FR2745385A1 - Mobile conductor speed measuring device - Google Patents

Abstract

The device includes two sensors (4) each placed around a Hopkinson bar (1,1) which flanks a sample (3) being analysed. An elastic deformation wave is generated in one of the bars by a pneumatic hammer (5) and a punch (7). Each sensor includes a coil (G) connected to a processing module (6,6). A ring-shaped permanent magnet is placed around the coil. The elastic waves propagating through the bars generate a variation of the magnetic flux across the coil which in turn generates a voltage (V). This voltage signal is transmitted to the processing module.

Description

SENSOR OF KINEMATICS
OF A CONDUCTIVE MOBILE
The present invention relates to a contactless sensor device intended for measuring the kinematic quantities of a conductive mobile, such as acceleration or speed.

 Multiple devices are known which make it possible to measure the dynamic behavior of materials and in particular deformation gauges which are generally fixed by gluing on a test tube of the material to be studied. If these strain gauges are particularly effective in the field of static measurements, it is not the same when it comes to performing dynamic measurements. In this type of measurement, they are indeed very fragile since, under the effect of acceleration, there is often a take-off of the gauge or a break in the connecting wires which connect them to electronic means. of measurement.

 It has been proposed, for dynamic measurements, to replace the strain gauges by sensors of other types and in particular by electromagnetic type sensors. These sensors consist of a coil which is glued to a test piece of the material to be tested and which is immersed in a uniform magnetic field, so that this coil is the seat of a voltage proportional to the speed of movement of the test piece . A first drawback of this type of device comes from the method of fixing by bonding the coil to the test piece which, as before, tends to come off under the effect of an acceleration undergone by the test piece.

In addition, the coil connection wires create parasitic induced voltages. Finally, a source of disturbance of these devices comes from the eddy currents which are induced in the conductive mass of the test piece.

 We turned to sensors which have no physical contact with the test tube used.

 We note that a preferential application of this type of sensors concerns the Hopkinson bars which constitute, as we know, a privileged test means to access the measurement of the dynamic behavior of certain conductive materials, ie the law. which links stresses and deformations when the deformation speed of these materials is high. In this technique the sample to be tested is placed between two long cylindrical bars on which measurements of deformation or of a dynamic quantity which is associated with them, such as speed or acceleration, are carried out. For such an application, it is particularly advantageous to use contactless measuring devices.

 Two main contactless measurement technologies are known, namely optical technology and electromagnetic technology.

In the optical field, one of the methods that can be used consists in measuring the particle speed at a point of the element using a laser effect velocimeter.
Doppler. Such a method has two notable drawbacks.

On the one hand the cost of the apparatus necessary for its implementation is very high, especially in comparison with the cost of a simple strain gauge, and on the other hand the apparatuses used are of a particularly delicate implementation which does not adapt well to certain experimental conditions. These methods can therefore in no way constitute an alternative to the use of strain gauges.

 As for the electromagnetic sensors, they operate in sinusoidal regime, so that the modulation frequency must be of the order of several MHz to obtain the same bandwidth as that provided by the strain gauges (of the order of MHz). , which therefore poses a number of technical constraints.

The object of the present invention is to propose a contactless sensor device capable of detecting a speed or an acceleration linked to a movement, and in particular to the passage of a wave, in a solid, for example in a bar of
Hopkinson.

The present invention thus relates to a contactless sensor device intended to measure a kinematic quantity of a conductive element of the moving electric current, such as acceleration or speed, characterized in that it comprises
means capable of creating on the mobile element a magnetic field with a normal component on the surface thereof,
- magnetic field or magnetic field detection means, arranged in the immediate vicinity of the surface of the mobile element,
- Receiving means able to collect a signal produced by the detector means.

 In an advantageous embodiment of the invention, the means for creating the magnetic field are capable of creating a magnetic field around the mobile element.

 In another embodiment of the invention, the detector means are arranged around the mobile element, the latter being able to be arranged inside means capable of creating the magnetic field.

 Preferably, the detector means consist of a coil which is wound around the movable element and at the terminals of which the potential difference produced during the measurement is measured.

Various embodiments of the present invention will be described below, by way of non-limiting examples, with reference to the appended drawing in which
FIG. 1 is a schematic view showing the application of the present invention to the measurement of kinematic quantities obtained from a Hopkinson bar.

 FIG. 2 is a sectional view of a sensor according to the invention intended for carrying out a measurement of kinematic quantities on the Hopkinson bar shown in FIG. 1.

 Figure 3 is a schematic view of the principle of a sensor according to the invention.

 Figure 4 is a schematic perspective view of an embodiment of the invention.

 Figure 5 is a schematic perspective view of an alternative embodiment of the invention.

 Figure 6 is a schematic perspective view of an alternative embodiment of a sensor according to the invention.

 FIG. 7a is a schematic view of an example of use of the sensor shown in FIG. 6.

 FIG. 7b is a schematic view of another example of use of the sensor shown in FIG. 6.

 FIG. 7c is a schematic view of another example of use of the sensor shown in FIG. 6.

 FIGS. 1 and 2 show two long cylindrical metallic bars 1,1 ′, called Hopkinson bars, between which is placed a sample to be studied 3. A pneumatic cannon 5 projects, by means of an expansion of compressed air, an impactor 7 on one end of one of the bars l, so as to create an elastic deformation wave (incident wave) which propagates therein. Part of the wave is reflected when it reaches the other end of this bar 1 (reflected wave) and the other part crosses the sample 3 and then propagates (transmitted wave) in the other bar 1 ' . It has been established that knowledge of these three waves gives access to the physical quantities which characterize the behavior of the sample tested 3.

 According to the invention, there is around each bar l and 1 ′, in the immediate vicinity of the periphery thereof, a sensor 4 connected to electronic processing means 6,6 ′ of the received signal. This sensor 4, as shown in FIG. 2, consists of a coil 9 joined by wires 11a, 11b to the processing means 6,6 '. There is also around the winding 9 an annular permanent magnet 15 capable of creating a radial magnetic field ssr around the bars 1 and 1 '. The internal diameter of the magnet 15 with radial field is preferably close to the external diameter of the winding 9.

 As shown schematically in FIG. 3, any displacement of the bar 1, or any wave propagating in it, has the effect of generating a variation in magnetic flux through the coil 9 which results in the terminals thereof. ci by the presence of a voltage V which is transmitted to the processing means 6,6 '.

In fact, as illustrated in the diagram in FIG. 3, the application of the radial magnetic field ssr on the metal bars l, l 'has the effect of generating an electromotive field
E = vAB which, in turn, produces a current J = yE (where y is the conductivity of the metal constituting the bars l, l ').

 The magnetic field ssr produced by the permanent magnet 15 being radial, the product currents J are circular and are centered on the center O of the straight section of the bar 1. These circular currents then create a magnetic field of axial direction a (directed towards the reader in FIG. 3) which in turn creates a flux through the coil 9. Any variation in the particle displacement v therefore produces a variation in the axial magnetic field a and consequently a variation in the flux through the coil 9 which induces a voltage at its terminals V. The latter is communicated by the wires 11a, 11b to the processing means 6,6 '.

 The sensor 4 thus formed therefore delivers at its terminals a voltage V linked to the derivative of the particle speed, ie to acceleration. Of course, the integration of the acceleration to obtain the speed and the integration of this to obtain the displacement further reduce the noise of the measurement.

 The permanent magnet 15 producing the radial magnetic field can optionally, as shown in FIG. 4, consist of a series of magnetic bars 15a which are held together by a hardenable resin 16 such as an epoxy resin.

 The permanent magnet, as shown in FIG. 5, can also be formed from a rectangular plate 15b of elastomer regularly magnetized over its entire surface (the magnetic field ssr being perpendicular thereto) which is then wound up.

 The winding 9 used must preferably include a large number N of turns. Indeed, insofar as the device must have a large bandwidth, we must take into account the RLC parameters of the coil 9. Its inductance L increases with the number of turns N and the radius thereof, and decreases with the cross section of the wire used. The resistance R here is that of the wire used and therefore increases with the number N of turns, and with the resistivity p of the wire and decreases with the cross section thereof.

Of course, the kinematic magnitude sensor of a conductive mobile according to the invention can be used for various displacement measurements other than on bars of
Hopkinson.

 This sensor thus makes it possible to measure displacement speeds on the surface of a solid conductor. FIG. 6 shows the external surface 20 of a solid which is moved in the direction of the arrow v A sensor 23 consists of a cylindrical tube 22 inside which two magnetic bars are arranged 24.24 'whose polarities are reversed. At the center of the tube 22, at the end thereof closest to the solid 20 is disposed a coil 26 connected by wires 28, 28 'to processing means, not shown in the drawing. The magnets 24 and 24 ′ create magnetic fields iff which, applied to the surface 20 of the solid, create with displacement v a field E which, in turn, creates an electric current J, as shown in FIG. turns of current produced in turn create an axial magnetic field a and consequently a flux through the coil 26, the variations of which are a source of a voltage V across its terminals.

 As shown in FIG. 7a, the sensors 23 of this type can be used to measure the speed of rotation at the periphery of a shaft 30, where as shown in FIG. 7b to measure the speed in a given radius r of a section right of this shaft 30. The sensor 23 will be arranged so that its axis of symmetry yy 'is perpendicular to the surface on which the measurement is made.

 Such sensors can of course, as shown in FIG. 7c, measure the speeds of longitudinal and transverse movement of a bench 30 'of a machine tool or of a moving member of a vehicle.

 It would of course be possible to implement the present device by replacing, in the sensor according to the invention, the detector means previously described by Hall effect detectors. Such detectors if they have the drawback of reducing the bandwidth produced nevertheless make it possible to directly measure the speed without it being necessary for this to integrate the acceleration.

Claims (8)

 1.- Contactless sensor device intended to measure a kinematic quantity of a conductive element (1) of the moving electric current, such as acceleration or speed, characterized in that it comprises  - means (15, 24, 24 ') capable of creating on the movable element (1) a magnetic field with normal component on the surface thereof,  - means for detecting the magnetic field (9,26) or of the variation of the magnetic field, arranged in the immediate vicinity of the surface of the mobile element (1),  - Receiving means (6,6 ') able to collect a signal produced by the detector means (9,26).  2.- Device according to claim 1 characterized in that the means for creating the magnetic field (15) are capable of creating a magnetic field around the movable element (1).  3.- Device according to one of claims 1 or 2 characterized in that the detector means (9) are arranged around the movable element.  4.- Device according to one of claims 2 or 3 characterized in that the detector means (9) are arranged inside the means (15,24,24 ') capable of creating the magnetic field.  5.- Device according to any one of the preceding claims, characterized in that the detector means consist of a winding (9,26).  6.- Device according to claim 1 characterized in that the detector means consist of at least one Hall effect detector.  7.- Device according to claim 4 characterized in that the element for creating a magnetic field comprises a cylindrical permanent magnet (15) of annular section capable of producing a radial magnetic field (ssr), inside which is disposed a winding (9) whose internal diameter of the turns is close to the external dimension of the movable element (1).  8.- Device according to claim 1 characterized in that it consists of at least one magnetic field source (24,24 ') and a coil (26) whose axis (yy') is parallel to that of said magnetic field source (24, 24 ′) and is arranged near the latter and on the part of the sensor intended to be positioned close to the mobile element (1).