FR2463913A1 - Gauging thickness of coatings on metal products - using spring actuator joined to wheel system and lever carrying magnet to engage product - Google Patents

Abstract

In appts. for gauging the thickness of a coating on a base, at least one of which is magnetic, an element (20), slidable on a casing (1), is coupled with the free end of a lever (18) fixed on an intermediate member (19) which meshes with a spring actuator (2) connected to one of the members of a wheel system (3). A lever (10) carries a permanent magnet (11) engageable with a product to be tested, a second lever (16) being cooperable with the first lever (10) for increasing the force applied to the magnet (11) to lift it away from the product. A coiled spring (9) is connected between the lever (10) and a shaft (8) of the wheel system (3) and a second spring (15) between lever (18) and the casing (1) in an adjustable manner. A lever (12) fixed to shaft (8) resets the lever (10) into an initial position. A pointer (22) carried by shaft (8) indicates the gauged thickness on the circular scale (23) fixed on the casing (1).

Description

The present invention belongs to the field of magnetic measurements and in particular relates to an apparatus for measuring the thickness of coatings of metallic articles.

The present invention can be used in particular for measuring the thickness of nickel coatings with a ferromagnetic or non-magnetic base, as well as for measuring the thickness of non-magnetic coatings with a ferromagnetic base.

 Dn knows an apparatus for measuring the thickness of coatings of metallic articles, the operation of which is based on the measurement of the force of attraction of a permanent measurement magnet towards the part to be checked. This device comprises a body inside which are mounted: a wheel system; a spring motor connected to one of the elements of the wheel system to drive the latter in rotation; two balanced levers, the first of which carries a permanent measuring magnet whose magnetic field interacts with the ferromagnetic coating of the article, or with its base in the case of a non-magnetic coating, while the second comes into action mutual with the first balanced lever in the event that the latter's force is insufficient to tear off the permanent measurement magnet from the part to be checked; two spiral springs, the first of which is connected by one of its ends to the first balanced lever, and by its other end, to one of the axes of the wheel system, while the second spiral spring is linked by one of its ends to the second balanced lever, and by its second end, to a means of adjusting the spring tension; a magnetic element fixed to said body and attracting the permanent measuring magnet after it is torn from the article to be checked; a return lever of the first lever balanced in its initial position, rigidly connected to the central axis of the gear train on which are mounted a winding head and an indicator hand used to display the values measured by the device on a circular graduated dial rigidly fixed to said body.

 During the reassembly of the device, which is achieved by turning the winding head wedged on the central axis of the wheel system, the end of the permanent measurement magnet comes out outside the base plane of the body of the device and stops the wheel system.

 When placing the device on the article to be checked, the end of the permanent measuring magnet is positioned flush with the base plane of the body, the wheel system, under the action of the spring motor, begins to rotate, so that the first spiral spring is twisted until the permanent measurement magnet is torn off. At this moment the first balanced lever rotates around its axis and the braking spring fixed on said lever stops the rotation of the braking wheel forming part of the wheel system of the device and, consequently, stops the rotation of all wheel system.

Once the permanent measurement magnet is torn from the article to be checked, it is attracted to the magnetic element, which ensures much more effective braking.

 This known device makes it possible to determine the thickness of the coatings in a wide range, thanks to the use of the second balanced lever, the tension of which is adjustable.

 But at the same time, the use of this device is not entirely convenient because of the difficulties which are manifested when reassembling the device by rotation of the head, the motor torque of which is not adjustable.

 The object of the present invention is therefore to create an apparatus for measuring the thickness of the coverings of metal articles, in which the winding mechanism is known to allow rapid and convenient reassembly of the apparatus and, consequently, would increase device performance.

This problem is solved by the fact that the apparatus for measuring the thickness of coatings of metallic articles, of the type comprising a body in which are mounted: a system of wheels, a spring motor comprising a means for its reassembly and connected to one of the elements of the wheel system to drive it in rotation, two balanced levers, the first of which carries a permanent measuring magnet whose field interacts with the ferromagnetic coating of the article, or with its base in the case of a non-magnetic coating, while the other lever interacts with the first balanced lever in the case where the force of the latter is insufficient to remove from the article to be checked the permanent measurement magnet, two springs hairsprings of which the first is connected by one of its ends to the first balanced lever, and by its other end, to one of the axes of the wheel system, while the second spiral spring is linked by one of its ends at the second balanced lever, and by its other end, to a means of adjusting the spring tension, a magnetic element fixed to said body and attracting the permanent measuring magnet after its tearing from the article to be checked, a lever for recalling the first balanced lever at its initial position, rigidly connected to the central axis of the wheel system, on which is mounted an indicator needle used to display the values measured by the device on a circular graduated scale which is rigidly fixed to the body of the device, is characterized, according to the invention, in that the means for reassembling the spring motor comprises a lever rigidly connected to an intermediate element engaging the spring motor, and a spring frame mounted on the body of the device so as to be able to move relative to this body and being in contact with the free end of this lever in order to rotate it during its own movement.

 Such an embodiment of the spring motor winding means makes the operation of the apparatus more reliable, ensures its rapid and convenient reassembly, and, consequently, increases the efficiency of the apparatus.

The invention will be better understood and other objects, details and advantages thereof will appear better in the light of the explanatory description which follows of an embodiment given solely by way of nonlimiting example with references to the drawing single annexed in which
- Figure 1 shows a schematic isometric perspective view of the apparatus for measuring the thickness of coatings of metal articles, according to the invention;
- Figure 2 shows a sectional view along II-II of Figure 1, on an enlarged scale.

The apparatus proposed for measuring the thickness of coatings of metallic articles comprises a body 1 (FIG. I) in which is mounted a motor or spring control 2 with a means 2a for its reassembly, connected to one of the elements of a wheel system for driving the latter in rotation, said system comprising pinions 3 and a braking wheel 4. The braking wheel 4 is locked by a pin 5 and a spring braking 6. On one end of the central axis 7 of the wheel system is engaged a shim, sole, shoe or the like 8 for fixing the inner end of a first spiral spring 9 whose outer end is fixed at the end of a first balanced lever 10. On the same end of the first balanced lever 10 are fixed the dowel 5 with the braking spring 6 and a permanent measuring magnet Il (sensitive element of the device) whose field comes into mutual action with the ferromagnetic coating of the article ( not shown in the figure), or with its base when the coating is non-magnetic. To return the first balanced lever 10 to its initial position, a return lever 12 is rigidly engaged on a return lever 12.

At the other end of the central axis 7 is arranged coaxially a means of adjusting the spring tension, produced in the form of a flywheel 13 with means (not shown) on which is engaged in a rigidly a shoe or the like 14 to which is fixed the inner end of a second spiral spring 15 o The outer end of the latter is fixed to the end of a second balanced lever 16. The same end of the second balanced lever 16 has a bent arm cooperating with the first balanced lever 10. The two levers 16 and 10 swing freely on axes of rotation 16a and 10a relative to which they are balanced.

The apparatus is provided with a magnetic element 17 fixed to the body 1 coaxially with the permanent measurement magnet 11, at a certain distance from the latter, and attracting the latter after being torn from the article to be checked.

The means 2a for reassembling the spring motor 2 comprises a lever 18 rigidly connected to an intermediate element 19 engaged with the spring motor 2, and a spring frame 20. The spring frame 20 is disposed on the part of the body 1 opposite to that where the permanent measuring magnet 11 is located, and this so as to be able to move relative to the body 1. The spring frame 20 is in contact with the free end of the lever 18 in order to rotate it during its own-displacement. Between the walls of the body 1 and of the frame 20 is installed a helical spring 21 for the return of the frame 20 to the initial position.

 The indications of the device are noted using an indicator needle 22 fixed on the central axis 7 of the wheel system, on the side of the wedge 8, and a circular scale 23 rigidly fixed to the body 1.

 The operation of the device for measuring the thickness of coatings of metal articles is as follows.

 When the spring frame 20 moves upwards relative to the body 1 of the device, the lever 18 being in contact with the winding frame 20 rotates by rotating the intermediate element 19, the spring motor 2 , the pinions 3 of the device's wheel system, the indicator needle 22 being on the central axis 7, and the return lever 12. At this time, the helical spring 21 is compressed.

The rotation of the pinions 3 of the wheel system and of the braking wheel 4 rotating with said pinions continues until the pin 5 comes to bear on the braking wheel 4. At the same time the free end of the magnet permanent measurement It drops lower than the level of the basic plane of the device. Once the device has been reassembled, the frame 20, under the effect of the helical spring 21, occupies its initial position.

When placing the device by its base plane on the surface to be checked of the article, the free end of the permanent measuring magnet It sinks flush with the base plane, while the first balanced lever 10 rotates at an angle sufficient to release the braking wheel 4 from the pin 5. The device's wheel system can then rotate under the action of the spring motor 2. The central axis 7 rotates in at the same time as the wheel system, by winding or twisting the inner end of the spiral spring 9 until the torque thus created is sufficient to tear off the permanent measurement magnet Il from the item to be checked.

When the permanent measurement magnet 17 is torn off, the first balanced lever 10 rotates about its own axis and the braking spring 6 fixed on said lever comes into contact with the braking wheel 4, stops its rotation and consequently that of the central axis 7 carrying the indicator needle 22.

In the event that the maximum possible winding or torsion angle of the first spiral spring 9 is insufficient to create the torque necessary to tear off the AixE permanent measurement magnet 11, it will be necessary to bring the second spiral spring 15, more rigid, and this, by turning the handwheel 13 by a given angle relative to the body 1 of the device. The torque produced on the second spiral spring 15 is applied via the second balanced lever 16 to the first balanced lever 10 at the point of contact of these levers.

 When checking articles of the same type produced in series, it is not always necessary to carry out absolute measurements, it suffices to determine whether the coating thickness is within the prescribed limits.

To indicate on the graduated dial 23 the zones corresponding to the required quality of the coatings, one can use indexes 24 (Figures 1, 2) whose position can be adjusted by independent rotation and locking of the movable rings 25 and 26 relative to the body 1 of the device.

 Of course, the invention is in no way limited to the embodiment described and shown which has been given only by way of example. In particular, it includes all the means constituting the technical equivalents of the means described as well as their combinations, if these are carried out according to the spirit and implemented in the context of the claim which follows.

Claims (1)

CLAIM Apparatus for measuring the thickness of coatings of metallic articles, of the type comprising a body in which are mounted: a wheel system, a spring motor provided with a means for its reassembly and connected to one of the elements of said wheel system to drive it in rotation, two balanced levers, the first of which carries a permanent measuring magnet whose magnetic field must interact with the ferromagnetic coating of the article, or with its base in the case of a magnetic coating, while that the second lever cooperates with the first balanced lever in the event that the force of the latter is insufficient to tear off the permanent magnet for measuring the article to be checked, two spiral springs, the first of which is connected by one of its ends to the first balanced lever, and by its other end to one of the axes of the wheel system, while the second spiral spring is linked by one of its ends to the second balanced lever, and by its aut re end, to a means of adjusting the spring tension, a magnetic element fixed to the body of the device and attracting the permanent measuring magnet after its tearing off from the article to be checked, a return lever of the first balanced lever in its initial position, rigidly connected to the central axis of the wheel system, an indicator hand being mounted on said central axis to display the values measured by the device on a circular graduated dial rigidly fixed to the body of the apparatus, characterized in that the means for reassembling the spring motor comprises a lever rigidly connected to an intermediate element engaged with the spring motor, and a spring frame mounted on the body of the apparatus so as to be able to move relative to this body and being in contact with the free end of this lever in order to make it rotate during its own movement.