NL8001483A - BODY OF PRESSURE DEPENDENT MATERIAL AND CONTACT SIGNALER PROVIDED WITH SUCH A BODY. - Google Patents

Description

t 'VO 238

Body of pressure-dependent material and contact signal transmitter provided with such a body.

The invention relates to a body of elastically compressible material, the electrical conductivity of which changes when compressed, consisting of a sponge, in which electrically conductive particles are embedded such that with increasingly stronger compression of the material, the contacts between the particles increasingly flow paths are formed through the material.

The invention further relates to a contact signal generator for generating a contact signal upon contact of a part with another part using a body 10 of the type described above. Such a contact signal transmitter is characterized in that on one part a first and a second electrically conducting contact member with an intermediate space is arranged between them, on this one part a body of said material is provided, which extends over the contact members and the intermediate space , this body is compressed upon contact of the parts and there is a signal circuit which is connected to the contact members and responds to changes in electrical resistance therebetween.

The invention will be explained in more detail below with reference to the drawing. In the drawing: Fig. 1 schematically shows a cross-section of a body of material according to the invention in a relaxed state; FIG. 2 is a sectional view of the body in a partially compressed state; Fig. 3 shows a contact signal generator, which has been built-up using the body, and which provides a density signal when closing a poppet valve; Fig. 4 shows a contact signal transmitter, which has been built-up using the body, which signals that the valve 800 1 4 83 * - 2 - has reached the open position and, for example, disables a setting actuator; and Fig. 5 is a variant of the embodiment according to Fig. 4.

In Fig. 1 schematically a sponge, e.g. made of plastic in section. The sponge contains a large number of air spaces, the walls 12 of which are made of a rubber-elastic material, e.g.

a rubber-elastic plastic. Electrically conductive particles 14 are embedded in this rubber-elastic material and partly also extend into the air spaces 10. In the relaxed state, as shown in Fig. 1, the particles are strongly separated from each other and insulated from each other by the non-conductive plastic and the air spaces 10. In this condition, the material has very little conductivity.

When the sponge, as indicated in fig. 2, is compressed, the particles 14 come into contact with each other more and more, so that longitudinal and transverse flow paths, e.g. 16 or 18 are formed. The more strongly the body is compressed, the more such flow paths are formed, so that the conduction of the body increases significantly when compressed.

A body of this type can be used in many ways. A preferred application of such a body is found in a contact signal generator, which is to supply a contact signal at the contact of one part with another part.

An application of such a contact signal generator is found in Fig. 3. A density signal must be generated when a poppet valve is closed. It is essential that the signal is only generated when the valve disc is indeed resting uniformly on the seat and the closing movement is not e.g. is bounded by a foreign body clamped between the seat and the dish.

In the embodiment according to Fig. 3, one valve, namely the valve disc 20, has a first and a second electrically conductive contact member. The first contact member is formed by a central contact plate 22 disposed on the valve seat side 20 on the valve disc 35, while the second contact member is formed by a contact ring surrounding the contact plate 22 concentrically with a gap 24 26. A body according to FIGS. 1 and 2 is arranged on this valve seat 20, which body extends over the contact members and the intermediate space 24. This body is a disc 28 (optionally also an annular disc), which is arranged on the valve seat side by the contact plate 22 and the contact ring 26 on the valve disc. The other part is a valve seat 30 which, when the valve is closed, rests against the disc 28 in the region of the gap 24. Upon contact of the two parts, viz. The valve disc 20 and the valve seat 30, the disc 28 is compressed, the conductivity of which changes. A signal generator circuit 32 is provided, which is connected via conductors 34, 36 to the contact members, namely the contact disc 28 and the contact ring 26, and responds to changes in electrical resistance therebetween. Such a signal generator circuit is known per se and will therefore not be further described here.

The valve disc 20, which is mounted on a valve pin 38 and is loaded by a closing spring 40, consists of electrically non-conductive material. The central contact plate 22 rests in a recess of the valve disc 20 and the contact ring 26 is recessed along the edge of the valve disc 20 so that an electrically non-conductive rib 42 is formed between the contact plate 22 and the contact ring 26. The disc 28 is uniformly compressed between this rib 42 and the valve seat 30.

The above-described contact signal transmitter does not only check whether the closing movement of the valve disc encounters resistance, e.g. this would be the case in the presence of a foreign body between the valve seat and the valve disc, even with an incorrectly closed valve, but also checks whether the valve disc 20 with the disc 28 rests uniformly along the entire circumference on the valve seat 30 . With only one-sided resting, the disc 28 would be compressed only locally, so that the total conductivity required to address the signal generator 300 would not be achieved. Compression of the disc 2Θ on one side with such great force does not affect the shape of the disc on the other parts of the circumference practically at all if it does not also rest on the valve seat 30 on the opposite side. The disc 28 of sponge-like material can at the same time serve as a sealing disc of the valve seat 30, which ensures a good sealing of the valve when properly resting.

Fig. 4 shows another application of a contact signal transmitter, which is provided with a body according to Fig. 1 and 2.

In the embodiment according to Fig. 4, a valve disc 44 is present, which cooperates with a valve seat 46 and which can be pressed by means of a valve pin 48 by a position actuator (not shown).

The valve disc 44 is loaded by a compression spring 50 which bears against a housing 52. The opening movement of the valve disc downwards in Fig. 4 is limited by an adjustable stop 54. The stop 54 is fed axially adjustable into a screw thread 56, which screw thread is provided in a sleeve-like projection 58 protruding from the inside of the housing 52. A sealing screw 60, which is also screwed into the thread 56, closes the interior of the sleeve-like projection 58 outwards. A cylindrical projection 64 is provided on the valve seat 44 and is axially displaceably guided in the sleeve-like projection 58. At the end of the projection 64 there is a contact signal transmitter 66, which comes to rest against the stop 54 at the desired full opening stroke of the valve disc 44. The occurring contact signal can be used to disengage the actuator. The closed position of the valve disc 44 is also checked by a contact signal transmitter 68, which checks the sealing of the valve in the closed position.

The contact signal generator S6 in the embodiment of FIG. 4 includes two half-annular contact members 70, 72 insulated from each other, which are separated from one another by an insulating rib 74,35. Over the 80 0 1 4 83 5 - # - 5 - contact members 70, 72 and the rib or spacing 74 extends a disk 76 of a foamy material of the type described above with reference to FIGS. 1 and 2.

Likewise, the contact signal generator 6-5 has two contact members 78, 80 in the form of two concentric contact rings separated from each other by a gap 82. The intermediate space 82 is formed by an annular rib of the valve disc 44 or an annular body 84 consisting of insulating material inserted into the valve disc 44. On the valve seat side, an annular disc 86 is located on the valve disc 44, which disc extends over the contact rings 78 and 80 and the spacing 82. Both contact rings 78 and 80 are connected to a signal generator circuit 88, which, when the valve disc 44 is resting on the valve seat 46, seals the valve tightness.

The operation of this contact signal generator corresponds to that of the contact signal generator according to Fig. 3.

The embodiment according to Fig. 5 strongly resembles that according to Fig. 4. and corresponding parts are therefore also provided with the same references. In contrast to the embodiment of FIG. 4, in the embodiment of FIG. 5, the contact signal generator 66 is not mounted on the projection 64 but on the stop 54.

The other construction is the same as in the embodiment according to fig. 4 and will therefore not be further elucidated here.

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Claims (5)

1. Body of elastically compressible material, characterized in that the electrical conductivity of the material changes upon compression, which body consists of a sponge, in which electrically conductive particles C243 are embedded such that when added. As the material is compressed by contacts between the ♦ particles C14D, more and more flow paths C16, 18] are formed in the material. 2. Contactor for generating a contact signal at the contact of one part with another part using a body according to claim 1, characterized in that on one part (20] a first and a second electrically conductive contact member (23, 26] with an intermediate space (24) arranged therebetween, a body (20] of said material is arranged on this one part (20], which body extends over the contact members (22, 26] and the intermediate space (24], this body (20] upon contact of the parts (20, 30] is compressed and a signaling circuit (32] is present, which is connected to the contact members (22, 26) and to changes in the electrical resistance between them) appeals. Contact signal generator according to claim 2 for generating a density signal when a poppet valve is closed, characterized in that the one part is a valve poppet (20) and the first contact member through a valve seat side on the valve seat side. valve disc arranged central contact plate (22] and the second contact member is formed by a contact ring (26] concentrically disposed therewith concentrically disposed therewith, the body of said material being a disc (28] or annular disc (06), which the valve seat side is fitted to the valve disc 30 (20] through the contact plate (22] and the contact ring (26)) and the other part is a valve seat (30] which, when the valve is closed, in the area of the gap (24] against the disc (23] or the annular disc (06) rests. 80 0 1 4 83 - 7 - -f 9 Contact signal generator according to claim 2, characterized in that the one part, the contact members and the body supporting one part is a valve disc (44), which can be brought into the open position by an actuator actuator, the other part 5 a stop ( 54) which limits the opening stroke of the valve disc (44) and the actuator can be switched off by the signal switching (88) (fig. 4). Contact signal generator according to claim 2, characterized in that said other part is a valve disc (44), which can be brought into the open position by an adjusting actuator, the contact members (70, 72) and the body ( 76) supporting one part is a stop (54) which limits the opening stroke of the valve disc (44) and the actuator can be switched off by the signal generator circuit (fig. 5). 15 8 0 0 1 4 83