure chamber of the scroll compressor, the differential pressure valve is press-fitted into the passage using a cylindrical jig. It hits only the jig accommodating part 17, without hitting. The large diameter part 12 is further provided with the fitting part 19 by which one part of the opening edge part expanded radially outward. The fitting portion 19 has an outer diameter slightly larger than the inner diameter of the passage between the intermediate pressure chamber and the low pressure chamber to be mounted, and is pressed against the inner wall of the passage when the differential pressure valve is pressed into the passage. As a result, the fitting portion 19 has a function of sealing between the passage and the differential pressure valve, and a function of fixing the differential pressure valve in the passage.

The plug 20 has a valve body 21 and a first guide 22 and a second guide 23 arranged at both ends in the axial direction thereof, for example, to withstand refrigerant in a refrigeration cycle and lubricant or temperature incorporated therein. It is formed integrally with resin with this.

The valve body 21 has a tapered surface whose diameter increases from the small diameter portion 11 toward the large diameter portion 12, and the tapered surface is capable of contact separation with respect to the valve seat 13. By setting it as the valve body 21 which has a taper surface, the characteristic of the flow volume with respect to the lift amount when the differential pressure valve starts to open does not become a sudden change.

The first guide 22 is formed at the tip of the valve rod 24 extending in the axial direction from the valve body 21 to the position beyond the inlet port 14, and has a piston shape loosely fitted to the small diameter portion 11. Have The valve rod 24 is thinly formed, and forms a passage through which the refrigerant flows between the inner wall of the small diameter portion 11. The first guide 22 is loosely fitted to the small diameter portion 11 to support the axial movement of the valve body 21 and cooperate with the small diameter portion 11 on the closed side of the damper chamber 25. ). The damper chamber 25 enters the axial direction of the valve body 21 integrated with the first guide 22 by entering and exiting the refrigerant gas or the lubricating oil through the clearance between the first guide 22 and the small diameter portion 11. Sudden operation of can be suppressed.

The second guide 23 extends in the axial direction from the valve body 21 toward the outlet port 15, and has a substantially rectangular outer shape as shown in FIG. 3, and has a shape with the second guide 23. Four refrigerant passages are secured between the large-diameter portions 12. In addition, in the second guide 23, a portion of the ridge formed by connecting the four vertices of the substantially square in the axial direction has a curvature substantially equal to the inner wall of the large diameter portion 12, and is loosely fitted to the large diameter portion 12. . Thereby, since the 1st guide 22 and the 2nd guide 23 which are in the axial end part of the valve body 21 are supported by the small diameter part 11 and the large diameter part 12, the axial movement is supported. It can contact and isolate without inclining with respect to the valve seat 13.

The pressing spring 30 is accommodated in the large diameter part 12 of the housing 10 so that the valve body 21 may be pressed in the direction of the valve seat 13, and a tapered spring is used. One end of the pressing spring 30 is caught by a groove concave in the end surface of the second guide 23, and the other end is formed in the opening side edge of the large diameter portion 12 to the spring receiving portion 16 bent inwardly. Hung by The pressing force of the pressing spring 30 is set according to how much the differential pressure between the pressure in the middle pressure chamber of the scroll compressor and the pressure in the low pressure chamber is set. That is, the pressing spring 30 is set to the pressing force which opens a valve at a desired differential pressure, when it compress | compresses to the position which bent the spring accommodating part 16 to a right angle direction, as shown in FIG. In addition, since the locking position of the pressing spring 30 can be changed by the bending angle of the spring accommodating part 16, after assembling a differential pressure valve, the setting differential pressure is changed by further changing the bending angle of the spring accommodating part 16. It becomes possible to make fine adjustments.

The differential pressure valve having the above configuration is provided by press-fitting into the passage between the intermediate pressure chamber and the low pressure chamber of the scroll compressor. When the refrigeration cycle is not operating, there is no difference between the pressure in the intermediate pressure chamber and the pressure in the low pressure chamber, so that the valve body 21 is seated on the valve seat 13 by the pressing force of the pressure spring 30 to close the valve. have.

When the scroll compressor is started, the pressure in the intermediate pressure chamber to which the compressed refrigerant is supplied from the high pressure chamber is high, and the low pressure chamber pressure at which the refrigerant is sucked by the compression is low. Here, when the difference between the pressure in the intermediate pressure chamber and the low pressure chamber pressure exceeds a predetermined value, the valve body 21 is lifted from the valve seat 13 in response to the pressing force of the pressure spring 30, and the differential pressure valve is opened. . When the differential pressure valve is opened, the differential pressure between the intermediate pressure chamber and the low pressure chamber is reduced, so that the differential pressure valve is closed. The differential pressure valve keeps the differential pressure between the intermediate pressure chamber and the low pressure chamber at a predetermined differential pressure by repeating the valve opening and the valve closing. At this time, the differential pressure valve periodically opens and closes, but since the first guide 22 integral with the valve body 21 constitutes the damper chamber 25, the periodic opening and closing operation at that time is greatly restricted. Therefore, the size of the hitting sound of the valve body 21 hitting the valve seat 13 at the time of valve closing becomes small, and the frequency of the hitting sound is also very low, so that the opening and closing noise at the time of opening of annoying moments can be greatly reduced. Can be.

When the differential pressure between the intermediate pressure chamber and the low pressure chamber is large, the differential pressure valve is maintained at an opening degree corresponding to the differential pressure, and operates to maintain a predetermined differential pressure. At this time, since the differential pressure valve is not closed, there is no occurrence of a hitting sound of the valve body 21 hitting the valve seat 13.

In addition, although the 2nd guide 23 which guides the valve body 21 in the side of the outlet port 15 was formed in substantially square shape in the above-mentioned embodiment, this invention is not limited to this, Polygon You can do Moreover, although the fitting part 19 is formed in the opening end side of the large diameter part 12 of the housing | casing 10 as a means for fixing while fixing a differential pressure valve in a channel | path, a seal is made into an O-ring, for example. For example, the differential pressure valve inserted into the passage may be prevented from dropping by fitting the ring to the refrigerant outlet side of the passage.

10: housing
11: small diameter part
12: large neck
13: valve seat
14: inlet port
15: outlet port
16: spring receptacle
17: jig receiving part
18: home
19: fitting
20: plug
21: valve body
22: first guide
23: second guide
24: valve rod
25: damper room
30: compression spring

Claims (3)

The valve seat is composed of a tubular small diameter portion in which the tip is closed and the inlet port is perforated, a cylindrical large diameter portion in which the tip is opened to form an outlet port, and a step formed at a joining position of the small diameter portion and the large diameter portion. Formed with a housing,
A valve body detachable from the valve seat, a position extending from the valve body to a position beyond the inlet port, and extending from the valve body toward the side of the outlet port from a first guide having a piston shape loosely fitted to the small diameter portion; A plug formed integrally with a second guide having a polygonal outline shape and a portion of the ridge formed by axially connecting the vertices of the polygon in the inner wall of the large diameter portion;
One end is caught by the said plug, and the other end is provided with the press spring which is caught by the some spring accommodating part bent inward by the part of the opening side edge of the said large diameter part, and presses the said valve body in the direction of the said valve seat, It is characterized by the above-mentioned. Differential pressure valve. The differential pressure valve according to claim 1, wherein the opening side edge of the large diameter portion has a jig accommodation portion projecting outwardly from the spring accommodation portion between the spring accommodation portions bent inwardly. The differential pressure valve according to claim 1, wherein the large diameter portion is provided with a fitting portion inflated radially outwardly at an opening end side thereof.

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