DE3220519A1 - Geodetic axle monitoring arrangement and device therefor - Google Patents

Abstract

A geodetic axle monitoring arrangement for monitoring the coaxiality of the axles of a possibly rotatable object supported or suspended at several points is described. It is characterised by the fact that several axle monitoring devices (5), acting in different directions, are allocated to the object (3) at each monitoring point and that the respective axle monitoring device (5) is provided with a sensor (6) which is in contact with the object (3), a housing (7) which is mounted with respect to a stationary understructure (1) of the object (3), a coupling member (8) guiding the sensor (6) in the housing (7), a pointer cooperating with the coupling member (8) and a pretensioning device (9, 10). <IMAGE>

Description

Geodetic axis monitoring arrangement

and device therefor. The invention relates to a geodetic Arrangement for monitoring the coaxiality of axes with respect to one in several Points supported or suspended, possibly rotatable object and a Device therefor. The axis monitoring arrangement is geodetic Methods set, i.e. "calibrated".

In this case, the coaxiality of the axes of an object is understood to mean that the axis of rotation and the geometrical axis of the object are uniaxial, i.e. in one Falling straight, the axis monitoring arrangement according to the invention will run used to monitor compliance with this coaxiality, or to determine the change in position of the axes.

From the changes detected with the axle monitors can be due to the occurrence of additional loads occurring in the rotating object can be deduced for objects with a large vertical dimension, for example the off-center at astuligen and the resulting deformations or subsidence can be prevented. For objects with large horizontal dimensions, E.g. in rotary kilns, a coaxiality error causes such loads that can lead to disaster.

Namely, if the axis of rotation coincides with the geometric axis of the rotary kiln is not uniaxial, on the one hand the wall of the rotary kiln is due to the the permanent bending load resulting from the rotation fatigues; on the other hand there is the fireclay lining destroyed. As a result of the latter, the rotary kiln heats up on the destroyed ones Places strong, which leads to further deformation or to burning through of the furnace.

The well-known monitoring arrangements measure the coaxiality the deformation of the object. From this measured deformation one can derive a Conclusion change of the axis of rotation.

It is also a method similar to the arrangement just described previously known, the position of the axis of rotation being determined on the basis of deformation calculations will. For this purpose photography is also used by shifting it in time Recordings are made and then compared with each other. The photos are e.g. placed on top of each other and x-rayed, whereby the deformation of the object is determined will.

For the solutions known from the prior art is summarized characteristic that they only provide indirect measurement results and not immediate ones Specify deviation values for the current position of the axis. From these indirect Measurement results must be deduced from the hypothetical deviation values. Of the Most of these methods can only be used with stationary, cold, empty, unloaded objects, sometimes only in the factory.

It is obvious how severe these limitations are to the inaccuracy and contribute to the errors of the known methods.

The object of the invention is therefore to provide an axis monitoring arrangement and to create devices for this, with which the current at the time of measurement Deviation values of the coaxiality can be determined in a direct manner.

The monitoring device should also meet small values, one easy handling and bad, sometimes harsh conditions which the objects to be monitored work, withstand.

The invention is based on the knowledge that the need for Calculations for the axis position are eliminated in the previously known solutions can, if not the deformation de outer wall of the object, but the position the axis is monitored.

The above object is achieved by the invention in that at each monitoring point several axis monitoring devices acting in different directions are assigned to the object and that the respective Acilsenübe.l-v; achungsvorrichtung with a feeler touching the object, one with respect to a stationary one Substructure of the object attached housing, one leading the sensor in the housing Coupling piece, one with the coupling piece cooperating indicator and one Pretensioning device is provided.

As can be seen, intersect in the arrangement according to the invention the lines of action of the axis monitoring arranged at a monitoring point svorr icljtungen in the spin axis of the object. As in the introduction mentioned, the axis of rotation of the object with its geometric axis be coaxial. For this purpose, every axis monitoring device is commissioned of the syxtem determined an initial value by geodetic method. When the read Values change for one of the set axis monitoring devices even. expect a change in the position of the axis. So it is in direct Way a deviation of the desired coaxiality is determined what the greatest Is an advantage of the solution according to the invention.

In a preferred embodiment of the invention, the pretensioning device as a spring which presses the sensor against the object and which has an adjusting screw to change the biasing force is adjustable, be formed, wherein the adjusting screw is screwed into a thread formed in the housing.

According to the invention, the sensor can be mounted in the coupling piece Role. According to the invention, the indicator can be arranged on the housing Be a scale and a pointer attached to the coupling piece.

The axis monitoring device can be used as an electronic unit be formed, it can be provided with an electronic indicator. The coupling piece can have an analog-digital converter and an electronic converter on it Be assigned a data display device and / or a recording device.

In this case it is also possible to use the data display device and / or the registration device from the axis monitoring device, ie from the Object itself removed, possibly in the control room of the object to be arranged.

Further details and advantages of the invention are provided below based on an exemplary embodiment with reference to the accompanying drawing explained in more detail. In the drawing shows: Fig, 1 a sketchy Representation of an exemplary embodiment of the axle monitoring device according to the invention in a use case; Figure 2 is a plan view of a preferred embodiment the axis monitoring device according to the invention, partially in section; Fig. 3 shows a sketchy perspective of the application according to FIG. 1; and FIG. 4 a Sketch of the mode of operation of the arrangement according to the invention.

In Fig. 1 is a substructure with reference number 1 and one to be monitored Object designated with 3. The following is an application of the invention Axis monitoring device 5 described, the object 3 being a rotary kiln is. This rotary kiln 3 is supported against the substructure 3 by support rollers 2. The track for the Tragrcllen 2 is ais attached to the rotary kiln 3 Race 4 formed. With each race 4 there is a so-called roller station of the rotary kiln 3 is provided, which is also a monitoring point within the meaning of this invention can be.

As already stated, we are here with a surveillance agency So with a roller station, several, acting in different directions Axle monitoring provisions 5 arranged. In Fig. 1 are an axis monitoring device 5 under the rotary kiln 3 between the two support rollers 2, another axis monitoring device 5 assigned to the same race 4 next to the rotary kiln 3. The straight line of action the axis monitoring devices 5 Scheicn yourself in the center of the cross section of the rotary kiln 3.

As can be seen from Fig. 1, the two axis monitoring devices 5 attached to the stationary substructure 1 of the rotary kiln 3. You close are attached to the race 4 through a sensor 6 each. The race 4 gives by the way the rotary kiln 3 an increased rigidity, which has the advantage that the monitoring is not influenced by local deformations.

The two axis monitoring devices 5 in this figure have different construction methods. The lower one has a vertical, while the lateral one has a horizontal direction of action. But they work in the same way Principle. This very different construction is of course not necessary if the Possibility of arranging several axis monitoring devices 5 with the same construction is given.

In Fig. 2 is the axis monitoring device 5 in a sketchy manner Top view, shown partially in section. The feeler is here as a role 6, which is mounted on the coupling piece 8. The axis monitoring device 5 is made on the stationary substructure 1 by means of its housing 7. The coupling piece 8 is led to this housing 7.

As can also be seen from Fi, 2, the axis monitoring device comprises: ung 5 also consists of a spring 9 and an adjusting screw 10, with respect to the bias variable bias device. The spring 9 is between the coupling piece 8 and the adjusting screw 10 arranged, the latter in one in the housing 7 provided thread is screwed. By screwing in the Adjusting screw 10 can increase the preload by unscrewing ben can be reduced in size.

A scale 11 and the coupling piece are used as indicators on the housing 7 8 a pointer, not shown in detail, is provided.

In Fig. 3 the rotary kiln 3 is on a relatively large scale shown in perspective. The axis monitoring devices connected to it 5 are illustrated by their lines of action. It's from above and from the side Acting axis monitoring devices 5 are provided.

Fig. 3 also gives an indication of the yeodetic character of the axis monitoring device 5. As I see it, the ones shown here are a total of eight axis transmission devices 5 one behind the other parallel to the Axis of the rotary kiln 3 arranged in a straight line. The measurement, the location and orientation before commissioning these axis monitoring devices 5 are carried out with geodetic instruments and geodetic methods.

The geodetic expert uses e.g. theodolite and measuring stick. After testing and setting up the system, only geodetic Funds are controlled.

During the rotation of the rotary kiln 3, for example, the two axis monitoring devices come into contact 5 constantly the race 4, the roller 6 of each axle monitoring device 5 expires on it. Any e; centricity can in this way be on the scale 11 can be read immediately.

If this eccentricity has a certain, monitoring device for each axis 5 exceeds the specified limit, an intervention can take place immediately or in the event of a disaster an alarm can be triggered. The axis monitoring devices 5 can if the technological instructions already provide for the Rotary kiln 5 can be read or checked.

As mentioned earlier, however, the axis monitoring device according to the invention 5 can also be designed as an electronic device, with an electronic Indicator is provided. In this case, in addition to direct reading, the electronic Remote reporting of information, data, etc. enables. The coupling piece 8 can be associated with an analog-digital converter with an electronic data display device and / or can be connected to a registration device. These devices can also in the control room of the rotary kiln 3 or another object, by the axis monitoring devices 5 even far away, be arranged.

The specialist providing service in the control room can check the status of the Check the rotary kiln 3 in this regard as well. The registration date of the eventual connected recording device can be used to evaluate an occurring error or used to determine guilt.

The axle monitoring devices 5 according to the invention cannot only objects that rotate during operation are used, but can also be considered a te of the technological process in the completion of large Objects can be used to control the generality of shapes. Chimneys or dam columns can, for example, be combined with the axle alignment devices according to the invention 5 provided test stand can be rotated, whereby the coaxiality of the axis of rotation with the geometrical axis can be controlled. If the eccentricity is too great, the product as a faulty product sorted. These errors can cannot be determined with the required accuracy nowadays. they do mostly only through the later occurring unexpected consequences of the off-center Visible loads.

The axle monitoring devices 5 according to the invention can also Alarm signaling devices can be connected, which a disaster by an early Signal message so that this can be avoided

Claims (6)

Geodetic axis monitoring sanordnun g and device therefor Claims Geodetic arrangement for monitoring the coaxiality of axes in relation to a multi-point supported or suspended, if necessary rotatable object, indicated that at every monitoring point several axis monitoring devices acting in different directions (5) are assigned to the object (3) and that the respective axis monitoring device (5) with a sensor (6) touching the object (3), one with respect to a stationary one standing substructure (1) of the object (3) attached housing (7), a sensor (6) in the housing (7j leading supplement piece (8), one with the pplungsstück (8) cooperating indicator and a pretensioning device (9,10) is provided. 2. Geodetic axis monitoring device according to claim 1, characterized it is noted that the pretensioning device as one of the sensor (6) on the object (3) pressing spring (9), which can be changed with an adjusting screw (10) the pre-tensioning force is adjustable, is formed, wherein the adjusting screw (10) is screwed into a thread formed in the housing (7). 3. Geodetic axis monitoring device according to claim or 2, in that it is indicated that the sensor is installed as one in the coupling pieces (8) mounted roller (6) is executed. 4 Geodetic axis monitoring device according to one of the preceding Claims, characterized in that the indicator as one on the Housing (7) arranged scale (11) and one attached to the coupling piece (8) Pointer is formed. 5. Geodetic axis monitoring device according to one of the preceding Claims, indicated by an electronic indicator, wherein an analog-digital converter on the coupling piece (8) and an electronic one on it Data display device and / or a recording device are connected. 6. Geodetic axis monitoring device according to claim 5, characterized e k c n n n e i n e t that the data display device and / or the recording device removed from the axles via the axling device (5), possibly in a control room of the object (3) are arranged.