FR2554589A1 - Pressure or load sensor - Google Patents

Abstract

The device consists of a diaphragm 5 mounted on a case 1. One end of a flexible conductor 14 is connected to the diaphragm and its other end is connected to a terminal 16 carried by an insulating plate 9. The insulating plate 9 also carries a resistive element 10 whose terminals 11 and 12 are connected to a voltage source. When the diaphragm 5 is deformed, the point of contact 18 of the deformable conducting element 14 is displaced on the resistive element 10 and the voltage received at the terminal 16 is therefore a function of the force exerted on the membrane 5.

Description

 The present invention relates to a pressure sensor and more particularly a sensor for measuring low pressures resulting from very low forces.

 In this type of sensor for which the pressure-sensitive membrane is only subjected to movements of small amplitude, it is necessary that the device for detecting the movements of the membrane be of very high precision, otherwise the measurements given by the pressure sensor cannot be used.

Pressure sensors responding to small efforts have already been made. In particular, American patent 4,214,225 describes a pressure sensor comprising a membrane mounted in a housing comprising two opposite openings which can respectively be connected to two media at different pressures, a first element having a substantially planar contact surface, electrically conductive and the ends of which can be connected to a voltage source, a second element in the form of a rigid cam, having a curvilinear surface having a conductive part and arranged to be able to tilt on the surface of the first element in response to the movement of the membrane, so that the contact point between the first and the second element moves along their conductive part.The mobile element is held in place by an elastic blade, one of the ends of which is fixed to the end of the rigid cam and the other end of which is fixed to the housing. The end of the movable cam opposite the end held by the elastic blade remains free and rests on the pressure-sensitive membrane
Due to the lack of fixing of the end of the movable cam which is in contact with the diaphragm, the tilting of the movable cam on the flat surface takes place in the form of a bearing with a sliding. This sliding, even slight, has the disadvantage of distorting the measurement of the displacement of the membrane and also of causing wear of the two elements in mobile contact with respect to each other.

 An object of the present invention is to provide a pressure or force sensor which is sensitive to very low forces and makes it possible to detect these with very high precision.

 Another object of the present invention is to provide a pressure or force sensor in which there is practically no wear of the mobile elements, during their movement relative to each other.

 For the realization of these objects, there is provided according to the invention a pressure or force sensor comprising an enclosure in which is disposed a movable part (5) which can be subjected to pressure or force, a resistive element (10) fixed in the enclosure and comprising current supply terminals, a conductive member (14) movable relative to the resistive element but remaining in contact with the latter according to a contact point (18) whose position varies in displacements of the movable part in which the movable conductive member is an elongate elastically deformable element having one of its ends secured to the movable part and the other end fixed at a point of the enclosure.

 Thus, the deformation of the conductive element at the point of contact with the resistive element is sufficient to allow rolling without sliding of the conductive member on the resistive element.

 According to other characteristics of the invention, the movable element is a wire or a tongue, the movable element is made of annealed bronze-beryllium alloy or of spring steel covered with a gold film and already the resistive element has a nonlinear resistance.

Other characteristics and advantages of the invention will appear on reading the following description made in relation to the figures among which
FIG. 1 is a sectional view of a pressure sensor according to the invention,
- Figure 2 is a top view of a resistive element with non-linear resistance.

 Referring to FIG. 1, the sensor according to the invention comprises a housing comprising a cylindrical cavity 1 partially closed on one side by an annular wall 2, from which extends a tubular conduit 3.

 The cylindrical part 1 comprises an annular rim 4 on which is mounted a flexible membrane 5, for example a very thin metal sheet stamped to produce circular corrugations 6 improving its flexibility in the transverse direction.

 The membrane 5 is held in place against the rim 4 by an annular crown 7 which keeps the membrane 5 applied against the rim 4, for example, by means of rivets passing through the annular crown 7, the edge of the membrane 5 and the rim 4 It is of course possible to use any other appropriate means of fixing the membrane 5, in particular the latter may be glued to the flange 4.

 Inside the housing, an insulating plate 9 has been fixed on studs 8 on which a resistive element 10 is deposited which can be formed for example by deposition by screen printing of a mixture of glass powder and metallic elements sintered at a temperature between approximately 6000C and 8000C or by the bonding of a film comprising on the face facing outwards a mixture of carbon black and of polymer known under the name of low temperature resistive polymer ink.

 The ends of the resistive element 10 are respectively connected to electrical terminals 11 and 12 connected to a voltage source 13.

 The movable element 14 is produced by means of an elastic metallic wire, such as for example a piano cord of 6/10 of a millimeter in diameter covered with a layer of gold fixed at one of its ends in a insulating plate 15 carried by the membrane 5. From the plate 15, the wire 14 comprises a rectilinear part 19 extending substantially perpendicularly to the plate then a curvilinear part 20 with a large radius of curvature connected to a bent part 21 whose l one of the sides makes an angle 22 with the curvilinear part and the end of which is fixed to a terminal 16 carried by the insulating plate 9. Terminal 16 is connected by a conducting wire 17 to a means of amplification or of direct exploitation of the signal taken by the driver 17.

 When the membrane 5 is deformed under the effect of a pressure difference between its two faces or under the effect of a force applied to its external face, the wire 14 is deformed and the point of contact 18 between the wire 14 and the resistive element 10 rolls without sliding on the resistive element 10.

 The device then acts as a potentiometer, the voltage appearing at terminal 16 being a function of the position of the contact point 18 on the resistive element 10.

 The movable element 14 can also be produced from a flexible tongue, the contact with the resistive element 10 then being made along a transverse line of the tongue. In addition, the mobile element can be produced in different forms provided that the radius of curvature at the point of contact with the resistive element is large enough to allow rolling without sliding of this point of contact during the deformation of the mobile element.

 The resistive element can be made in the form of a strip of constant width. The voltage collected at terminal 16 will then be exactly proportional to the distance from contact point 18 with respect to terminals 11 and 12 of the resistive element-10. On the contrary, as shown in FIG. 2, the resistive element can have a variable width so that the voltage collected at terminal 16 is not exactly proportional to the displacement of the contact point 18.

Thus, in the case represented in FIG. 2, the device will be more sensitive to the forces, when the contact point 18 is located in the vicinity of the terminal 11.

In particular, the law of variation of the resistance of the resistive element 10 can be studied to evolve in inverse manner to the law of variation of deformation of the element 14 as a function of the force on the membrane 5, so that the voltage collected at terminal 16 is finally a linear function of the force exerted on the membrane 5.

 In order to improve electrical performance, it is possible, in a preferred version not shown, to associate the output conductor 17 with an amplification or impedance lowering system comprising a transistor arranged in a cathodic charge circuit.

Similarly, in order to make the output voltage more or less insensitive to fluctuations in the supply voltage, the bias voltage of the resistive element 10 can be stabilized by means of a diode.
Zener.

 The applications of the device according to the invention are numerous, in particular, in the version represented in FIG. 1, the sensor can be used as a device for measuring the level of the liquid in a tank by placing the membrane 5 near the bottom of the tank. , while the pipe 3 is connected to an opening opening to the outside of the tank.

In this application, as shown, it is advantageous to pass the conductors through the pipe 3. However, such an arrangement is not compulsory and the conductors can pass through the housing at any point suitable for the intended use.

 In another application of the invention, where the sensor is used as a flow meter, the device comprises two boxes similar to the box 1 arranged on either side of the membrane 5, the conduits 3 being connected at two distinct points along of the pipe through which the fluid flows whose flow is desired.

 The sensor according to the invention can also be used in a weighing device by resting the weighing plate on the membrane of a series of sensors, the output signals of the various sensors being added by means of a conventional electronic device.

 The present invention is not limited to the embodiments which have been described but is susceptible to variations which will appear to those skilled in the art. In particular, although the description has been made in connection with a waterproof membrane subjected to different pressures on its faces and reacting by a displacement at this differential pressure, it will be noted that the sensor according to the invention can be used as a sensor for any force exerted on the membrane, the membrane can then be perforated and even replaced by a moving part disposed in a guide cylinder. This could in particular be the case in a weighing application where the platform could then include feet engaging in the cylinders and resting on the upper face of the moving part while the lower face would be connected to the upper end of the conducting wire. .

Claims (7)

 1. Pressure or force sensor comprising an enclosure in which is disposed a movable part (5) capable of being subjected to pressure or force, a resistive element (10) fixed in the enclosure and comprising supply terminals in current, a conductive member (14) movable relative to the resistive element but remaining in contact with the latter according to a contact point (18) whose position varies in the movements of the movable part, characterized in that l movable conductive member is an elastically deformable elongated element having one of its ends secured to the movable part and the other end fixed at a point of the enclosure.  2. Pressure sensor according to claim 1 characterized in that the movable element is a wire.  3. Pressure sensor according to claim 1 characterized in that the movable element is a tongue.  4. Pressure sensor according to claim 2 or claim 3, characterized in that the movable element is made of annealed bronze-beryllium alloy.  5. Pressure sensor according to claim 2 or claim 3 characterized in that the movable member is made of steel covered with a gold film.  6. Pressure sensor according to one of claims 1 to 5 characterized in that the resistive element has a non-linear resistance.  7. Pressure sensor according to claim 1, characterized in that the movable member comprises a rectilinear part 19 extending substantially perpendicular to the membrane, a curvilinear part (20) of large radius of curvature and a bent part (21) one of the sides of which forms an angle (22) with the curvilinear part.