DE9318589U1 - Pulse generator with tear-off oscillator - Google Patents

Description

Description

The invention relates to an electronic pulse generator which preferably uses the breakaway oscillator principle and which is intended for use in or on a motor vehicle according to the preamble of claim 1.

State of the art:

Electronic pulse generators are known in many different forms. A particularly important area of application for such pulse generators is the determination of rotational speeds (angular speeds) of rotating shafts, wheels, etc., where it is necessary to generate one or more pulses per revolution of the rotating object, so that the angular speed of the shaft or a wheel, etc., can be determined based on the electrical pulse properties.

A distinction is made between pulse generators that are suitable for a speed range below a typical device maximum speed up to any low speed (static pulse generators) and those that are suitable for monitoring speeds in a range above a minimum speed up to a maximum speed (dynamic pulse generators). Pulse generators that meet special requirements in terms of durability and resistance to increased temperatures and contamination are known for use in motor vehicles. It goes without saying that for lower speed ranges, static pulse generators can be used more universally than dynamic ones.

It is also state of the art to determine the driving speed of a vehicle, such as a passenger car or truck, via the rotational speed of the vehicle wheels or via those vehicle parts that are in direct kinematic contact with them.

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connection, as is the case for individual gear wheels, cardan shafts and others.

For this purpose, a slotted or toothed pulse wheel made of soft or hard magnetic material is usually provided. This is kinematically connected to one of the vehicle parts mentioned, its rotational frequency (or angular velocity) is proportional to the speed of the vehicle. The slots or teeth of such a pulse wheel cause a change in the magnetic flux density at the installation location of a suitable magnetic field-sensitive sensor or pulse generator, such as a Hall sensor or an inductively operating proximity sensor. In this way, the periodically generated changes in a local magnetic field are converted into electrical pulses by a sensor element within a pulse generator. The pulses of such a pulse generator represent a path-proportional signal, which is sent to the input of an associated display or recording device. - In practice, electronic pulse generators have proven to be useful for measuring speed, which have an oscillator circuit with an inductively acting sensor element as the frequency-determining component. Such an oscillator is preferably connected as a so-called chopping oscillator, i.e. it oscillates at a substantially constant frequency, provided that the frequency-determining inductance has a minimum required inductance value, and which terminates the oscillation if the inductance is smaller than a lower limit value.

Problem:

Arrangements of the type described have also proven themselves in use at higher temperatures. Depending on the size of the speed to be measured and the requirements for the accuracy of the speed determination (resolution), it is still necessary to use slotted or toothed

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Pulse wheels with different numbers of teeth are used. It goes without saying that the use of pulse wheels with a relatively high number of teeth or slots leads to better accuracy, since a larger amount of information is given out per revolution of a pulse wheel. Efforts are therefore being made to use existing gear wheels suitable for determining the speed of a motor vehicle as cost-effective pulse wheels, which also have a very high pitch accuracy due to their design.

As a rule, it is technically advantageous to keep the distance between such gear wheels (usually spur gear wheels) and a pulse generator as large as possible, provided that the electronic requirements allow this. The actually required distance between the gear wheel or a pulse wheel and an associated pulse generator depends on the structural dimensions of the gear wheel to be scanned. Depending on the distance between the teeth and the size of such a gear wheel, the rotation of the gear wheel results in a change in the inductance of the oscillator, which is different for each gear wheel. This is based on the fact that teeth and parts of the gear wheel serve as movable magnetic return elements. Since this change should be as large as possible, adapted, differently sized and differently shaped soft magnetic flux guide pieces for the oscillator inductance must be provided - depending on the structural conditions of the gear wheel to be scanned. Accordingly, depending on the geometric dimensions of the gears to be scanned and their tooth spacing, breakaway oscillators are available which look similar on the outside, but whose frequency-determining inductances have differently shaped soft magnetic cores or flux guides. With a shell core, a working air gap of approximately half the

MK Nov. 1993

The cup core diameter corresponds to the tooth and gap if the tooth and gap are approximately the same size or larger than the cup core diameter. For finer resolutions, as may be required for scanning gears, for example, a cup core with a very small diameter and correspondingly small working air gap would have to be used. However, if a flux guide piece in the form of a cylindrical core is used, more favorable conditions arise, i.e. the working air gap can be kept larger.

It is therefore of particular interest to create a pulse generator that is as universal as possible. This should be able to scan both conventional pulse wheels with a diameter of approx. 50 to 250 mm and a maximum of 8 teeth at a distance (working air gap) of around 2 mm, as well as gear wheels with a slightly smaller working air gap.

The object of the invention is therefore to provide a cost-effective pulse generator of the static type, the oscillator electronics of which are located within the pulse generator housing and the inductive sensor or oscillator element of which is suitable for a wide range of applications, so that in particular gear wheels of different sizes and numbers of teeth as well as conventional pulse wheels with a maximum of 8 teeth can be reliably scanned.

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Invention:

This object is achieved in that the pulse generator has a circuit board 12 with an oscillator electronics 30 of a uniform type within a housing 10 and a sensor head 18 of a variable type selected from a number of different sensor head types compatible with the oscillator electronics 30, the sensor head 18 of the pulse generator preferably being provided with a standardized sensor element receiving device 14 which is equipped with a mechanical snap spring 15 and at least one electrical contact spring 20 and is positively secured to the associated circuit board 12 of the pulse generator by means of a snap connection. At the same time, the sensor element receiving device 14 is connected to the oscillator electronics 30 by means of one or more contact springs 20 via the contact surfaces 21.

In this way, the following advantages are achieved: The manufacturing costs of such a sensor are reduced by limiting the use of only one version of the oscillator electronics, by limiting the use of only one or a few versions of the housing and by limiting the use of a small number of sensor head types with different inductances or associated cores. The assembly of a pulse sensor to be manufactured is made significantly easier by using a standardized, inexpensive contact device within the pulse sensor housing. The invention also makes it possible to inexpensively produce sensor head variants with inductances according to special specifications for smaller quantities.

Description of the invention:

These and other aspects of the invention are described in detail below with reference to the drawing.

It shows:

Fig. 1 shows the design diagram for a pulse generator according to the invention with a standardized housing and oscillator electronics, and a holder for a sensor with a shell core.

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Fig. 2 the design diagram for a pulse generator with a standardized housing and oscillator electronics and a holder for a sensor with a pin core.

Fig. 3 a top view of an uncovered pulse generator

The pulse generator shown in Fig. 1 is encased in a housing (preferably a plastic housing) 10. In this housing there is an oscillator electronics 30, which is arranged on a printed circuit board 12 and is preferably connected in the manner of a breakaway oscillator. According to the known state of the art, either discrete switching elements in the form of transistors, resistors, etc. can be used for this purpose, or essential parts of the circuit can be mounted in the form of a so-called integrated circuit (IC). The associated inductance, which determines the oscillation frequency of the oscillator, consists of a coil 17, which usually has a ferromagnetic core and whose inductance can be varied to a certain extent due to externally present parts of the associated magnetic circuit. For this reason, it is necessary that the inductance of a sensor head of the

Pulse generator is arranged near one of its front sides and, when the pulse generator is in operation, is only a short distance from a registering gear or pulse wheel. Accordingly, the shell core 16 shown in Fig. 1 extends almost directly to a front surface of the sensor housing 10. This shell core forms part of the magnetic circuit, which consists of parts such as a gear wheel, one or more teeth of such a gear wheel and a magnetic air gap. For this reason, it is advantageous to provide plastic material or another non-magnetic material for the housing 10 in order to prevent magnetic shunts and, if necessary, eddy currents. The shell core 16 is attached to the front side of an angled holder 14 and is fitted in the usual way with a coil 17, the two winding ends of which are connected to contact springs 20. The holder 14 is provided with a snap spring 15, which has a circular snap tongue tip 22 at its end. When the holder 14 is plugged onto the circuit board 12 together with the attached sensor head 18, the snap spring 15 snaps into an associated opening 13 in the circuit board 12 with its snap tongue tip 22, resulting in a positive, centered connection between the sensor head 18 and the circuit board 12. Additional centering is achieved by a centering lug 23 on the holder 14, whereby the centering lug protrudes into a corresponding recess in the circuit board 12 and prevents lateral displacement of the holder 14 relative to the circuit board. After the holder 14 has been plugged onto the circuit board 12, the contact springs 20 touch the contact surfaces 21 provided for making contact and effect the electrical connection of the coil 17 with the oscillator electronics 30. This is supplied with electrical energy in a substantially known manner via two of the four cable wires 4, 5, 6, 7 of a connecting cable 3 and emits the desired electrical useful signal (pulses) via the remaining wires of the

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Cable. The wire ends of the connecting cable 3 are brought into contact with the circuit board in a known manner by means of a solder, plug or clamp connection with corresponding conductor tracks on the circuit board 12. During the manufacture of the pulse generator, however, this only takes place when the fully assembled circuit board is inserted into the housing 10 along the guide grooves 8 (Fig. 3). Instead of guide grooves, guide ribs can also be provided. The hold-down device 9, which is attached to the housing cover 11, serves as strain relief for the cable 3. The housing cover also has a catch so that it can be plugged into the housing in a mechanically secure manner, and also a filling opening so that the cavities inside the housing 10 can be filled with a suitable, self-hardening casting compound 19.

Fig. 2 shows the assembly of the circuit board 12 of a pulse generator with a sensor head with a pin core 46. This consists, for example, of a ferrite material suitable for high frequencies and has a diameter of a few millimeters. Its end pointing towards the front of the pulse generator is wound or provided with a coil 47 of a few millimeters in length, the ends of which are also connected to two contact springs 20'. The pin core is located in a hollow cylindrical recess of a holder 14', which is provided with a snap spring 15' in a similar manner to that shown in Fig. 1. This snaps into the corresponding opening on the circuit board 12 when the holder 14' is plugged in, so that here too there is an exactly coaxial alignment of the pin core 46 relative to the cylinder axis of the pulse generator. The contact springs 20' according to Fig. 2 are, similar to Fig. 1, expediently located laterally next to the snap spring and have such dimensions that they rest on the intended contact surfaces 21 of the circuit board 12 when the receptacle 14' is placed on the circuit board

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This makes it possible to equip a standardized electronic unit, consisting of a standard circuit board and standard oscillator electronics, with different inductances, so that the pulse generator can be adapted and manufactured for different detection tasks with comparatively little effort.

Finally, Fig. 3 shows a top view of the pulse generator, cable 3 and mounting plate 1, which is provided with a mounting hole 2 and, if necessary, with additional positioning aids in the form of guide grooves or the like.

Claims (1)

52295 File: 11. 11. 1993 hx Title: Pulse generator with breakaway oscillator Protection claims: Pulse generator with breakaway oscillator for determining rotary movements, particularly for use in motor vehicles, characterized, that the pulse generator has, within a housing (10), a circuit board (12) with an oscillator electronics (30) of a uniform type and a sensor head (18) of a variable type selected from a number of different sensor head types compatible with the oscillator electronics (30). Pulse generator with breakaway oscillator for determining rotary movements, particularly for use in motor vehicles,
characterized, that the sensor head (18) of the pulse generator is provided with a standardized sensor element receiving device (14), wherein the sensor element receiving device (14) is provided with a mechanical snap spring (15) and at least one electrical contact spring (20) and is positively attached to an associated circuit board (12) of the pulse generator by means of a snap connection. »2 Pulse generator according to claim 1 or 2, characterized in that the circuit board (12) has an opening (13) for accommodating a snap-in tongue tip (22) and at least one contact surface (21) for contacting an electrical contact spring (20). Pulse generator according to one of the preceding claims, characterized in that the pulse generator has a housing (10) which is provided with guide grooves (8) or webs for receiving the circuit board (12), with a cable feedthrough (3') and a hold-down device (9) for cables (3). Pulse generator according to one of the preceding claims, characterized in that the housing (10) enclosing the pulse generator and the cable end is filled with a casting compound (19) in the assembled state and is closed by means of a latchable cover (11). Pulse generator according to one of the preceding claims, characterized in that the sensor head (18) alternatively has a shell core (16) or a pin core (46). Pulse generator according to one of the preceding claims, characterized in that the circuit board (12) has an oscillator circuit which can be connected optionally and without modification either to a sensor head (18) with a pin core (46) or to a sensor head (18) with a shell core (16). MK NovN