DE19651614A1 - Eddy current measuring device for a pointer instrument - Google Patents

Abstract

The invention concerns an eddy current measuring arrangement for an indicating instrument, said arrangement comprising a rotary magnet (8) which is disposed in rotationally rigid manner on a primary shaft and lies opposite an eddy current body (9) which is made of electrically conductive material and is secured in rotationally rigid manner on an indicator shaft (10), said rotary magnet being designed to transmit a first torque to the indicator shaft when the primary shaft (6) rotates. The arrangement further comprises a torsion spring (11) which transmits to the indicator shaft a second torque acting in the opposite direction to the first torque, a short-circuit member (12, 13) which is disposed behind the eddy current body and/or behind the rotary magnet, and a temperature-dependent compensation element (14, 17) for compensating an attenuation of the magnetic field of the rotary magnet and a reduction in the conductivity of the eddy current body as the temperature increases. According to the invention, the compensation element (14 - 17) takes the form of a spring element which is designed to reduce the second torque transmitted by the torsion spring (11) to the indicator shaft (10) or to maintain constant the first torque transmitted to the eddy current body (9) as the temperature increases.

Description

The invention relates to an eddy current measuring device for a pointer instrument, especially for a speedometer and / or a tachometer, with a rotatably arranged on a drive shaft rotating magnet, wel cher an eddy current body rotatably fixed on a pointer shaft made of electrically conductive material and when rotating the drive shaft for transmitting a first torque to the Pointer shaft is formed with a second, the first torque transfer the opposite torque to the pointer shaft the torsion spring, with one behind the eddy current body and / or behind the rotary magnet arranged yoke body and with a tem temperature-dependent compensation element to compensate for a Weakening of the magnetic field of the rotating magnet and one Reduction of the conductivity of the eddy current body with increasing Temperature.

Such eddy current measuring devices are used, for example, in tachometers used and are therefore known. As a compensation element at the well-known eddy current measuring mechanism over the pole pairs of the Drehma a compensation ring made of a material, whose magnetic resistance increases as the temperature rises. Here by the magnetic field generated by the rotating magnet  weakened at low temperatures and weakening at rising temperatures Temperatures decreased continuously.

The invention is based on the problem of an eddy current measuring device type mentioned so that it is as small as possible dim has solutions and is inexpensive to manufacture.

According to the invention, this problem is solved in that the compen sationselement is designed as a spring element, which to reduce the second transmitted from the torsion spring to the pointer shaft Torque or to keep the eddy current body constant transmitted first torque with increasing temperature det.

This design is used to compensate for the influence of temperature on the eddy current measuring mechanism no to be attached to the rotary magnet the compensation ring is more necessary. The rotary magnet can therefore against the eddy current body with a particularly small distance survive. As a result, the rotary magnet can be made particularly small and be made from an inexpensive magnetic material. The we Belstrommeßwerk therefore has particularly small dimensions and is inexpensive to manufacture.

The invention can of course also be realized if one in kinema table reversal of the conditions of the permanent magnet on the pointer shaft and provides the eddy current body on the drive shaft.

The eddy current measuring mechanism exists according to an advantageous further development extension of the invention from particularly few components when the Drehfe the one for training as a compensation element from a spring cone material with increasing temperature is made. There  the torsion spring for generating the second torque anyway there is no additional component for the compensation element needed.

According to another advantageous development of the Invention automatically set by the compensation element when the compensation element as an axial spring to reduce the axial Distance between the eddy current body and the rotary magnet rising temperature is formed.

Alternatively, the invention can also be implemented in that the compensation element as an axial spring to reduce the axial Distance between the yoke body and the eddy current body or the rotary magnet is formed with increasing temperature. This Design does not increase the size of the eddy current measuring mechanism because, thanks to the invention, a particularly small rotary magnet is used, which the eddy current body with particularly low Distance faces.

If a compensation element according to the invention that the Tempe raturgang fully compensated, only with a disproportionately large Effort can be realized, it is advantageous to use a compensation element use that does not exactly compensate for the temperature response and to realize the missing compensation with known means. Like this far the compensation element the compensation only incomplete executes, can advantageously also with undercompensation the missing in the working air gap with known compensation materials Compensation can be achieved. If a compensation element is about compensated, can advantageously by introducing Kompensa tion material, such as. B. FeNi alloys, in conclusion a compensa  tion can be achieved together with the compensation element temperature-neutral measuring mechanism realized.

The compensation element can be designed in almost any way and is particularly inexpensive if it is according to another advantageous Further development of the invention made of plastic in the injection molding process is done.

The one transferred from the rotary magnet to the eddy current body Torque is reduced with common material combinations and egg When the temperature rises by 10 ° C by about 4 to 8%. The Kompensa tion element is the same according to another advantageous development Invention this change over a particularly large temperature range vall out if it is made of a plastic with appropriate temperature behave like B. polyoxymethylene.

The compensation element made of plastic has even at high Temperatures sufficient strength and a low buckling if, according to another advantageous further development of the Er is fiber reinforced. For example, fiber reinforcement is suitable wise inserts made of glass fibers.

Spring elements often have a limited temperature spring range linearly variable. This temperature range can be easily enlarged if the spring element several behind other arranged, with changing temperature their spring constant un has differently changing sections.

To further reduce the cost of producing the eddy current measuring unit contributes if the rotary magnet according to another advantageous development of the invention is made of hard ferrite.  

The invention permits numerous embodiments. For further ver Clarification of their basic principle are four of them in the drawing represents and are described below. This shows in

Fig. 1 shows an inventive Wirbelstrommeßwerk with a designed as a compensation element torsion spring,

Fig. 2 shows an embodiment of the eddy current measuring unit according to the invention,

Fig. 3 shows the detail A from Fig. 2,

Fig. 4 shows another embodiment of the fluidized invention strommeßwerkes,

Fig. 5 shows the embodiment of a possible Kompensationselemen tes.

Figs. 1, 2 and 4 show, respectively, a pre-arrange in a housing 1 tes Wirbelstrommeßwerk 2-5 with a trained for connecting a flexible shaft 6 connecting piece 7. A rotary magnet 8 made of a permanent magnetic material is set in rotation via the flexible shaft 6 and is opposite a eddy current body 9 at a short distance. The eddy current body 9 consists of a material with an electrical conductivity, for example made of copper or aluminum, and is rotatably attached to a rotatable with respect to the rotary magnet 8 pointer shaft 10 . A rotation of the rotary magnet 8 generates an eddy current in the we belstromkörper 9 by magnetic induction. As a result, a first torque is transmitted to the pointer shaft 10 , which is greater, the faster the rotary magnet 8 rotates relative to the eddy current body 9 . This first torque is counteracted by a second torque transmitted from a torsion spring 11 to the pointer shaft 10 , which torque is greater the further the pointer shaft 10 is deflected. In order to improve the magnetic induction's a return body 12 , 13 is arranged on the top of the eddy current body 9 and on the bottom of the rotary magnet 8 . The torsion spring 11 is shown conically in the drawing. Of course, this can also be a flat spiral spring.

In the eddy current measuring mechanism 2 shown in FIG. 1, the torsion spring 11 is made to form a compensation element 14 from a material which reduces the spring constant of the torsion spring 11 with increasing temperature by the same amount by which the body torque transmitted to the eddy current body 9 drops . This compensates for the temperature dependency of the magnetic material of the rotary magnet 8 and the conductivity of the eddy current body 9 . Polyoxymethylene, for example, is suitable as the material for the torsion spring 11 .

FIG. 2 shows an axial spring designed as a compensation element 16, which belstromkörper reduces the distance between the magnet 8 and the rotary We 9 with increasing temperature. Since this distance is decisive for the eddy currents generated in the eddy current body 9 , this design compensates for a reduction in the torque transmitted by the torque 8 to the eddy current body 9 as the temperature rises. To illustrate the rotary magnet 8 , the eddy current body 9 and the yoke body 12 , 13 are shown cut GE.

In Fig. 3 it can be seen that between the pointer shaft 10 and the compensation element designed as an axial spring 16 in a bearing bush 16 b axially displaceable axial bearing 16 a for low friction La like the pointer shaft 10 is provided.

In the eddy current measuring mechanism 5 shown in FIG. 4, a compensation element 17 designed as an axial spring is arranged between the rotary magnet 8 and the lower yoke body 13 , which compensated for the rotary magnet 8 from the yoke body 9 as the temperature increased. Since the eddy currents generated in the eddy current body 9 , the stronger the smaller the distance of the return body 13 from the rotary magnet 8 , the temperature influences on the eddy current measuring mechanism 5 are thereby compensated.

The compensation element 15 shown in FIG. 5 is made in one piece from plastic in an injection molding process. It also has a web 18 and a locking clip 19 in addition to the actual spring element. With the help of the locking clip 19 , the compensation element can simply be pressed into the housing 1 until it engages and is thus completely installed. The web 18 then effects the desired position of the compensation element 15 in the eddy current measuring mechanism according to the invention.

Claims (10)

1. eddy current measuring mechanism for a pointer instrument with a rotating magnet arranged on a drive shaft in a rotationally fixed manner, which opposes an eddy current body made of electrically conductive material fixed in a rotationally fixed manner on a pointer shaft and which is designed to transmit a first torque to the pointer shaft when the drive shaft rotates, with a second, the first torque counteracting torque on the pointer shaft transmitting torsion spring with a arranged behind the eddy current body and / or behind the rotary magnet yoke body and with a temperature-dependent compensation element for compensating for a weakening of the magnetic field of the rotary magnet and a reduction in the conductivity of the eddy current body with increasing temperature, characterized in that the compensation element ( 14-17 ) is designed as a spring element, which for reducing the torsion spring ( 11 ) on the pointer shaft ( 10 ) transmitted second torque or for keeping constant on the eddy current body ( 9 ) transmitted first torque is formed with increasing temperature. 2. Eddy current measuring mechanism according to claim 1, characterized in that the torsion spring ( 11 ) for training as a compensation element ( 14 ) is made from a spring material ver reducing material with increasing temperature. 3. Eddy current measuring mechanism according to claim 1, characterized in that the compensation element ( 16 ) is designed as an axial spring to reduce the axial distance between the eddy current body ( 9 ) and the rotary magnet ( 8 ) with increasing temperature. 4. eddy current measuring device according to claim 1, characterized in that the compensation element ( 17 ) is designed as an axial spring to reduce the axial distance between the yoke body ( 12 , 13 ) and the eddy current body ( 9 ) or the rotary magnet ( 8 ) with increasing temperature. 5. Eddy current measuring device according to one of the preceding claims, there characterized in that an additional magnetic com pensation through a first material with temperature-dependent per meability in the working air gap and / or with a second material temperature-dependent permeability outside the working air gap is present as a magnetic yoke. 6. eddy current measuring device according to at least one of the preceding claims, characterized in that the Kompensationsele element ( 14-17 ) is made of plastic by injection molding. 7. eddy current measuring device according to at least one of the preceding claims, characterized in that the Kompensationsele element ( 14-17 ) is made of polyoxymethylene. 8. eddy current measuring device according to at least one of the preceding claims, characterized in that the Kompensationsele element ( 14-17 ) is fiber-reinforced. 9. eddy current measuring device according to at least one of the preceding claims, characterized in that the Kompensationsele element ( 14-17 ) has several successively arranged, with changing temperature their spring constant differently changing pieces. 10. Eddy current measuring mechanism according to at least one of the preceding claims, characterized in that the rotary magnet ( 8 ) is made of hard ferrite.