FR2548365A1 - Method of measuring small pressures using a flexible pin made of conducting material, of which at least one point of contact moves over a resistive element, and the device for the implementation thereof - Google Patents

Abstract

Method of measuring small pressures. The end 5 of a flexible conducting pin 6 is fixed on to the plate 1. The shape of the pin 6 is such that any pressure along the arrow P1, at its other end 7, causes the displacement of the point of contact 8 on the resistor element 2. If a vertical force substantially perpendicular to the plate 1, along the arrow P1, is imparted to the end 7, the point of contact 8 moves in the plane of the plate 1 in the direction P2, for the pin 6 has a rolling motion on the resistor element 2. The potential difference across the pin 6 will therefore be a function of the force which is applied at the end 7; it is measured at the terminal 25. The invention applies especially to apparatuses for measuring small pressures.

Description

 The subject of the invention is a method for measuring low pressures as well as the device for implementing the method.

 The measurement of low pressures or small efforts is necessary in many areas. This is particularly the case for the measurement of the level in a tank, the measurement of the flow in a pipe, the differential measurement of the pressures at the terminals of a capillary, the measurement of the weight on a plate, the control of the filling functions, the emptying, dosing, weighing ...

 Current devices all include a more or less complex mechanical part and / or an electronic part. The mechanical part is often unreliable and faithful, because it is subject to many forces and forces of friction. It is therefore necessary to check and adjust frequently the measuring instrument, all mechanical parts exhibiting hysteresis phenomena due to friction. This mechanical part may comprise elements such as floats, valves, solenoid valves, O-rings, finned wheels. These mechanical parts and their assembly very quickly increase the cost of these measuring devices. The cost of these measuring devices is high as soon as they work under specific conditions; thus the insulation is expensive to manufacture such measuring devices because of the presence of many mechanical parts and moving parts.

 The invention tends to solve these problems.

 The method according to the invention makes it possible to measure very low forces, and therefore very low pressures because it operates without mechanical friction, its fidelity and sensitivity are very large.

 The method according to the invention consists in measuring the variation of the voltage (electrical potential difference) of a wire bridge formed by at least two elements, a movable element and a fixed element, the assembly being electrically connected by three terminals 25, 3 and 4. Two of the terminals 3 and 4 are fixed on a fixed resistive element, while the third terminal 25 of the second mobile element, which is a flexible pin acting as a conducting material 6, is in contact with each other. by a point 8 with said resistive element.

 In a preferred version according to the invention, the power supply is provided by terminals 3 and 4 of the resistive element. The voltage variation at the terminal 25 makes it possible to measure the micro displacement of the contact point 8 on the resistive element.

 Another embodiment may be designed by electrically feeding the terminals of the two elements together such as 25.4 or 25.3 and such that the displacement of the contact point 8 is no longer ensured by the micro displacement of the element on which is fixed the terminal 25, but by the resistive element itself, which becomes mobile and which moves relative to the point of contact 8.

 The voltage variation makes it possible to measure the micro displacement and thus to measure the variation of the pressure.

 The shape of the flexible conductive pin is such that its point of contact with the resistive element moves on this resistive element, without introducing sliding friction between the pin and the resistive element.

 In a preferred version according to the invention, the resisitive element is made of resist film. This resistive element may have an ohmic value of the order of 3000 nm squared. This film is polarized between its ends by a current source of about ten volts.

 The device for carrying out the method consists, according to a preferred version, of sticking on a support plate a resistive element and of fixing the end of a flexible pin of conductive material on said support plate while the other end is in direct or indirect contact with the object to be measured, the shape of the pin is such that between its two ends, the pin has a point of contact with the resistive element and any pressure variation at the level of the end of the pin, which is on the side of the element to be measured, causes a displacement of the point of contact.

 The flexible conductive pin may be made of elastic metal wire.

The pin may for example be a piano wire a few millimeters in diameter. This pin has, in the vicinity of the point of contact with the resistive element, a small local curvature.

 According to another preferred embodiment, the pin may be covered with a coating intended to improve its contact properties.

Said coating may in particular be a gilding.

 Any vertical force perpendicular to the plate moves the point of contact of the pin. The polarization of the pin is therefore a function of the effort that is applied to it. To measure the pressure, it is therefore sufficient to analyze the polarization variations of the pin.

 Due to the shape of the pin, the friction forces are almost zero and therefore negligible for the point of contact between the pin and the resistive element.

 In another embodiment, the pin may be secured to another plate, said displacement sensor plate, connected by means of a flexible membrane to the walls of a housing which contains the entire device, and which communicates with the outside by a pipe. The stress on the pin is therefore proportional to the pressure difference between the external environment and the pressure in said pipe.

 In a preferred version according to the invention, the flexible membrane is very thin metal (a few tens of microns thick), and the pin is fixed directly on this membrane.

 The electrical performance can be improved by combining an electronic means of current amplification or lowering of the impedance, using a transistor mounted in "follower". Similarly, to make the output voltage nearly insensitive to fluctuations in the supply voltage, it is possible to stabilize the bias voltage of the resistive element by a Zener diode.

 The resistive element may have a shape such that the law of variation of the output voltage is perfectly proportional to the pressure exerted on the pin or any increasing monotonous law desired by the user.

 For many applications and in particular the weighing of a scale, the plate can be based on one or more displacement sensors, it is sufficient to add the response voltages by operational amplifiers, which is known in electronics. The total response is then proportional to the weight deposited on the weighing pan.

 The method according to the invention can also be used as a flow meter. Thus the device can be mounted in a branch on a pipe segment between two flexible membranes. Upstream, the flexible membrane is fixed with its sensor plate at the end of the pin, and downstream, the flexible membrane isolates the plate which receives the resistive element in contact with a portion of the pin and the other end of the pin.

 Preferably, an incompressible neutral fluid fills the space between the two membranes.

 The accompanying drawings given by way of indicative and non-limiting example will make it easy to understand the invention. They represent preferred embodiments according to the invention.

 Figure 1 is a schematic view of the device according to the invention, seen from above.

 Figure 2 is a schematic view of the device according to the invention, seen from the side.

 FIG. 3 is a schematic view of the device of the invention, viewed from the side, in which the pin is integral with the plate and a membrane, the assembly being immersed in a fluid and connected to the outside by a pipe .

FIG. 4 is a schematic view of a conceivable electrical scheme for improving electrical performance (lowering or increasing the impedance, stabilizing the polarization of the resistive element
Figure 5 is a view of a device in section, used as a level gauge in a tank.

 Figure 6 is a view of a resistive film form that can be used.

 Figure 7 is a sectional view of the device used as a flow meter.

 Figures 8 and 9 are views of one or more devices used for a weight measuring instrument such as a scale.

 Figure 10 is a view of another embodiment and implementation of the pin through a positioning bracket.

 FIG. 11 is a sectional view along the X-Y axis represented in FIG. 8.

 On a plate 1, is disposed or glued a resistive element 2 such as a resist film. This resistive element 2 is biased between its terminals 3 and 4 by a current source of about ten volts, for example.

 The end 5 of a flexible conductive pin 6 is also fixed on said plate 1. The shape of the pin 6 is such that any pressure along the arrow P1 at its other end 7 causes the displacement of the contact point 8 on the Resistive element 2. The pin 6 has, at the point of contact 8 with the resistive element 2, a small local curvature.

 If a vertical force substantially perpendicular to the plate 1 is imposed at the end 7, according to the arrow P1, the point of contact 8 moves in the plane of the plate 1 in the direction P2, since the pin 6 has a rolling movement on the resistive element 2. The polarization of the pin 6 will therefore be a function of the force that is applied at the end 7, it is measured at the terminal 25.

 In FIG. 3, the pin 6 is integral with a displacement sensor plate 9, connected via a flexible membrane 10 to the walls of a housing 11 which contains the entire device and which communicates with the outside. by a pipe 12. The force on the pin 6 is proportional to the pressure difference between the external medium P3 and the pressure P4 prevailing in the pipe 12.

 FIG. 4 shows the electrical diagram of the means that can be used in combination to amplify the current, or to lower the impedance. At the power supply terminals 13 are mounted a conventional film or coil resistor 14, and in parallel, a Zener diode 15 and a resistive film 16, to which the pin 6 is connected and a high-gain transistor 17, which amplifies the current coming from said pin 6.

 In Figure 5, the device is put in place to be used as a gauge 18 of the level 19 of a tank or a tank 20. Said gauge 18 may in particular be a gauge for a fuel tank. The electrical connections pass through the pipe 12.

 As shown in FIG. 7, the device can be used as a flow meter, in which case the device is shunted on the main line 18. Upstream 19, the bypass is in contact with the flexible membrane 10, the displacement sensor plate 9 and the end 7 of the pin 6; downstream 20, the device is isolated by another flexible membrane 21 which receives the plate 1, support of the resistive element 2 and the other end 5 of the pin 6. The device is filled, preferably between the two membranes 10 and 21, by an incompressible neutral fluid 24, such as for example a transformer oil.

 Figures 8 and 9 show an electronic balance. The weighing plate 22 of the scale 23 rests on the ends 7 of the pins 6 or on the displacement sensor plates. The scale displays, for example, the weight, the price of the kilogram, the price. According to the assembly shown in FIG. 9, the measurements of each device on which said weighing plate 22 is based are added.

 Figures 10 and 11 show another embodiment according to the invention and especially a method of positioning the pin 6. The end 5 of the pin 6 is no longer fixed on the support plate 1, but on a stem 23 in a conductive material. A machine can easily measure the polarity of the pin 6, and depending on this measurement, position the pin 6 on the bracket 23 and fix it for example by a point of glue.

 Similarly, the method may allow adequate mounting of the membrane 10 and the end 7 of the pin 6.

 The membrane 10 is generally metallic in a preferred version and the pin 6 is integral with this membrane.

To assemble the assembly, it is necessary to assemble the membrane 10 to the housing 11 for example by welding, and then the pin 6 to the membrane 10 by the following method
- The membrane 10 has at its point of attachment with the pin 6, a cup filled either with a polymerizable adhesive or a hot melt (pierced at its center for the passage of the pin 6).

 - Once the membrane 10 and the cup are assembled, the adhesive polymerizes without exerting detrimental stress on the pin 6, or performs a slight heating in the center of the membrane 10 which melts the hot melt, and thus ensures the perfect assembly.

This method ensures
10 an assembly without constraint,
Excellent electrical insulation for the membrane 10 with respect to the pin 6.

 This method applies to devices used in particular as sealed potentiometers.

Claims (12)

 A method for measuring low pressures or small stresses characterized in that it consists in measuring the variation of the voltage of a closed-wire bridge of at least two elements (2,6), a movable element and a fixed element, the assembly being connected by at least three terminals, two of the terminals connected to each other provide the power supply, the third terminal measures the voltage variation; one of the elements is a flexible pin means (6) of conductive material, the other element is a resistive element (2), the two elements (2 and 6) have in common a contact point (8) which moves, since one of the two elements is fixed (2) and the other mobile (6) on the resistive element (2) and this according to the pressure or effort variations to be measured.  2. A method for measuring low pressure or small forces according to claim 1 characterized in that it consists in measuring the variation of the voltage (electrical potential difference) of a wire bridge formed of at least two elements. (2,6), a movable element (6) and a fixed element (2), the assembly being electrically connected by at least three terminals (25, 3, 4); two of the terminals (3 and 4) are fixed on a fixed resistive element (2), while the third terminal (25) of the second movable element which is a flexible pin-like means (6) of conductive material, is in contact by a point (8) with said resistive element (2).  3. A method for measuring low pressure or small forces according to claim 1 characterized in that the terminals of the two elements (2 and 6) are electrically powered between them, such as (25,4) or (25,5 ), and such that the displacement of the contact point (8) is provided by the resistive element (2), which is movable and moves relative to the contact point (8).  4. A method for measuring low pressures or small forces according to any one of claims 1, 2 or 3 characterized in that the shape of the flexible conductive pin (6) is such that its point of contact (8) with the resistive element (2) moves on this resistive element (2), without introducing sliding friction between the pin (6) and the resistive element (2).  5. Device for implementing the method according to any one of claims 1, 2, 3 or 4 characterized in that a plate (1) is arranged or bonded a resistive element (2), this resistive element (2) is biased between its terminals (3 and 4) by a current source; the end (5) of a flexible conductive pin (6) is also fixed on said support plate (1); the shape of the pin (6) is such that any pressure along the arrow (P1) at its other end (7) causes the displacement of the contact point (8) on the resistive element (2).  6. Device for implementing the method according to any one of claims 1, 2, 3, or 4 characterized in that the pin (6) has, at the point of contact (8) with the resistive element (2), a small local curvature.  7. Device for implementing the method according to any one of claims 1, 2, 3 or 4 characterized in that the pin (6) is integral with a displacement sensor plate (9), connected by via a flexible membrane (10) to the walls of a housing (11) which contains the entire device and which communicates with the outside through a pipe (12); the force on the pin (6) is therefore proportional to the pressure difference between the external medium (P3) and the pressure (P4) prevailing in the pipe (12).  8. Device for carrying out the method according to any one of claims 1, 2, 3 or 4 characterized in that means may be used in combination to amplify the current, or lower the impedance. 9. Device for implementing the method according to any one of claims 1, 2, 3 or 4 characterized in that it is mounted in shunt on a main line (18>, upstream (19), the branch is in contact with the soft blurred membrane, the displacement sensor plate (9) and the end (7) of the pin (a), downstream (20), the device is isolated by another flexible membrane (21). ) which receives the plate (1), support of the resistive element (2) and the other end (5) of the pin (6), the device is filled, preferably between the two membranes (10 and 21) by an incompressible neutral fluid (24).  10. Device for carrying out the method according to any one of claims 1, 2, 3 or 4 characterized in that the weighing plate (22) of a scale (23) can rest on one or more ends (7) pins (6), or displacement sensor plate (9).  11. A method of positioning the pin (6) according to any one of claims 1, 2, 3, 4, 5, 6, 7, 8, 9 or 10 characterized in that the pin (6) is fixed on a bracket (23) of a conductive material; a machine can easily measure the polarity of the pin (6), and depending on this measurement, position the pin (6) on the bracket (23) and fix it by a point of glue.  12. A method of assembling the membrane (10) according to any one of claims 1, 2, 3, 4, 5, 6, 7, 8, 9 or 10 characterized in that to assemble the assembly, it It is advisable to assemble the membrane 10 with the housing 11, for example by welding, and then the pin (6) to the membrane (10) by the following method  - The membrane (10) has, at its point of attachment with the pin (6), a cup filled either with a polymerizable adhesive or a hot melt (pierced at its center for the passage of the pin (6)). ))  - Once the membrane (10!) and the cup are assembled, the glue polymerizes without exerting harmful stress on the pin (6), or performs a slight heating in the center of the membrane (10) which melts the thermofusible, and thus ensures perfect assembly.