DE102012204189A1 - Shielding a sensor in a rotary handle - Google Patents

Abstract

Twist grip arrangement (1) for the power control of a vehicle, comprising a twist grip (2) which is movable with respect to a fixed grip part (4), the position of the twist grip (2) being detected by means of a sensor (6) and an output signal from the sensor ( 6) is a measure of the position of the rotary handle (2) and the power control takes place based on the output signal, characterized in that the sensor (6) is a magnetic sensor interacting with a magnet (5) and around the sensor (6) Shielding element (7) is arranged.

Description

The invention relates to a rotary handle assembly for the power control of a vehicle, comprising a rotatably mounted with respect to a fixed grip part rotary handle, wherein the position of the rotary handle is detected by a sensor and an output signal of the sensor is a measure of the position of the rotary handle and based on the Output signal, the power control is carried out according to the features of the preamble of claim 1.

Rotary handle assemblies for power control of vehicles, such as motorcycles or the like, are known. If the driver turns on a rotary handle which is rotatable with respect to a fixed handle part, for example a handlebar, he can accelerate and thereby increase or decrease the speed of the vehicle. In order for the power control to take place, it is necessary to know the position of the rotary handle in relation to the fixed handle. Depending on the determined position, an output signal is generated by the sensor, which represents the position of the rotary handle and on the basis of which the power control of the drive motor of the vehicle takes place.

In known rotary handle arrangements, the position of the rotary handle with respect to the fixed handle part is determined by means of potentiometers. Although these potentiometers work reliably in practice, they have the disadvantage that they are subject to wear over their service life. Due to this wear, erroneous output signals or even no output signals from the sensor can occur, as a result of which the operation of the vehicle is impaired or even no longer possible.

The invention is therefore based on the object to avoid the disadvantages described above and to provide a rotary handle assembly that not only works wear-free, but also meets the conditions in practice in terms of operational readiness and freedom from errors.

This object is solved by the features of claim 1.

According to the invention, it is provided that the sensor is a magnetic sensor cooperating with a magnet (also called Hall sensor) and a shielding element is arranged around the sensor. The magnet is arranged on the rotatably arranged rotary handle, while the sensor (Hall element) is arranged on the fixed handle part. The reverse arrangement is also conceivable, namely that the magnet is arranged on the stationary handle part, while the sensor (Hall element) is arranged on the rotatably arranged rotary handle. Such a magnetic sensor has the advantage that it works wear-free over the life of the rotary handle assembly, since during the rotational movement of the rotary handle relative to the handle part no mechanical contact takes place, because the magnet is arranged at a predeterminable distance with respect to the magnetic sensor. Although such a sensor arrangement operates wear-free, but is exposed to external disturbing influences, such as interference signals, magnetic fields and the like, it is further provided that a shielding element is arranged around the sensor. A shielding element around the magnet is not required because the magnetic field emanating from the magnet should strike the magnetic sensor exactly in its effective range. Outside this effective range of the magnetic sensor, a shield should be carried out, for which purpose the shielding element is arranged around the sensor. By means of the shielding element, interference signals from the outside, in particular interfering magnetic fields, which can prevail around the rotary grip arrangement, are shielded. As a result, there is advantageously no distortion of the output signal of the magnetic sensor due to external influences. By shielding or its effect through the shield so influencing the sensor array by external magnetic fields if not avoided, then definitely be significantly reduced. The external interference magnetic field is attenuated by the shielding effect of the shielding, so that the influence of the disturbing magnetic field on the sensor assembly or on the magnetic sensor has no or only a small and therefore negligible influence.

In a further development of the invention, the shielding element is designed as a sheet metal part. For this purpose, the shielding plate is mounted over the sensor arrangement, that is to say the magnetic sensor, such that its effective area is only or largely exposed to the magnetic field of the magnet and the other areas of the magnetic sensor, which are not active area, are shielded by the shielding element. In this case, geometry, thickness, material and position of the shielding depending on the application or geometric design of the entire rotary handle assembly can be dimensioned differently and adapted to the respective installation space. In addition, such a sheet metal part has the advantage that it can be made quickly, easily and inexpensively. Thus, such a sheet metal part may be formed, for example, as a stamped bent part or as a punched roll part.

In a development of the invention, the shielding element is arranged rotationally symmetrically at least partially around the sensor. That is, the shielding member may, for example, have a cylindrical shape with a bottom, wherein the magnetic sensor is arranged in this can-like structure. The active surface of the magnetic sensor is thus not surrounded by the shielding, so that the magnetic field can impinge unhindered on the effective surface of the magnetic sensor.

In a further development of the invention, the shielding element is integrated in the rotary handle. If, for example, the rotary handle is made of a plastic material, it is conceivable that, with the manufacture of the rotary handle, for example in a plastic injection molding process, the shielding element is manufactured with production of the rotary handle. In the aforementioned plastic injection molding method, it is conceivable that the shielding element is inserted from an electrically and magnetically conductive material in the injection mold and then the injection molding process takes place. After removal of the finished rotary handle this can be mounted and fed to its function. Alternatively, it is of course also possible that the rotary handle and the shielding element form separate components from each other, which are joined together in a suitable manner. It is also conceivable that the shielding element is not arranged in the rotary handle, but in the stationary handle part, depending on whether the magnetic sensor is stationary and the magnet is relatively movable, or vice versa.

An embodiment of a rotary handle assembly according to the invention will be described in more detail below and explained with reference to an embodiment.

In the figure, as far as shown in detail, a rotary handle assembly 1 shown having a rotatably mounted rotary handle 2 having, wherein the rotary handle 2 around a longitudinal axis 3 is rotatably arranged. Fixed to this rotatable knob 2 is a handle part 4 provided where that by rotation of the rotary handle 2 relative to the fixed handle part 4 "Gas can be given". As an alternative to the arrangement described above, it is of course also conceivable that the rotary handle 2 fixed, for example, mounted on a handlebar, is arranged, and relative to the handle part 4 is movable.

To the relative position between the rotary handle 2 and the handle part 4 to be able to detect, as a wear-free sensor assembly is a magnet 5 and one with the magnet 5 cooperating sensor 6 , a magnetic sensor, available. In the embodiment shown, the magnet 5 fixed to the handle 4 arranged while the sensor 6 in the twist grip 2 and thus movable with respect to the handle part 4 is arranged. The reverse arrangement is conceivable, namely that of the magnet 5 is moved and the sensor 6 is arranged statically. To this sensor arrangement, consisting of magnets 5 and sensor 6 to shield against external interference magnetic fields is around the sensor 6 around a shielding element 7 arranged. In the embodiment, the shielding element 7 of an electrically and magnetically conductive material has an L-shaped cross-section. Which has the advantage that the sensor 6 which can be arranged on a circuit board with further electronic components, on the shielding element 7 can be mounted as a unit. Present, but not shown, are means that allow the output signal, resulting from the sensor 6 is generated in the direction of an engine control unit, also not shown for the power control of the vehicle is transmitted.

While in the above description it has been assumed that the rotary handle 2 rotatable with respect to the fixed handle part 4 can be moved, the inventive solution of the wear-free sensor assembly with its shielding also includes movement forms that are not rotational, but, for example, linear. For example, the rotary handle 2 not be designed as a rotatable, but as a longitudinally movable handle. Other forms of movement, for example, combinations of rotational and linear movements, are of course conceivable.

LIST OF REFERENCE NUMBERS

1

Rotary handle assembly

2

rotary handle

3

longitudinal axis

4

handle part

5

magnet

6

sensor

7

shielding

Claims (4)

Turning handle arrangement ( 1 ) for the power control of a vehicle, comprising one with respect to a fixed handle part ( 4 ) movably arranged rotary handle ( 2 ), wherein the position of the rotary handle ( 2 ) by means of a sensor ( 6 ) and an output signal of the sensor ( 6 ) a measure of the position of the rotary handle ( 2 ) and based on the output signal, the power control is carried out, characterized in that the sensor ( 6 ) with a magnet ( 5 ) is a cooperating magnetic sensor and around the sensor ( 6 ) a shielding element ( 7 ) is arranged. Turning handle arrangement ( 1 ) according to claim 1, characterized in that the shielding element ( 7 ) is formed as a sheet metal part. Turning handle arrangement ( 1 ) according to claim 1 or 2, characterized in that the shielding element ( 7 ) rotationally symmetrical at least partially around the sensor ( 6 ) is arranged around. Turning handle arrangement ( 1 ) according to claim 1 or 2, characterized in that the shielding element ( 7 ) in the rotary handle ( 2 ) is integrated.

Images