ARRANGEMENT FOR FASTENING A POWER ELECTRONIC DEVICE SUCH AS A FREQUENCY CONVERTER

Abstract

An arrangement for fastening, at multiple fastening points, a power electronic device such as a frequency converter (1) to a base (2) susceptible to vibration, at least a portion of which fastening points are vibration-damped, and which fastening points are on two opposite sides of the frequency converter (1). The invention is realized such that there are at least two fastening points (3, 4; 3, 4, 5) on each of two opposite sides of the frequency converter (1), wherein fastening points (3, 4, 5) on one side are damped while fastening points (3, 4) on the other side are undamped.

Claims

1. An arrangement for fastening, at multiple fastening points, a power electronic device such as a frequency converter to a base susceptible to vibration, at least a portion of which fastening points are vibration-damped, and which fastening points are on two opposite sides of the frequency converter, wherein there are at least two fastening points on each of two opposite sides of the frequency converter, wherein fastening points on one side are damped while fastening points on the other side are undamped.

2. The arrangement according to claim 1, wherein the undamped fastening points include a screw and a base plate, which screw is screwed tightly into the base, and the damped fastening points include a screw, a base plate and a damping bush, which screw is screwed tightly into the base.

3. The arrangement according to claim 1, wherein there are two damped fastening points and two undamped fastening points.

4. The arrangement according to claim 2, wherein the frequency converter is substantially in the shape of a rectangle when viewed from above, and the fastening points are located at corners of the rectangle or in the immediate vicinity of the corners.

5. The arrangement according to claim 2, wherein the material of the damping bush is silicon-based Sylomer SR220.

6. The arrangement according to claim 2, wherein there are two damped fastening points and two undamped fastening points.

7. The arrangement according to claim 3, wherein the frequency converter is substantially in the shape of a rectangle when viewed from above, and the fastening points are located at corners of the rectangle or in the immediate vicinity of the corners.

8. The arrangement according claim 3, wherein the material of the damping bush is silicon-based Sylomer SR220.

9. The arrangement according claim 4, wherein the material of the damping bush is silicon-based Sylomer SR220.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0009] The invention is explained in further detail below with the aid of examples relating to advantageous embodiments, by referring to the accompanying drawings, in which

[0010] FIG. 1 shows the fastening of an upper edge of a frequency converter in an exploded view,

[0011] FIG. 2 shows the fastening of a lower edge of a frequency converter in an exploded view, and

[0012] FIG. 3 shows the fastening of a frequency converter as viewed from one end.

DETAILED DESCRIPTION

[0013] FIG. 1 shows the fastening of an upper edge of a power electronic device, for example a frequency converter 1, to a base 2 thereof according to the present invention. The base may be any object to which the frequency converter is to be fastened. For this purpose there are two holes in the upper edge of the frequency converter, through which holes two screws 3 are screwed into holes (not shown) in the base. Between the screw head and the upper edge is mounted a base plate 4, which may be designed such that it shape-locks the upper edge of the frequency converter to the base 2 when the screws are tightened. The frequency converter 1 is advantageously rectangular in shape when viewed from above.

[0014] As can be discerned from FIG. 1, between the base plate 4 at the right-hand fastening point and the upper edge of the frequency converter is further mounted a damping bush 5, which is made of a soft damping material such as silicon-based Sylomer SR220.

[0015] FIG. 2 shows the fastening of a lower edge of the same frequency converter 1 to the base 2. Fastening is accomplished in the same way as in the upper edge, i.e. by screws 3 and base plates 4. Again, between the right-hand base plate and the fastening hole (lower edge) is mounted a damping bush 5, which is advantageously of the same kind as the damping bush used in the fastening of the upper edge.

[0016] Thus, in the invention, a frequency converter or other power electronic device, which is susceptible to vibration arising from a mounting site, is fastened at its corners or near to its corners by four screws 3, wherein fastening of the screws on one side is damped by the damping bush 5 while fastening of the screws on the other side is undamped. Thus, since the frequency converter is fastened on one side, it begins to turn, under the action of vibration, so that the rigid fastening acts as a turning point 6 or as a turning axle, as shown by the dotted line in FIG. 3. Sideways motion is thus composed of two components: upwards and to the side. The upwards-directed component has a different natural frequency from the sideways component, and for this reason the upwards-directed component acts as a damper for the sideways component. The phenomenon occurs because the damped side permits upwards-directed motion.

[0017] An eccentric damping concept for small power electronic devices such as frequency converters 1 is thus realized in the invention. Vibration is damped on only one side of the frequency converter. On the other side it is fastened rigidly without damping in the most critical direction of sideways vibration. Thus the rigidly fastened side becomes a turning point 6 or axle for the vibrating frequency converter, and since this turning axle is at a different point from the centre of gravity 7 in a sideways direction, sideways motion becomes a two-component motion direction, as explained above.

[0018] It will be clear to a person skilled in the art that the invention is not limited to the embodiment examples presented above, but can vary within the scope of the accompanying claims. The invention is primarily intended for the fastening of small plastic-framed power electronic devices, for example of less than 40 kg. Large devices require more fastening screws 3, so the invention does not apply to the mounting of such devices. An advantageous application of the invention is for example a rectangular frequency converter comprising four fastening points, one at or near each corner of the device. There could even be more than two fastening points on both opposite sides, and the number thereof need not be the same on both sides. Thus there could be for example two fastening points on one side and three fastening points on the other side.

[0019] Distinguishing features which may have been presented together with other distinguishing features herein may also be used independently of each other as required.