WO2013156179A1

WO2013156179A1 - Magnet assembly, particularly for a solenoid valve of a fuel injector

Info

Publication number: WO2013156179A1
Application number: PCT/EP2013/053344
Authority: WO
Inventors: Thomas Nierychlo; Marco Beier
Original assignee: Robert Bosch Gmbh
Priority date: 2012-04-16
Filing date: 2013-02-20
Publication date: 2013-10-24
Also published as: EP2839143A1; EP2839143B1; DE102012206215A1

Abstract

The invention relates to a magnet assembly, particularly for a solenoid valve of a fuel injector, having a magnetic core (21) and an armature (22). On one end face (23), on the armature plate side, the magnetic core (21) has an inner pole surface (24a) and an outer pole surface (25a). A residual air gap disc (40) is arranged between the magnetic core (21) and the armature (22), said residual air gap disc being held on the armature plate-side end face (23) of the magnetic core (21) by means of a clamping connection (50). The clamping connection (50) has a tension ring (60) which presses the residual air gap disc (40) against the armature plate-side end face (23) of the magnetic core (21).

Description

Description title

Magnetic assembly, in particular for a solenoid valve of a fuel injector prior art

The invention relates to a magnet assembly, in particular for a solenoid valve of a fuel injector according to the preamble of claim 1.

Common rail injectors use so-called servo valves, which control the pressure in a control room. As an actuator for such servo valves u. a. Magnetic actuators used. Such magnetic actuators have a magnet assembly with a magnetic core and a magnet armature, wherein a so-called residual air gap disk is used to set a minimum residual air gap between an armature surface and a pole face. The

Residual air gap disc has the function to limit remanence effects

(Magnetic bonding) and also to realize a damping when hitting the magnet armature on the magnetic core. The residual air gap disk can be arranged above the inner pole or outer pole of the magnetic core.

From DE 10 2009 001 706 Al a magnetic assembly is known, in which an outer residual air gap disk is clamped between the magnetic core and a magnetic sleeve receiving the magnetic core. Since high forces are necessary for an unambiguous position of the magnetic core and the contact surfaces between the magnetic core and magnetic sleeve can not be produced ideally coplanar, this solution has the disadvantage that the residual air gap disc is exposed to high mechanical loads.

Disclosure of the invention The magnetic assembly with the characterizing features of claim 1 has the advantage that only very low demands on the

Manufacturing tolerances of magnetic core and magnetic sleeve must be provided. The clamping connection by means of the clamping ring allows geometric tolerances and expansions due to temperature influences can be compensated.

Advantageous developments of the invention are possible by the measures of the subclaims.

Conveniently, the clamping ring presses the residual air gap disc on the Außenpolfläche. An appropriate non-positive connection between the armature plate side end of the magnetic core and the residual air gap disc is achieved by a clamping ring receptacle is provided with a counter surface in which the clamping ring is received, wherein the clamping ring is supported with a radial clamping force on the counter surface and by means of a counter surface derived resulting resilience against the

Residual air gap disk presses.

The clamping ring receptacle with the mating surface is expediently formed on an overlap arranged on a magnet sleeve, which holds the

Ankerplattenseitigen end side of the magnetic core radially overlaps, so that the mating surface is at an axial distance radially below the residual air gap disc.

The clamping ring may have a round cross section or a cross section with at least one conical support surface. In a circular cross-section, the counter surface for supporting the clamping ring is a bevel, which generates the resulting clamping force in the direction of the residual air gap disc, or the counter surface for supporting the clamping ring is one at a gap

trained clamping surface, so that the clamping ring wedged in the gap due to its radial clamping force and presses with the resulting clamping force against the residual air gap disc. For a clamping ring with a conical

Support surface, the support surface is formed on the outer circumference of the clamping ring, with the clamping ring is supported on a complementary conical surface as a counter surface.

embodiments

Embodiments of the invention are illustrated in the drawings and explained in more detail in the following description. Show it:

Fig. 1 shows a cross section through a solenoid valve with an inventive

Magnet assembly,

Fig. 2 is an enlarged detail X of Fig. 1 according to a first

embodiment,

Fig. 3 is an enlarged detail X of Fig. 1 according to a second

embodiment,

Fig. 4 is an enlarged detail X of Fig. 1 according to a third

Embodiment and

Fig. 5 is a plan view of a clamping ring.

The illustrated in Fig. 1 solenoid valve of a fuel injector has

Valve element 10 and a magnet assembly 20 which are arranged in an injector body 11. The valve element 10 comprises a closing element 12, which acts on a valve seat 13. By means of the closing element 12 is a

Control chamber 15 connected to the control of a nozzle needle, not shown, connected to a low-pressure chamber 16 or closed.

The magnet assembly 20 includes a magnetic core 21 and a magnet armature 22. The magnet core 21 has an armature plate side end face 23 which forms a pole face. In the magnetic core 21, a magnetic coil 26 is inserted, so that the magnetic core 21, an inner pole 24 and an outer pole 25 is formed. At the armature plate-side end face 23 of the magnetic core 21, an inner pole face 24a is thus formed at the inner pole 24, and an outer pole face 25a is formed at the outer pole 25. The magnetic core 21 is received in a magnet sleeve 28 which is clamped by means of a clamping sleeve 27 with the injector body 10. The magnetic core 21 rests with its armature plate-like end face 23 on an annular surface 29 formed on the magnet sleeve 28. The armature 22 has an anchor plate 31 with an outer diameter and an anchor sleeve 33, wherein the anchor sleeve 33 at the same time

Closing element 12 forms. The outer diameter defines an armature surface 32 on the armature plate 31. The armature sleeve 33 is guided on its outer circumferential surface in a valve piece 34 formed on the injector body 10.

Between the magnetic core 21 and the armature 22 is a

Residual air gap disc 40 is arranged, which is designed as a circular ring and thus represents an outer residual air gap disc. The residual air gap disk 40 has a clamping-ring-side end face 41 and a magnet core-side end face 42 and is held on the armature-plate-side end face 23 of the magnetic core 21 in the region of the outer pole face 25a by means of a clamping connection 50. The clamp connection 50 has a clamping ring holder 51 with a

Counter surface 52 and a clamping ring 60. The clamping ring 60 has a radial clamping force with which the clamping ring 60 at the in the

Clamping ring 51 trained counter surface 52 is supported. Due to the position of the mating surface 52, which has inclined to the residual air gap disk 40, on the mating surface 52 from the radial clamping force of the clamping ring 60 a

resulting clamping force in the direction of the residual air gap disc 40 derived so that the clamping ring 60 with the resulting clamping force against the

clamping ring-side end face 41 of the residual air gap disk 40 presses. As a result, the clamping ring 60 realizes with the resulting clamping force the required clamping force for the clamping connection 50, with which the residual gap plate 40 with the magnetic core side end 42 is held frictionally on the armature plate side end face 23 of the magnetic core 21. To apply the necessary bias when inserting the clamping ring 60 in the

Clamping ring 51, the clamping ring 60 according to Figure 5 has a slot 61.

To carry out the clamping ring holder 51, an overlap 53 is formed on the magnet sleeve 28, axially below the annular surface 29, which overlaps the

Ankerplattenseitigen end face 23 of the magnetic core 21 overlaps. At the overlap 53 of the magnet sleeve 21, the clamping ring holder 51 with the counter surface 52nd formed so that the clamping ring receiver 51 is disposed below the residual air gap disk 40 and the counter surface 52 is located at an axial distance below the clamping ring side end face 41 of the residual air gap disk 40.

In the embodiments in Figures 2 and 3, the clamping ring 60 has a round cross-section. The counter surface 52 is in the embodiment of Figure 2 is a slope on which the clamping ring 60 acts with its radial clamping force and a corresponding resulting clamping force in the direction of the residual air gap disc 60 dissipates, with the clamping ring 60 against the

clamping ring-side end face 41 of the residual air gap disk 40 presses.

In the embodiment according to FIG. 3, the clamping ring receptacle 51 has a mating surface 52 with a curved course. Due to the curve shape, the clamping force of the clamping ring 60 can be adjusted over itself

Diameter of the clamping ring 60 can be varied. Again, the clamping ring 60 presses with the resulting clamping force against the clamping ring-side end face 41 of the residual air gap disc 40th

But it is also conceivable that the counter surface for supporting the clamping ring 60 is formed on a gap clamping surface, wherein the clamping ring 60 wedged due to its radial clamping force in the gap between the clamping surface and the residual air gap disk 40 and the resulting clamping force against the residual air gap disk 40th suppressed.

In the embodiment according to FIG. 4, the clamping ring 60 has a conical support surface 54 at least on the outer peripheral surface. The counter-surface 52 for the support surface 54 is a complementary conical surface on the clamping ring 51 and the overlap 53. Due to the radial clamping force of the clamping ring 60 and the mutually acting conical surfaces creates a resulting clamping force, the clamping ring 60 against the clamping ring side end 41st the residual air gap disk 40 presses.

Claims

claims

1. Magnetic assembly, in particular for a solenoid valve of a

A fuel injector comprising a magnetic core (21) and a magnet armature (22), said magnet core (21) having an inner pole surface (24a) and an outer pole surface (25a) on an armature plate side end (23), a residual air gap disc (40) being sandwiched between said magnetic core (25). 21) and magnet armature (22), which is held on the armature plate side end face (23) of the magnetic core (21) by means of a clamping connection (50), characterized in that the clamping connection (50) has a clamping ring (60), which the Residual air gap disc (40) to the armature plate side end face (23) of the magnetic core (21) presses.

2. Magnet assembly according to claim 1, characterized in that the clamping ring (60) presses the residual air gap disc (40) to the Außenpolfläche (25 a).

3. Magnet assembly according to claim 1, characterized in that a clamping ring receptacle (51) having a counter surface (52) is provided, on which the clamping ring (60) is supported with a radial clamping force and by means of a on the mating surface (52) derived resulting clamping force presses against the residual air gap disc (40).

4. Magnet assembly according to claim 3, characterized in that the clamping ring receptacle (51) with the mating surface (52) is arranged on a magnet sleeve (28) disposed over-grip (53), the anchor plate side end face (23) of the magnetic core (21). engages so that the counter surface (52) with axial distance radially below the

Residual air gap disc (40) is located.

5. Magnet assembly according to claim 1, 2 or 3, characterized in that the counter surface (52) for supporting the clamping ring (60) is a slope which generates the resulting clamping force in the direction of the residual air gap disc (40).

6. Magnet assembly according to claim 1, 2 or 3, characterized in that the mating surface (52) for supporting the clamping ring (60) has a

has a curved course, which generates the resulting clamping force in the direction of the residual air gap disc (40).

7. Magnet assembly according to claim 1, 2 or 3, characterized in that the counter surface (52) for supporting the clamping ring (60) is formed on a gap clamping surface, that the clamping ring (60) due to its radial clamping force in the gap between the Wedged clamping surface and the residual air gap disc (40) and presses with the resulting clamping force against the residual air gap disc (40).

8. Magnet assembly according to claim 1, characterized in that the clamping ring (60) has a round cross-section

9. Magnet assembly according to claim 1, characterized in that the clamping ring (60) on the outer circumference a conical support surface (54), with which the clamping ring (60) on a complementary conical surface as a counter surface (52) is supported.

10. Magnet assembly according to one of the preceding claims, characterized in that the residual air gap disc (40) is designed as a circular ring.