FR2693266A1 - Thickness and curvature measuring system for test pieces subject to mechanical force - has drive system for moving inductive distance detectors mounted at opposite sides of specimen, perpendicularly to specimen, and connected to dimension calculating appts. - Google Patents

Abstract

The instrument has a holder (12,17) for holding a test piece (E). A pair of detectors (35,35') is arranged in front of opposite faces (Fs,Fi) of the sample (E). The detectors are arranged along a common line so that each measures a distance on one of the faces. A support (29,30,32) carries the detectors and moves the detector assembly perpendicularly. A reading unit (46) reads the distances and calculates the sample thickness and its deflection. USE - Measuring thickness of samples subject to mechanical deformation eg flexing and ageing.

Description

APPARATUS FOR MEASURING TEST SIZES
SUCH AS THICKNESSES OR DEFLECTIONS
DESCRIPTION
The invention relates to an apparatus capable of measuring certain dimensional sizes of test pieces, in particular their thickness in several places, or even determining the form of curvature of a bent test piece.

 This device comprises in particular a sensor which is walked on one face of a test tube, in a manner analogous to a roughness meter. But the roughness s are rather designed for surface texture measurements where one is interested in relief accidents; they do not make it possible to assess the thickness of the test piece, any more than its curvature, even if it is sometimes possible to deduce from their measurements the bulge or the overall digging of the faces examined.

 The apparatus I according to the invention is substantially more complex and defined in its most general form by means for wedging and fixing the test piece; a pair of facing sensors arranged in front of opposite faces of the test piece, the sensors being oriented towards the dimensions to be measured on a common line and designed to measure each a distance to one of the faces; a device carrying the sensors and able to move the sensors together and perpendicular to the dimensions; and a di spositi f of reading distances and calculating dimensions.

 It is understood that since the sensors perform independent measurements, it is possible to combine their measurements in several different ways to calculate the local thickness of the test piece or the position of the mean line of the test piece, that is to say di re estimate the bending deformations, or the bulge of the two surfaces.

 Other improvements can also be proposed. The sensors can have adjustable positions on the device which carries them, which allows their use on test pieces of different thicknesses, or on flat measurements then on edge of the same test piece. It is then useful to provide calibration specimens, machined with high precision and of known dimensions, to adjust the information of the sensors, that is to say to calibrate them.

 A particular calibration test piece may be provided with an origin mark, such as a ball projecting from a blind hole with a conical bottom of this test piece, to provide a reference or origin of the mark in which the results of the measures will be transcribed. The advantage is that a uniform reference exists for a whole series of test pieces which undergo the measurements successively. The only condition to be respected is that the test pieces are calibrated in an identical way.

 One can use supports on three perpendicular planes to wedge the test-tube.

We will now move on to the commentary to the following figures, which are annexed to the illustration and not limitation, which describe an actual embodiment of the invention:
- Figure 1 is an overall perspective view of the device;
- Figure 2 is a top view of the device;
- Figure 3 is a detailed view of the measuring and control parts of the device;
- Figure 4 illustrates a thickness measurement of specimen on edge;
- Figure 5 shows the means of attachment to the base of dolls supporting the test pieces;
- Figure 6 shows a spring for clamping test pieces;
- Figure 7 is a representation of the sensors;
- And Figure 8 details a calibration specimen.

 The device firstly comprises (FIG. 1) a rectangular base 1 perched on four feet 2 situated at its corners and of which only two appear.

The base 1 is notched with a longitudinal groove 3 which extends over its entire thickness and is used to receive a reference doll 4 and an adjustment doll 5 which serve as support for the test pieces E to be measured.

Each of the dolls 4 and 5 has for this purpose a lower keel 6 which slides in the groove 3 and two pads 7 on either side of the keel 6 and which rest and slide on the upper surface of the base 1. The keel 6 is provided with a vertical thread 8 (visible in FIG. 5), intended to receive a locking screw 9, the head of which rests on the lower surface of the base 1 and clamps the pads 7 on the base 1, which blocks the doll 4 or 5 concerned at the desired location of the groove 3. The keel 6 has indeed a depth less than that of the groove 3.

One of the pads 7 of the vertical reference doll 4 is provided with a vertical bore capable of coming into correspondence with holes 10 of the same diameter established on the base 1 in a row parallel to the groove 3. It then suffices to engage a indexing pin 11 in the vertical bore and the hole 10 chosen to maintain the position of the reference headstock 4 at a position known with precision and immutable. If there are several holes 10, it is to allow placing
The test piece E examined towards the middle of the base 1 whatever its length.

 The adjusting headstock 5 is devoid of this indexing means and its position is adjusted without precision as a function of the length of the test piece E by means of the locking screw 9.

The reference doll 4 carries (FIGS. 1 and 2) a corner 12 at its top in order to provide a fixed position reference to the test pieces. Three abutment surfaces delimit it: a horizontal support surface 13 on which one end of
The test piece E rests, a vertical stop surface 14 which serves as a longitudinal position reference for the test piece E and a vertical side surface 15, perpendicular to the previous one and parallel to the groove 3 which serves to define the transverse position of the test piece E. The adjustment doll 5 has a similar corner 12 ′ but which only has surfaces 13 ′ and 15 ′ in extension of the surfaces 13 and 15, on which the other end of the test piece E is placed and supported. The position of the test piece E on the base 1 is therefore perfectly defined. There is no longitudinal setting of the test piece E on the adjustment headstock 5, but a sensor support 16 close to the corner 12 ′ and which we will come back to later.

 The fixing of the test pieces is ensured by flanges 17, of which there may be a whole play depending on the test pieces which are used. The flanges 17 are rigid and elongated plates which generally include at least one oblong hole 18 and a thread 19 in which is engaged a pressure screw 20 with a long rod, the end of which clamps the test piece on a support surface 13 or 13 '; as for the oblong hole 18, it allows to pass another pressure screw 20 'which is engaged in a thread 21 at the top of the headstock 4 or 5. A lock nut 22 is engaged at the top of the rod of the screw pressure 20 '.

It is enough to lower it by unscrewing so that it blocks the flange 17 on the top of the headstock 4 or 5.

 Note that the dolls 4 and 5 are also provided with other internal threads 23, transverse instead of being vertical like the previous ones 21, and which serve to exert an identical fixing of the test piece E by the flanges 17, but by placing the test piece E on edge (FIG. 4): the clamping pressure is then exerted on the lateral surfaces 15 and 15 ′. In the case of flat test pieces with rectangular section like the one shown, it is then in fact the width of the test piece that can be measured.

 It is conceivable to use flanges 17 in place more flexible fixing means such as leaf springs 25 (Figure 6) having two rounded 26 and 27, oriented in the same direction, at their ends and an intermediate oblong hole 28 The intermediate oblong hole 28, like that 18 of the flanges 17, lets pass a pressure screw 20 'screwed on the headstock 4 or 5 and which carries a lock nut 22, the tightening of which presses one of the rounded sections 27 on the headstock and the 'other rounded 26 on one end of the test piece E.

 The device also includes measurement means located on two superimposed tables (Figures 2 and 3). The first table 29, fixed on the base 1 behind the groove 3, comprises a movable upper plate along the groove 3, and the second table 30 is placed on this plate and itself comprises a movable p, may s towards groove 3 or away from it. The plate of each of the tables 29 and 30 has its movement controlled by a stepping motor, respectively 31 and 31 '. We thus achieve what is often called a position adjustment in X-Y with this mechanism, which will not be described further because it is of a well-known type.

 The second table 30 carries a fork 32 whose branches 33 and 33 'are horizontal and superimposed at a distance large enough to largely frame the test piece E placed on the dolls 4 and 5. Each of the branches 33 and 33' has a bore 34 or 34 'intended to receive a 35 or 35' sensor. These are sensors already on the market, in the form of a pencil and which comprise (FIG. 7), in addition to a cylindrical casing 36, a magnetic core 37 sliding freely in the casing 36 and attached to a feeler rod 38 whose end 39 touches the surface of the test piece E. Two coils 40 and 41, joined by a median wire 42, surround different portions of the core 37. When a displacement is inflicted on the latter, the magnetic inductions which it causes in the two windings 40 and 41 undergo opposite variations, so that it suffices to compare the evolution of the voltages between the wires 42 and 43 (between which the winding 40 extends), and 42 and 44 (between which extends the winding 41), to determine with great precision the displacements of the rod 38.

The sensors 35 and 35 'are similar, and they are oriented in extension and towards one another, that is to say that their rods 38 and 38' are coaxial and come to touch two opposite faces of the test piece
E, respectively an upper face Fs and a lower face Fi. It then suffices to compare the measurements of the two sensors 35 and 35 'and to carry out the sum of the displacements of the rods 38 and 38' from a reference position in order to deduce the local thickness of the test piece E between the two faces Fs and Fi. By subtracting these displacements, however, it is possible to deduce the height of the mean line of the specimen
E. A collation of such measurements along the test piece E makes it possible to deduce its curvature or the deflections it has undergone. The cancellation of each sensor makes it possible to evaluate the shape of the surface on which the other sensor is walking.

 The sensors 35 and 35 ′ are therefore connected to a measurement acquisition card 45 (FIG. 3) which converts the electrical phenomena manifested in the windings 40 and 41 into displacement and position information, and which is itself connected to a computer 46 for presenting the results. The motors 31 and 31 ′ are controlled by the computer 46 by means of a displacement central 47.

Finally, a third 35 "sensor similar to the previous ones and oriented along the length of
the test piece E is housed in a bore 34 "of the sensor support 16 of the adjustment doll 5. Its rod 38" touches the longitudinal end face of the test piece E opposite to that, on the opposite end, which abuts against the stop surface 14. The 35 "sensor therefore makes it possible to measure the total length of the test piece E.

The sensors 35, 35 'and 35 "have an adjustable position in their bore 34, 34' and 34"; a pressure screw, 48, 48 'and 48 "respectively, allows
lock it in the desired position, after having
close or distant depending on the thickness of
the test piece E or its curvature. It is necessary in
these conditions of having calibration specimens so that the dimensions are known with as great a precision as possible in order to be able to serve as a reference to the information of the sensors 35, 35 ′ and 35 ″.

The calibration test pieces are simple in shape, advantageously parallelepipeds or test pieces of the same shape as the test pieces on which the measurements are actually carried out. They are fixed on the dolls 4 and 5 and the length and thickness measurements made by the sensors 35, 35 'and 35 "are corrected by the computer 46 to find the correct quantities.

 There is also a calibration test piece 49 of special shape (FIG. 8), entirely flat except for a blind hole 50 with a conical bottom 51. A ball 52 is placed on the conical bottom 51 and protrudes from the surface of the test tube 49.

Once this test piece 49 is fixed to the dolls 4 and 5 and in abutment on the surfaces 13, 13 ', 14, 15 and 15', the sensor 35 is moved on its upper surface Fs and on the ball 52 until its summit is reached. The states of the stepping motors 31 and 31 ′ which correspond to this position of the tables 29 and 30 are noted and provide the information for defining an origin common to all the measurements carried out on series of similar test pieces.

 The computer 46 is programmed so as to automatically receive the desired information on a large quantity of points on the surfaces of the test pieces E after having ordered the appropriate movements of the stepping motors 31 and 31 ′. It is equipped and programmed to provide the desired graphical visualizations and conventional in this kind of techniques, for example in the form of tables or maps of the specimen E with spots of different colors depending on the categories of information or drawings .

 The invention can be applied to the control of the dimensions and shapes of the test pieces or to deformation measurements due to bending, tensile, aging tests, etc., on test pieces which have been tested.

 The device I can, with minor modifications, carry out these measurements under controlled stress level.

Claims (10)

 1. Apparatus I for measuring dimensions of test pieces, characterized by means (12, 12 ', 17, 25) for wedging and fixing a test piece (E); a pair of facing sensors (35, 35 ') arranged in front of opposite faces (Fs, Fi) of the test piece (E), the sensors being oriented towards the dimensions on a common line and designed to measure each a distance to one of the faces; a device (29, 30, 32) carrying the sensors and able to move the sensors together and perpendicular to the dimensions; and a device (46) for reading the distances and calculating the dimensions.  2. Measuring device according to claim 1, characterized in that the dimensions are thicknesses and deflections of the test pieces.  3. Measuring device I according to any one of claims 1 or 2, characterized in that it comprises a third sensor (35 ") oriented in the longitudinal direction of the test piece and designed to measure a distance to a face d the longitudinal end of the test piece, one face of an opposite longitudinal end of the test piece being pressed against an abutment surface (14) of the means for wedging the test piece.  4. Measuring device according to any one of claims 1 to 3, characterized in that the device which carries the sensors is designed with means (48, 48 ') for placing the sensors in adjustable positions.  5. Measuring device according to any one of claims 1 to 4, characterized in that it comprises a calibration test piece (49) provided with an origin mark.  6. Measuring device according to claim 5, characterized in that the origin mark consists of a ball (52) projecting from a blind hole (50) with conical bottom (51) of the calibration test piece (49 ).  7. Measuring device according to any one of claims 1 to 6, characterized in that the device carrying the sensors comprises a double table (29, 30) sliding in two directions perpendicular to the means for wedging and fixing the test piece .  8. Measuring device according to any one of claims 1 to 7, characterized in that the means for wedging the test piece consist of supports (13, 13 ', 14, 15, 15') on three perpendicular planes.  9. Measuring device according to claim 8, characterized in that the supports are located on two longitudinal end parts of the test pieces and located on two dolls (4, 5) of which at least one is movable and has an adjustable position compared to the other  10. Measuring device according to any one of claims 1 to 9, characterized in that the means for wedging and fixing the test piece are designed to wedge and fix the test pieces flat and on edge.