DE4243674A1 - Magnetic valve, esp. for hydraulically operable route valve - Google Patents

Abstract

The magnetic valve includes a magnetic yoke (25) and coil (26). A housing (10) includes the electromagnet (12) in a bore (11). Two channels are included, one (43) in the housing and linked with the other channel (40). An anchor plate (13) is located in a valve chamber (42) before the electromagnet.The first channel (40) allows flow of pressure fluid into the valve chamber. The anchor plate is pressure-equalised when the first channel is open in the direction of movement. The anchor plate attracted towards the electromagnet.

Description

The invention is based on a solenoid valve that has the features from the preamble of claim 1. Such a measure The solenoid valve is intended in particular as a pilot control valve for a hydraulically operated directional control valve can be used.

In use as a pressure control valve is a solenoid valve with the features from the preamble of claim 1 from the DE-AS 12 85 270 already known. The anchor plate is located there in one formed by the housing and the electromagnet Valve chamber and carries a valve cone with which it connects with a valve seat formed centrally on the magnetic yoke. As far as the cone is within the seat edge, it will acted upon by the high pressure in a supply line. Anson The valve plate is surrounded on all sides by the pressure medium, in which is at a lower pressure than in the feed line. The Pressure difference generated on an area that the valve seat a force in the opening direction is described on the anchor plate tion of the valve. They act in the closing direction of the valve Force one clamped between the housing and the anchor plate helical compression spring and the magnetic force.

From DE 37 04 504 C2 a solenoid valve is known, which if has an anchor plate. Within an additional Pipe section leads a first pressure medium channel centrally through the Magnetic yoke. The anchor plate is supported by a helical compression spring in the direction away from the electromagnet, i.e. away from the mouth of the first pressure medium channel in the valve chamber in which the anchor plate is located, loaded and is thereby out switched electromagnet just within its outer contour pressed against a collar of another piece of pipe. The valve is a safety valve in a cascade of gas centrifuges, thus intended for a gaseous medium. The flow Rich Scripture does not indicate that this medium is used.

The invention has for its object to provide a solenoid valve to design the features from the preamble of claim 1 ten that it as a switching valve, especially as a pilot control valve can be used and that it is made with few items can be produced inexpensively with good function.

This object is achieved by a solenoid valve solves that the features from the preamble of claim 1 points and in accordance with the characterizing part of the claim 1 the first pressure medium channel the inflow of pressure medium into the Serves valve chamber and in which the anchor plate when open Most pressure medium channel partially pressure-compensated in the direction of movement is similar and of the electromagnet against that because of the only partial pressure equalizing force is attractable. With egg No spring is necessary to the solenoid valve according to the invention to move the anchor plate. A partial pressure equalization will easily achieved in that the anchor plate on their the Mün formation of the first pressure medium channel opposite, second Page out of print within a certain area is acted upon when the first pressure medium channel to the valve chamber is open. So at the anchor plate he becomes a force witnesses that the anchor plate from the mouth of the first pressure with telkanals keeps away and ensures that the first pressure middle channel and the second pressure medium channel safely together stay connected. The only partial pressure equalization limits the force acting in the opening direction so that the electromagnet Anchor plate against this force can tighten to the first Seal the pressure medium duct.

Advantageous embodiments of a magnetic valve according to the invention tils can be found in the subclaims.

The solenoid valve can be designed as a 2/2-way valve. It is however also possible, according to claim 4, a third print to provide medium channel, which alternates with the first pressure with telkanal is connectable to the second pressure medium channel. This third pressure medium channel preferably opens on the second side the anchor plate centrally in the valve chamber and is alternating  seal with the first pressure medium channel from the anchor plate bar. The anchor plate can still be a closing member wear that is attached to it as a separate part.

So that the anchor plate si around the first pressure medium channel cher lies close to the magnetic yoke and thus possibly fine surface to be processed is small, is provided according to claim 5 hen that the first side of the An kerplatte in an area radially within the recess for the winding is normal to the axis of the electromagnet and outside of this area drops slightly to the outside. By This slight drop is due to the anchor plate resting against the Ma Ensure gnetjoch within the recess for the winding continuous

A partial pressure equalization on the anchor plate can e.g. B. can be obtained in that the bottom of the housing bore, the houses the electromagnet and the armature plate, one or has several surveys on which the anchor plate at fenem first pressure medium channel lies flat. The ge create surface area on both sides of the anchor plate leads to the force in at the same pressure on both sides Opening direction of the valve. Easier than surveys in the However, it seems to create such a hole exercise on the second side of the anchor plate where it should be can be turned during the manufacture of the anchor plate.

If there is a third pressure medium channel according to claim 4, so you get a non-pressure balanced anchor plate according to An Proverb 8 also by a central increase on the second page the anchor plate, with which the third pressure medium channel is closed like a cone seat. At the Area within the seat, the pressure does not work, so that force directed away from the mouth of the first pressure medium channel results on the anchor plate.

The anchor plate is advantageously ge on its outer circumference leads and has when the second pressure medium channel is radial  or on the second side of the anchor plate into the valve chamber flows according to claim 9 on its outer circumference or within its outer circumference at least one axially extending to the the first side of the armature facing the first pressure medium channel plate open towards, outside the mouth of the first pressure with passage. This is advantageous Passage also open to the second side of the anchor plate.

Even if the anchor plate is open when the first pressure medium channel is open closely around the opposite mouth of the second pressure Telkanals on the housing, a connection between the two pressure medium channels are produced in that the Anchor plate centrally a sack hole open to the second side tion and at least one radial bore opening into the blind bore tion. The radial bore can be made with one pass Claim 9 be connected or, if such does not exist is and the pressure medium in a gap between the outside catch the anchor plate and the housing flows, ver with the gap be bound. A simple solution is also when the through course so inclined that it is on the first side of the An kerplatte outside the mouth of the first pressure medium channel be starts and on the second side of the anchor plate inside the Mouth area of the second pressure medium channel ends. Should he Passage less sloping or even parallel to the axis of the An kerplatte run, so you can according to claim 12, the survey form a ring on the second side of the anchor plate, where then the passage within the elevation to the second side the anchor plate is open.

According to claim 13, the anchor plate has one on its outside catch circumferential groove. This is particularly advantageous when the second pressure medium channel opens radially into the valve chamber det. Then no special precautions need to be taken so that a located on the outer periphery of the anchor plate Passage or a radial bore and the second pressure medium ca are aligned with each other.  

If you want the first pressure medium channel and / or one opposite lying third pressure medium channel each ver conical seat can close, the anchor plate is advantageously with provided an additional closure part. According to the cheap Construction according to claim 14 is a ball as an additional Closure part used in a central bore of the anchor plate is pressed in on the first and / or on the two protrudes from the anchor plate and with which the first and / or the third pressure medium channel closes like a cone seat are cash.

The first pressure medium channel is pressure medium according to claim 15 preferably via a housing channel, an annular space between the magnetic yoke and the housing as well as a cross hole leads behind the recess for the winding in Ma gnetjoch is located. Then builds in the axial direction of the electromagnet the solenoid valve is not high.

The claim 16 contains a for the attachment of the Elektroma gneten in the housing bore and for sealing the ring space favorable training of the magnetic yoke and the bore. It should be noted that the configurations according to Merkma len 15 and 16 are also advantageous regardless of features from the preceding claims.

Several embodiments of a magnetic circuit according to the invention tils are shown in the drawings. Based on the figures these drawings, the invention will now be explained in more detail.

Show it

Fig. 1, the first embodiment, the anchor plate on its outer periphery a plurality of axial passages, having a central, bores open towards the second side pocket bore and a plurality of radial,

Fig. 2 shows a second embodiment, the anchor plate has axial passages, in turn, on its outer periphery, and also a perforated gutters central elevation on the two-hand side,

Fig. 3 shows a third embodiment in which the anchor plate has an annular elevation on its second side, within which axial passages end, and

Fig. 4, the fourth embodiment, in which, unlike the first three versions, not two, but three pressure medium channels are available and in which a ball is pressed as a closure part in a central bore of the anchor plate.

The magnetic valves shown include a housing 10 made of a non-magnetizable steel, into which a bore 11 is made, which receives the electromagnet 12 and an armature plate 13 . Three bore sections 14 , 15 and 16 can be distinguished at the bore 11 . The bore section 14 extends with a constant diameter from the outside into the depth of the housing 10 . In an inclined shoulder 17 of the bore portion 14 merges into the bore portion 15 through, the sen diameter slightly smaller than the diameter of portion 14 is approximately Boh. The bore section 14 is also approximately four times as long as the bore section 15 . At the bore section 15 adjoins the bore section 16 to the inside, the diameter of which is reduced once again compared to that of the bore section 15 , with a straight shoulder 18 being located between the two bore sections 15 and 16 .

The electromagnet 12 essentially comprises a magnetic yoke 25 made of a magnetizable material, in particular steel, and a winding 26 . The magnetic yoke has a rotationally symmetrical outer shape with a central axis coinciding with the axis of the bore 11 . With its front end face 27 it sits on the straight shoulder 18 , with its rear end face 28 it is flush with the outside of the housing 10 . Immediately at the rear end 28 , the magnetic yoke 25 has an annular bead 29 , the largest outer diameter of which corresponds to the diameter of the bore section 14 . Also subsequently on its front end 27 , the magnetic yoke 25 has an annular bead, which is designated 30, which is axially approximately as long as the bore section 15 and the largest outer diameter of which corresponds to the diameter of the bore section 15 . The diameter of the bore sections 14 and 15 and the annular beads 29 and 30 are coordinated so that there is a slight press fit between the housing 10 and the magnet yoke 25 .

The annular beads 29 and 30 seal an annular space 31 , which is located axially between the annular beads and radially between the magnet yoke 25 and the housing 10 , from the outside of the housing or to the bore section 16 . In the annular space opens out a housing channel 32 perpendicular to the axis of bore 11 aligns is.

The winding 26 is located in an annular recess 33 in the magnetic yoke 25 , which is open toward the front end face 27 . After the winding 26 has been inserted, the recess on the end face 27 is closed in a pressure-tight manner by two non-magnetic ring disks 34 and 35 and with a sealing compound 36 .

A first pressure medium channel 40 runs centrally in the magnetic yoke 25 in the axial direction and extends from the front end face 27 to behind the winding 26 . There it is connected to the annular space 31 via a transverse bore 41 of the magnetic yoke.

A valve chamber 42 , in which the armature plate 13 is located, is delimited by the electromagnet 12 and the bore section 16 . This extends up to close to the wall of the bore and is guided on its substantially circular outer contour in the bore section 16 in the axial direction. It also extends radially beyond the recess 33 into the region of the part of the magnetic yoke that is located outside the recess.

The embodiments according to FIGS. 1 to 3 are 2/2-way valves having a second pressure fluid channel 43 next to the pressure medium channel 40 facing away from the electromagnet 12, second side 44 of the anchor plate 13 aligned centrally to the pressure with telkanal 40 in the Valve chamber 42 opens. The anchor plate has on its second side 44 a central elevation 49 , with which it lies flat on the bottom of the bore 11 when the valve is open. Through this flat support, it is sufficient that the anchor plate 13 is not pressure compensated when the valve is open, that rather a force acts in the opening direction because of the larger magnet-side surface, provided that there is pressure in the lines and in the valve chamber. Because the bearing surface is smaller than the total area on the second side 44 of the anchor plate 13 , the size of this force acting in the opening direction is limited. It can still be overcome by the force of the electromagnet to close the valve. When the valve is closed, the armature plate 13 bears around the mouth of the first pressure medium channel 40 on the end face 27 of the magnetic yoke 25 . For a large overlap he ste 46 side to the inner edge of the recess 33 is completely flat and parallel to the end face 27 . From the inner edge of the recess 33 , as shown in FIGS. 1 to 3 for clarification, the page 46 drops slightly towards the outside. This has two advantages. It is ensured that a contact between the armature plate 13 and the electromagnet 12 takes place only radially within the inner edge of the recess 33 , because earlier contact outside of this inner edge is excluded by the taper when closing. In addition, if the surface of the anchor plate is machined, the size of the area to be machined is limited.

In the embodiment of Fig. 1, the armature plate 13 has on its outer contour a plurality of extending over the entire height of the armature plate 13 extending on both sides so axially open through passages 45. From the second side 44 a blind bore 47 is made centrally in the anchor plate 13 , the diameter of which corresponds to the diameter of the second pressure medium channel 43 and which is connected via a plurality of radial bores 48 , each with a passage 45 .

With the solenoid valve open, as shown in Fig. 1, a pressure medium from the first pressure medium channel 40 via the inter mediate space between the electromagnet 12 and the armature plate 13 via the passages 45 , the radial bores 48 and the blind hole 47 to the second pressure medium channel 43 reach. If the winding 26 of the electromagnet 12 is energized, the kerplatte 13 is used on the end face 27 of the magnet and closes the first pressure medium line 40 .

In Fig. 1 it is indicated with dashed lines that the second pressure medium channel can also open radially or eccentrically axially in the valve chamber 42 . In these cases, the radial holes 48 and the blind hole 47 are not necessary.

The anchor plate 13 of the embodiment of FIG. 2 has wesentli chen the same outer contour as that of the embodiment according to Fig. 1. There are also passages 45, but not the stanchions Radialboh and the blind bore present. Rather, the survey 49 is divided into individual sectors by individual radial channels 50 . When the valve is open, pressure medium passes through the passages 45 , along the second side 44 of the anchor plate 13 and through the grooves 50 to the second pressure medium channel 43 . The channels 50 slightly reduce the contact area of the anchor plate 13 at the bottom of the bore compared to the embodiment according to FIG. 1, provided that the elevation 49 has the same diameter as in FIG. 1. By increasing the diameter, you can get back to the same contact surface.

In the embodiment of Fig. 3, the elevation 49 on its second side 44 of the armature plate 13 is spaced from the Mün extension of the second pressure medium duct 43 and has a ring shape. Depending on the distance of the elevation 49 from the axis of the valve, the width of the ring can be chosen so that the contact surface is exactly as large as in the embodiments according to FIGS. 1 and 2. The passages 45 are formed in the embodiment according to FIG. 3 by bores which are open on both sides within the outer circumference of the armature plate 13 and parallel to the axis of the valve. These holes have on the first side 46 of the anchor plate 13 such a large distance from the first pressure medium channel 40 that when the valve is closed, sufficient tightness is guaranteed. On the other hand, the annular elevation 49 on the second side 44 of the anchor plate 13 is so far away from the second pressure medium channel 43 that the bores 45 on the second side 44 are located within the elevation 49 . When the valve is open, pressure medium can flow through the bores 45 from the first one to the second side of the anchor plate 13 and from there into the second pressure medium channel 43 .

The embodiment of FIG. 4 is a 3/2-way valve, wherein the second pressure fluid channel 43 opens out radially into the valve chamber 42. A third pressure medium channel 51 opens centrally on the second side 44 of the anchor plate 13 into the valve chamber 42 . The anchor plate has, as in the embodiments according to FIGS. 1 and 2, axially open passages 45 on both sides on its outer contour. In addition, a radially open annular channel 52 is placed around the anchor plate 13 . A ball 53 is fastened to the anchor plate 13 as a separate closure part in that it is pressed into a central through-hole 54 in the anchor plate 13 . The ball 53 protrudes on both sides above the anchor plate 13 and acts like a cone seat with the conically widening mouths of the first pressure medium channel 40 and the third pressure medium channel 51 .

If the electromagnet 12 is switched off and the first Druckmit telkanal 40 connected to a pressure source, the connec tion between the first pressure medium channel and the second pressure medium channel 43 is open. Pressure medium can flow on the side 46 of the kerplatte 13 along to the passages 45 , from there into the annular channel 52 and then into the pressure medium channel 43 . The anchor plate 13 is not pressure balanced since the surface of the ball 53 located within the seat edge on the third pressure medium channel 51 is not impacted by pressure or by a lower pressure. The third pressure medium channel 51 is generally connected to the tank. If the electromagnet is turned on, the armature plate 13 is pulled towards it. The ball moves away from the pressure medium channel 51 and lies in the mouth of the pressure medium channel 40 . Now a connection between the pressure medium channels 43 and 51 is created.

The solenoid valves shown can be built very small and are particularly advantageous for being used as pre-control valves for hydraulically operated directional valves. Here is z. B. to think of a circuit in which each two 2/2-way valves of the type according to the invention are each assigned to a side of a directional control valve. Via the one valve, one side of the directional control valve can be connected to a pressure source and the other directional control valve to a tank. To control the directional control valve, the one side with the pressure source and the other side with the tank connecting valve are brought into position by switching on the electromagnet. Two 2/2-way valves can also be replaced by a 3/2-way valve according to FIG. 4. In another control circuit, one side of a directional valve is connected to the tank via a nozzle and can be connected to a pressure source via a 2/2-way valve of the type according to the invention. If the pilot valve is actuated, i.e. blocked, then the pressure on one side of the directional control valve is released via the nozzle to the tank. When the magnet is switched off, i.e. the pilot valve is open, a control pressure builds up in front of the nozzle.

Claims (16)

1. solenoid valve, in particular pilot control valve, with an electromagnet ( 12 ) having a magnetic yoke ( 25 ) and a winding ( 26 ) which is located in an annular, one-sided axially open recess ( 33 ) of the magnetic yoke ( 25 ) with a housing ( 10 ) which receives the electroma ( 12 ) in a bore ( 11 ), and with an armature plate ( 13 ) which is placed in front of the electromagnet ( 12 ) in a valve chamber ( 42 ) into which a central and axially in the magnetic yoke (25) ver running and lockable through the anchor plate (13) or a stigtes her BEFE part (53) the first pressure fluid channel (40) and extending in the housing (10) with the first pressure medium channel (40) connectable to the second Pressure medium channel ( 43 ) open, characterized in that the first pressure medium channel ( 40 ) serves the inflow of pressure medium into the valve chamber ( 42 ) and that the anchor plate ( 13 ) with the first pressure medium channel ( 40 ) open in movement direction Seal is partially pressure balanced and can be attracted by the electromagnet ( 12 ) against the force acting due to the partial pressure compensation. 2. Solenoid valve according to claim 1, characterized in that the second pressure medium channel ( 43 ) on the mouth of the most pressure medium channel ( 40 ) opposite second side ( 44 ) of the anchor plate ( 13 ) preferably opens centrally into the valve chamber ( 42 ). 3. Solenoid valve according to claim 1, characterized in that the second pressure medium channel ( 43 ) opens radially into the valve chamber ( 42 ). 4. Solenoid valve according to claim 3, characterized in that a third pressure medium channel ( 51 ) on the mouth of the first pressure medium channel ( 40 ) opposite the second side ( 44 ) of the armature plate ( 13 ) centrally into the valve chamber ( 42 ) and that at open first pressure medium channel ( 40 ) the third pressure medium channel ( 51 ) is closed by the anchor plate ( 13 ). 5. Solenoid valve according to a preceding claim, characterized in that the electromagnet ( 12 ) facing, he ste side ( 46 ) of the armature plate ( 13 ) in a region radially within the recess ( 33 ) normal to the axis of the electromagnet ( 12 ) runs and falls slightly outside this area. 6. Solenoid valve according to a preceding claim, characterized in that the armature plate ( 13 ) is guided on its circumference. 7. Solenoid valve according to a preceding claim, characterized in that the armature plate ( 13 ) on its the electromagnet ( 12 ) facing away from the second side ( 44 ) has a centrally arranged ring or disc-like elevation ( 49 ) with which it open first pressure medium channel ( 40 ) rests flat on the Ge housing ( 10 ). 8. Solenoid valve according to claim 4 or according to claim 4 and claim 5 or 6, characterized by a central elevation ( 53 ) on the second side ( 44 ) of the anchor plate ( 13 ) with the third pressure medium channel with the first pressure medium channel ( 40 ) open ( 51 ) is closed like a cone seat. 9. Solenoid valve according to a preceding claim, characterized in that the armature plate ( 13 ) on its outer circumference or within its outer circumference at least one axially end, at least to the first pressure medium channel ( 40 ) facing first side ( 46 ) of the armature plate ( 13 ) open towards, outside of the mouth of the first pressure medium channel ( 40 ) passage ( 45 ). 10. Solenoid valve according to one of the preceding claims, characterized in that the armature plate ( 13 ) has a central blind bore ( 47 ) open to the two sides ( 44 ) and at least one radial bore ( 48 ) opening into the blind bore ( 47 ). 11. Solenoid valve according to claim 9, characterized in that the axial passage ( 45 ) to the second side ( 44 ) of the armature plate ( 13 ) is open and that the elevation ( 49 ) at least one to the axially opening into the valve chamber ( 42 ) Druckmittelka channel ( 43 ) has an open channel. 12. Solenoid valve according to claim 9, characterized in that the elevation ( 49 ) is annular and that the axial passage ( 45 ) within the elevation ( 49 ) to the second side (44) of the armature plate ( 13 ) is open. 13. Solenoid valve according to one of claims 9 to 12, characterized in that the armature plate ( 13 ) has a circumferential groove on its outer circumference ( 52 ). 14. Solenoid valve according to one of the preceding claims, characterized in that a ball ( 53 ) is pressed into a central bore ( 54 ) of the armature plate ( 13 ), that the ball ( 53 ) on the first and / or on the second side ( 46 , 44 ) protrudes beyond the anchor plate ( 13 ) and that the first and / or the third pressure medium channel ( 40 , 51 ) can be closed with a cone seat using the ball ( 53 ). 15. Solenoid valve, in particular according to a preceding claim, characterized in that between the magnetic yoke ( 25 ) and the housing ( 10 ) an outwardly and to the valve chamber ( 42 ) sealed off annular space ( 31 ) is formed, which extends axially to behind the winding ( 26 ) receiving recess ( 33 ) of the magnetic yoke extends radially into the annular space ( 31 ) Ge housing channel ( 32 ) and that behind the recess ( 33 ) between the annular space ( 31 ) and the first pressure medium channel ( 40 ) a transverse bore ( 41 ) extends through the magnetic yoke ( 25 ). 16. Solenoid valve, in particular according to a preceding claim, characterized in that the magnet yoke ( 25 ) at its front and rear ends has a preferably beaded fitting section ( 29 , 30 ) on the outside, that the outer diameter of the front fitting section ( 30 ) is smaller than the outer diameter of the rear fitting section ( 29 ) that the Ge housing bore ( 11 ) has a rear bore section ( 14 ) with the diameter of the rear fitting section ( 29 ) and one in front of the bore section ( 15 ) with the diameter of the front fitting section ( 30 ) and that the front fitting section ( 30 ) is in the region of the front bore section ( 15 ) and the rear fitting section ( 29 ) is in the region of the rear bore section ( 14 ).