EP1636518A2

EP1636518A2 - Electromagnetic valve

Info

Publication number: EP1636518A2
Application number: EP03789180A
Authority: EP
Inventors: Christoph Voss
Original assignee: Continental Teves AG and Co OHG
Current assignee: Continental Teves AG and Co OHG
Priority date: 2002-12-13
Filing date: 2003-12-09
Publication date: 2006-03-22
Also published as: US20060017033A1; JP2006516703A; WO2004055420A3; WO2004055420A2

Abstract

The invention relates to an electromagnetic valve comprising a valve receiving body (3) into which a section of a first tubular body (1), located opposite a second tubular body (2), is inserted in such a way that it is tight in relation to a pressurised medium. The section of the second tubular body (2), which is adjacent to the first tubular body (1), is fixed to the valve receiving body (3), and the section of the first tubular body (1), which is adjacent to the second tubular body (2), is inserted into the second tubular body (2). The first tubular body (1) lies against an abutment surface (6) of the second tubular body (2), creating a simple, tight tubular connection.

Description

Solenoid valve

The invention relates to an electromagnetic valve according to the preamble of claim 1.

From DE 199 28 750 AI an electromagnetic valve of the closed type in the basic position has become known, the two tubular bodies of which are welded or folded together to form the valve housing. The manufacturing effort required for this is relatively high.

The object of the invention is to produce an electromagnetic valve of the specified type with as little effort as possible, so that a welded or seam connection between the two tubular bodies can be dispensed with.

This object is achieved for an electromagnetic valve of the type specified with the characterizing features of claim 1.

Further features, advantages and possible uses of the invention emerge from the subclaims and the following description of several exemplary embodiments.

Show it:

FIG. 1 shows a longitudinal section through an electromagnetic valve which is caulked in a stepped bore in a valve receiving body, FIG. 2 shows the electromagnetic valve according to FIG. 1 before caulking by means of a caulking tool in the valve receiving body,

FIG. 3 shows a longitudinal section through an electromagnetic valve designed as a two-stage valve, the further valve closing element of which is guided directly in the first tubular body,

Figure 4 shows a longitudinal section through an electromagnetic valve designed as a two-stage valve, the further valve closing member is guided in a spring stop inserted separately in the tubular body.

1 shows, in a considerably enlarged illustration, a longitudinal section through a solenoid valve which is closed in the basic position, with a valve housing which accommodates a magnet armature 9, a magnet core part 10, a valve closing member 11 and a valve seat 12 and which is formed from a first and a second tubular body 1, 2 is, the two tubular bodies 1, 2 are joined in sections with their open ends facing each other coaxially. The electromagnetic valve is fastened in a block-shaped valve receiving body 3, in which the tube section of the first tube body 1 facing away from the second tube body 2 is inserted in a pressure-tight manner. The tubular section of the second tubular body 2 facing away from the first tubular body 1 carries a magnetic coil 13 outside the valve receiving body 3. The magnetic coil 13 extends along the plug-shaped magnetic core part 10, which closes the end of the second tubular body 2 protruding from the valve receiving body 3. Located between the magnetic core part 10 and the valve seat 12 formed on the bottom of the first pot-shaped tubular body 1 is the magnet armature 9 which carries the valve closing member 11 and which runs along the inner wall of the second tubular body 2 is led. Due to the action of a compression spring 14 clamped between the magnet core part 10 and the magnet armature 9, the valve closing member 11, which is pressed as a ball into the end of the magnet armature 9, closes the pressure medium opening in the valve seat 12 in the basic position shown in the illustration. The valve seat 12 is preferably precise and nevertheless inexpensive by means of an embossing process molded into the bottom of the deep drawn second tubular body 2. The lateral surface of the second tubular body 2 has, at the level of a transverse channel 15 penetrating the valve receiving body 3, a further opening 17 which, like the opening 16 in the valve seat 12, is produced by an embossing process. A ring filter 18 which is supported in the stepped bore 5 on a collar 4 of the second tubular body 2 and below the opening 17 on the first tubular body 1 prevents dirt from penetrating into the magnet armature space from the direction of the transverse channel 15. A channel opening into the stepped bore 5 below the valve seat 12 also has a filter if desired or required.

The invention provides that the section of the second tubular body 2 facing the first tubular body 1 is fastened directly to the valve receiving body 3 and that the section of the first tubular body 1 facing the second tubular body 2 is inserted into the second tubular body 2 and is attached to a stop surface 6 of the second tubular body 2 supports. This enables a particularly simple, tight and secure connection of the first tubular body 1 to the second tubular body 2 within the valve receptacle body 3 by simply pressing the two tubular bodies 1, 2 with the individual valve parts functionally pre-assembled therein into the stepped bore 5 using a caulking tool 19 without the need for a welded or folded joint. An amazingly simple fixation of the tubular body 2 is obtained if the end of the second tubular body 2 facing the valve receiving body 3 has a radially outwardly directed collar 4, for example in the form of a stock ice, which is fastened in a stepped bore 5 of the valve receiving body. An absolutely tight, non-detachable fastening of the collar 4 in the stepped bore 5 takes place through the plastic deformation of the material of the valve receiving body 3 by means of the caulking tool 19, which encloses the collar 4 at least along its edge.

To produce the stop surface 6, the second tubular body 2 is provided with a housing step 7, the inner diameter of which is chosen to be smaller at the end of the joining section 8 of both tubular bodies 1, 2 than the outside diameter of the first tubular body 1 in the region of the joining section 8. The housing step 7 is also through a plastic deformation of the second tubular body 2 in the end region of the joining section 8 is produced inexpensively and is preferably carried out as a double offset.

The first and second tubular bodies 1, 2 consist of thin-walled sleeves manufactured using the deep-drawing process, which are connected to one another in the joining section 8 by means of an interference fit.

The first, pot-shaped tubular body 1 is supported with its end facing away from the joining section 8 in the second tubular body 2 in the stepped bore 5 of the valve receiving body 3, the axial distance X between the bottom of the pot of the first tubular body 1 and the bottom of the stepped bore 5 being smaller than that Length L of the overlap of both tubular bodies 1, 2 in the region of the joining section 8, so that even if the press connection between the first and second tubular bodies 1, 2 is loosened, the overlap is sufficient two tubular body 1, 2 remains in the joining section 8 to ensure the functionality.

2 shows, differently from the illustration according to FIG. 1, the electromagnetic valve during assembly in the valve receiving body 3, for which purpose the hollow cylindrical caulking tool 19 is placed over the second tubular body 2 and is located on the inner circumference with an inner shoulder 20 on the housing step 7 and with its outer shoulder 21 on Bund 4 supports. The outer circumference of the caulking tool 19 is provided with two housing stages 22, 23, to which a conical section 24 connects in the direction of the flat outer shoulder 21. This results in a caulking tool 19 which decreases in the direction of the stepped bore 5 in the outer diameter and which, by means of the second housing stage 23, displaces the material of the bore stage of the valve receiving body 3 in the direction of the conical section 24 until finally the first housing stage 22 also bears against the undeformed housing section of the stepped bore 5 , When the first housing stage 22 is placed on the non-deformable housing section of the stepped bore 5, the conical caulking point shown in FIG. 1 is produced on the collar 4, which ensures a tight and firm connection of the electromagnetic valve to the valve receiving body 3.

FIGS. 3 and 4 each show in a considerably enlarged illustration a longitudinal section through a solenoid valve which is closed in the basic position and whose valve housing has a magnet armature 9, a magnet core part 10, two valve closing elements 11, 25 and two valve seats 12, 26 and consists of a first and a second tubular body 1 , 2 is formed, wherein the two tubular bodies 1, 2 are pressed in sections with their open ends facing each other coaxially. In addition, it is pointed out that all other individual parts cited are also in a specified are arranged coaxially within the valve housing.

3, 4 is fastened in a block-shaped valve receiving body 3, in which the pipe section of the first pipe body 1 facing away from the second pipe body 2 is inserted so as to be pressure-tight. The tubular section of the second tubular body 2 facing away from the first tubular body 1 carries a magnetic coil 13 outside the valve receiving body 3. The magnetic coil 13 extends along the plug-shaped magnetic core part 10, which closes the end of the second tubular body 2 protruding from the valve receiving body 3. Located between the magnetic core part 10 and the first pot-shaped tubular body 1 is the magnet armature 9, which carries the valve closing member 11 and is guided along the inner wall of the second tubular body 2. Due to the action of a compression spring 14 clamped between the magnet core part 10 and the magnet armature 9, the spherical valve closing member 11, which is provided with a plunger and is pressed into the open end of the magnet armature 9, closes the diaphragm-shaped opening 27 of the further valve closing member 25, in the bottom of the pot of which, in the pot bottom so-called further valve seat 26 which delimits the opening 27 is arranged. The valve seat 26 is preferably inexpensively and precisely molded into the bottom of the valve closing member 25 by an embossing process.

The so-called further valve closing member 25 consists of a sleeve pot which is axially movable in the first tubular body 1, deep-drawn from thin sheet metal and, if necessary, also heat-treated, the pot bottom of which performs the actual function of the valve closing member 25 (to a certain extent in the function of a valve piston), which under the force of the compression spring 14 in the basic position is pressed sealingly against the valve seat 12 fixed in the first tubular body 1. 3, 4 that the inner diameter of the first tubular body (1) is at least partially adapted to the outer diameter of the further valve closing member 25 for the precise reception and guidance of the further valve closing member 25 corresponding to the valve closing member 11. Here, a sufficiently dimensioned clearance fit between the first tubular body 1 and the outer wall of the cup-shaped valve closing member 25 is to be provided, so that the further valve closing member 25 can move without jamming and center on the valve seat 12.

In FIG. 3, the valve seat 12 is designed as a solid valve plate that can be handled separately, which is alternatively inexpensively and precisely molded directly into the bottom of the deep-drawn first tubular body 1 by an embossing process in FIG.

In FIGS. 3, 4, the lateral surface of the first tubular body 1 has a plurality of openings 17 at the level of a transverse channel 15 opening laterally into the valve receiving body 3, which opening is also produced by an embossing process, like the aperture-shaped opening 27 arranged in the bottom of the valve closing member 25. A ring filter 18 supported in the stepped bore 5 on a collar 4 of the second tubular body 2 and below the opening 17 on the first tubular body 1 prevents dirt from entering the valve housing from the direction of the transverse channel 15. Of course, a channel opening into the stepped bore 5 below the valve seat 12 can also be provided with a filter if desired or required.

In FIGS. 3, 4 the section of the second tubular body 2 facing the first tubular body 1 is directly on Valve receiving body 3 attached, wherein the portion of the first tubular body 1 facing the second tubular body 2 is inserted into the second tubular body 2 as a press connection and is supported on a stop surface 6 of the second tubular body 2. This enables a particularly simple, tight and secure connection of the first tubular body 1 to the second tubular body 2 within the valve receptacle body 3 by simply pressing the two tubular bodies 1, 2 with the individual valve parts functionally pre-assembled therein, into the stepped bore 5 using a caulking tool without the need for a welded or folded joint.

Furthermore, a spring stop 28 is provided in both figures to support a further compression spring 29 on the first tubular body 1. The further compression spring 29 is clamped between the spring stop 28 and the further valve closing member 25, so that the further compression spring 29 counteracts the compression spring 14, which is arranged between the magnet armature 9 and the magnet core part 10, in a simple manner.

In order to be able to support one end of the further compression spring 29 on the valve closing member 25 as simply as possible, the sleeve end of the valve closing member 25 facing away from the pot bottom is bent radially outward in the direction of the first tubular body 1 to form a collar 30.

In the embodiment according to FIG. 3, the spring stop 28 is produced directly and particularly cost-effectively by a step of the first tubular body 1 that is constricted stepwise in the deep-drawing process.

In contrast, in the exemplary embodiment according to FIG. 4, the spring stop 28 is preferred as one separately in the first Inserted tubular body 1, thin-walled deep-drawn guide sleeve, which at its lower sleeve end, through which the further valve closing member 25 extends in the direction of the valve seat 12, has a bent edge in the direction of the sleeve longitudinal axis, on which one end of the compression spring 29 rests. The sleeve-shaped spring stop has a guide section in the overlap region of the two tubular bodies 1, 2, which lies against the inner wall of the first tubular body 1 without play, in order to center the spring stop 28 well in the valve housing.

Instead of the guide sleeve, the design of the spring stop 28 as an insert in the form of a flat disk would alternatively also be conceivable.

In summary, it can now be stated that the clever design of the electromagnetic valve in the area of the first tubular body 1 creates optimal structural conditions in order to present the electromagnetic valve as a two-stage valve in a particularly space-saving manner with the fewest possible components that are easy to manufacture.

The electromagnetic valve has a pre-throttle stage formed from the valve closing member 11 and the further valve seat 26 and a main stage. The pre-throttling stage is effective when the magnet armature 9 is electromagnetically excited by lifting the valve closing member 11 from the (further) valve seat 26, as a result of which the diaphragm-shaped opening 27 is released by the valve closing member 11. The throttle-free main stage is only effective when the pre-throttle stage is open and in the balance of forces the valve opening force exerted by the compression spring 29 exceeds the hydraulic forces acting on the valve closing member 25, so that the valve closing member 25 essentially formed by the pot bottom under the action of the compression spring 29 dated Valve seat 11 lifts, whereby the large flow cross section of the opening 16 is released.

LIST OF REFERENCE NUMBERS

1 tubular body

2 tubular bodies

3 valve body

4 fret

5 stepped holes

6 stop surface

7 housing level

8 joining section

9 magnetic armatures

10 magnetic core part

11 valve closing member

12 valve seat

13 solenoid

14 compression spring

15 cross channel

16 opening

17 opening

18 ring filter

19 caulking tool

20 inner shoulder

21 outer shoulder

22 housing level

23 housing level

24 cone section

25 valve closing member

1 26 valve seat

27 opening

28 spring stop

29 compression spring

30 collar

Claims

claims

1. Solenoid valve with a valve housing receiving a magnet armature, a magnetic core part, a valve closing member and a valve seat, which is formed from a first and a second tubular body, the ends of which are joined together in sections and have a joining section, with a valve receiving body into which the Section of the first tubular body facing away from the second tubular body is inserted in a pressure-tight manner, the portion of the second tubular body facing away from the first tubular body carrying a magnetic coil outside the valve receiving body, characterized in that the first tubular body

(1) facing section of the second tubular body (2) is fastened to the valve receiving body (3) and that the section of the first tubular body (1) facing the second tubular body (2) is inserted into the second tubular body (2) and onto a stop surface (6 ) of the second tubular body (2) is directed.

2. Electromagnetic valve according to claim 1, characterized in that the end of the second tubular body (2) facing the valve receiving body (3) has a radially outwardly directed collar (4) which is fastened in a stepped bore (5) of the valve receiving body.

3. Electromagnetic valve according to claim 2, characterized in that the fastening of the collar (4) in the Stuferi bore (5) by the plastic deformation of the material of the valve receiving body (3) which surrounds the collar (4). Electromagnetic valve according to claim 1, characterized in that for producing the stop surface (6) the second tubular body (2) is provided with a housing step (7), the inner diameter of which is selected to be smaller at the end of the joining section (8) of both tubular bodies (1, 2) than the outer diameter of the first tubular body (1) in the region of the joining section (8).

Electromagnetic valve according to claim 4, characterized in that the housing stage (7) is produced by plastic deformation of the second tubular body (2) in an end region of the joining section (8) which is located at a distance from the open end of the second tubular body (2).

Electromagnetic valve according to claim 5, characterized in that the housing stage (7) is produced by a double offset in the end region of the joining section (8).

Electromagnetic valve according to claim 4, characterized in that the first and second tubular bodies (1, 2) consist of sleeves which are thin-walled in the deep-drawing process and are connected to one another by means of a press fit in the joining section (8).

Electromagnetic valve according to claim 4, characterized in that the end of the first tubular body (1) is supported with its end facing away from the joining section (8) in a stepped bore (5) of the valve receiving body (3), the axial distance (X) between the first tubular body ( 1) and a bottom of the stepped bore

(5) is less than the length (L) of the overlap of both tubular bodies (1, 2) in the region of the joining section

(8th) .

9. Electromagnetic valve according to claim 5, characterized in that the housing stage (7) and / or the collar (4) for mounting and caulking the second tubular body (2) in the valve receiving body (3) is a hollow cylindrical

Take up the caulking tool (19), which is supported with its inner shoulder (20) on the housing step (7) and / or with its outer shoulder (21) on the collar (4).

10. Solenoid valve according to claim 9, characterized in that the outer circumference of the caulking tool (19) is provided with two housing stages (22, 23), to which a conical section (24) connects in the direction of the planar outer shoulder (21), and by means of the second housing stage (23) the material of the bore stage of the valve receiving body (3) is displaced in the direction of the cone section (24).

11. Electromagnetic valve according to claim 1, characterized in that for receiving a further valve closing member (25) corresponding to the valve closing member (11), the inside diameter of the first tubular body (1) is adapted at least in sections to the outside diameter of the further valve closing member (25).

12. Electromagnetic valve according to claim 11, characterized in that the further valve closing member (25) is formed from a sleeve pot guided in the first tubular body (1), the pot bottom of which, under the action of a pressure spring (14), seals in the basic position against the valve seat (12) is pressed.

13. Solenoid valve according to claim 12, characterized in that one of a further Ven- in the pot bottom tilsitz (26) limited opening (27) is arranged, which is closed in the basic valve position by the valve closing member (11).

14. Electromagnetic valve according to claim 11, characterized in that the first tubular body (1) has a spring stop (28) for supporting a further compression spring (29) which is clamped between the spring stop (28) and the further valve closing member (25), and that the further compression spring (29) counteracts the compression spring (14) arranged between the magnet armature (9) and the magnetic core part (10).

15. Electromagnetic valve according to claim 14, characterized in that the further valve closing member (25) at its sleeve end facing away from the pot bottom is bent radially outwards to form a collar (30) on which one end of the further compression spring (29) is supported.

16. Electromagnetic valve according to claim 14, characterized in that the spring stop (28) is formed directly by a step-like constricted shoulder of the first tubular body (1).

17. Electromagnetic valve according to claim 14, characterized in that the spring stop (28) is formed either by a guide sleeve inserted separately into the first tubular body (1) or by a flat disk through which the further valve closing member (25) is located Direction of the valve seat (12) extends.