FR2879714A1 - Solenoid valve for fuel injection installation of a motor vehicle, has annular volume with section aligned in direction of axis and delimited by cylindrical and frontal surfaces of case and by envelop and annular surfaces of armature - Google Patents

Abstract

The valve has an annular volume (15) between a case (12) and an armature (14). The volume has a rectangular section aligned in a direction of an axis and delimited by cylindrical and frontal surfaces (19, 17) of the case and by envelop and annular surfaces (21, 20) of the armature. A length of the surface (21) in the direction of the axis and a width of the surface (20) in a transversal direction of the axis are in a preset ratio.

Description

Field of the invention

  The present invention relates to an electromagnetic valve, in particular for a fuel injection installation of a motor vehicle comprising a housing and an armature between which there is an annular volume, the armature being movable in a back-and-forth motion substantially parallel to the axis.

  State of the art There is generally known such an electromagnetic valve. The movement back and forth of the armature drives the valve to the open state and the closed state. In the open state, a fluid including fuel passes through the annular volume. When the valve closes, the fluid passage is stopped abruptly. It is known that this can result in a cavitation effect.

  The effect of cavitation means the development of a cavity generated for example by a fast moving liquid so that the pressure drop develops steam. When collapsing or imploding cavities of steam still called cavitation bubbles the energy is released. If at this point the cavitation bubbles are in the vicinity of the material surface of the armature or valve housing, this will damage the material. This effect is called cavitation erosion.

  It is also known to avoid cavitation erosion by coating the surface of material with particularly hard layers. But this can apparently only be done with significant resources related to the manufacture of the electromagnetic valve.

  OBJECT OF THE INVENTION The object of the present invention is to develop an electromagnetic subpape which is not likely to be exposed to damage to the material by cavitation effect without necessitating the implementation of important means.

  DESCRIPTION AND ADVANTAGES OF THE INVENTION To this end, the invention relates to an electromagnetic valve of the type defined above, characterized in that the annular volume has a substantially rectangle-shaped section aligned in the direction of the axis, this section being mainly delimited by the surface of the cylinder and the front surface of the housing as well as by an envelope surface and an annular surface of the armature, and the length (a) of the envelope surface in the direction of the axis and the length (b) the annular surface of the armature in the direction transverse to the axis are in a ratio of the order of 2 (a / b 2).

  According to the invention, the annular volume between the armature and the valve housing is made with a section substantially corresponding to an elongated rectangle in the direction of the axis. Thus, during the passage of the valve from its open state to its closed state, the fluid stream is transferred in a vortex in the annular volume. The cavitation bubbles which develop if necessary because of the abrupt passage in the closed state are taken by this vortex. This results in the advantage that the cavitation bubbles can not reach the surface of the material of the armature or the housing but still remain in the vortex and are thus inside the annular volume. When cavitation bubbles are pulsed, there is no risk of damaging the surface of the material of the armature or the housing.

  Advantageously, the passage between the front surface and the cylindrical surface of the housing has a radius R1 as large as possible, and the passage between the annular surface and the envelope surface of the armature has a radius R2.

  The development of the annular volume according to the invention thus creates a kind of impulse chamber for any cavitation bubbles that develop. The cavitation bubbles thus implode in this implosion chamber and do not risk damaging the surface of the armature or valve housing. The production of the annular volume according to the invention thus avoids damaging the material without requiring additional hard layers or similar means.

  According to an advantageous development of the invention, the portion of the annular volume formed by the housing of the valve preferably has the largest possible radius. Thus, the vortex mentioned above develops in a guaranteed way in the annular volume.

  It is particularly advantageous that the parts of the armature delimiting the annular volume have a radius of curvature.

  According to another advantageous development of the invention, at least one stall edge is provided which improves the development of the vortex accordingly.

  Thus, the armature has an outer shell surface and a front surface, and the passage from the front surface to the inner shell surface and / or the annular surface to the outer shell surface has a stall edge.

  Preferably, the stall edge has a surface whose junctions with the adjacent surfaces in the direction of the axis and substantially perpendicular to this axis correspond each time to a distance (c, d), the distances (c, d) being in a ratio greater than 3 (d / c> 3). In addition, the shorter distance (c) of the two distances (c, d) is turned towards the frontal surface or the outer envelope surface of the armature.

  Finally, advantageously, the annular surface and / or the inner surface of the inner armature form an angle (w) with respect to the axis or are perpendicular to it.

  Drawings The present invention will be described in detail below with the aid of an exemplary embodiment shown in the accompanying drawings in which: - Figure 1 is a schematic sectional view of an embodiment of An electromagnetic valve according to the invention, - Figure 2 shows a schematic enlargement of the annular volume of the valve of Figure 1, and - Figures 3a, 3b show the schematic detail of the enlargement of Figure 2.

  DESCRIPTION OF AN EMBODIMENT OF THE INVENTION FIG. 1 shows an electromagnetic valve 10 having a shape substantially symmetrical in rotation with respect to the axis 11. The sectional view of FIG. 1 thus passes through the axis 11.

  The valve 10 may be for example the control valve of a particular fuel injection installation equipping a motor vehicle.

  The valve 10 consists of a housing 12 housing an electromagnetic coil 13 and an armature 14. An annular volume 15 exists between the armature 14 and the housing 12.

  The annular volume 15 receives a liquid. When the valve 10 is used in a fuel injection installation, the fluid or fluid is a fuel.

  The armature 14 is movable in a reciprocating manner in the direction of the axis 11. The valve 10 can thus open and close. Figure 1 shows the valve 10 in the open state.

  Figure 2 shows on an enlarged scale the annular volume 15 with the armature 14 and the housing 12. Figure 2 shows the valve 10 in the open state.

  In this open state, the front surface 16 of the armature 14 diagonally transverse to the axis 11 and the front surface 17 of the facing housing 12 are spaced from one another to form a radial gap . When the valve 10 is closed, there remains a residual gap between the end surfaces 16 and 17 avoiding that the two end surfaces 16, 17 are glued by magnetic effect.

  FIG. 2 shows an annular gap between the envelope surface 18 of the armature 14 and the cylindrical surface 19 facing the casing 12. This annular gap exists whether the valve 10 is in the green state or in the closed state .

  This results in a fluid or liquid movement in the annular volume 15, in the annular gap and in the radial gap.

  As already indicated, the annular volume 15 is formed between the armature 14 and the casing 12. According to FIG. 2, the casing 12 has the cylindrical surface 19 already mentioned aligned substantially parallel to the axis 11 and extending into the zone of the annular volume 15. In addition, the housing 12 also comprises the front surface 17 already mentioned. This surface is substantially perpendicular to the axis 11 and also extends in the region of the annular volume 15. In this area of the annular volume 15, the two surfaces 17, 19 meet. According to Figure 2 this junction corresponds to a radius of curvature R1.

  The armature 14 comprises the envelope surface 18 already mentioned aligned substantially parallel to the axis 11. To form the annular volume 15, this surface 18 continues with an annular surface 20 substantially transverse to the envelope surface 18 and thus aligned substantially transversely by relative to the axis 11. In addition, the armature 14 comprises the front surface 16 already mentioned. To form the annular volume 15, this front surface 16 continues with an envelope surface 21 substantially transverse to the front surface 16 and thus aligned substantially parallel to the axis 11. According to FIG. 2, the two surfaces 20, 21 are together. The junction is made according to a radius R2.

  According to FIG. 2, the front surface 16 is spaced from the annular surface 20 of the armature 14 by a distance (a) in the direction of the axis 11. The envelope surface 21 is spaced from the envelope surface 18 of the distance (b) in the direction transverse to the axis 11.

  The ratio of distances a, b is chosen so that the section of the annular volume 15 in the direction of the axis 11 corresponds to an elongated rectangle with two rounded corners. Preferably, for this the ratio of distances a, b is chosen substantially equal to 2, ie a / b 2. This is done for example for a distance (a) between 0.8 mm and 1, 2 mm in particular equal to 1.0 mm and a distance (b) between 0.4 mm and 0.6 mm and in particular equal to 0.5 mm.

  It is further provided that the radius R1 is greater than the radius R2. The radius R1 should be chosen as large as possible. The radius R1 is for example between 0.5 and 0.7 mm and in particular equal to 0.6 mm while the radius R2 is between 0.15 mm and 0.3 mm and in particular equal to 0.2 mm.

  The transition between the front surface 16 and the envelope surface 21 of the actuator 14 is shown in FIG. 3 in an enlarged manner for the detail X. This enlarged view shows that the front surface 16 firstly joins a surface 22 to join then the envelope surface 21.

  The transition line between the front surface 16 and the surface 22 is spaced from the distance (c) with respect to the transition line between the surface 22 and the envelope surface 21, this distance being measured transversely with respect to the axis 11. In the direction parallel to the axis 11, the transition lines mentioned above have a distance (d).

  FIG. 3 further shows that the envelope surface 21 is not exactly parallel to the axis 11 but makes an angle w with respect to the axis 11.

  The ratio of the two distances (d) and (c) is greater than 3. Thus d / c> 3. The distance (c) is preferably between 0 mm and 0.03 mm and the distance (d) included between 0 mm and 0.1 mm.

  The angle w is preferably between -5 and +5 and is preferably -5.

  FIG. 3b shows the passage between the annular surface 20 of the actuator 14 and the envelope surface 18 on an enlarged scale corresponding to the detail Y. This passage is made by a surface 23. In FIG. 3, corresponding distances c are shown in FIG. , d and a corresponding angle w. For these distances and this angle of Figure 3b, we have the same conditions as for the corresponding distances and the angle of Figure 3a and for more details, reference is made to the description of Figure 3a.

  In FIG. 3b, the distance c is measured in the direction parallel to the axis 11 and the distance d in the direction transverse to the axis 11. In addition, the angle w is measured between the surface 20 and the transverse direction to axis 11.

  The surfaces 22, 23 of FIGS. 3a, 3b are always arranged so that the shortest distance c is each time close to the directly adjacent gap. The surface 22 is thus associated with the annular gap formed by the surfaces 16, 17 while the surface 23 is associated with the annular gap formed by the surfaces 18, 19. The surfaces 22, 23 thus constitute staking edges for these intervals.

  During the operation of the valve 10, high fluid velocities are encountered at these intervals. When the valve 10 goes to the closed state, these flow rates increase as a function of the geometric reduction of the gap. The embodiment as described of the annular volume 15 instantly transforms the flow into a vortex. This comes in particular from the large radius R1 of the housing 12. This reinforces the effect of the stall edges of Figures 3a, 3b.

  Insofar as cavitation bubbles develop, they will be taken by the vortex generated in the annular volume 15. The cavitation bubbles implode in this vortex inside the annular volume 15 and not on the wall of the armature 14 or the housing 12. This avoids damaging the material by cavitation erosion.

Claims (7)

  1) Electromagnetic valve (10) in particular for a fuel injection installation of a motor vehicle comprising a housing (12), an armature (14) and between them an annular volume (15), the armature (14) being movable in a reciprocating manner substantially parallel to the axis (11), characterized in that the annular space (15) has a substantially rectangle-shaped section aligned in the direction of the axis (11). ) of the valve (10), and mainly delimited by the surface (19) of the cylinder and the front surface (17) of the housing (12) as well as by an envelope surface (21) and an annular surface (20) of the armature (14), and the length (a) of the envelope surface (21) in the direction of the axis (11) and the width (b) of the annular surface (20) of the armature (14) in the direction transverse to the axis (11) are in a ratio of the order of 2 (a / b 2).   2) valve (10) according to claim 1, characterized in that the passage between the front surface (17) and the cylindrical surface (19) of the housing (12) has a radius (R1) as large as possible.   3) valve (10) according to claim 1, characterized in that the passage between the annular surface (20) and the envelope surface (21) of the armature (14) has a radius (R2).   4) Valve (10) according to claim 1, characterized in that the armature (14) has an outer casing surface (18) and a front surface (16), and the passage of the front surface (16) to the surface inner shell (21) and / or the annular surface (20) at the outer shell surface (18) has a stall edge.   5) A valve (10) according to claim 4, characterized in that the stall edge has a surface (22, 23) whose junctions with the adjacent surfaces in the direction of the axis (11) and substantially perpendicular thereto. axis correspond each time to a distance (c, d), the distances (c, d) being in a ratio greater than 3 (d / c> 3).   6) Valve (10) according to any one of claims 4 or 5, characterized in that the shortest distance (c) of the two distances (c, d) is facing the front surface (16) or the outer surface envelope (18) of the armature (14).   Valve (10) according to claim 1, characterized in that the annular surface (20) and / or the inner envelope surface (21) of the armature (14) is at an angle (w) to the axis (11) or are perpendicular to it.