DE102008003210A1 - Force- or position-controlled proportional pressure control or relief valve for a vehicle common rail fuel injection system comprises an armature with an off-center axial passage containing a contact for a spool body - Google Patents

Abstract

Pressure valve for a hydraulic system comprises an armature with at least one off-center axial passage (8) containing a contact (9) for a spool body (4). The armature actuates a control element closing a pressurized medium opening in a valve housing (2) containing an electromagnetic converter with the spool body. Preferred Features: A flat armature (12) is used. The armature has two off-center axial passages each containing a contact (9) for the spool body.

Description

The The invention relates to a pressure valve for a hydraulic Installation, in particular for a high-pressure fuel system, according to the preamble of claim 1.

Pressure valves, designed as pressure relief valves or pressure control valves are known and serve to control the Pressure medium pressure in a hydraulic system. In known pressure valves For example, an electromagnet acts via an armature directly, less often indirectly via a compression spring on Valve. The control of the valve is predominantly as Seat cone, less common than longitudinal slide or nozzle baffle system educated. It can be the one exercised on the control Magnetic force - and thus the fluid pressure in the hydraulic Plant - by changing the electrical input current be varied without the electromagnetic transducer a Hub executes. The transducer acts as electromagnetic Feather.

For example, by the DE 197 13 858 A1 a pressure valve for a high-pressure fuel system of a vehicle is known, with a valve housing in which an electromagnetic transducer is used with a bobbin and an axially displaceable armature for actuating a control of the pressure valve, wherein the control can close a pressure medium opening in the valve housing. The contacts or leads for the bobbin are guided in the valve housing at a radial distance from the armature, wherein the armature is limited in its radial extent by the contact guide and the arrangement of the bobbin.

In a particular embodiment, disclosed in the European patent application EP 1 088 182 (Applicant: Hydraulik-Ring GmbH, application number: 99936347.6) is shown graphically and verbally - it is considered with this reference as fully contained in this application as a reference application - can be a high-pressure diesel valve with an elongated, extended, flat anchor, which is a substantially circular Form, so that the high-pressure control valve is referred to as Flachanker pressure valve or Flachankerhochdruckdieselventil.

Another illustration of a pressure relief valve with a flat anchor can the figures of DE 43 05 789 A1 (Applicant: Mannesmann Rexroth GmbH, filing date: 25.02.1993) are taken, in which axial holes are provided in the anchor, so that the assembly tool can engage the anchor and set with extensive distance mandrels the air gap between the armature and adjacent pole piece during the assembly process. As the description of the figures correctly states, the axial bores have the sole task of allowing only assembly.

Of the Space requirement of the pressure valve is not optimized.

Of the Invention has for its object to provide a pressure valve whose radial space requirement is reduced.

The Task is with a pressure valve with the features of the claim 1 solved.

Thereby, that in the anchor at least one at a distance from its longitudinal axis arranged axial passage or an axial bore provided is, in which a contact is passed for the bobbin, is a constructional measure specified, the radial extent the pressure valve, due to the contact in the To reduce valve body.

Of the Anchor could by this constructive measure also protrude radially over the bobbin, creating the dimensions of the anchor itself without magnification could increase the total radial space of the pressure valve.

Advantageous The valve can be used as a high pressure control valve for fuel applications used in the motor vehicle in pressure ranges up to more than 2000 bar be, even on the tank return side of the valve 40th bar pulsewise or over a longer period occur can.

preferred Designs emerge from the dependent claims.

In a particularly preferred embodiment of the pressure valve, the armature has two eccentric, axial passages through which a contact for the bobbin is guided. It may be purposeful be moderate to arrange a contact in a metal sleeve, which is guided by an axial passage through the armature, and to lead a contact with a rigid electrical insulation layer through the second axial passage through the armature.

All in all it is positive if the same contacts for the via can be taken through the anchor. That means in a layer view, the strand-like inner is electrically conductive contact surrounded by an insulating layer. One of the contacts is in the area of the anchor by a metal sleeve guided.

alternative Can the insulation around the contact by a coating on the Metal sleeve made with an insulating coating become.

Ideally the contacts are isolated. In one embodiment has the metallic contact, z. B. a strand, an insulating Sheath, which in turn surrounded by a sleeve becomes. At least one metal sleeve is present. In a alternative embodiment may also both in insulation material guided contacts each of a metal sleeve be enclosed.

The Metal sleeve and the electrical insulation are with a Clearance fit, which also takes into account the thermal expansion of the components, through the eccentric, axial passages through led the anchor. In this way results in addition an anti-twist device for the anchor.

The eccentric, axial passages can arranged symmetrically to a central axis of the armature in this be. The anchor is preferably a flat anchor and the invention Pressure valve is suitable for use in a common rail fuel injection system a vehicle in the form of a force-controlled or position-controlled Proportional pressure control valve or proportional pressure relief valve for Regulation or limitation of a fluid pressure.

Of the Flat anchor should with different holes, as a rule two, be provided by the contacts for in the Lid integrated plug are guided. The contacts lead to the coil of the electrical part of the valve. This embodiment has several advantages. An advantage lies in the security against rotation of the armature, which is resistant to rotation. One advantage is the particularly favorable leadership the contacts. The contacts are encased in plastic. One of the Both plastic cords are further covered with a sleeve, the is not magnetizable. As material for the sleeve suitable are aluminum, stainless steel, brass, nickel. In a Another embodiment, the anchor can now be designed so that fixed elements in the area of the lid in the space of the anchor can protrude, because the anchor can no longer twist. The sleeve has the further positive effect to reduce the hysteresis due to friction of the armature on the plastic. This carries a one-sided sleeve in many design examples for sufficient hysteresis reduction. Another sleeve drives the cost of manufacturing only upwards. Often while the hysteresis reduction is not improved to the same extent. The two holes for the contacts in the anchor are usually created equal. If the holes are symmetrical lie, the anchor can be mounted arbitrarily. Only through the Arrangement of the sleeve, the security against rotation is ensured. It is important that the coil contacts are not connected to the armature obtained in the electrical sense, but is a mechanical connection usually not harmful. Another advantage lies in that the tolerances of many components of the valve significantly be interpreted generously.

From Seen from the outside, the strand-like contacts work through the anchor like plastic cords.

Two Embodiments are described below with reference to the drawing shown. In the drawings show:

1 a perspective view of a pressure regulating valve,

2 a partial, perspective longitudinal section through the pressure control valve in 1 .

3 a plan view of the armature of the pressure control valve in 1 .

4 a sectional view of a further embodiment, wherein only the magnetic part is partially represented,

5 a view of an object 4 from the marked viewing direction X (without Cover), and

6 a representation after 4 in 3-D representation extracted from a CAD system.

In 1 is in a perspective view as a proportional pressure control valve 13 formed pressure valve 1 shown for a common rail fuel injection system of a passenger car. The proportional pressure control valve 13 is with a cylindrical valve body 2 formed for screwing in and unscrewing the proportional pressure control valve 13 in a pump housing of a high-pressure pump an external hexagon 14 has approximately in the axial center of the valve.

The (not in 1 shown) contacts of the plug 16 need of the plug 16 to the in 2 shown bobbin 4 be electrically contacted. The lid 15 is, as in the sectional drawing of 2 shown, equipped with a minimum lateral wall thickness. To make matters difficult for a reliable contact management is the lateral arrangement of a, in particular around circumferential, seal 17 added. By providing the seal 17 the wall thickness is even further reduced.

As in 2 in a partial perspective longitudinal section through the proportional pressure control valve 13 is shown in the valve housing 2 an electromagnetic transducer 3 for actuating a plunger-type control element 6 used. The control 6 is with a flat anchor 12 formed, axially displaceable anchor 5 firmly connected and presses a ball, not shown, on a conically expanding into the valve interior pressure medium opening.

The flat anchor 12 is in the axial direction of the proportional pressure control valve 13 between a lid 15 , which is the proportional pressure regulator 13 closes to the outside, and a bobbin 4 arranged. The flat anchor 12 projects radially beyond the bobbin 4 , whose contacts 9 . 9 ' by an off-center, axial passage 8th . 8th' through the flat anchor 12 are guided (cf. 3 ). The passages 8th . 8th' are mirror-symmetrical to a central axis 11 of the flat anchor 12 arranged, with a passage 8th from one, the contact 9 surrounding, non-magnetic metal sleeve 10 is traversed and the other eccentric, axial passage 8th' from an isolated contact 9 ' for the bobbin 4 is traversed.

Simplified are the passages 8th . 8th' through the same contacts 9 , each one an insulation layer 18 , at least in the area of the flat anchor 12 have interspersed. The contact 9 is at least in the area through the insulating layer 18 protected against electrical leakage and short circuits in which the anchor 5 its maximum travel distance along the contact 9 can go back.

The flat anchor 14 has a diameter so wide that the flat anchor 14 almost over the entire radial width of the valve 1 extends. The flat anchor 14 is in its radius only approximately through the thickness of the valve housing 2 limited. The flat anchor 14 has the width of the valve 1 less the thickness of the valve body 2 ,

The 4 . 5 . 6 show an alternative embodiment to the illustration after 1 and 2 , wherein similar parts with the same reference numerals as in the 1 and 2 have been designated. In a valve housing 2 , which primarily carries the magnetic part of the valve, lies outside of a bobbin 4 , in particular above a bobbin 4 , and more particularly on one side of the bobbin 4 , a flat anchor 12 , The flat anchor 12 is interrupted in its surface. The flat anchor 12 , which in its center usually offers a receptacle for the pestle, is still riddled. The flat anchor 12 offers off-center passageways 8th . 8th' through the contacts 9 . 9 ' for the electrical contacting of the bobbin 4 are guided. One of the contacts 8th is with a sliding sleeve 10 overdrawn. The sleeve 10 promotes the longitudinally movable displacement of the flat anchor 12 and thus reduces the mechanical / electrical hysteresis of the valve, ie the dependence of the mechanical change in position of the armature 12 from the excitation current passing through the bobbin 4 flows.

As with the dimensions a and b in 5 The air gap between the flat anchor is visible 12 , more precisely the wall of the hole of the passage 8th . 8th' that of the sleeve 10 is penetrated, narrower than without corresponding sliding sleeve 10 , The anchor 5 , which can undergo radial deflections during its axial displacement, is guided by the sliding sleeve 10 stabilizing steered. Due to the metallic storage between flat anchors 12 and the sliding sleeve 10 in the case of contact, the Axialverschieblichkeit the flat anchor 12 only minimally inhibited. The sliding sleeve 10 thus has a hysteresis-reducing effect in the mechanical sense.

As 5 shows is the electrical contact 9 . 9 ' at least in the area of the metal sleeve 10 on the bottom of the metal sleeve 10 from the insulation layer 18 enclosed. As insulation layer 18 In addition to plastic sheathing, such as conventional sheathed single-core cable, and insulating coatings and insulation coatings on the metal sleeve, in particular the inside of the metal sleeve can be arranged.

For easier installation of the valve according to the invention 1 It is beneficial if only one of the passes 8th . 8th' , the off-center about the plunger or the control 6 are arranged around, namely the passage 8th , has a wider diameter than the one or more passages 8th' so that the anchor 5 actually assemble only in a rotational position. The different diameters of the passages 8th . 8th' Promote assembly safety and facilitate the assembly process, especially in manually assembled valves 1 ,

In general, the bobbin 4 with two electrical contacts, for the plus and the minus connection, to the plug 16 introduced. With split coils and otherwise shaped bobbins, it may be necessary to have more than just two passes 8th . 8th' provided by the anchor.

During the experimental phase of valves according to the invention, another surprising effect became apparent. The flat armature, which is to be flushed around and surrounded by the hydraulic medium on both sides, moves rotating movements in the armature space without suitable rotation inhibition. The rotating movements seem to have a negative effect on the energy expenditure for pressure regulating valve adjustment. In particular, by the radial positional bond of the armature when using a sleeve through which the pivotal play is given only in the scope of the free space b, the amount of electrical energy to be expended for a valve according to the invention in the percentage range can be reduced. LIST OF REFERENCE NUMBERS: reference numeral importance 1 pressure valve 2 valve housing 3 Transducer, electromagnetic 4 bobbins 5 Anchor, axially displaceable 6 control 7 Pressure center opening 8th . 8th' Passage, off-center 9 . 9 ' Contact 10 metal sleeve 11 central axis 12 flat armature 13 Proportional pressure control valve 14 External hexagon 15 cover 16 plug 17 poetry 18 insulation layer a Air gap, in particular between insulation layer and anchor b Air gap, in particular between metal sleeve and anchor

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• DE 19713858 A1 [0003]
• EP 1088182 [0004]
• - DE 4305789 A1 [0005]

Claims (7)

Pressure valve for a hydraulic system, in particular for a high-pressure fuel system, with a valve housing ( 2 ) into which an electromagnetic transducer ( 3 ) with a bobbin ( 4 ) and an axially displaceable armature ( 5 ) for actuating a control ( 6 ) of the pressure valve ( 1 ) is used, wherein the control ( 6 ) a pressure medium opening ( 7 ) in the valve housing ( 2 ), characterized in that the anchor ( 5 ) at least one eccentric, axial passage ( 8th ), in which a contact ( 9 ) for the bobbin ( 4 ) is passed. Pressure valve according to claim 1, characterized in that the armature ( 5 ) two eccentric axial passages ( 8th . 8th' ), in each of which a contact ( 9 . 9 ' ) for the bobbin ( 4 ) is passed. Pressure valve according to one of claims 1 or 2, characterized in that by an eccentric, axial passage ( 8th . 8th' ) in the anchor ( 5 ) a non-magnetic metal sleeve ( 10 ) with radial play, in which a contact ( 9 ) runs. Pressure valve according to one of claims 1 to 3, characterized in that by an eccentric, axial passage ( 8th' ) in the anchor ( 5 ) an isolated (18) contact ( 9 ' ) is passed. Pressure valve according to one of claims 2 to 4, characterized in that the eccentric, axial passages ( 8th . 8th' ) axisymmetric to a central axis ( 11 ) of the anchor ( 5 ) are arranged. Pressure valve according to one of claims 1 to 5, characterized in that the armature ( 5 ) a flat anchor ( 12 ). Pressure valve according to one of claims 1 to 6, characterized in that the pressure valve ( 1 ) a force-controlled or position-controlled proportional pressure control valve ( 13 ) or proportional pressure relief valve of a common rail fuel injection system of a vehicle.