DE102009055118A1 - Solenoid valve for e.g. anti-lock braking system, has inlet channel that is in fluid connection with fluid area, and outlet channel with outlet connection arranged at valve body on same side concerning valve seat as fluid inlet connection - Google Patents

Abstract

The valve (1) has a valve body (2), a valve seat (9), outlet channel (11) with a fluid outlet connection (12) and an inlet channel (23) with a fluid inlet connection (24) provided in the valve body. The inlet channel is in fluid connection with fluid area (10) by releasing the valve seat by a sealing element (8). The fluid inlet connection is provided at front side (25) of the valve. The fluid outlet connection is arranged at the valve body on the same side concerning the valve seat as the fluid inlet connection.

Description

State of the art

The invention relates to a solenoid valve having a valve body, wherein in the valve body, a valve seat, at least one fluid channel in fluid communication with an outlet outlet outlet and provided by releasing the valve seat by a sealing member with the fluid space in fluid communication inlet channel with a fluid inlet port of the solenoid valve are, wherein the fluid inlet port is provided on the end face of the solenoid valve. The invention further relates to a driver assistance device.

Disclosure of the invention

In solenoid valves, in particular normally closed, continuously adjustable solenoid valves, with radial flow, it is necessary to redirect the flow within the solenoid valve or the valve body. By radial flow is to be understood that the at least one fluid inlet port is arranged for example in a lateral surface of the valve body or the solenoid valve. Through the fluid inlet port, the fluid to be supplied to the solenoid valve is directed into an axial riser bore which is in fluid communication with the valve seat. The necessary flow deflection of the radial flow of the solenoid valve in the axial flow of the valve seat or the valve seat can be arranged in the sealing element is thus achieved by a corresponding recess or bore in the valve body, the riser. Here, the radially supplied fluid is passed through radial bores in the valve body and deflected into the axial riser hole, so that the valve seat or the sealing element can be flowed axially against the end face. The riser is usually introduced from below the valve seat in the valve body. Therefore, it is necessary to close the riser below the at least one fluid inlet port to redirect the fluid toward the valve seat. For this purpose, a closing body, for example a ball, is pressed into the rising hole. By means of the at least one fluid inlet connection, it is thus possible for fluid to pass into the riser bore and thus into the region of the valve seat. If the sealing element is in a closed position, it sits in the valve seat in such a way that the fluid connection between the fluid inlet connection and the fluid outlet connection is interrupted. On the other hand, if the sealing element is in a release position, then the fluid connection is present, so that the fluid can pass through the valve seat into the fluid space and thus to the fluid outlet connection. For this purpose, the at least one fluid outlet port is in fluid communication with the fluid space via an outlet passage. For example, four outlet channels and fluid outlet connections are provided, wherein the outlet channels are in the form of axial bores.

For new applications of the solenoid valves, it may be necessary, however, to flow the solenoid valve no longer radially, but axially. In the case of solenoid valves with axial flow, the at least one fluid inlet connection is provided, for example, on the end face of the magnet valve, so that the fluid flows in substantially in the axial direction onto the valve seat. In such solenoid valves, it is known from the prior art, the outlet channel and the fluid outlet port in the radial direction, starting from the fluid space, in a wall of the valve body form. In this case, the fluid outlet connection to the valve body is designed such that it lies on the side of the valve seat facing away from the fluid inlet connection. This has the consequence that an external device, for example a pump housing, in which the solenoid valve is to be used, must be adapted to the arrangement of the fluid inlet port and the fluid outlet port.

In contrast, the solenoid valve with the features mentioned in claim 1 has the advantage that the external device does not need to be or only slightly adapted to use both solenoid valves with radial and axial flow can. This is achieved according to the invention by arranging the fluid outlet connection on the valve body on the same side with respect to the valve seat as the fluid outlet connection. This position information is to be understood with reference to the longitudinal or axial direction of the solenoid valve. If, for example, the fluid inlet connection is arranged below the valve seat, then the fluid outlet connection is also present below the valve seat. Under "fluid inlet port" is the connection of the solenoid valve to understand, through which the fluid comes into the solenoid valve or in the valve body. Likewise, the term "fluid outlet port" is to be understood such that at this point the fluid is removed from the solenoid valve or the valve body. The fluid inlet connection is present, for example, at the point in which the inlet channel opens into the end face of the solenoid valve. Accordingly, the fluid outlet connection is present at the location of the magnetic valve or the valve body, at which the outlet channel opens into the lateral surface or the front side of the solenoid valve or of the valve body. In this way, the external device in which the solenoid valve is to be used, no longer specifically on the Direction of flow of the solenoid valve can be adjusted. Rather, only the flow direction can be reversed.

That is, the fluid inlet port of the radial direction solenoid valve is now used as the fluid outlet port on the axial flow solenoid valve and the fluid outlet port of the radial flow solenoid valve is used as the fluid inlet port of the axial flow solenoid valve. So there are no geometric changes to the external device necessary, as was previously the case with the known from the prior art solenoid valves with axial flow of the case. The solenoid valves with different flow are interchangeable. As a further advantage of such a design of the solenoid valve a simpler and more cost-effective production is possible because the closing body for closing the riser is no longer necessary, but rather can be omitted. This is due to the fact that the inlet channel can now run continuously from the end face of the solenoid valve to the valve seat. By an appropriate design of the valve body, therefore, the new, axial flow direction is realized while maintaining an interface of the external device.

A development of the invention provides that the outlet channel is at least partially angled relative to the longitudinal axis of the solenoid valve. This means that a longitudinal axis of the outlet channel is not coaxial or parallel to the longitudinal axis of the solenoid valve. Rather, at least one region of the outlet channel with respect to the longitudinal axis should have an angle not equal to 0 °, ie be angled with respect to this. In order to make the formation of the outlet channel in the valve body as simple as possible, it is provided that this runs straight. It follows that the entire exhaust duct is angled. However, it can also be provided that the outlet channel has at least one region which runs parallel to the longitudinal axis of the magnetic valve and merges into at least one further region of the outlet channel, which is angled.

A development of the invention provides that the outlet channel, starting from the fluid space, opens with the fluid outlet connection into a jacket surface of the valve body. The outlet passage extends from the fluid space to the fluid outlet port and establishes fluid communication therebetween. It is provided that the fluid outlet port is formed in a region of the lateral surface of the valve body, which is present on the same side with respect to the valve seat as the fluid inlet port on the valve body. Accordingly, the position of the fluid outlet port for the axial flow solenoid valve proposed herein corresponds to the fluid inlet port of the radial flow solenoid valve known in the art.

A further development of the invention provides that the distance between the fluid outlet connection and the valve seat in the axial direction is smaller than the distance between the fluid inlet connection and the valve seat. This is the case, for example, if the fluid outlet port is present on the lateral surface of the valve body and the fluid inlet port on the end surface.

A development of the invention provides that the outlet channel opens through a base surface of a base into the fluid space, which is angled relative to a bottom surface of the fluid space. In the fluid space so the base is provided, which is preferably arranged on the bottom surface of the fluid space. The base may be an independent base member which is attached to the valve body or integral with the valve body, so be formed by this. The base in this case represents a survey relative to the bottom surface of the fluid space. The base has a base surface, which is angled relative to the bottom surface, that is, has an angle of not equal to 0 °. In this case, the base surface is preferably inclined to the longitudinal axis of the solenoid valve. Through this base surface, the outlet channel opens into the fluid space. The mouth of the outlet channel in the fluid space is therefore not provided in the bottom surface, but rather above the bottom surface in the base or its base surface. As described above, it is advantageous if the base surface of the longitudinal axis of the solenoid valve is inclined. Accordingly, the mouth of the outlet channel of the longitudinal axis is inclined.

A development of the invention provides that the outlet channel is formed at least partially perpendicular to the base surface. Advantageously, the outlet channel opens vertically into the base surface, an opening surface of the mouth of the outlet channel is thus flat in the base surface of the base. This results in advantages in the design of the exhaust duct. This is made for example by drilling. It is advantageous if the drill can be applied perpendicular to a drilling surface. This drilling surface is represented by the base surface, so that when a vertical formation of the outlet channel in the region of the base surface, a migration of the drill in the formation of the outlet channel is at least reduced or avoided altogether.

A development of the invention provides that the base forms an at least partially circumferential collar in the fluid space. Of the Collar is at least partially increased compared to the bottom surface of the fluid space. If the collar is designed as a circumferential collar, it is present as a ring collar. This is for example designed such that it fully encloses the valve seat, which is formed in the valve body. However, it can also be provided that the collar is present only in the region of the outlet channel or its mouth into the fluid space, that is to say as an interrupted collar or annular collar.

A development of the invention provides that the base forms at least one region of a diffuser for a fluid flowing through the fluid space. With an appropriate arrangement of the sealing element, to which this is at least partially displaced in the direction of the release position, fluid flows through the valve seat into the fluid space, passes through this and enters the outlet channel. The fluid space is thus flowed through by the fluid in this case. In order to improve the flow or to direct the fluid flow of the diffuser is provided. In this way, a reduction of the force acting on a magnet armature of the solenoid valve disturbance can be reduced. Thus, a better distribution of the fluid in the fluid space and a more uniform flow are achieved by the diffuser. The diffuser is advantageously formed at least partially through the base. The socket can therefore fulfill several functions. On the one hand, it can serve as the starting surface for the production of the outlet channel, on the other hand it creates a diffuser effect for the fluid flow in the fluid space.

A development of the invention provides that a filter element is arranged in the inlet channel. In order to avoid contamination of the valve seat and thus an impairment of the switching capacity of the solenoid valve, the filter element is provided. This is provided at least partially in the inlet channel. Advantageously, it is present in the inlet channel between the fluid inlet port and the valve seat. However, it can also be provided that the filter element is present in the region of the fluid outlet connection or forms it with it.

The invention further relates to a driver assistance device, in particular ABS, TCS or ESP device, having at least one solenoid valve having a valve body, in particular according to the preceding embodiments, wherein in the valve body a valve seat, at least one with a fluid space in fluid communication outlet channel with a Fluid outlet port and provided by releasing the valve seat by a sealing member with the fluid space in fluid communication inlet channel with a fluid inlet port of the solenoid valve, wherein the fluid inlet port is provided on the end face of the solenoid valve. In this case, the fluid outlet port should be arranged on the valve body on the same side with respect to the valve seat as the fluid inlet port. The use of the above-described solenoid valve for the driver assistance device is advantageous, since thus functions can now be realized with the driver assistance device, which require an axially impinged solenoid valve, without a device of the driver assistance device, in which the solenoid valve is arranged, especially on the geometry of To adapt solenoid valve. It can thus be realized by simply replacing the solenoid valve functions, for which the use of axially impinged solenoid valves is necessary.

The invention will be explained in more detail below with reference to the embodiments illustrated in the drawing, without any limitation of the invention. Show it:

1 a cross section through a solenoid valve with a valve body, wherein the solenoid valve is designed for an axial flow and a radial outflow,

2 a section through the valve body, and

3 an isometric view of the valve body.

The 1 shows a portion of a solenoid valve 1 , which has a valve body 2 and a housing at least partially comprehensive 3 features. It is also an area of an external facility 4 recognizable, in which the solenoid valve 1 is arranged. The valve body 2 consists of a magnet armature 5 and a closure element 6 , which in an end region of the magnet armature 5 is arranged. In the embodiment illustrated here, the magnet armature 5 complete and the closure element 6 at least partially from the housing 3 embrace. The magnet armature 5 is an actuator 7 assigned, which preferably fixed to the armature 5 connected is. The actuator 7 has at its the closure element 6 facing the end of a sealing element 8th on which with a valve seat 9 cooperates to provide fluid communication through the solenoid valve 1 to release or interrupt. Alternatively, the magnet armature 5 be designed as a basic body, the function of the armature 5 from the actuator 7 is taken over. This is arranged displaceably in such an embodiment in the base body.

In the valve body 2 is a fluid space 10 provided, which by cooperation of armature 5 and closure element 6 is trained. The actuator 7 , the sealing element 8th as well as the valve seat 9 are at least partially in the fluid space 10 arranged. The fluid space 10 is in permanent fluid communication with four exhaust ports 11 , wherein in the section of the solenoid valve shown here 1 only two of the outlet channels 11 are recognizable. The outlet channels 11 each with a Fluidauslassanschluss 12 of the solenoid valve 1 in fluid communication. On the other side they open with a mouth 13 in the fluid space 10 one.

The fluid outlet connections 12 are in a lateral surface 14 the closure element 6 or the valve body 2 intended. Through the outlet channel 11 or the fluid outlet port 12 from the solenoid valve 1 thus flowing fluid has at least one radial velocity component. The estuary 13 is in a base surface 15 a pedestal 16 educated. Here is the base surface 15 opposite a floor surface 17 of the valve body 2 Angled, so it is not parallel to this. The outlet channel 11 is perpendicular to this base surface over its entire longitudinal extent 15 educated. In this way, a production of the outlet channel 11 simplified. This is often made by drilling. Due to the vertical design of the outlet channel 11 to the base surface 15 A running away of the drill during machining or drilling is avoided.

The base 16 is as a circumferential collar 18 formed, so includes the valve seat 9 completely in the circumferential direction. Here is the collar 18 in its radially outer region (with respect to a longitudinal axis 19 of the solenoid valve 1 ) opposite the floor surface 17 higher than in its radially inner region. The base 16 can, in particular in its radially inner region, in the bottom surface 17 run continuously, so have no jump or the like at this point. However, it is not intended that the entire floor area 17 is angled so that a vertical formation of the outlet channels 11 on this is possible. Rather, it is envisaged that the pedestal 16 the base surface 15 and a radially outer transition surface 20 which is from a vertex 21 of the pedestal 16 relatively steep in the floor area 17 opens.

In this way, the pedestal forms 16 at least partially a diffuser 22 for that the fluid space 10 flowing fluid out. Thus, in an at least partial displacement of the sealing element 8th in the direction of the release position into the fluid space 10 inflowing fluid over the collar 18 steered, causing a reduction in the armature or on the actuator 7 caused by the fluid force is effected. The fluid is in the solenoid valve 1 through an inlet channel 23 which has a fluid inlet port 24 on a front side 25 of the solenoid valve 1 or the valve body 2 having. In the area of the fluid inlet connection 24 is in the inlet channel 23 a filter element 26 arranged, for example, in the fluid inlet port 24 pressed in and held there by clamping. Like from the 1 as can be seen, the inlet channel runs 23 from the fluid inlet port 24 coaxial or parallel to the longitudinal axis 19 of the solenoid valve 1 up to the valve seat 9 ,

It can also be seen that the fluid outlet ports 12 on the valve body 2 on the same side with respect to the valve seat 9 are arranged as the fluid inlet port 24 , In the example shown here, both the fluid outlet ports 12 as well as the fluid inlet port 24 below the valve seat 9 intended. Around the mouth 13 the fluid outlet port in the fluid space 10 and the fluid outlet port 12 on the lateral surface 14 and at the same time on the same side with respect to the valve seat 9 as the fluid inlet port 24 to arrange, are the outlet channels 12 opposite the longitudinal axis 19 of the solenoid valve 1 bent. This means that they are not parallel or coaxial with them. At the same time it is envisaged that the distance between Fluidauslassanschluss 12 and valve seat 9 in the axial direction is smaller than the distance between the fluid inlet port 24 and valve seat 9 ,

The 2 shows a sectional view of the closure element 6 of the valve body 2 , Here are the mouths 13 the outlet channels 11 and the fluid outlet ports 12 on the lateral surface 14 of the valve body 2 recognizable. It can also be seen that the valve seat 9 is frustoconical and has a connection opening 27 which part of the inlet channel 23 but has a smaller diameter than the other areas of the inlet channel 23 , a fluid connection to the fluid inlet port 24 is made. The closure element 6 of the valve body 2 corresponds to that in the 1 Shown. In this respect, reference is made to the preceding statements.

The 3 shows an isometric view of the closure element 6 of the valve body 2 , The closure element 6 again corresponds to the already on the basis of 1 and 2 described. Here, too, reference should be made to the above statements.

Claims (10)

Magnetic valve ( 1 ) with a valve body ( 2 ), wherein in the valve body ( 2 ) a valve seat ( 9 ), at least one with a fluid space ( 10 ) in fluid connection outlet channel ( 11 ) with a fluid outlet port ( 12 ) and by releasing the valve seat ( 9 ) by a sealing element ( 8th ) with the fluid space ( 10 ) in fluid communication inlet channel ( 23 ) with a fluid inlet port ( 24 ) of the solenoid valve ( 1 ) are provided, wherein the fluid inlet port ( 24 ) on the front side ( 25 ) of the solenoid valve ( 1 ), characterized in that the fluid outlet port ( 24 ) on the valve body ( 2 ) on the same side with respect to the valve seat ( 9 ) as the fluid inlet port ( 24 ) is arranged. Solenoid valve according to claim 1, characterized in that the outlet channel ( 11 ) at least in regions relative to the longitudinal axis ( 19 ) of the solenoid valve ( 1 ) is angled. Solenoid valve according to one of the preceding claims, characterized in that the outlet channel ( 11 ), starting from the fluid space ( 10 ), with the fluid outlet port ( 12 ) in a lateral surface ( 14 ) of the valve body ( 2 ) opens. Solenoid valve according to one of the preceding claims, characterized in that the distance between the fluid outlet connection ( 12 ) and valve seat ( 9 ) in the axial direction is smaller than the distance between the fluid inlet port ( 24 ) and valve seat ( 9 ). Solenoid valve according to one of the preceding claims, characterized in that the outlet channel ( 11 ) by a base surface ( 15 ) of a socket ( 16 ) into the fluid space ( 10 ), which faces a floor surface ( 17 ) of the fluid space ( 10 ) is angled. Solenoid valve according to one of the preceding claims, characterized in that the outlet channel ( 11 ) at least partially perpendicular to the base surface ( 15 ) is trained. Solenoid valve according to one of the preceding claims, characterized in that the base ( 16 ) an at least partially circumferential collar ( 18 ) in the fluid space ( 10 ) trains. Solenoid valve according to one of the preceding claims, characterized in that the base ( 16 ) at least a portion of a diffuser ( 22 ) for a fluid space ( 10 ) forms fluid flowing through. Solenoid valve according to one of the preceding claims, characterized in that in the inlet channel ( 23 ) a filter element ( 26 ) is arranged. Driver assistance device, in particular ABS, TCS or ESP device, with at least one valve body ( 2 ) having magnetic valve ( 1 ), in particular according to one or more of the preceding claims, wherein in the valve body ( 2 ) a valve seat ( 9 ), at least one with a fluid space ( 10 ) in fluid connection outlet channel ( 11 ) with a fluid outlet port ( 12 ) and by releasing the valve seat ( 9 ) by a sealing element ( 8th ) with the fluid space ( 10 ) in fluid communication inlet channel ( 23 ) with a fluid inlet port ( 24 ) of the solenoid valve ( 1 ) are provided, wherein the fluid inlet port ( 24 ) on the front side ( 24 ) of the solenoid valve ( 1 ), characterized in that the fluid outlet port ( 12 ) on the valve body ( 2 ) on the same side with respect to the valve seat ( 9 ) as the fluid inlet port ( 24 ) is arranged.

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