DE3844020A1 - Displacement sensor (position pick-up) having mechanical gearing elements - Google Patents

Abstract

Displacement sensor having non-linearly operating mechanical gearing elements for transforming the linear movement of a drive rod of a drive for regulating, control and blocking (shut-off, stop) fittings, having a Hall sensor whose non-linearity opposes the non-linearity of the gearing elements in order to compensate the non-linearity of the gearing elements; cf. Figure 2. <IMAGE>

Description

The invention relates to an arrangement according to Preamble of claim 1.

Such arrangements are known as assemblies of control, control and shut-off valves and have proven themselves many times in practice. Your task is usually the linear movement of the drive rod of an actuator, for. B. a valve actuator and to report to a central monitoring point. So far this has been done e.g. B. by means of differential transformers or push potentiometers, in which the linear movement of the drive rod by means of straight parts of the measuring system, such as by the core or the grinder, is detected. The measured variable, ie the path s , is converted linearly with sufficient accuracy as a result of the change in amplitude or resistance into a corresponding electrical signal.

However, these straight-line measuring systems have for the practical use, especially in harsh environments conditions, such as in the process engineering industry, some serious disadvantages. So z. B. straight line only  to seal against moisture and dust that a corresponding lifespan or the desired number of movements is safely achieved. Besides, one is mechanical adaptation to the measuring range is not possible, so that with reduced measuring ranges with poorer technical Data, especially with regard to linearity, Resolution u. a. - must be expected.

For these reasons, measuring systems with rotating Entry movement enforced. The straight line Movement, e.g. B. the aforementioned valve rod, via a Pen and a lever in a corresponding angular movement converted.

This angular movement of the shaft is simple and Way with a round cord ring or an O-ring made durable and insensitive to dirt. Also are capacitive transducers, resolvers, rotary potentiometers etc. known.

A disadvantage of these systems is the fact that the Swivel angle of the lever shaft linear as electrical Output size is shown and not the straightforward Movement of the valve stem.

As is known, there is a connection between the translational path s and the angle ϕ of the measuring shaft

when R is the distance between the point pin and the axis of rotation and the lever for s = 0 is perpendicular to the actuator stem.

The non-linearity corresponding to the arc-sin function is however not acceptable for many applications. A appropriate electrical compensation is expensive.

The invention is therefore based on the object To create a measuring system for linear movements, the despite lever linkage and rotary union in a housing linear measurement signal results without a special mechanical and / or electrical linearization is.

This object is achieved by the characterizing Features of claim 1 solved.

According to the invention, a sensor is therefore used, the electrical output variable just the reverse function of the lever system, that is to say corresponds precisely to the sine function. Such a system advantageously consists of two Magnets and a Hall sensor. Hall sensors are in themselves known, cf. H. Völz, Electronics, 1st edition, Berlin 1979.

In such sensors, the output voltage is U _H , namely the Hall voltage according to the equation

U _H ~ I · B (Eq. 2)

proportional to the product of current I and magnetic induction B.

If the Hall plate according to the invention for s = 0 is fixed in the field with its effective area parallel to the magnetic induction B _o , the effective component of the induction B _{eff changes} according to the equation

B _eff = B _o · sin ϕ . (Eq. 3)

So that will

and thus

Since = const, it can be seen immediately that the output signal U _{H is} directly proportional to the path s .

According to a development of the invention, instead of one Hall sensors other sensors can be used, provided this the required property with regard to the angular function have, e.g. B. optical, so radiation sensors.

Further features of the invention result from the Subclaims.

DE 35 10 252 A1 already has a Hall sensor as position transmitter for a hydraulic working cylinder became known, in a surrounding the piston rod Housing is arranged on the piston end of the Working cylinder is placed. Because with this arrangement mechanical transmission links that have a pivoting motion  execute, are missing, there occur the basis of the invention problems.

The invention is based on one in the drawing illustrated embodiment explained.

It shows

Fig. 1 shows the functional structure of an arrangement having a mechanical transmission link non-linear motion converter and a hinged signal generator according to the invention,

Fig. 2 shows the schematic structure of a serving as a signal transmitter Hall sensor,

Fig. 3 shows the structural design of serving as a signal transmitter Hall sensor in front view,

Fig. 4 shows the Hall sensor partially cut in side view

Fig. 5 shows the Hall sensor of Fig. 3 partially cut in plan view.

For a better understanding of the invention, the problem to be solved is described in advance with reference to the basic arrangement shown in FIGS. 1 and 2.

This arrangement consists of a drive rod 1 ( FIG. 1), a signal transmitter 2 ( FIG. 2) and a lever 3 . One end of the lever 3 lies in the example shown with a support pin attached to it under tension of a spring on a guideway which is perpendicular to the axis of the drive rod 1 and defines the position of the drive rod 1 . To the other end of the lever 3 which is rotatably mounted measuring shaft 6 is rigidly of the signal generator 2 is connected, which is about the pivot angle φ of the lever 3 relative to the perpendicular to the axis of the drive rod 1 twisted, when the drive rod 1 defined from the through this vertical zero position is shifted by the distance s . The signal generator 2 accordingly gives the angle of rotation of the measuring shaft and thus the pivoting angle ϕ of the lever 3 but not a linear displacement signal s of the drive rod 1 as a measurement signal.

According to FIG. 1, the relationship mentioned at the beginning exists between the translational path s and the angle ϕ of the measuring shaft

if R is the distance of the (pinpointed) support pin on the support track from the axis of rotation of the measuring shaft and if the lever 3 for s = 0 is perpendicular to the drive rod 1 .

In order to compensate for the non-linearity corresponding to the arc-sin function, a non-linear sensor is used as the signal generator, the electrical output signal of which changes in the opposite way to the motion converter and thus after the sin ϕ .

Such a signal generator, as shown in FIG. 2, consists of the two magnetic poles 7 and 8 and the intermediate Hall sensor 9 , which is connected to the measuring shaft 6 of the signal generator 2 in FIG. 1 and rotated by the angle of rotation ϕ . The Hall voltage becomes the output voltage

U _H ∼ IB (2)

supplied, which is the product of electricity and magnetic Induction is proportional.

If the Hall plate is fastened in the field with its effective area parallel to the magnetic induction B _o in accordance with the inventive idea for s = 0, the effective component B _{eff of} the induction B _o according to FIG. 2 changes according to equation (3)

B _eff = B _o · sin d .

So that will

and thus

Since = const, it can be seen that the output signal U _{H is} directly proportional to the path s . In the event that the lever 3 is articulated via a pin attached directly to the drive rod 1 , a sensor of the proposed type leads to a noticeable reduction in the linearity error. Then however applies

if L is the distance perpendicular to the direction of movement between the point of application of the pin and the axis of rotation of the measuring shaft. Although this function is not completely compensated for by the sine curve of the actual sensor, the error is in any case significantly less than in the case of a sensor with a linear assignment of the angle d to the output signal.

In FIGS. 3 to 5 a constructive embodiment is shown of a realized sensor. The Hall plate 9 is fixed since it is pressed by a prestressed spring 10 via a carrier lever 11 against a fixed stop 12 in the housing 13, which is only indicated. The rotary movement of the measuring lever, not shown, is here transmitted to the magnets 17, 18 via the measuring shaft 6 , on which a bell-shaped carrier 15 is fastened by means of a flange 16 . In the middle position, the field lines of the magnets 17 and 18 run parallel to the effective surface of the Hall plate 9 ' .

This non-positive mounting of the Hall plate carrier effective temperature is easily Compensation reached.

Claims (6)

1. Arrangement for generating the size of a linear movement proportional electrical signals, with non-linear mechanical transmission members for converting the linear movement into a corresponding rotary movement, characterized in that a non-linear signal generator ( 2 ) is used to generate the electrical signals, the non-linearity of which Non-linearity of the mechanical transmission elements ( 2, 3 ) is opposed to compensate for the non-linearity of the transmission elements. 2. Arrangement according to claim 1, characterized by its use as a path measuring system for detecting the rectilinear movement of the actuator stem ( 1 ) of drives for regulating, control and shut-off valves with conversion of the rectilinear movement of the actuator stem ( 1 ) into a rotary movement of the signal generator ( 2nd ) attached by means one of a signal transmitter on and hinged or via a pin (4) to the drive rod supported on this lever (3) existing motion converter. 3. Arrangement according to claims 1 and 2, characterized in that a Hall sensor serves as the signal transmitter ( 2 ), in which either the Hall plate ( 9 ) against fixed magnets ( 7, 8 ) or magnets ( 17, 18 ) is rotatably arranged relative to the fixed Hall plate ( 9 ' ). 4. Arrangement according to claims 2 and 3, characterized in that the magnets ( 7, 8/17, 18 ) are arranged so that in the neutral central position of the Hall plate, its effective area parallel to the magnetic field lines between its two poles is aligned. 5. Arrangement according to claim 3, characterized in that the Hall plate ( 9 ' ) is mounted on a rotatable in the measuring shaft ( 6 ) support lever ( 11 ) which is non-positively (stop 12 , spring 10 ) is held in its rest position. 6. Arrangement according to claims 1 and 2, characterized in that an optical sensor serves as the signal transmitter ( 2 ), the light-sensitive surface exposed to parallel light is arranged rotatable relative to the luminous flux.