DE3317979C2 - - Google Patents

Description

The invention relates to a pressure control direction, in particular for a hydraulic vehicle braking system, with a housing in which one with a Pressure medium source connected inlet space and a an outlet space connected to a slave cylinder are arranged with a between inlet and outlet space neten, closing at a predefinable switching pressure Valve device, consisting of one on a valve sleeve arranged valve seat and one of a control force in Opening direction of the valve device acted upon valve piston on which a valve closing member is arranged and that passes through the valve sleeve, with one under pressure slope from the outlet space to the rear opening opening impact valve, with a radial between peripheral surfaces the valve sleeve and the housing arranged sealing element, and with one in the closing direction of the valve device pointing, housing-side stop for the valve sleeve.

Such a pressure control device is in DE-OS 29 30 476 described. The known pressure control device has a multiply graduated housing bore in which a inlet space connected to a pressure medium source and an outlet space connected to a slave cylinder are formed, between which a valve device is arranged. In the housing bore are on the inlet side a first valve sleeve and a second sleeve set by means of sealing arranged in ring grooves  elements are sealed against the housing. Through a Ring that is threaded into the open end of the case the second sleeve is screwed in was in contact with the valve sleeve and this in turn held a housing stop. Is on the valve sleeve the valve seat is formed. The valve closing element is on attached to a valve piston that through the valve sleeve and sets against a control force depending on pressure the closed position is movable. A check valve opens with closed valve device and Druckge make a connection between inlet from outlet to inlet let room and outlet room. The check valve enables the pressure reduction on the slave cylinder only when the Inlet pressure becomes less than the outlet pressure, i. H. in the Connection to the reduction phase when pressure builds up first of all when the pressure drops with falling pressure at the on a constant pressure at the outlet, which only decrease can after the inlet and outlet pressure speak.

However, it is required for certain applications Lich that the outlet pressure before reaching the Equal pressure can decrease.

The invention has for its object to provide a pressure control device of the type mentioned, in which the outlet pressure also decreases with decreasing inlet pressure before pressure equality is reached. The pressure control unit should continue to be simple in construction and easy to assemble.

According to the invention this object is achieved in that the Valve sleeve in the opening direction of the valve device against the opposite Housing stationary sealing element is slidable.

This training ensures with extremely simple Average the desired pressure curve; it is only minor Compliant design changes compared to a version required with fixed valve sleeve; the number of Components remain almost unchanged.

An advantageous development of the invention provides that the diameter of the abge through the sealing element sealed area of the valve sleeve equal to the diameter of the valve seat; the slope of the pressure curve at Pressure build-up corresponds to the slope in this design during pressure reduction. Choosing the diameter of the through the Sealing element sealed area of the valve sleeve is larger than the diameter of the valve seat a steeper increase in pressure reduction than in Pressure build-up.

Another embodiment provides that the through knife of the area sealed by the sealing element the valve sleeve is equal to the diameter of the valve sleeve receiving housing section.

It is appropriate that abge the valve seat face of the valve sleeve a compression spring is applied, which is supported fixed to the housing.  

It can also be provided that the displacement of the Valve sleeve in the closing direction by a housing-fixed Stop is limited.

An embodiment in which the Valve sleeve is formed in two parts with a housing firmly arranged, the stop in the opening direction forming first sleeve element and a displaceable second sleeve member having the valve seat that axially between the first and second sleeve element Sealing element is arranged and that the second sleeves element is guided with play in the first sleeve element; the assembly the valve sleeve is simplified and the leadership improved. In this embodiment, it is appropriate that the compression spring rests on the second sleeve element.

It is particularly advantageous to shift the Ven piston in the opening direction by one on the valve limit sleeve-trained stop; a feather, the valve sleeve against a stop fixed to the housing presses can be omitted because the valve sleeve through the Force of the control spring is pressed against this stop.

An embodiment of the invention is in the Drawing shown and described in more detail below. It shows

Fig. 1 a pressure control means in section,

FIG. 2 shows the pressure curve of the pressure control device according to FIG. 1.

In the upper half of the sectional view in Fig. 1, the components of the pressure control device are drawn in the position that they take when the valve device is closed. The lower half indicates the conditions in the event of a pressure reduction at the inlet.

In a housing 1 , a stepped housing bore 2 is formed, into which a pressure medium connection 4 assigned to an inlet space 3 and a pressure medium connection 6 assigned to an outlet space 5 open. The inlet space 3 is in a section 8 of larger diameter of the housing bore 2 , the outlet space 5 is in a section from 7 smaller diameter of the housing bore 2 . The pressure medium connection 4 is with a pressure medium source, for. B. connected to the master cylinder of a hydraulic driving brake system; the pressure medium connection 6 is connected to a wheel cylinder of the rear axle of a vehicle. The housing bore 2 is sealed on the input side by a closing element 9 . Between the input space 3 and the output space 5 , a valve sleeve 12 consisting of two sleeve elements 10, 11 is arranged.

The first sleeve element 10 is annular and bears against the housing shoulder between the sections 7, 8 of the housing bore 2 . The inner bore of the sleeve element 10 is stepped. The smaller diameter bore section starts from the end face that is assigned to the housing shoulder.

The second sleeve element 11 has three sections with different diameters. The outlet-side section with the smallest diameter B passes through the smaller bore section of the first sleeve element 10 with play and has the valve seat 13 at the end. The sealing edge of the valve seat 13 has the diameter B. This section is followed by a central section with a larger diameter C , to which the Endab section, the outer diameter of which corresponds to the diameter of the larger section 8 of the housing bore 2 . The section with the diameter C of the second sleeve element 11 is arranged with play in the larger Bohrabab section of the first sleeve element 10 . The second sleeve member 11 can be struck with the section between its sections with the diameters B and C lying against the section lying in the inner bore of the first sleeve member 10 . The second sleeve element 11 has a stepped inner bore 14 , which serves as a pressure medium channel. The section of the inner bore 14 with the smaller diameter starts from the end face on which the valve seat 13 is formed. On the opposite end face of the second sleeve element 11 on the input side, radial pressure medium channels 16 are provided for connecting the pressure medium connection 4 to the inner bore 14 .

A sealing element 15 is arranged radially between the outer circumferential surface with the diameter C of the second sleeve element 11 and the wall of the section 8 of the housing bore 2 . It lies axially between the end face of the first sleeve element 10 facing away from the housing shoulder and the end face of the second sleeve element 11 , which is formed between the middle section and the end section of the largest diameter. The sealing element 15 allows an axial displacement of the second sleeve element 11 , but is itself held stationary with respect to the housing 1 .

The two-part valve sleeve 12 is penetrated by the valve piston 20 , which carries at its left end in FIG. 1 the valve closing member 21 with the elastic sealing body 22 that can be placed against the valve seat 13 . In the area in which the valve piston 20 is given by the valve sleeve, it has a step in diameter which forms an axial stop.

The substantially annular sealing body 22 has on the inner circumference a sealing lip 23 which cooperates with the valve piston 20 and forms a check valve through which the between the inner wall of the second Ven tilhülse 11 and the valve piston 20 ring-shaped pressure medium channel via a bore 24 with the outlet space is connectable if there is a pressure drop from the outlet space 5 to the inlet space 3 when the valve is closed. The other end of the valve piston 20 , which has the diameter A , projects out of the housing 1 in a sealed manner and is acted upon by a control force F acting in the opening direction at this end.

Between the second sleeve member 11 and the end element 9 , a compression spring 25 is arranged, which strikes the second sleeve member 11 in the direction of the outlet chamber 5 .

The mode of operation of the pressure control is shown below direction described.  

When the brake system is depressurized, the control force F acting on the valve piston 20 causes the valve to be in the open position; the sealing body 22 is removed from the valve seat 13 ; the valve piston 20 lies with its step against the stop which limits the opening movement and which is formed by the shoulder in the inner bore 14 of the second sleeve element 11 . The sleeve elements 10, 11 and the sealing element 15 are in the position shown in the upper part of FIG. 1. The pressure medium passes from the pressure medium connection 4 via the pressure medium channels 16 , the inner bore 14 and the ge-opened valve passage to the outlet space 5 and thus to the pressure medium connection 6 , which is connected to the slave cylinder.

When the pressure builds up on the inlet side, a pressure corresponding to the pressure on the inlet side is built up on the outlet side due to the open valve. After He reach the switching pressure a ( Fig. 2), which is determined by the control force F , the valve closes due to the movement of the valve piston 20 to the right in Fig. 1 by the sealing body 22 on the valve seat 13th

Since, as shown, the diameter A is smaller than the diameter B , the pressure control device operates in a known manner, as described in DE-OS 29 30 476, as a pressure reducing unit. The slope of the brake pressure curve between points a and b is due to the factor

m = (B ²- A ²) / B ²

featured.  

At the input-side pressure reduction acts on the United sliding unit - valve piston 20 and second sleeve element 11 - against the control force F, a force that results from the product of the outlet pressure PA and the effective circular area with the diameter C. An opposing force results from the product of the inlet pressure PE and the circular area with the outside diameter C and the inside diameter A. The slope of the brake pressure curve is by the factor

m = (C ²- A ²) / C ²

featured.

As shown, the diameter C can be chosen to be larger than the diameter B or equal to the diameter B ; in the latter case, the slope of the brake pressure curve during the pressure build-up phase is equal to the slope of the brake pressure curve during the pressure release phase.

When the pressure at the inlet is reduced, the brake pressure curve according to FIG. 2 initially runs in a small area due to the differently sized effective annular areas during the pressure build-up phase (annular area with the diameters B and A ) and during the pressure reduction phase (annular area with the diameters C and A ) as through Just marked bb ' . Then the pressure is reduced along the line b'-a ; the check valve opens when the pressure at the inlet drops further; When the check valve is open, the further pressure drop at the outlet corresponds to the pressure reduction at the inlet (section a -0 of the brake pressure curve).

In Fig. 2, the course of the brake pressure curve during the pressure reduction phase is marked marked with dashed lines, which occurs when the valve sleeve is not displaceable and the check valve alone causes the pressure reduction at the outlet.

Claims (9)

1. Pressure control device, in particular for a hydrau lic vehicle brake system, with a housing in which an inlet space connected to a pressure medium source and an outlet space connected to a slave cylinder are formed, with an inlet space and outlet space arranged between an inlet and outlet, closing at a preselect switching pressure Valve device, consisting of a valve seat arranged on a valve sleeve and a valve piston which can be acted upon by a control force in the opening direction of the valve device, on which a valve closing element is arranged and which passes through the valve sleeve, with a non-return valve opening in the event of a pressure drop from the outlet space to the inlet space, with a radial arranged between peripheral surfaces of the valve sleeve and the housing Dichtele element and with a housing-side stop pointing in the closing direction of the valve device for the valve sleeve, characterized in that the valve sleeve in opening ric Attention of the valve device ( 11 to 13 , 20 to 23 ) against the fixed to the housing ( 1 ) sealing element ( 15 ) is displaceable. 2. Pressure control device according to claim 1, characterized in that the diameter ( C ) of the region of the valve sleeve sealed by the sealing element ( 15 ) is equal to the diameter ( B ) of the valve seat ( 13 ). 3. Pressure control device according to claim 1, characterized in that the diameter ( C ) of the area of the valve sleeve sealed by the sealing element ( 15 ) is larger than the diameter ( B ) of the valve seat ( 13 ). 4. Pressure control device according to claim 1, characterized in that the diameter ( C ) of the region sealed by the sealing element ( 15 ) of the valve sleeve is equal to the diameter of the housing section receiving the valve sleeve. 5. Pressure control device according to one or more of the preceding claims, characterized in that on a valve seat ( 13 ) facing away from the end face of the valve sleeve is a compression spring ( 25 ) which is supported fixed to the housing. 6. Pressure control device according to one or more of the previous claims, characterized records that the displacement of the valve sleeve in the closing direction by a stop fixed to the housing is limited.   7. Pressure control device according to one or more of the preceding claims, characterized in that the valve sleeve ( 12 ) is formed in two parts with a housing-fixed arranged, the stop in the opening direction forming the first sleeve element ( 10 ) and a displaceable second sleeve element ( 11 ), the Valve seat ( 13 ) that the sealing element ( 15 ) is arranged axially between the first ( 10 ) and second sleeve element ( 11 ) and that the second sleeve element ( 11 ) is guided with play in the first sleeve element ( 10 ). 8. Pressure control device according to claim 7, characterized in that the compression spring ( 25 ) abuts the second sleeve element ( 11 ). 9. Pressure control device according to one or more of the preceding claims, characterized in that the displacement of the valve piston ( 20 ) in the opening direction is limited by a stop formed on the valve sleeve.