EP2325472A1 - Seal assembly and valve with same - Google Patents

Abstract

The component has a flexible membrane (26) comprising an inner membrane edge (261) and an outer membrane edge (262). The flexible membrane with the inner membrane edge is sealed against a force transmission element (50), and with the outer membrane edge is sealed against a body (51). A medium (24) with definite flow limit is enclosed between the membrane and an area of the body, where the area is covered by the membrane. The membrane is made of stainless steel sheet metal and elastomer. A ring i.e. sliding ring (48), is fixed on the force transmission element. The medium with the definite flow limit is utilized as an elastomer and grease. The component utilizes a medium with increased flow limit such as a Bingham fluid, silicone oil and transformer oil.

Description

State of the art

The invention is based on a seal assembly for sealing a power transmission element guided in a bushing in a body.

A known seal assembly of this type (" The manual of the metal bellows ", Witzenmann GmbH, Pforzheim, publication 441, 1997, page 176ff .) Has a power transmission element covering bellows made of metal, one end of which is fixed to the power transmission element and the other end face concentric to the body bushing on the body each liquid-tight. The power transmission element is, for example, a spindle with relative to this rotatable spindle head for a shut-off or control valve for liquids or gases, which is rotationally guided in a passage in the valve body and immersed in a valve body formed in the valve chamber and controls a valve opening via the axially displaceably guided spindle head.

A known injection valve ( DE 10 2007 028 490 A1 ) is formed in a valve seat body inserted into a valve body, which consists of a valve opening and a valve seat enclosing this valve seat carrier and the valve seat carrier end face final lid, a valve space and made in the valve housing a connection between a fluid inlet and the valve chamber. In the valve body, more precisely in the cover, a central passage is formed, through which a force transmission element in the form of a valve head carrying a closing head extends up to the valve opening. The valve needle is loaded to close the valve opening with a valve closing spring and driven to release the valve needle by a piezoelectric actuator, where the valve needle with their from the end facing away from the closing head frictionally rests under the action of the valve closing spring. To seal the non-fluid-resistant actuator relative to the fluid in the valve chamber, a sealing member sealing the valve needle bushing is provided which is designed as a bellows. The corrugated bellows is pushed onto the valve needle and fixed fluid-tight by welding at one end to the valve needle and at the other end to the cover. The cover in turn covers the one open front end of the actuator accommodating actuator housing fluid-tight.

Disclosure of the invention

The seal assembly according to the invention with the features of claim 1 has the advantage that an existing in the implementation guide gap between the power transmission element and the body is reliably sealed by the medium, which can not pass through the guide gap due to its correspondingly selected yield point. The seal assembly seals reliably even when acting on the membrane, very high pressures, which are above the limit pressure load of Wellbälgen. Only the flow limit of the medium used must be selected according to the prevailing maximum pressure. The medium can be freely selected with regard to its environmental compatibility, cleanliness, temperature and swelling behavior, thus opening up a wide field of use for the sealing member.

The seal assembly of the invention may e.g. are advantageously used in valves, in particular in injection valves in motor vehicles, in which high fluid pressures of e.g. up to 200bar and more occur.

The measures listed in the further claims advantageous refinements and improvements of claim 1 seal assembly are possible.

According to an advantageous embodiment of the invention, the medium is inserted or injected in the space bounded by the membrane and body. In this case, a soft elastomer is preferably used as the medium.

According to an advantageous embodiment of the invention, the medium has at least two substances arranged in a layered manner with different yield points, the substance having the higher yield point directly covering the region of the body spanned by the membrane. By these measures, a reliable seal at even higher pressures is possible.

According to an advantageous embodiment of the invention, the membrane is made of a thin sheet steel or of an elastomer and made in both cases, the sealing of the membrane edges by material bond. In the case of the formation of the membrane made of sheet steel, the material connection between the membrane and the body on the one hand and membrane and power transmission element on the other hand by welding or soldering and in the case of the production of the membrane made of an elastomer by injection into the body and the force transmission element.

According to an advantageous embodiment of the invention, a ring is fixed fluid-tightly on the force transmission element, on which the sealing of the inner membrane edge of the membrane is made with respect to the force transmission element. By means of this ring, the definition of the inner edge of the membrane manufacturing technology can reliably and inexpensively. In this case, the ring can also take over the function of a sliding ring for sliding guide of the power transmission element in the implementation, which limits together with the body existing in the implementation sliding gap.

According to an advantageous embodiment of the invention, a medium-filled chamber is formed in the body, which is in communication with the region of the body covered by the membrane. About the chamber covered by the membrane area of the body can be filled with medium after mounting the membrane.

According to an advantageous embodiment of the invention, the force transmission element is slidably guided in a region of the bushing which lies in a body region delimiting the chamber on its rear side facing away from the membrane, and the connection of the chamber is also made by an annular channel over the region of the body covered by the membrane. the one of the the inner membrane edge receiving ring and the body is limited. To slide the power transmission element, a guide ring is fixed fluid-tight on this, which limits the sliding gap with the body. In addition, the sliding gap can be sealed by means of a radial seal.

According to an advantageous embodiment of the invention, the filling of the chamber with the medium via a running in the power transmission element and opening into the chamber filling hole, which is closed after filling takes place. Preferably, the filling hole is realized from a introduced from the front end axial blind hole and at least one opening into this and in the chamber radial bore and closed the blind hole by means of a pressed ball.

A valve with a seal assembly according to the invention is specified in claim 15.

Short description of the drawing

Fig. 1

einen Längsschnitt eines Einspritzventils für ein Fluid,

Fig. 2

eine vergrößerte Darstellung des Ausschnitts II in Fig. 1 mit einer konstruktiven Modifikation,

Fig. 3

eine gleiche Darstellung wie in Fig. 1 mit einem modifizierten Dichtungsglied.

The invention is explained in more detail in the following description with reference to exemplary embodiments illustrated in the drawings. It shows in sections:

Fig. 1

a longitudinal section of an injection valve for a fluid,

Fig. 2

an enlarged view of the section II in Fig. 1 with a constructive modification,

Fig. 3

a same representation as in Fig. 1 with a modified seal member.

The presented here, novel seal assembly will be described below in connection with their installation in an injection valve for fuel, which is used in the cylinder head of an internal combustion engine and metered under high pressure fuel injected into the combustion chamber of the internal combustion engine.

The seal assembly is also applicable in other valves where high reliability in the sealing of the valve, e.g. polluting liquid or gases is required. In principle, the seal assembly can be used anywhere where an axially displaceable, passing through a trained passage in a body, sliding in the implementation or rotationally guided power transmission element that transmits a valve applied by a manual or electro-mechanical actuator adjusting force on a valve opening controlling the valve opening to seal reliably.

In the Fig. 2 For this purpose, a seal assembly sketched in isolation has a flexible, eg annular membrane 26, which is sealed with an inner membrane edge 261 against the force transmission element 50 and with an outer membrane edge 262 against the body 51, and a medium 24 with a defined yield point between the membrane 26 and a covered by the membrane 26 portion of the body 51 is included. The membrane 26 consists for example of a thin steel sheet and the sealing of its membrane edges 261, 262 is effected by material connection between the metallic body 51 and the membrane 26 on the one hand and the metallic force transmission element 50 and the diaphragm 26 on the other. The material bond is made here by welding, as shown by the welds 37 and 36 in Fig. 2 is indicated. Alternatively, the membrane 26 is made of an elastomer. In this case, the sealing of the membrane edges 261, 262 by edge-side injection of the membrane edges 261, 262 in the force transmission element 50 and the body 51. The passage 52 forms a sliding guide for the power transmission element 50, wherein in the implementation of a sealing of the seal assembly sliding gap 53 remains. The yield point of the medium 24 is selected as a function of a pressure acting on the membrane 26. If, for example, the sliding gap 53 present between the force transmission element 50 and the body 51 in the bushing 52 has a gap width of 5 μm and a gap length of 20 mm, a medium 24 with a yield point of at least 3750 N is at a maximum pressure of 300 bar acting on the membrane 26 / m ² selected. As the medium 24, a soft mass with high yield point, preferably elastomer or fat, is used, which is inserted or injected into the limited space 26 of the membrane 26 and the body 51 space. In the embodiment of Fig. 2 The medium 24 has at least two layers arranged substances 241 and 242, which are, for example elastomers with different flow limit or strength. The substance 241, which bears directly on the front side of the body 51, thereby has the greater strength.
On the power transmission element 50, a ring is placed in a fluid-tight manner, wherein the fluid-tight connection by material connection (weld 31) is made, and the determination of the inner membrane edge 261 of the membrane 26 is made on the ring. As a result, the diaphragm 26 with its inner diaphragm edge 261 can be set to a favorable design on the force transmission element 50. The ring takes over as a sliding ring 48 at the same time sliding and guiding function for the power transmission element 50 in the implementation 52nd

In the in Fig. 1 The longitudinal section of a valve, shown in longitudinal section, serves for the above-described sealing assembly for the reliable sealing of non-fluid-resistant components in the valve with respect to the fluid under pressure in the valve. For example, the valve is an injector and the fluid is fuel for gasoline or diesel engines and the seal assembly seals a fuel-resistant piezoelectric actuator 20. The actuator 20 is accommodated in an actuator housing 21, which in turn is arranged in a valve housing 11. On the valve housing 11 from this axially projecting, funnel-like valve seat carrier 14 is fixed by means of a circumferential weld 13. On the side facing away from the valve housing 11 free end of the valve seat carrier 14 is a valve opening 16 and a valve opening 16 surrounding the valve seat 17 and a guide 18 for a valve needle 19 is formed. The other end of the valve seat carrier 14 is closed fluid-tight with a cover 27, which also closes the actuator housing 21 also fluid-tight. Both in the valve seat carrier 14 and in the actuator housing 21, the lid 27 by means of the fluid-tightness producing, circumferential welds 29, 34 attached. In the valve seat carrier 14 closed by the cover 27, a valve space 22 is formed, which communicates with an annular gap 23 present between the valve housing 11 and the actuator housing 21 with an inflow for the fluid or the fuel, not shown here. The valve needle 19, which is designed here, for example, as an outwardly opening valve needle 19, carries at its one end a closing head 191 which cooperates with the valve seat 17 on the valve seat carrier 14 for closing and releasing the valve opening 16. The closing of the valve is effected by a valve closing spring 46, which is supported on the valve seat carrier 14 and a spring plate 47 on the valve needle 19, the opening of the valve takes place by the actuator 20 to which the passing through the lid 27 and slidably guided therein valve needle 19 rests positively with their facing away from the closing head 191 front end.

Compared to that too Fig. 2 described seal assembly is the valve chamber 22 delimiting cover 27, the body 51 with passage 52 and here in the implementation 52 slidably guided power transmission element 50, the valve needle 19, the closing force of the valve closing spring 46 and the opening force of the actuator 20 seated on the valve seat 17 Closing head 191 transmits. In the region of the passage 52 sits on the valve needle 19 of the sliding ring 48 which is fluid-tightly connected to the valve needle 19 via the weld 31, wherein between the slide ring 48 and the cover 27 of the membrane 26 and medium 24 sealed sliding gap 53. The membrane 26 is fastened in the same way on the sliding ring 48 and cover 27, as to Fig. 2 is described. The enclosed by the membrane 26 and the lid 27 medium 24 is different than in Fig. 2 from a single substance, as stated in the remarks Fig. 2 is specified. The medium 24 is inserted or injected. The space 29 enclosed between membrane 26 and lid 27 can also be filled from the rear side of the lid 27 with the medium 24 via simple axial channels, which are then closed.

In the in Fig. 3 The exemplary embodiment of the valve, which is likewise embodied as an injection valve, is modified in section and in the body 51 in addition to a medium-filled chamber 25 which surrounds the body 51 into a front body part 511 provided with the membrane 26 and the actuator housing 21 subdivided final rear body part 512. In the region of the passage 52 located in the front body part 511, a connection of the chamber 27 to the space 29 enclosed by the diaphragm 26 and the body 51 is established, and in the region of the passage 52 located in the rear body part 512 is the sliding guide of the force transmission element 50 realized. The existing between power transmission element 50 and body 51 sliding gap 53 is additionally sealed by means of a radial seal, whereby drag losses are avoided by the sliding gap 53.

Is concrete in Fig. 3 the front body part 511 is formed by the cover 27 terminating the valve space 22 and the rear body part 512 by an end plate 33 closing off the actuator housing 21 in a fluid-tight manner. the end plate 33 is seated in a fluid-tight manner on an overhanging projection 11 of the valve seat carrier 14 projecting axially over the cover 27, which limits the chamber 25 enclosed between the cover 27 and the end plate 33 at its circumference. The fluid-tight connections of the end plate 33 are in turn made by welds 34 and 35. Unlike in Fig. 1 Here is the valve seat carrier 14 in two parts and composed of a means of the weld 13 on the housing fluid-tight housing insert 142 and an axially inserted in the housing insert 142 and with a weld 15 fluid-tight at this fixed sleeve 141 composed. In the lid 27 located in the region of the passage 52, which in comparison to the implementation 52 in Fig. 1 and 2 designed to be significantly larger, the valve needle 19 carries a ring 30, which is different than in Fig. 1 and 2 has no sliding function, but only for attachment of the inner membrane edge 261 of the membrane 26 is used. Between the ring 30 and the cover 27 leads an annular channel 32, which establishes the connection of the chamber 25 to the space enclosed by the membrane 26 and lid 27 space 29.

The sliding guide in the region of the bushing 52 located in the end plate 33 is realized by a guide ring 42, which is fastened in a fluid-tight manner to the valve needle 19 by means of a weld 41 and which delimits the sliding gap 53 with the end plate 33. The radial seal is realized by means of a sealing ring 40 which rests in an inserted into the end plate 33 annular groove 39 and presses against the guide ring 42. Because of the high yield point of the medium 24 located in the chamber 24, a simple O-ring can be used for radial sealing.

The filling of the chamber 25 and thus the space 29 via an introduced into the valve needle 19 filling hole, which opens into the chamber 25. In the illustrated embodiment, the filling hole is composed of a blind hole 43 introduced into the valve needle 19 at the front side and at least one radial bore 44 introduced into the valve needle 19 in the area of the chamber 25, which runs into the blind bore 43. In the illustrated embodiment, two radial bores 44 are present, which are realized by opening into the chamber 25 transverse bore. After filling the medium 24 is the Blind hole 43 closed, which is made here by pressing a ball 45. As a medium 24 can also be a soft mass with high yield point, such as elastomer or fat, or a liquid with high yield point, eg Bingham fluid, viscous silicone oil, transformer oil, u. Like. Be used.

Claims (15)

A seal assembly for sealing a power transmission member (50) carried in a passageway (52) in a body (51), characterized by a flexible diaphragm (26) having an inner diaphragm rim (261) against the force transmitting member (50) and an outer diaphragm rim (262) is sealed against the body (51) and by a fluid (24) having a defined yield point trapped between the membrane (26) and a portion of the body (51) covered by the membrane (26). Sealing assembly according to claim 1, characterized in that the yield point of the medium (24) is selected depending on a maximum pressure acting on the membrane (26). Seal assembly according to claim 2, characterized in that the force transmission element (50) in the passage (52) is slidably guided and a medium (24) is selected whose yield point at a in the bushing (52) sliding gap (53) having a gap width of 5μm and a gap length of 20mm and at a pressure acting on the membrane (26) pressure of a maximum of 300bar is at least 3750 N / m ² . Sealing assembly according to one of claims 1 to 3, characterized in that the medium (24) is a high yield point soft mass, preferably elastomer or fat, or a high yield point liquid, preferably Bingham liquid, viscous silicone oil or transformer oil. Sealing assembly according to one of claims 1 to 4, characterized in that the membrane (26) made of a thin sheet steel or elastomer and the sealing of the membrane edges (261, 262) by material connection between the membrane (26) and body (51) on the one hand and Membrane (26) and power transmission element (50) on the other hand, preferably by welding or injection, is made. Seal assembly according to one of claims 1 to 5, characterized in that on the force transmission element (50) a ring is fixed in a fluid-tight manner, at which the sealing of the inner membrane edge (261) of the membrane (26) against the force transmission element (50) is made. Seal assembly according to claim 6, characterized in that the ring is a sliding ring (48) which, together with the body (51) delimits the sliding gap (53). Sealing assembly according to one of claims 1 to 6, characterized in that in the body (51) with the medium (24) filled chamber (25) is formed, which with the membrane of the (26) covered area of the body (51) in Connection stands. Seal assembly according to claim 8, characterized in that the force transmission element (50) is slidably guided in a region of the passage (52) lying in a body region delimiting the chamber (25) on its rear side facing away from the membrane (26), and in that Connection of the chamber (25) to the region of the body (51) covered by the membrane (26) is produced by an annular channel (32) which extends from the ring (30) receiving the inner membrane edge (261) and the body (51). is limited. Sealing assembly according to claim 9, characterized in that on the force transmission element (50) a guide ring (42) is fixed in a fluid-tight manner with the body (51) defining the sliding gap (53) in the passage (52). Sealing assembly according to claim 10, characterized in that the sliding gap (53) is sealed by means of a radial seal. Seal assembly according to one of claims 8 to 11, characterized in that the chamber (25) via at least one in the force transmission element (50) extending, in the chamber (25) opening out filling hole with the medium (24) can be filled and the filling hole is closed when the filled chamber (25). Sealing assembly according to one of claims 1 to 7, characterized in that the medium (24) is inserted or injected into the region of the body (51) covered by the membrane (26). Seal assembly according to claim 13, characterized in that the medium (24) has at least two layered substances (241, 242) with different yield point and that the substance (241) with the higher yield point directly the body (51) covered. Valve, in particular injection valve for a fluid, characterized by a seal assembly according to one of claims 1 to 14, wherein the body (51) defines a valve opening (16) having an inflow associated valve chamber (22) and the force transmission element (50 ) is formed by a in the passage (52) in the body (51) slidably, the valve space (22) penetrating valve needle (19).

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