DE19748649C2 - Device for lubricating moving components - Google Patents

Abstract

A device for lubricating moving components, e.g. B. rotating shafts with very small amounts of lubricant as in micro-lubrication, in which the amount of lubricant is supplied to the lubrication point by a magnetostrictive micropump or a magnetostrictive valve, the on and off function of which is controlled by an external magnetic field, which is controlled by the movement of the Component itself is brought into magnetic interaction with the pump or the valve to actuate it. The magnetostrictive micropump or valve is arranged at a distance from the moving component, a magnet being attached to the component, the field of which, when it moves, interacts with the pump or valve, or the magnetostrictive micropump or the valve is fastened to the moving component itself and the magnet is arranged in a fixed distance therefrom, the pump or the valve interacting with the field of the magnet during the movement of the component.

Description

The present invention relates to a device for Lubrication of moving components, e.g. B. rotating wel len with very small amounts of lubricant as with the Mi Kroschmierung, in which the amount of lubricant Lubrication point through a magnetostrictive micropump or a magnetostrictive valve is fed, whose input and switch-off function by means of an exterior related to it Magnetic field is controlled by the movement of the Component itself in magnetic interaction with the Pump or the valve is brought to their actuation.

The invention is concerned with the lubrication of moving ten components, preferably rotating shafts with very small amounts of lubricant, as in the so-called Micro lubrication are needed. A procedure for Lubricate moving parts with very small Lubricant quantities are known from DE 38 23 497 A1, the amount of lubricant of the lubrication point by a Micropump is supplied and their on and off switching function is controlled by a field which through the movement of the component itself in interaction is brought into operation with the pump. Here the micropump is driven using the piezoelectric effect. Furthermore there are devices known instead of a piezoelectric alternative have a magnetorestrictive actuator.

The object of the invention is an advantageous Specify the device by dividing its elements, with which the lubrication only when needed, d. H. only if the movement or rotation of the component really takes place, is started. To solve the task the present invention proposes a device as specified in claim 1. Another, advantageous solution to the problem is in claim 2  specified. Advantageous embodiments of the invention are to be seen in the features of the subclaims.

The particular advantage of the invention is that only when the pump or valve is ge mutual change of position in the field area of the Magne a certain amount of lubricant from Reservoir is delivered to the lubrication point and thus lubrication when rotating z. B. a wave always safe is posed. The permanent magnet offers the wide range ren advantage of the powerless control of the pump what with the accessibility of the device, for its weight and is important for your operational security.

Further details of the method are explained in more detail below and with reference to FIGS. 1 to 5. To show it

Figs. 1 and 2, permanent magnets on a moving part with stationary magnetortriktiver micropump

Fig. 3 is a magnetostrictive micropump on the wegten be part with stationary permanent magnet,

However, selmagnetfeld Figure 4 is a device such as with a 3 Wech.

FIG. 5 shows an application in the machining of the workpiece.

The device described is based on a method for lubricating moving components, e.g. B. from rotie shaft with very small amounts of lubricant such as they are required for so-called micro-lubrication. For this, the necessary amount of lubricant becomes the lubricant set by a magnetorstrictive micropump or magnetostrictive valve supplied, their on and off switching function by a, related to them, outer mag  netfeld is controlled. This is due to the movement of the component itself in magnetic interaction the pump or the valve to operate them. Magnetorstrictive micropumps or valves have egg a magnetostrictive actuator, d. H. an element which shape under the influence of a magnetic field or changed its location. This change will Pumps for conveying, with valves for opening and closing of the valve passage used. One for this purpose suitable actuator can e.g. B. a magnetorictive Membrane. That means that the respective actuator is always excited when the pump or valve is moved into the magnetic field, d. H. the actuator is through the external magnetic field is remote controlled. Typical users Fields of application for the process can, for. B. small turbi internal drives or workpiece machining by turning or milling. The Schmie is advantageously carried out tion only when necessary, d. H. only if the Movement or rotation really takes place.

Figs. 1 to 5 show various devices now in use of the method described above.

Referring to FIGS. 1 and 2, there are permanent magnets 1 and 7 for generating direct fields on the moving part 2, the pumps or valves 3 are stationary profiled instal. This means that the magnetostrictive micropump or valve 3 is arranged at a distance from the shaft 2 and on this the magnet 1 , 7 is attached, the field of which, when it moves with the shaft, interacts with the pump or the valve.

Referring to FIGS. 3 and 4, magnetic fields are used vice versa, which are arranged fixed and on which the valves or pumps 3 on the moving part 2 moving past in the movement or rotation. This means here that the magnetostrictive micropump or valve 3 is attached to the shaft 2 itself and the magnet 1 , 7 is arranged at a distance from it, the pump or the valve interacting with the field of the magnet when the shaft is moving occurs.

Fig. 1 shows a permanent magnet 1 in a horseshoe shape for generating a uniform constant magnetic field which is mounted on a rotatable shaft 2 and the distance from him fixedly arranged magneto Restrictive micropump 3 or a magnetostrictive valve upon rotation of the shaft 2 stimulates periodically. The pump 3 then delivers lubricant from a lubricant reservoir 6 via the line 4 to the lubrication point 5 . The arrangement is chosen so that the pump 2 or the Ven valve is located between the poles of the horseshoe magnet 1 .

FIG. 2 shows a modified embodiment of FIG. 1. Here the permanent magnet consists of a bar magnet 7 , the pump 3 or the valve moving periodically in the inhomogeneous field of the bar magnet 7 . Several magnets 7 can also be divided over the circumference of the shaft 2 . The pump function is the same as in FIG. 1.

Fig. 3 shows a permanent magnet 8, the stationary now is disposed from the shaft 2, the pump 3 or the valve whereas on the shaft 2 are mounted as a moving part. Here the pump 3 moves past the magnet 8 when the shaft 2 rotates, the function is the same as described above. FIG. 4 shows a modification of FIG. 3, the permanent magnet being replaced by the alternating magnetic field of a coil 9 .

In FIG. 5, an example of application of the device is shown, the workpiece machining during turning. A rotating part 10 is turned off with the turning tool 11 , the interface 12 is to be supplied by the magnetostrictive micro pump or a corresponding valve 13 via line 15 from a reservoir 14 during processing with lubricant. For this purpose, the horseshoe magnet 16 is attached to the chuck 17 of the rotating part 10 and rotates with it past the pump such that the U of the magnet periodically engages around the pump 13 and thereby actuates its actuator.

Reference symbol list:

1

Permanent magnet

2nd

wave

3rd

magnetostrictive pump or valve

4th

management

5

Lubrication point

6

Lubricant reservoir

7

Permanent magnets

8th

Permanent magnet

9

Solenoid

10th

Turned part

11

Turning tool

12th

interface

13

magnetostrictive pump or valve

14

reservoir

15

management

16

Horseshoe magnet

17th

Chuck

Claims (4)

1. Device for lubricating moving components, eg. B. rotating shafts with very small lubricant quantities such as in micro-lubrication, in which the amount of lubricant is supplied to the lubrication point by a magnetic tostrictive micropump or a magnetostrictive valve, the on and off function of which is controlled by an external magnetic field, which is controlled by the movement of the component itself is brought into magnetic interaction with the pump or the valve to actuate it, characterized in that the magnetostrictive micropump or the valve ( 3 , 13 ) is arranged in a fixed distance from the moving component ( 2 , 10 ) and on the component ( 2 , 10 ) a magnet ( 1 , 7 , 16 ) is attached, the field of which, when moving with the component ( 2 , 10 ), interacts with the pump or the valve ( 3 , 13 ). 2. Device for lubricating moving components, eg. B. rotating shafts with very small lubricant quantities such as in micro-lubrication, in which the amount of lubricant is supplied to the lubrication point by a magnetic tostrictive micropump or a magnetostrictive valve, the on and off function of which is controlled by an external magnetic field, which is controlled by the movement of the component itself is brought into magnetic interaction with the pump or the valve to actuate it, characterized in that the magnetostrictive micropump or the valve ( 3 ) is attached to the moving component ( 2 ) itself and the magnet ( 8 , 9 ) is arranged at a fixed distance from it, the pump or the valve ( 3 ) interacting with the field of the magnet ( 8 , 9 ) when the component ( 2 ) is moved. 3. Device according to claim 1 or 2, characterized draws, that the magnet is a permanent magnet with a constant field is. 4. The device according to claim 1 or 2, characterized draws, that the magnetic field is the DC or AC field of an electromagnet.