Bistable Solenoid Valve for a Hydraulic Brake System, Activation Method and Assembly Method for the Same, and Brake System Having a Solenoid Valve of Said Type

Abstract

A bistable solenoid valve for a hydraulic brake system has a guide sleeve in which an upper immovable pole core is fixedly arranged and a closing element is displaceably arranged. The closing element is forced into a valve seat during a closing movement and lifts off from the valve seat during an opening movement, and is fixedly connected to a magnet assembly. An actuation of the movement of the closing element is performed by the magnet assembly via a coil positioned around and substantially surrounding the guide sleeve. A lower immovable pole core is fixedly arranged in the guide sleeve and the magnet assembly is positioned between the lower and the upper pole core.

Claims

1. A bistable solenoid valve for a hydraulic brake system, comprising: a guide sleeve; an upper non-moving pole core fixedly arranged in the guide sleeve; a valve seat; a closing element movably arranged in the guide sleeve and configured to enter the valve seat during a closing movement and lift out of the valve seat during an opening movement; a magnet assembly to which the closing element is fixedly connected; a coil positioned around the guide sleeve and substantially enclosing the guide sleeve, the coil configured to actuate movement of the closing element via the magnet assembly; and a lower non-moving pole core fixedly arranged in the guide sleeve, the magnet assembly positioned between the lower pole core and the upper pole core.

2. The bistable solenoid valve as claimed in claim 1, wherein the magnet assembly is molded onto the closing element.

3. The bistable solenoid valve as claimed in claim 1, wherein the magnet assembly has a first side facing the upper pole core and a second side facing the lower pole core, the first and second sides having magnetic poles with the same polarity.

4. The bistable solenoid valve as claimed in claim 1, wherein the magnet assembly comprises two permanent magnets.

5. The bistable solenoid valve as claimed in claim 4, wherein the two permanent magnets are positioned oppositely relative to one another.

6. The bistable solenoid valve as claimed in claim 4, wherein the two permanent magnets are separated from one another by an insulation.

7. The bistable solenoid valve as claimed in claim 1, wherein the lower non-moving pole core is pressed into the guide sleeve.

8. The bistable solenoid valve as claimed in claim 1, wherein at least one of the lower pole core and the upper pole core is positioned at least partially within the coil.

9. The bistable solenoid valve as claimed in claim 1, wherein the closing element consists of non-magnetizable material.

10. A method for controlling a bistable solenoid valve that includes a guide sleeve; an upper non-moving pole core fixedly arranged in the guide sleeve; a valve seat a closing element movably arranged in the guide sleeve and configured to enter the valve seat during a closing movement and lift out of the valve seat during an opening movement a magnet assembly to which the closing element is fixedly connected; a coil positioned around the guide sleeve and substantially enclosing the guide sleeve, the coil configured to actuate movement of the closing element via the magnet assembly; and a lower non-moving pole core fixedly arranged in the guide sleeve, the magnet assembly positioned between the lower pole core and the upper pole core, the method comprising: energizing the solenoid valve in a first current direction to magnetize the upper pole core and the lower pole core in such a way that the upper pole core repels a first permanent magnet of the magnet assembly that is associated with the upper pole core and the lower pole core attracts a second permanent magnet of the magnet assembly that is associated with the lower pole core; and energizing the solenoid valve in a second current direction to magnetize the upper pole core and the lower pole core in such a way that the lower pole core repels the second permanent magnet and the upper pole core attracts the first permanent magnet.

11. A method for assembling a bistable solenoid valve that includes a guide sleeve; an upper non-moving pole core fixedly arranged in the guide sleeve; a valve seat; a closing element movably arranged in the guide sleeve and configured to enter the valve seat during a closing movement and lift out of the valve seat during an opening movement; a magnet assembly to which the closing element is fixedly connected; a coil positioned around the guide sleeve and substantially enclosing the guide sleeve, the coil configured to actuate movement of the closing element via the magnet assembly; and a lower non-moving pole core fixedly arranged in the guide sleeve, the magnet assembly positioned between the lower pole core and the upper pole core, the method comprising: connecting the upper pole core to the guide sleeve, positioning the closing element in the lower pole core, inserting the closing element, together with the lower pole core, into the guide sleeve, positioning the lower pole core, together with the closing element, in the guide sleeve, and connecting the lower pole core and the closing element to said guide sleeve in a fourth step, or connecting the upper pole core to the guide sleeve, positioning the closing element in the guide sleeve, inserting the lower pole core into the guide sleeve, positioning the lower pole core in the guide sleeve, and connecting the lower pole core to said guide sleeve.

12. A hydraulic brake system for a motor vehicle, comprising at least one solenoid valve configured as the bistable solenoid valve as claimed in claim 1, the at least one solenoid valve configured for controlling a brake fluid.

13. The bistable solenoid valve as claimed in claim 3, wherein the first and second sides of the magnet assembly both have magnetic south pole or magnetic north pole polarity.

14. The bistable solenoid valve as claimed in claim 1, wherein the magnet assembly comprises a plurality of permanent magnets.

15. The bistable solenoid valve as claimed in claim 9, wherein the closing element consists of non-magnetizable plastic.

Description

IN THE FIGURES

[0040] FIG. 1 shows a schematic sectional view of a bistable solenoid valve according to one embodiment of the invention; and

[0041] FIG. 2 shows a view of a detail of the closing element and of the magnet assembly according to one embodiment of the invention; and

[0042] FIG. 3 shows a basic outline of the effective forces and movements given different energization according to one embodiment of the invention.

[0043] FIG. 1 shows a schematic sectional view of a bistable solenoid valve. In this case, the solenoid valve 1 has a guide sleeve 2. An upper pole core 5 and a lower pole core 6 are anchored in said guide sleeve 2. Furthermore, a closing element 3 is positioned in a movable manner in the guide sleeve 2. A magnet assembly 8 is connected to said closing element 3 in a fixed manner. Said magnet assembly 8 consists of two permanent magnets 8 and 8. The two permanent magnets 8 and 8 are separated from one another by an insulation 9. In a lower position, the closing element 3 interacts with the valve seat 4 in a sealing manner, as illustrated in FIG. 1. In the event of a deflection out of said position, the closing element 3 releases the valve seat 4 and allows a hydraulic medium to flow. In this case, the closing element 3 runs through a hole in the lower pole core 6 and is guided in this way. Furthermore, a coil 7 is pushed onto the guide sleeve 2. Said coil 7 encloses the entire periphery of the guide sleeve 2. The length of the coil 7 or the position of the upper pole core 5 and lower pole core 6 are selected, or matched to one another, such that the coil 7 at least partially encloses the upper pole core 5 and the lower pole core 6. In this case, the pole cores 5, 6 each protrude into the field coil, that is to say the coil 7, and fill part of the length of said coil.

[0044] FIG. 2 shows a view of a detail of a closing element and of the magnet assembly. In this case, the permanent magnet assembly 8 is formed from an upper permanent magnet 8 and a lower permanent magnet 8. The two permanent magnets 8 and 8 are arranged in a manner separated from one another by the insulation 9. Furthermore, the permanent magnets 8 and 8 have a hole through which the closing element 3 is guided. In this case, the closing element 3 is formed from plastic. By way of example, an injection-molding method is used for production. A fixed connection between the magnet assembly 8 and the closing element 3 is ensured by molding-on and undercutting.

[0045] FIG. 3 shows a basic outline of the effective forces and movements given different energization. In this case, the illustration on the left-hand side shows a magnetic field line of a resulting magnetic field and effective forces given first energization. Here, a polarized magnetic field is generated by means of applying a defined first (for example positive) voltage to the coil 7. The illustrated oval line shows, by way of example, a magnetic field line. The upper pole core 5 and the lower pole core 6 are also magnetized by said magnetic field. The magnetization of the pole cores (and also the magnetic field which is generated by the coil 7) leads to interaction with the magnet assembly 8. For example, the magnet assembly 8 (more precisely the lower permanent magnet 8) is repelled by the lower pole core 6 which is magnetized in a polarized manner. At the same time, the magnet assembly 8 (more precisely the upper permanent magnet 8) is attracted by the upper pole core 5 which is magnetized in a polarized manner. This results in a movement of the axially movable magnet assembly 8, and also of the closing element 3 which is connected to said magnet assembly in a fixed manner, to the upper position. This force and also the resulting movement are illustrated by the upwardly directed arrow. In the upper position, the closing element 3 is held by the magnetic force of the magnet assembly 8 (in particular of the upper permanent magnet 8) even after the energization of the coil 7 is removed. Therefore, the solenoid valve 1 is in a stable open state. Furthermore, the illustration on the right-hand side of FIG. 3 shows the magnetic field and effective forces given second energization. Here, a magnetic field which is polarized oppositely to the first defined voltage is generated by means of applying a defined second (for example negative) voltage to the coil 7. In an analogous manner to the previous description, the magnet assembly 8 (more precisely the lower permanent magnet 8) is repelled by the upper pole core 5 which is magnetized in an oppositely polarized manner. At the same time, the magnet assembly 8 (more precisely the upper permanent magnet 8) is attracted by the lower pole core 6 which is magnetized in an oppositely polarized manner. This results in a movement of the axially movable magnet assembly 8, and also of the closing element which is connected to said magnet assembly in a fixed manner, to the lower position. In the lower position, the closing element is held by the magnetic force of the magnet assembly 8 (in particular of the lower permanent magnet 8) even after the energization of the coil 7 is removed. Therefore, the solenoid valve 1 is in a stable closed state.