FR2521341A1 - Automobile manometric pressure sensor and insulating support mfr. - has two fixed contacts embedded in insulating block with one attached to metallic base - Google Patents

Abstract

The manometric contactor has a metal base through which a central bore, which communicates the fluid pressure to be sensed, passes to a pressure membrane. Two electrical contactor strips are embedded in an insulating block. One of the contactors is electrically connected to the conducting base. The pressure is transmitted, via the membrane, to a sliding piston which has a cylindrical head which moves in the bore of a capping section. A spring, calibrated for the pressure to be sensed, bears against the end of an annular trough in the capping section and a conducting ring. At low pressures, the spring forces the ring down into electrical contact with the ends of the two contactor strips to complete an electrical circuit. When the pressure increases, the piston lifts the ring off the contactor strips.

Description

 The present invention relates to a pressure switch whose function is to modify the state of an electric circuit when a predetermined pressure of a given fluid is reached. Preferably, the contactor is intended to close the electrical circuit when the pressure exceeds the predetermined threshold.

 Such a device can be used for example in a motor vehicle, to alert the driver that the minimum pressure of the engine oil is reached.

 Known manometric contactors are conventionally formed of an at least partially insulating body which defines a pressure chamber communicating with the fluid which it is desired to detect a pressure threshold and which is delimited on one side by a deformable membrane, a pusher being swept by the membrane, opposite the chamber; a spring, calibrated as a function of the fluid pressure threshold to be detected, acts on the pusher and the diaphragm to urge them to move towards the chamber, and electrical means cooperating with the pusher detects the displacement of the diaphragm when the pressure in the chamber crosses said threshold.

 The electrical means used up to now are constantly formed of two separate conductive elements having respective extensions substantially normal to the axis of displacement of the pusher, and spaced apart from one another along said axis of displacement. is made at least partially in flexible and deformable form and cooperates with the pusher and the membrane so that it can be brought into contact with the other conductive element, fixed, when the minimum pressure, ale is reached in the chamber, In contrast, when the pressure in the chamber exceeds the minimum pressure, the diaphragm is pushed out of the chamber and the electrical circuit is opened again by separating the conductive elements.

 Figure 1 of the accompanying drawing illustrates, in axial section, a manometric switchtored of the conventional type. More precisely the right half of the drawing shown the contactor in the closed position of the electrical contact (minimum pressure) and the left half, in the open position of the electrical contact. This figure 1 shows the body of the contactor, formed of a base 10 and a cap 30. The base 10, made of conductive material is provided with an axial orifice 11, in communication with the fluid which is desired detect a pressure threshold. The orifice 11 opens into a chamber 12 defined between a deformable membrane 20 and the base 10.

 The membrane 20 supports, opposite the chamber 12, a pusher of insulating material 21. The base 10 is crimped on the cap 3Q made of insulating material, so as to trap between the cap 30 and the base 10 , a transverse plate 40 of conductive metal, electrically connected to the base 10, to form one of the aforementioned conductive elements. the plate 40 ~ is provided with an axial orifice in which the pusher 21 is movable.The cap 30 supports at its upper part a second conductive element 50 which forms a bearing surface for a calibrated spring 60, electrically conductive disposed between this second conductive element 50 and an electrically conductive contact bowl 70, supported by a bearing surface 23 defined on the pusher 21, and directed towards the second conductive element 50.

 The operation of the pressure switch shown in Figure 1-is the following. When the pressure of the fluid contained in the chamber 12 is greater than the reaction force of the calibrated spring 6Q, the pressure acts on the membrane 2Q suollicivter the pusher 21 towards the second conductive element 5Q, until the base 22 the pusher 21 comes into contact against the plate 40. Thus the pusher lifts the contact bowl 70 and away from the plate 40 electrically connected to the base 10 (left half clive of the figure ?.

 When the fluid pressure in the chamber 12 is equal to the reaction force of the calibrated spring 60, the system is in equilibrium. If this pressure becomes less than the reaction force of the spring 60 (right half of the figure), it pushes the contact bowl 70 against the plate 40 so as to establish an electrical connection therebetween. An electrical path is then defined between the base 10 and the second conductive element 50 supported on the upper part of the pressure switch, via the plate 40, the bowl 70 and the spring 60.

 I; However, it turns out that depending on the use made of the pressure switch, the intensity of the current flowing between the base 10 and the second conductive element 5Q is higher or lower, which causes a variable heating of the spring. In some particular cases it may even be necessary to circulate in the spring 60 a high current causing excessive heating thereof. Some car manufacturers thus wish to test a large number of indicator lights, in series of the contactor which requires the use of a relatively high intensity current which must imperatively go through the spring. As a result, the mechanical characteristics of the spring 60 are altered and an adjustment in the setting of the device can occur.

 To try to remedy this drawback, it has been proposed to isolate the spring 6Q, the second conductor 50, and to design a resilient cup electrically integral with the plate 40 and the base 10. Such an embodiment is shown, in axial section, in Figure 2 of the accompanying drawing.

More precisely the right half of the drawing represents the contactor in the open position of the electrical contact while the left half represents the contactor in the closed position of the electrical contact (minimum pressure). In fact, in this FIG. 2, the base 10 made of conductive material, provided with an axial orifice 11, provides a communication between the fluid whose pressure threshold is to be detected and the chamber 12 defined between the deformable membrane. 20 and the base 10. It is further provided a sleeve 80 on which is crimped the base 10, so as to clamp between said sleeve 80-and the base 10, an electrically conductive elastic bowl 85, a conductive metal plate 40 and the deformable membrane 20. An inner cap body 30 of insulating material is overmolded on the sleeve 80. The inner cap body 30 is provided with an axial orifice in which a second elongate conductive member 50 is engaged carrying a conductive part at its lower end. 51 of large flare projecting from the periphery of the inner cap body 30 below the conductive bowl 85. The part 51 is thus able to be in contact with said bowl 85. As it appears in FIG. 2, the internal body 30 defines a bearing surface, oriented towards the membrane 20, serving as a seat for the calibrated spring 60 disposed between the inner body 30 and the elastic bowl 85. In addition, a cup 21 made of insulating material forming a pusher is inserted between the deformable membrane 20 and the elastic bowl 85.

 The operation of the device shown in FIG. 2 is the following. When the pressure of the fluid in the chamber 12 is greater than the reaction force of the calibrated spring 60, this pressure acts on the deformable membrane 20 to move the pusher 21, itself bearing against the elastic bowl 85, so as to move away the latter of the conductive piece 51 supported in the internal cap body 30, and thus cut the electrical connection between this piece 51 and the right base 10 of Figure 2). When the fluid pressure becomes less than. the reaction force of the calibrated spring 60, the latter pushes the electrically conductive elastic bowl 85 against the conductive part 51, to establish again the electrical connection between the latter and the base 10 (me left y of Figure 2).

 The electrical path formed between the base 10 and the second conductive element 50 is thus formed by the elastic bowl 85. This arrangement certainly makes it possible to solve the drawback mentioned above, in the measure ol the spring 60 is no longer involved in the establishment of the electrical connection. The elastic bowl 85 has in fact sufficient dimensions so that the current flowing through it does not cause appreciable heating and thus its mechanical characteristics are not affected by the value of the intensity of the current.

 However, this last solution raised a second problem as important as the first one. Indeed, the electrically conductive elastic bowl 85 acts on the deformable membrane 20, via the pusher 21, against the pressure of the fluid, and consequently, intervenes in the calibration of the spring 60. found that it was particularly difficult to machine in a simple and fast manner such electrically conductive elastic cups 85 having constant mechanical characteristics. It is therefore understandable that it is still very difficult, if not impossible, to obtain a correct and constant precision of the contactor since two flexible elements intervene to determine the pressure threshold. Whatever it may be, such a bowl raises substantially the cost of the contactor. On the other hand, in general, the intervention of a flexible deformable element for the formation of the electrical path greatly weakens the reliability of the contactor.

 Previously existing pressure switches do not give satisfaction. Indeed it has not been known, so far, achieve simple and economical manometric contactors, which are> both. reliable and accurate and in a wide range of conditions of use such as those, which are imposed in the vicinity of a motor vehicle engine.

 The present invention now proposes a new pressure switch that eliminates the aforementioned drawbacks while being simple, fast, robust and economical.

 The pressure switch according to the present invention is of the type comprising an at least partially insulating body which defines a pressure chamber communicating with a fluid which it is desired to detect a pressure threshold and which is delimited on one side by a deformable membrane, a pusher supported by the diaphragm, opposite the chamber, a spring, calibrated according to the threshold-fluid pressure to be detected, which acts on the pusher and the membrane to urge the movement thereof to the chamber, wherein the electric zoo cooperating with the pusher to detect the displacement of the membrane when the pressure in the chamber crosses said threshold, comprises two conducting elements, riidess and separated, supported in a fixed position by the body, and whose ends s' extend, on both sides of the pusher, and sensi> bleement in a common plane, normal to the axis of movement of the pusher, and a rigid member, electrically conductive, supported by the pusher transversely L the axis of movement thereof and which is moved between an isolated position and a position of contact with the two conductive elements to establish or cut the electrical connection between them when the pressure in the chamber crosses said given threshold, causing the displacement of the membrane and the pusher, so that when the electrical connection is established between the two conductors, the electrical path is formed solely by rigid members.

 The invention of the present invention, thus consisting in introducing a third conductive element capable of being moved between an isolated position and an almost identical intact position with the two fixed conductive elements in order to establish that the electrical connection between them is cut off, makes it possible to to overcome the aforementioned drawbacks. Indeed, in such a case, only the calibrated resistor 60 acts on the deformable membrane 20 against the pressure of the fluid. The setting of the spring 60 is then simple to achieve.En addition, it is understood that the electrical path being formed only by perfectly rigid members, the reliability of the pressure switch according to the present invention is significantly increased compared to previously existing devices asqu no deformable element intervenes in the establishment of the electric path; the spring 60 simply playing the role of return spring.

 According to a feature of the present invention, the body is formed of a base recessed internally and traversed by a hole that communicates with the fluid, a hollow support of insulating material of generally cylindrical shape held on the base so as to grip against it the periphery of the membrane, to define between the membrane and the base said chamber, into which the orifice opens, and to support the two conductive elements in appropriate position, while defining an axial recess which houses the spring and the pusher, and a cap immobilized on the insulating support to serve as a fulcrum spring acts on the pusher.

 Preferably, the pusher is guided, on the one hand, by a cylindrical chamber provided in the cap, on the other hand by the base of the insulating support.

 According to a first embodiment, one of the conductive conductors is electrically connected to the base formed of conductive material, while the second conductive element is housed in the insulating part of the body and projects from the outside of the body. this one.

 According to a second embodiment, the two upstream conductor elements housed in the insulating support and pass through the cap of the body so as to project outside the latter. In this case, the cap will preferably be shaped as a connector.

 Advantageously, the pusher carries two spaced apart transverse members, between which are arranged the extensions of the two conductive elements, one of the members playing the role of rigid transverse conductor member for establishing the electrical connection between the two conductive elements and limiting the displacement, in one direction, of the membrane, the other acting as an abutment intended to limit the displacement in the other direction of the same membrane, to avoid any deterioration thereof.

 The rigid transverse member intended to establish the electrical connection between the two conductive elements may be disposed either opposite the calibrated spring with respect to the extensions of the conductive elements, or the side of the calibrated spring with respect to the prolongations of said conductive elements, the spring being calibrated either according to a minimum pressure, or according to a maximum pressure.

 According to an alternative embodiment, the method for producing the insulating support of the conductive elements for a pressure switch in accordance with the present invention consists in overmolding on a single, elongated conductive part an insulating element of generally cylindrical shape provided with an axial recess transverse to said piece, and a. eliminating at this recess the bridge between the two parts of the part disposed on either side of the recess to form two separate conductive elements having two half-sectors protruding inside the support.

Of course, such a method is simple, fast and particularly economical.

 Other advantages and features of the present invention will appear on reading the detailed description which follows and with reference to the accompanying drawings given by way of non-limiting example and in which FIGS. 1 and 2 have already been described. 3 shows in axial section a pressure switch in accordance with a first embodiment of the invention, in a closed positron of the electrical contact, FIG. 4 shows the pressure switch of FIG. 3 in the open position of the electrical contact, FIG. 5 shows an alternative embodiment of a manometric con tactor of the present invention, responsive to the maximum pressure; more precisely the left half of this figure 5 represents the contactor in the open position while the right half of this same figure represents the contactor in the closed position, - Figure 6 shows another embodiment of a pressure switch in accordance with the present more precisely the left half of this figure represents the contactor in the closed position, while the right half of this same crack represents the contactor in the open position, - Figures 7A to 7C show the two conductive elements according to an embodiment of the invention. the invention, according to their initial form.

 The body of the pressure switch shown in Figures 3 and 4 consists of a base 110, an insulating support 130 crimped on it and a cap 180.

The recessed base 110, made of conductive metal, such as brass, forms in cooperation with a deformable membrane 120, a chamber 112 which communicates with the fluid, the pressure thresholds of which it is desired to detect, via a axial orifice 111 which passes through the base 110 and opens into the chamber 112. The axis OO of the orifice 111 corresponds to the axis of symAtrive of the base 110. The membrane may be formed for example of polyimide, cut and preformed cold. A portion 110 A of the base is threaded externally, while another portion 110 B is shaped like a nut so that the base 110 of the contactor can easily be introduced and clamped in a threaded bore corresponding to the portion 11Q A, provided for example in the crankcase of a
Motor vehicle when it comes to detecting the pressure thresholds of the engine tile.

 The insulating support 13Q is of generally cylindrical shape and has its periphery a bearing surface directed yers the opposite of the base 110; so that the insulating support 130 is' secured to the base 110 by crimping a skirt 113 thereof which clamps the periphery of the deformable membrane 120 against the base 110 and further compresses a seal 114 of elastomer disposed in an annular groove in the base 110, below the membrane 120, to seal the chamber 112.

 As can be seen in FIGS. 3 and 4, the insulating support 130 fixedly holds two electrically conductive metal tongues 140 and 150 whose ends A41 and 151 extend on either side of a pusher 121. made of material insulator which is supported by the membrane 12 opposite the chamber 112. The method of producing the insulating support 130, formed for example by overmolding phenoplast on conductive tabs 140 and 150 based on a copper and zinc alloy will be described in more detail in the following description. The tab 140 extends perpendicular to the axis OO of displacement of the pusher 121, while the tab 150 has a first section normal to the axis 0-0, which makes projection 9 inside the insulating support 130, and that extends the other side by a second section parallel to the axis OO to protrude outside the contactor.

 The insulating pusher 121, formed for example by molding polysulfone is formed by a plurality of cylindrical segments integral with each other common OO axis axes, having decreasing diameters of the segment 122 disposed adjacent the deformable membrane 120, towards the free end pusher.

The pusher 121 is housed in an axial recess provided in the insulating support 130, and is thus able to move, depending on the deformations of the membrane, along the axis referenced OO in Figure 3, which is normal to the mean plane of the membrane 120.

 The cap 180, which is made of insulating material, such as polyamides, is ench ssX on the conductive tab 150 that passes through the insulating support 130 and protrudes outside the cap 180.

 The second tongue 140 is in contact with the crimped skirt 113 of the base so that the two conductive tabs 140 and 150 are electrically accessible from the outside.

 The lB0 cap serves as a bearing surface for a cylindrical compression spring 160, centered on the pusher, which acts on a rigid metal member 170 electrically conductive, in the form of a centrally recessed disk which rests on a segment 123 of the pusher support directed towards the opposite of the chamber 112.

 The profited ends 141 and 151 of the conductive tongues protrude inside the axial recess of the insulating support, in a common plane substantially normal to the axis of displacement of the pusher 121, so that the rigid member 170, which is disposed transversely to this axis of displacement, opposite the chamber 112 with respect to said ends can be moved between an isolated position (Figure 4) during the compression of the spring 160 and a position of contact with the ends 141 and 151 ( figure 3) when extending the spring 160.

 Preferably, the rigid metal member 170 or the ends 141 and 151 of the tongues 140 and 15 comprise at least two contact projections referenced 171 in FIGS. 3 and 4, on which the bosses are represented on the member 170.

 By rigid metal member 170 is meant an element for which the flexibility does not intervene actively in the establishment or the cutting of the electric circuit.

But of course such a member may in itself have a certain flexibility, Such a member 170 may be made for example in the form of a washer based on a copper and zinc alloy whose surface is treated with using a silver-based alloy to improve electrical contact.

 The pusher 121 is guided on the one hand by a cylindrical chamber 181 disposed in the cap 180 and into which the end segment 124 thereof penetrates, on the other hand by the insulating support 130 whose diameter of the internal bore corresponds substantially to the outer diameter of the aforementioned pusher segment 122. The distance between the two guide lands of the pusher 121 eliminates the risk of setting oblique position thereof and the metal contact member 170, and thereby improves the accuracy of the contactor compared to previously existing devices.

 A groove 125 externally for the entire length of the end segment 124 (pusher) avoids the piston effect that could be caused by the displacement of the pusher in the closed guide chamber 181 ensuring the constant conmlunicatron thereof with the outside.

 Channels 182 are provided between the cap 180 and the insulating support 130 <opposite the conductive tab 150>, to ensure communication with the atmosphere of the volume above the deformable membrane 120, so as to allow freely displacement thereof as a function of fluctuations in the pressure of the fluid in the chamber 112.

 The cap 180 includes an outer portion 183 which covers the insulating support 130 to prevent penetration of any foreign body into the contactor via the channels 182.

 Thus, the cap 180 provides the support and centering functions of the calibrated spring 160, the guide of the pusher 121 and the protection of the channels 182 for venting the upper chamber of the contactor.

 Preferably, the setting of the spring 160 corresponds to the average temperature of the fluid which it is intended to detect.

 As shown in FIG. 4, when the pressure of the fluid in the chamber 112 is greater than the minimum pressure to be detected, and therefore the setting of the spring 160, the diaphragm 120 and the pusher 121 are pushed back to the op posed the chamber 112, thereby removing the rigid member 170 of the conductive elements 151 and 141.

 The segment 122 of the pusher bearing on the ends 141 and 151 avoids harmful deformation of the membrane, which may be caused by a suppression of the fluid in the chamber 112.

 When the fluid pressure reaches the predetermined pressure, the system is in equilibrium.

 On the other hand, as shown in FIG. 3, as soon as the pressure of the fluid in the chamber 112 becomes less than: the predetermined pressure and therefore the setting of the spring 160, the latter urges the displacement of the pusher 121 and the diaphragm 120 to the chamber 112 so as to bring the member 170 into almost simultaneous contact with the electrical conductors 141 and 151 to provide an electrical path therebetween. If the pressure of the fluid continues to decrease, the deformation of the membrane 120 increases in the direction of the chamber 112 but the contact remains established between the rigid member 170 and the ends 141 and 151. In other words, the race of the membrane 120 is greater than the displacement of the metal member 170 relative to the tabs 140 and 150.

 Such a pressure switch can be used for example to detect the minimum pressure of engine oil in a vehicle automohile; closing the electrical circuit between the tabs 140 and 150 (between the mass of the vehicle and a terminal) when the oil reaches said minimum pressure which can be easily used to ensure the ignition of a warning light disposed on the dashboard of the vehicle.

Of course, according to an alternative embodiment, the spring 160 could be calibrated as a function of the maximum pressure of the fluid to be detected. Thus, when the pressure of the fluid in the chamber 112 is less than the maximum pressure, the rigid member 170 is in contact with the conductive elements 140 and 150 (FIG. 3), whereas when the pressure of the
fluid in the chamber 112 exceeds the maximum pressure, the membrane 120 is deformed and the pusher is pushed towards
the outside of the chamber thus separating the organ 170 and the
tabs 140 and 150. In such a case it is necessary to provide, further means detecting the opening of the electrical circuit to light accordingly the control of a
appropriate tear.

In general, the car manufacturers want the pressure switch to close the electrical circuit when the pressure to be detected is reached so that it is sutist to have a serial indicator light switch to view the alarm. The detection of a circuit opening requires a specific mounting
than additional to cause the lighting of a pilot light.

We will now describe the mode of realization
pressure switch according to this invention
which has been shown in Figure 5 and which is intended
detecting the maximum fluid pressure by closing an electrical circuit.

Only the structure of the insulating pusher 121 and
the rigid metal contact member 170 differs from the embodiments shown in FIGS. 3 and 4; the at
therefore, the contactor elements will not be rewritten.

As shown in FIG. 5, the pusher 121 formed an elongated cylinder 126 of small diameter supporting at its base a cylindrical segment 122 which
it is coaxialt thin, but large diameter
as long as they are oldaried to membrane 120.

The rigid metal member 170, electrically conductive, in the form of a centrally hollowed disc is threaded
on lve pusher 1211 bearing on the segment 122 of large diameter. To impoil the member 170 on the pusher 121, a sleeve 127 of insulating synthetic material is then engaged by force on the elongate cylinder 126 of the pusher 121 to tighten the member 170 against said segment 122.

 In this position the pusher 121 is engaged from below in the insulating support 130 so that the metal contact member 170 is disposed on the side of the chamber 112 relative to the ends 141 and 15 of the conductive tabs 140 and 150. A washer 128 is then threaded on the cylinder 126 and the sleeve 127, opposite the chamber 112 relative to said ends 141 and 151. The washer 128 thus rests on a bearing surface provided on the outside of the sleeve 127, towards the opposite of the chamber 112. The spring 160 itself bears on the washer 128. The spring 160 is calibrated according to the maximum pressure to be detected.

The operation of the contactor shown in Figure 5 is as follows.

 As is shown in the left half of FIG. 5, when the fluid pressure in the chamber 112 is less than the maximum pressure to be detected, and therefore the setting of the spring 160, the diaphragm 120 and the pusher 121 are pushed in the direction of the chamber 112 by the spring 16Q which acts on the washer 128. The latter abutting against the extrei nies 141 and 151 of the tongues 14Q and 150 lij'.ite the action of the spring 160 on the membrane 20 of in order to avoid excessive deformation and deterioration when the pressure in the chamber 112 is low.

 When the fluid pressure in the chamber reaches the maximum pressure the system is in equilibrium.

 On the other hand, as shown in the right half of FIG. 5, when the pressure of the fluid in the chamber defends the maximum pressure threshold to be detected, and therefore the setting of the pressure 1a0, the said pressure pushes back the diaphragm 120 and the pusher 121 opposite the chamber 112 until the rigid metal member 170 comes into almost simultaneous contact with the; ends 141 and 15X, closing the electrical contact between the tabs 140 and 150.Là still the displacement of the membrane 120 when the pressure of the fluid present in the chamber 112 increases is limited by the metal contact member 17Q which bears against the lower surface of the ends 141 and 151.

 The embodiment of the contactor shown in FIG. 6 will now be described.

 This contactor differs from that shown in Figures 3 and 4 by the structure of the insulating support 130, the conductive elements 140 and 150 and the cap 180. Only these elements will now be described.

 According to the embodiment shown in Figure 6, the two conductive tabs 140 'and 150 are identical to the tab 150 above. The two tabs 140 'and 150 thus have a first section normal to the axis OO of displacement of the pusher 121, which opens into the axial recess of the insulating support 130 on either side of the pusher and in a normal common plane. axis of displacement. The first section is extended by a second section normal to the first, which passes through the insulating support 130 and the cap 180. parallel to the axis of displacement 0-0 d; push and protrude outside the hat.

The two tabs 140 'and 150 are thus substantially diametrically opposite on either side of the axis of movement of the pusher. There are therefore two tabs 140 'and 150 iSolées of the base 110 of the contactor and therefore the mass of the vehicle. This arrangement thus makes it possible to avoid conventional problems of mass, and if necessary to use an apparatus which has been isolated from the mass.

In the groove where the two tabs 140 'and 150 are completely elongated and accessible outside the contactor, the cap 120 will preferably be molded in the form of a connector as shown in FIG. in order to make it easy to ensure, in a splash-proof manner, the electrical connection between the tongues and the light indicator,
We will now describe an advantageous manufacturing method for the insulating support of the conductive elements 140 and 150 of a pressure switch according to the present invention.

 The first step of the method consists in overmolding on a single metal part 145, as represented in FIGS. 7a to 7c, an element made of insulating material, based for example on phenoplast. The part 145 shown in these figures 7a to 7c has a U shape. This part is intended to be inserted into a contactor similar to that of FIG. 6. Of course, the method which will be described here could be implemented in a similar for the embodiment of the contactor shown in Figures 3 to 5 by adapting the shape of the part 145.

 This piece 145 is composed of a base 146 from which two parallel branches 147, normal to the base 146, start.

 The insulating material molded on the piece 145 has a generally cylindrical shape provided with an axial recess transverse to the base 146. The walls of said material then envelop a portion of the base 146 and branches 147.

 Then, it is necessary to eliminate at this recess the bridge (represented by the hatched area referenced 148 in Figure 7c) existing between the two parts 145 disposed on either side of the recess to form the two separate conductive elements 140 and 150 so that they each have a half-sector protruding inside the support.

 In a general way, all the parts are in fact of simple and economic realization. In addition, the assembly of the contactor according to the present invention can easily be performed on a channe.

 Finally, the pressure switch has a reliability and accuracy very much superior to previously existing devices. Indeed, on the one hand no flexible element involved in the production of the electrical path, on the other hand the accuracy is excellent since the return spring 160 is only to intervene against the pressure of the fluid.

 Of course, the present invention is not limited to the embodiments that have just been described from which we can imagine many alternative embodiments without departing from the scope of the present invention. Thus, the embodiments shown in Figures 3 and 5. may optionally be combined to form a pressure switch which detects the crossing of the minimum threshold and the maximum pressure threshold of a fluid.

However, it is necessary to remarry that this embodiment requires either to prepare a precisely calibrated spring 160 as a function, on the one hand, of the minimum pressure, on the other hand, of the maximum pressure, ie to have a means of of rules
SE of the two contact members 170 disposed on the pusher on either side of the ends 141 and 151 of the conductive tabs. Furthermore, in such a case it is necessary to dispense with at least three fixed conducting elements regularly distributed around the pusher, that is to say at least one conductor serving as mass and two respective conductors associated with the detection of the minimum pressure and the maximum pressure.

Claims (11)

 1. Manometric contactor of the type comprising a corpus, at least partially insulating, which defines a pressure chamber communicating with a fluid which it is desired to detect a pressure threshold, and which is delimited on one side by a deformable membrane, a pusher supported by the diaphragm, opposite the chamber, a calibrated spring as a function of the fluid pressure threshold to be detected, which acts on the pusher and the diaphragm to urge the displacement thereof towards the chamber and electrical means co-operating with, the pusher for detecting the movement of the membrane when the pressure in the chamber crosses said threshold, characterized in that the electrical means comprise two rigid and separate conductive elements (140, 150), supported in a fixed position by the body (130) and whose ends (141, 151) extend on either side of the pusher (121), and substantially in a common plane, normal to the axis of displacement (O- O) of the pusher, and a rigid member (170), electrically conductive, supported by the pusher (121) transversely to the axis of displacement (OO) thereof and which is moved between an isolated position and a position contacting the two conductive elements to establish or cut the electrical connection between them when the pressure in the chamber exceeds said given threshold.  2. Manometric contactor according to claim 1, characterized in that the body is formed of a base (110) recessed 'internally and through which a hole (111) which communicates with the fluid, a support (130) hollow of insulating material of cylindrical general shape held on the base so as to grip against it the periphery of the membrane (120) to define between the membrane and the base, said chamber (112), in which opens the orifice (111), and supporting the two conductive members (140, 150) in an appropriate position while defining an axial recess which houses the spring (60) and the pusher (121), and a cap (180) immobilized on the insulating support to serve as a fulcrum spring acting on the pusher.  3. Manometric contactor according to claim 2, characterized in that the spring (160) is guided on the one hand by a cylindrical chamber (181) provided in the cap (180), on the other hand by the base of the insulating support (130).  Manometric contactor according to one of claims 1 to 3, characterized in that one of the conductive elements (140) is electrically connected to the base (110) formed of conductive material, while the second conductive element ( 150) is housed in the insulating portion (130) of the body and projects outwardly therefrom. (Figures 3 and 4).  5. Manometric contactor according to one of claims 2 and 3, characterized in that the two conductive elements (140, 150) are housed in the insulating support (130) and pass through the cap (180) of the body to make protruding outside of it (Figure 6).  6. Manometric contactor according to claim 5, characterized in that the cap (180) is shaped as a connector (Figure 6).  7. Manometric contactor according to one of claims 1 to 6, characterized in that the pusher (121) carries two spaced transverse members (170, 122)., Between which are arranged the ends (141, 151) respectively of the two conductive elements (140, 150), one (170) playing the rigid transverse member roll for establishing the electrical connection between the two conductive elements, and limiting the movement in one direction of the diaphragm (120) , the other (122) ,, stop for limiting the displacement in the other direction of the membrane.  8. Pressure switch according to one of claims 1 to 7, characterized in that the rigid transverse member (170) for establishing the electrical connection between the two conductive elements (140, 150) is arranged opposite the springtaré (160) relative to the conductive elements (Fig.5).  9. Manometric contactor according to one of claims 1 to 7, characterized in that the rigid transverse member (170) for establishing the electrical connection between the two 'conductive elements (140, 150) is disposed on the side of the spring calibrated (160) relative to the conductive elements (Figures 3, 4 and 6).  Manometric contactor according to one of Claims 1 to 9, characterized in that the two conductive elements (140, 150) are initially formed of a single elongate piece (145) on which an insulating part (130) of cylindrical general shape provided with an axial recess transverse to said part at which the bridge between the two parts of the part disposed on either side of the recess is subsequently eliminated to form two separate conductive elements.  11. A method of producing the insulating support of the conductive elements for a pressure switch according to one of claims 1 to 10, characterized in that it consists of overmolding on a piece elongate single ~ (145), a material element insulator (130) of generally cylindrical shape provided with an axial recess transverse to said part, and to eliminate at this recess the bridge between the two parts of the part arranged on either side of the recess to form two separate conductive elements 140, 150).