The invention relates to a hydraulic pump or hydraulic motor having a rotation speed sensor in accordance with the features of claim 1. Such hydraulic machines, which are used as a pump or a motor, have a rotating shaft, which is mounted in a fixed position in the housing, and a device for the purpose of determining its speed of revolution, which is required, for example, in the case of inclined-axis motors for the detection of the vehicle speed. In this case, the rotation speed is tapped off from the rotating parts via a sensor, in which case annular gears or magnet rings are often used which are fitted to the rotating parts and have the task of producing pulses for a sensor fixed to the housing.
The shaft is an option for the positioning of the pulse generator. The sensor in this case needs to be provided opposite on the housing. Owing to the different installation conditions of the machines, there is not always the desired amount of space available for this. Inclined-axis motors, for example, are often installed in extremely short wheel-hub drives. This requires a housing version (cartridge), in which a large proportion of the rotating parts are located in the region of the gear mechanism. There is then no longer sufficient space available for the rotation speed sensor and its fixing parts in order to be able to mount it perpendicularly with respect to the shaft along an axis parallel to the attachment flange. In this case, individual solutions need to be found in each case for the various housing designs. These circumstances will be explained briefly below with reference to
The present invention aims to provide a hydraulic pump or a hydraulic motor having improved rotation speed sensing.
This object is achieved by the measures in accordance with claim 1. Developments of the invention are included in the dependent claims.
The hydraulic pump or the hydraulic motor according to the invention has a rotating shaft, which is mounted in a fixed position in a housing and on which a pulse generator is provided. A rotation speed sensor, which is fixed to the housing, comprises a sensor element, which is associated with the pulse generator and fitted eccentrically and offset with respect to the insertion axis of the rotation speed sensor. It is thus possible for the outwardly leading main part of the rotation speed sensor to be displaced into a region where there is free space available in the housing variants in question, while the sensor element can be fitted within the housing with optimum proximity and alignment with respect to the pulse generator. This makes sensing of the rotation speed possible even in regions within the housing of hydraulic pumps and motors which are otherwise not accessible or are only accessible with difficulty.
The rotation speed sensor is preferably in the form of an L-shaped built-in part, on whose first limb the sensor element is provided, and on whose second limb fixing means, intended for installation in the housing, and a plug element, for electrically connecting the sensor element to electronics fitted outside the housing, are provided. Owing to the L shape, the sensor element can be displaced eccentrically to quite a considerable extent, given a corresponding length of the limb, with the result that the sensor can be adapted to quite different installation requirements. The distance between the sensor element and the insertion axis (central axis of the accommodating hole) may in this case be greater than the radius of the housing hole, provided around this axis, for the purpose of accommodating the rotation speed sensor.
The sensor element is preferably in the form of a Hall probe, and the pulse generator is preferably in the form of a magnet element. Inductive sensor elements, GMR sensors (giant magnetoresistive sensors) or AMR sensors (anisotropic magnetoresistive sensors) can advantageously be used. The pulse generator may be in the form of, for example, an annular gear.
It is advantageous if the first limb, bearing the sensor element, of the L-shaped rotation speed sensor is considerably longer than the second, outwardly pointing limb. The design engineer therefore has additional freedom in optimizing the offset of the sensor element with respect to the insertion axis and the process of passing the plug part through the housing wall and fixing it. The first limb of the L-shaped rotation speed sensor in this case preferably comprises a printed circuit board, which bears the sensor element and makes a particularly space-saving solution possible. The second limb of the rotation speed sensor is designed such that it closes off the wall of the housing in a sealing manner once it has been installed in said housing. The connection to the outside takes place merely via the plug connection. Components which protrude far out of the pump contour and are thus unprotected are avoided.
One further advantage results from the fact that the rotation speed sensor can be combined with a temperature sensor, with the result that only one built-in part is required for both measurements. Further features and advantages of the invention result from the description below relating to the exemplary embodiment.
The rotation speed is tapped off from the shaft 5, which is mounted in a fixed position in the housing 6a and on which an annular, magnetic pulse generator 4 is fixed, said pulse generator 4 producing corresponding pulses in the sensor element 3, a Hall probe, on rotation of the shaft 5. The Hall probe 3 is arranged on a printed circuit board 13, which extends along a first limb 14 of the L-shaped rotation speed sensor 1a. The limb 14 requires very little physical space. It can be matched optimally to the free space between the shaft 5 and the housing wall, with the result that the sensor element lies precisely opposite the pulse generator 4 in the immediate vicinity thereof.
The second limb 15 of the L-shaped rotation speed sensor 1a, which is designed to be inserted into the housing wall along the insertion axis 2, closes off the housing to the outside with a corresponding sealing element. Protruding parts and the resulting risk of damage are thus avoided.
The L shape of the sensor makes it possible to select the eccentric offset of the sensor element 3 in relation to the insertion axis 2 to be so great that the sensor element 3 lies outside the accommodating hole, which is provided for the limb 15, or the sealing element located there. The point at which the plug part is passed through the housing wall can thus be displaced into a suitable region, which is largely independent of where the sensor element needs to be fitted.
At the same time, the problem of having to find in each case individual solutions for rotation speed sensing for different installation conditions is reduced to a single design which can be applied to different cases.
The design of the rotation speed sensor with a considerably eccentric arrangement of the sensor element in relation to the insertion axis also allows for a very cost-effective, automated production of the compact arrangement including the printed circuit board, conductor tracks and plug connectors by omitting flexible conductor connections and cables.
Number | Date | Country | Kind |
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10 2005 021572.6 | May 2005 | DE | national |