FR2858679A1 - Electromagnetic control valve for ventilating fuel tank of motor vehicle internal combustion engine, has annular sealing toric ring that is inserted into valve seat and is attached on support body - Google Patents

Abstract

The valve has a solenoid piston (70) that is activated by a magnetic coil, where the piston undergoes to and fro movement between opening and closing positions. A support socket defines the closing position of side of the solenoid piston turned towards a valve seat. An annular sealing toric ring (9) is inserted into the valve seat and attached on a support body.

Description

I

  Technical Field The invention relates to an electromagnetic valve, particularly for tank aeration in motor vehicles, comprising a magnetic coil and a solenoid piston, which can be actuated by the magnetic coil and undergo a forward and reverse movement. return between an open position and a closed position, the closed position being defined by the bearing of a face of the solenoid piston, facing a valve seat, on the valve seat with interposition of a sealing body 10 which can be removably attached to a support body.

  STATE OF THE ART Electromagnetically controlled valves for the metered introduction of fuel vapor, which volatilizes from a fuel tank of an internal combustion engine, into a suction tube of the combustion engine. internal combustion are known and often described by the authors. They normally comprise a valve housing with a supply connection to be connected to a fuel tank or an adsorption filter mounted downstream thereof and a flow connection to be connected to the suction tube. . Inside the valve housing is a magnetic coil with a magnetic core and a solenoid piston. If the magnetic coil receives current, the solenoid piston can be put in an open position against the spring effect from a closed position defined by its seating on the seat valve. In known valves, the maximum stroke of the solenoid piston is normally limited by abutment surfaces, generally on the magnetic core, on the side of the solenoid piston opposite the valve seat.

  It is known to equip the solenoid pistons, on their side facing the valve seat, a sealing body made of an elastomer to seal and to reduce noise. Solenoid pistons having a through passage through which the seal body extends to the opposite side of the valve seat and spring protruding therefrom to provide a stop buffer for application to the surfaces are also known. of stops on the magnetic core. The seal body can be overmolded by vulcanization on the solenoid piston.

  In an electromagnetic valve of the generic species, the seal body is located on the solenoid piston so as to be releasably attachable. From EP 0 099 771 AI, there is thus known a solenoid valve with a solenoid piston, in which a cap made of an elastomer overcomes the side facing the sealing seat, the solenoid piston having a cylindrical passage in which the Elastomer body extends until the passage is completely filled. To attach the elastomeric cap to the solenoid piston, the latter has, on the side facing the seal seat, in a rear portion, a groove-shaped undercut, which extends over the outer periphery. and can be brought into engagement with the trailing edge of the elastomeric shell. Such an assembly is also known from EP 1 235 014 A2. This document discloses a solenoid piston which has on its side facing the seal seat a conical tip which, in the closed position of the valve, sinks at the upper end of the flow connection, in an inlet shaped accordingly. The conical tip is here completely covered with a cap 20 shaped accordingly and made of a sealing material, the cap being engageable with its outer edge, with a groove-like counterpane which extends over the outside rim at the foot of the conical tip.

  The disadvantage of the electromagnetic valves described is a very complex geometry of the sealing bodies, the manufacture of which is therefore complex and expensive.

  SUMMARY OF THE INVENTION The object of the invention is to improve an electromagnetic control valve of the generic species so as to reduce the cost of manufacturing the solenoid piston. This object is achieved by an electromagnetic control valve having all the features of claim 1. Advantageous embodiments of the invention are described in the subclaims.

  Given an electromagnetically controlled valve, particularly a motor vehicle tank vent valve, which includes a magnetic coil and a solenoid piston that can be actuated by the magnetic coil and undergo a back and forth motion between an open position and a closed position, the closed position being defined by the bearing on the side of the solenoid piston, facing a valve seat, on the valve seat with interposition of a valve body. According to the invention, the sealing body can be removably attached to a support body, and the sealing body is constructed as a substantially annular sealing element which can be attached to the support body.

  Due to the use of a simple and substantially annular sealing element instead of the complex geometry elastomeric sealing bodies described above, it is possible not only to considerably reduce the manufacturing cost of the valve, but also to substantially simplify the handling assembly of the sealing body. It is possible to visually check, in a simple manner, whether the sealing element is properly in place, but not if the elastomeric caps are well positioned, since the securing segments that snap into the groove are hidden below the elastomeric cap.

  The sealing element according to the invention is made in a substantially annular form. Significantly annular means that the sectional area does not have to be strictly circular. It may be advantageous, for improving the positioning in the housing groove, to provide a section surface which deviates from the circular shape and is (partially) angular, for example. It may also be advantageous if the geometric shape of the sectional area is not constant all around the ring, but is made differently, at least in parts.

  The conformation of the sealing element according to the invention has been considerably simplified in comparison with the known sealing bodies, including taking into account the above possibilities of variation, with regard to the geometrical configuration, the selection of materials which can be used for the sealing element is considerably greater than in the case of complex geometry sealing bodies. More particularly, it is possible to choose the characteristics of the material in a targeted manner in view of the intended field of implementation of the valve. Thus, for the preferred application of the valve as a tank aeration valve for motor vehicles, materials, and more particularly elastomers, which are optimized in terms of their heat resistance and acoustic attenuation, such as fluorsilicone, for example.

  For a secure attachment of the sealing element to the support body, it is advantageous to provide on the sealing body an annular peripheral groove with lateral limiting walls in which the sealing element can be clipped.

  The sealing member may be placed not only on the sealing seat, but also on the solenoid piston. The solenoid piston is preferably used as a support body, since it is very complicated and expensive to provide an annular groove, accommodating the sealing element, in the comparatively thin wall of the flow connection. the level of the valve seat, in terms of the manufacturing technique, in particular because of a very complex tool arrangement resulting from the fact that it must take account of demoulding. In addition, it may be necessary to block the sealing element by another component.

  Still with regard to the manufacturing technique, it is difficult to provide the annular groove in the end face of the solenoid piston facing the valve seat and directed downwards. In this context, it is important to mention the life of the tool, which is clearly limited because of the given dimensions. Therefore, the annular groove is advantageously provided on the solenoid piston 30 on the outer periphery side, the side wall of the groove, located on the side of the solenoid piston, constituting, with the sealing element bearing on it, the place where the sealing seat can come to apply. The diameter of the front portion of the solenoid piston facing the seal seat is reduced accordingly until said front portion further prevents the seal seat from being applied to the seal member. sealing, that is to say that the outer diameter of the solenoid piston in the front part must be smaller than the inside diameter of the outlet orifice surrounded by the sealing seat. Furthermore, the side wall of the groove, facing the sealing seat, should still sufficiently cover the sealing element radially outwardly so as to preserve it from a fall.

  In a preferred embodiment of the invention, the annular groove is formed as a prismatic slide, that is to say with a substantially V-shaped profile. This embodiment has the advantage that, because of V-widening of the hollow space of the groove, the edge of separation of the form has sufficient clearance and thus does not manifest inconveniently. It has also proved advantageous, when determining the dimensions of the hollow space of the groove, to take account of the swelling of the material of the sealing element in contact with the fuel vapors. A favorable contour is obtained with respect to fluid mechanics if the solenoid piston has a tapered portion at its end facing the valve seat. This has a lasting effect on the fine metering capacity of the valve, which car manufacturers are demanding more and more often.

  In a preferred embodiment of the invention, an O-ring seal is used as a sealing element. O-ring rings are easy to manufacture and cost-effective.

  In another preferred embodiment of the invention there are provided, on the solenoid piston, for limiting the maximum stroke length of the solenoid piston, abutment surfaces that cooperate with associated counter-abutment surfaces on the solenoid piston to limit the maximum stroke length of the solenoid piston. side of the solenoid piston opposite the valve seat (actuator side).

  Stop buffers are preferably provided between the abutment surfaces and the abutment surfaces to reduce noise.

  A simple solution with regard to the construction technique and an advantageous cost is also to implement, as abutment buffer, a substantially annular sealing element, and more particularly an O-ring. in this case, preferably in a groove made as a prismatic slide. What has been said above is valid as regards the geometrical configuration possibilities including this sealing element.

  The counter-abutment surfaces may be made at the end of the solenoid piston-side magnetic core, for example. In the case of electromagnetically controlled valves with centrally located adjusting screw to adjust the length of the maximum stroke of the solenoid piston, the counter-stop surfaces may also be provided at the end of the solenoid piston side adjusting screw. . The sealing member 10 serving as a stop buffer may be attachable not only to the solenoid piston side, ie to the end of the actuator side solenoid piston, but also to the actuator side, ie for example, at the end of the adjusting screw or solenoid piston-side magnetic core or other support for holding the sealing element. It should be noted that the housing of the sealing element, preferably made as a prismatic slide, can be located not only on the outer periphery, but also on the inner periphery of a corresponding bore in the support, for example, on the inside perimeter of the bore at the end of the solenoid piston on the actuator side, which bore 20 is usually used to receive the screw pressure spring. In all these solutions, it is sufficient to ensure that the geometric positions of the abutment surfaces, abutment surfaces and abutment buffer are tuned to each other.

  In the case of the position of the sealing member acting as an abutment buffer at the end of the actuator-side solenoid piston, it has proven advantageous to use a plastic preform to hold the actuator element. sealing. This can be achieved, for example, essentially as a hollow cylinder which can be inserted into a corresponding bore on the side of the solenoid piston opposite the valve seat and having at its upper end a sealing surface. housing, which extends in the axial direction and short on the outer periphery, with a collar-like termination for attaching and securing the sealing element. The solenoid piston described is simply manufactured and at an advantageous cost.

  Other advantages in terms of fluid technology are obtained if the flow connection is made as a Laval nozzle.

  The electromagnetic control valve according to the invention is suitable for both the proportional mode and the synchronized mode.

Brief description of the figures

  In what follows, the invention will be explained in more detail with reference to the figures.

  Figure 1 is a schematic representation of an electromagnetic valve according to the invention, seen in longitudinal section; FIG. 2 shows, in the same mode of representation as FIG. 1, a solenoid piston for an electromagnetically controlled valve according to a preferred embodiment of the invention.

  Embodiment of the Invention In FIG. 1, a magnetic control valve 1 is recognized in a housing 2 with a supply connection 3 which can be connected to a ventilation connection 20 of a fuel tank, not shown here, or an adsorption filter mounted downstream thereof, as well as with a flow connection 4 to be connected to a suction tube of an internal combustion engine, also not shown.

  The valve 1 comprises a magnetic coil 5 with a magnetic core 6, to which a solenoid piston 7 is conjugated. The solenoid piston 7 can undergo a forward and backward movement between an open position and a closed position. closing according to the supply of the coil 5 in current, the closed position being defined by the support of the solenoid piston 7 on a valve seat 8 at the inlet port 30 of the flow connection 4. The solenoid piston 7 does not bear directly on the valve seat 8: a sealing element is interposed, which is produced, according to a preferred embodiment of the invention, as a ring O-ring. sealing 9 attachable. According to another preferred embodiment of the invention, the O-ring seal 9 is attachable to the solenoid piston 7 which, for this purpose, is provided on its outer periphery, on the side facing the valve seat. 8, an annular peripheral groove 10 made as a prismatic slide. In the embodiment shown, the solenoid piston 7 is guided in what is called a Glyco socket 11. The Glyco socket 11 is surrounded by the magnetic cheek 12.

  Inside the magnetic core 6 in the form of a hollow cylinder is a set screw 13 which, in the embodiment shown, constitutes, without limiting the generality of the invention, an abutment to the movement of the piston stroke In order to adjust the stop, the adjusting screw has a thread which engages in a complementarily made counter-thread. The adjusting screw 13 projects, with its solenoid piston-side end, into a bore 14 formed accordingly on the side of the solenoid piston 7 opposite the valve seat 8. Between the end of the adjusting screw 13 on the piston side of the solenoid and the bottom of the bore 14 is a screw pressure spring, not shown in the figure, which pushes the solenoid piston, in the non-energized state of the magnetic coil 5, to the valve seat 8 , the valve is closed. When the magnetic coil 5 is energized, the solenoid piston 7 is lifted from the valve seat 8 to 20 against the spring force, the valve opens.

  To limit stroke length, the solenoid piston 7 has abutment surfaces 15 which are constituted by an annular shoulder in the bore 14 of the solenoid piston 7, which bore widens conically upwardly. . In the embodiment shown, the associated abutment surfaces 16 are, without limiting the generality of the invention, provided at the end of the solenoid piston-side adjusting screw 13 in the form of a peripheral shoulder. also annular with stop buffer. According to a particularly preferred embodiment of the invention, an O-ring sealing ring 17 serves as an abutment buffer, which O-ring seal is attachable on the end of the adjusting screw 13 solenoid piston side. For this purpose, the end of the solenoid piston-side adjusting screw 13 is provided with a prismatic slide for the sealing ring 17 in the portion of the annular peripheral shoulder.

  In order to improve the characteristics of the valve with regard to the fluid technique, the channel 18 which passes through the flow connection 4 is produced, in a manner known per se, in the form of a Laval nozzle.

  In Figure 2 is shown, by way of example, a preferred embodiment of a solenoid piston mountable in a valve according to the invention. The solenoid piston 70 is made in two parts with an outer shell 71, substantially cylindrical in shape, made of a metallic material and provided with a bore 14 on the actuator side, and with a plastic preform 72 which can be inserted into this piercing 14 to accommodate the O-ring seal 17.

  In the present embodiment, the plastics preform 72 is, without restricting the generality, essentially constructed as a hollow cylinder pot. It has, at its upper end, a housing surface 72a which extends axially and short on the outer periphery, with a collar-like termination 72b for attaching and securing the O-ring 17. The bottom 72c of the preformed plastic material 72 in the form of hollow cylinder can serve as a stop for a screw pressure spring not shown in the figure. The solenoid piston 70 has, at its end facing the sealing seat, a portion 71b which follows the annular groove 71a for receiving the O-ring 9 and which tapers in the shape of a groove. cone down.

  Due to the realization of the cone-shaped solenoid piston wall in this part, the fine metering by the valve is improved.

Claims (18)

  Electromagnetically operated valve, in particular a tank ventilation valve for motor vehicles, which comprises a magnetic coil (5) and a solenoid piston (7) which can be actuated by the magnetic coil (5) and undergo movement back and forth between an open position and a closed position, the closed position being defined by the bearing on the side of the solenoid piston (7) facing a valve seat (8), on the valve seat (8) with a sealing body insertably removably attachable to a support body, characterized in that the sealing body is formed as a sealing element (9) substantially ring which can be attached to the support body.   Electromagnetically controlled valve according to Claim 1, characterized in that an annular groove is provided on the support body in which the sealing element (9) can be clipped.   Electromagnetically controlled valve according to claim 1 or 2, characterized in that the support body is the solenoid piston (7).   Electromagnetically controlled valve according to Claim 2 or 3, characterized in that the annular groove (10, 71a) is located on the outer circumference of the solenoid piston (7) on the side thereof facing the seat of valve (8).   Electromagnetically controlled valve according to one of claims 2 to 3, characterized in that the annular groove (10, 71a) is formed as a prismatic slide.   Electromagnetic actuated valve according to one of Claims 1 to 4, characterized in that the solenoid piston (7) has on the side facing the valve seat (8) a part (71b) which slimming cone.   Electromagnetic actuated valve according to one of Claims 1 to 5, characterized in that the stop surfaces (15) which cooperate are provided for limiting the maximum stroke length of the solenoid piston (7). with counter-stop surfaces on the side of the solenoid piston (7) opposite the valve seat (8) (actuator side).   An electromagnetically controlled valve according to claim 6, characterized in that stop buffers are provided between the abutment surfaces (15) and the abutment surfaces.   Electromagnetically controlled valve according to claim 7, characterized in that the stopper buffer is constituted by a substantially annular sealing element, and preferably an O-ring (17).   10. Electromagnetically controlled valve according to claim 8, characterized in that there is provided a prismatic slide to accommodate the sealing member resp. the O-ring seal (17).   Electromagnetic actuated valve according to one of claims 6 to 9, characterized in that the abutment surfaces are provided at the end of the magnetic solenoid piston core (6).   Electromagnetic actuated valve according to one of Claims 6 to 9, characterized in that an adjusting screw (13) is provided for adjusting the maximum stroke length of the solenoid piston (7) and that the Counter-abutment surfaces (16) are provided at the end of the solenoid piston-side adjusting screw (13).   13. Electromagnetically controlled valve according to one of claims 8 to 11, characterized in that the sealing element resp. the sealing ring (17) is attachable on the actuator side.   Electromagnetic actuated valve according to one of Claims 8 to 11, characterized in that the sealing element resp. the O-ring (17) is attachable on the solenoid piston side.   An electromagnetically controlled valve according to claim 13, characterized in that the solenoid piston (7) comprises a plastics preform (72) for holding the sealing element resp. the O-ring seal (17).   An electromagnetically controlled valve according to claim 14, characterized in that the preform (72) is essentially formed as a hollow cylinder which can be inserted into a corresponding bore (14) on the side of the solenoid piston. (7) opposite to the valve seat (8) and having at its upper end a housing surface (72a), which extends axially and short on the outer periphery, with a collar-like termination (72b) to attach and fix the sealing element resp. the O-ring seal (17).   Electromagnetic control valve according to one of claims 1 to 15, characterized in that the flow connection (4) is designed as a Laval nozzle.   Electromagnetically controlled valve according to one of claims 1 to 16, characterized in that the substantially annular sealing element (9) is an O-ring.