SK306492A3 - Rotating table for positioning of technical objects - Google Patents

Abstract

The turntable serves for setting down technical objects, which are irradiated on all sides with electromagnetic waves for testing their electromagnetic compatibility. It has a separate table plate (DR) with coupling means (KO) on the underside (U), approximately at the centre of gravity (Z). A separate centre shaft (W) can be made to move vertically into the said coupling means. A drive (M1;RA) serves for rotating the table plate once the centre shaft has been moved into the coupling means. Rolling means (LK) are provided or can be fitted on the underside (U) of the table plate, so that it is freely displaceable on the base (B), complete with the technical object located on it, once the centre shaft is moved out. This has the advantage that the table plate can be pushed out of the anechoic chamber without altering the construction of the technical object. <IMAGE>

Description

The electromagnetic compatibility of technical objects, i.e. their insensitivity to electromagnetic waves, is of increasing importance. The operational safety and functionality of the objects used can not be impaired in any way even if, under certain circumstances, these objects are suddenly exposed to high-frequency and high-power electromagnetic radiation. This applies in particular to technical articles in which, depending on the circumstances, it circulates a greater amount of radio frequency electrical signals for the exchange and transmission of data.

For this reason, in particular, such technical objects must be tested for their electromagnetic compatibility in the so-called EMV test, since these objects contain electrical and electronic components. Examples of such objects are data processing equipment, such as a computer and associated peripheral devices, power supply equipment, such as switchgear, switchgear, transformers, and the like, motor vehicles containing, for example, electronic fuel injection devices and engine control systems, powertrain aircraft, and protective technical equipment, etc.

The testing of such technical objects is usually carried out in specially constructed so-called absorption halls. These absorption halls are screened outwards electromagnetically and are provided with electromagnetically sealed approaches such as doors or edges. The absorption halls are lined inside so that virtually no reflections of the electromagnetic waves occur. To this end, at least the walls and ceilings are completely lined with pointed absorbent bodies of pyramid shape.

When testing electromagnetic compatibility, it is essential that the subject matter in question be exposed to electromagnetic radiation uniformly from all sides, and that radiation has the desired frequency range. For this purpose, so-called rotary tables are used, which allow even irradiation of the technical articles to be tested inside the absorption hall from all sides.

There are already known rotary tables which are loosely placed on the floor of the hall or, depending on the circumstances, completely embedded in the floor, so that they have no edges.

The problem now exists that the technical object tested for electromagnetic compatibility must be installed on the rotary table in a fully operational condition. Especially in the case of electrical devices, such as switchboard cabinets, a considerable preparation time is to be expected for such constructions. During the installation of the test item, the use of the absorption hall is blocked. Significant delays thus incur considerable costs, which make the absorption hall rental more expensive.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a rotatable table in an absorption hall for testing technical articles for electromagnetic compatibility structurally, so as to allow faster exchange of technical articles to be tested.

SUMMARY OF THE INVENTION

The object of the present invention is to provide a rotatable table for establishing technical objects which are irradiated from all sides in order to test their electromagnetic compatibility, in particular by high-frequency electromagnetic waves, according to the invention which consists of a separate plate especially in the axis of rotation, by means of fasteners, from a separate central shaft which, by means of lifting means, can vertically travel into the fasteners on the underside and come out of it from the rolling means provided on the underside of the plate, sliding on the floor and from the drive to rotate the plate when the central shaft is engaged in the fasteners.

It is advantageous if the central shaft with the lifting means is located in a receiving shaft embedded in the floor.

According to a preferred embodiment, the rolling means is further dimensioned such that the rotary table plate is tiltable on the ground in the engaged state of the central shaft. In this case, air cushions are provided on the underside of the plate as rolling elements.

According to a preferred embodiment, they are in. head portions of the central shaft facing the coupling means on the underside of the plate are provided with connection means, in particular for supplying power and / or for transmitting the control signals to at least one technical object arranged on the rotary table, providing means to allow access to the coupling means, at least in the locked condition of the central shaft, to the coupling means.

According to the invention it is further preferred that the separate rotary table plate has a circular shape, wherein the drive for rotation acts on the edge of the plate.

Finally, it is advantageous if the coupling means on the underside of the rotary table plate allow for a non-rotatable connection with the central shaft in the engaged state, the drive for rotating the plate acting on the central shaft and in particular being integrated therein.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail with reference to the accompanying drawings, in which: FIG. 1 shows a rotary table with a plate laid on the floor of the hall and a central shaft arranged recessed in the receiving shaft, and FIG. 2 is a rotary table with a plate placed on a separate intermediate additional floor and a central shaft seated on the floor of the hall and located below the plate.

DETAILED DESCRIPTION OF THE INVENTION

The rotary table according to the invention consists of a separate plate DR provided on its underside U in the Z-axis of rotation by means of fasteners KO. In these fasteners KO, a separate central shaft W can be vertically driven in or out by means of the lifting means HM. Furthermore, rolling elements LK are provided on the underside of the U-plate DR according to the invention, if necessary, so that the separate plate DR is in the extended state. Finally, the rotary table according to the invention is provided with a first drive M1, by means of which the plate DR can be rotated when the central shaft W is driven into the coupling means KO.

This arrangement has the advantage that the essential components of the rotary table, i.e. the plate DR, the central shaft W and the drive M1, are not fixedly connected to one another, but can disconnect from each other as the individual central shaft W decreases. The separate plate DR, together with the technical object established thereon, can therefore be pushed out of the absorption hall by sliding it on the floor. The necessary rebuilding work on the technical object to be tested for electromagnetic compatibility, respectively the dismantling and assembly of these and the object on the DR board need not be carried out inside the absorption hall, but can be carried out outside, in adjacent laboratory areas. At the same time, another plate DR on which another test item has been previously set up and put into operation can be inserted into the absorption hall and connected there to a separate central shaft W.

Therefore, all installation, fitting, assembly and alignment work on the test item can be carried out in the external absorption halls without having to interrupt the measurement operation in the absorption hall and without the EMV test, The table was removed and re-installed after the disguise. Therefore, a single DR sheet is fixed to one technical object throughout the test cycle. Therefore, the technical assembly for the measurement, in particular for making the technical object operational, must be carried out only once on the associated separate DR plate and it is retained even if the testing is temporarily interrupted. The invention therefore has the particular advantage that the technical article in its entirety, with a separate plate as a support, can be relocated several times from the absorption hall several times as needed, and can be relocated back to the EMV test after some work.

In FIG. 1 shows a possible embodiment of a rotary table according to the invention. The separate board DR lies directly on the floor B. This floor B represents the floor of the absorption hall intended for walking and traveling and preferably provided with an electrically conductive lining or covering. On the upper side of the O-plate DR, any technical objects can be set up; 1 not shown. The plate DR is provided with fasteners KO in the axis of rotation Z on the underside U. A separate central shaft W can be driven vertically into these fasteners KO or can go out again. The engagement of the central shaft W in the fasteners KO on the underside of the plate DR has the effect that the plate DR is no longer displaceable on the floor B, but can only rotate about the axis of rotation.

According to the invention, furthermore, rolling elements LK are provided on the underside of the U-plate DR, so that the separate plate DR is free to slide on the floor B in the extended state W of the central shaft W, for example rubber wheels. under the underside of the U plate DR. In another embodiment, already shown in FIG. 1, the air cushions LK preferably are fixed air cushions incorporated in the lower side U. These air cushions are evenly distributed over the lower side U and are made of a non-conductive material. According to a further advantageous embodiment, the rolling means LK is additionally dimensioned such that, even in the engaged state of the central shaft W into the fasteners KO of the plate DR, it is possible to rotate the plate DR on the floor B without tilting and without friction. Such an embodiment is particularly advantageous in those cases in which the plate DR is either of a large size and / or is unilaterally loaded by other technical objects. The rolling means LK then allows both a slight rotation of the DR plate when performing the EMV test and a slight movement of the DR plate when the test is interrupted.

According to another embodiment, already shown in FIG. 1, the separate central shaft W, together with the lifting means HM for its propulsion, is located in the receiving shaft AS, embedded in the floor B. This makes it possible to arrange a separate plate DR almost directly laid on the floor B. by extension of the central shaft W, if necessary, raised so that it is possible to irradiate the technical object set on the upper side 0 in an elevated position from all sides. In another embodiment, not shown in the figures, it is also possible that the separate plate DR is embedded in the floor B such that a stepless, completely straight transition occurs between the upper sheet 0 of the plate DR and the floor B. In this case, the separate plate DR to be replaced by the separate central shaft W and the lifting means HM would first have to be lifted out of the shaft at. This means that the separate central shaft W can then be lowered out of the fasteners KQ by means of suitable means.

The lifting means HM for the vertically movable separate central shaft W can be of various designs. For example, it is possible to provide the lifting and lowering movement of the central shaft W by means of hydraulically driven compressed air cylinders.

In other embodiments, the raising and lowering of the central shaft W may be performed mechanically by means of an electrically driven spindle. In the example of FIG. 1, the electric motor is symbolically shown as a second drive M2 of the lifting means HM. The double arrow inside the bearing shaft AS symbolizes the stroke range of the central shaft W.

At the upper end of the receiving shaft AS are further provided sealing means in the form of contact springs KF which abut the surface of the central shaft W and form at least a mechanical sealing of the receiving shaft AS against the floor B. In the case where floor B is provided with an electrically conductive covering the central shafts W and the contact springs KF can be electrically conductive. Curved elastic bands are particularly suitable as contact springs KF. As a result, the electrical wiring of the floor B is also possible through the storage shaft AS and the central shafts W.

Depending on the type of relevant electromagnetic compatibility test, the DR plate may be made of various materials.

It is preferably made of an electrically non-conductive material, for example wood or plastic; In addition, the plate thickness DR and the head height W of the central shaft W can be aligned with each other in the coupling means KO on the underside 11 so that the upper side 0 occupies a predetermined distance from the floor B of about 10 cm.

Further, the separate plate DR may have different shapes. According to a preferred embodiment, see FIG. 1 and 2, the plate DR has a circular shape.

In this case, the drive M1 for rotating the plate DR in the state of the central shaft W driven into the coupling means KO can be engaged simply, for example by means of the friction wheel RA, directly with the outer edge R of the plate DR. The actuator M1 may be mounted either on the guide plate DR on the floor surface B or, in another embodiment (not shown), it may be embedded in an additional receiving shaft. In a further embodiment, the drive for rotating the plate DR can act directly on the central shaft W.

According to a particularly preferred embodiment, the drive in the form of a direct drive can then be arranged in the Z-axis of rotation and integrated directly into the central shaft W.

If this drive is engaged with the central shaft W, then the plate DR may have any shape. A square, rectangular or polygonal shape is then possible. In the direct drive of the plate DR by the central shaft W, it is necessary that the contact means KO on the underside of the U plate DR form a non-rotatable connection with the central shaft W in the engaged state.

Otherwise, it is sufficient that the plate DR is rotatably mounted, preferably without friction, on the hub of the central shaft W in the engaged state of the central shaft W by means of fasteners KO.

According to another embodiment, FIG. 1, the connection means K is arranged in the head portion of the central shaft W which faces the coupling means KO on the underside of the U-plate DR. These connection means K can be used in particular for supplying power and / or transmitting control signals for at least one technical object installed on a turntable. In this embodiment. further means are provided on the upper side 0 of the plate DR approximately in the axis of rotation 7, for example in the form of lids D, which allow access from above to the coupling means K at least in the state of the central shaft W into the coupling means KO.

In the example shown in FIG. 1, the connection means K are located in the connection shaft or the connection recess AM in the head portion of the vertically displaceable central shaft W. The connection means K may be, in particular, plugs and connections for conducting electrical, pneumatic or hydraulic power. A technical object (not shown), mounted on the top surface 0, can be connected to these connection means K, thereby rendering it operable. The connection recess AM is easily accessible by the lid D on the upper side 0 of the DR plate. In addition, the connection recess AM is provided approximately in the center of the plate DR in the axis of rotation.

Particularly after several test objects are radially arranged on the circular plate DR on the upper surface 0 of the pivot axis 0, these objects can be connected in a simple manner to the power sources by means of connection means K provided in the connection recess AM. If the examination of technical items for electromagnetic compatibility has to be temporarily discontinued and the separate plate DR is to be moved temporarily out of the absorption head together with the objects installed thereon, then only the relevant lines leading from the object to be connected to the connection devices in K must be disconnected. AM and the separate central shaft W are allowed to come out vertically from the fasteners KO. The entire remaining test apparatus on the upper surface 0 of the DR plate, which in some circumstances may be very expensive, remains intact.

In the example of FIG. 1, the main connecting cable AKI is brought to the turntable by a separate central shaft W in the foot area of the receiving shaft AS. The power supply of the rotary table drive means and the connection means K in the connection recess AM for the test objects on the upper side O is ensured and the control and control signals are exchanged. In this way, for example, the air cushions representing the rolling elements LK provided on the underside of the turntable and the electric motor constituting the second drive M2 and serving to drive the lifting means HM of the separate central shaft W can be supplied with electric energy. . In addition, the necessary media can be fed to the connection means K by means of another connection cable AK2, shown in dashed lines, which are intended for supplying the relevant test objects, such as electric current or compressed air.

Fig. 2 shows another exemplary embodiment of a rotary table according to the invention. Individual; In this case, the plate DR is in connection with its separate additional base ZB with its underside U. The additional base ZB is preferably made of a non-conductive material, for example wood, and is seated on the actual floor B of the absorption hall by means of the supports ST. There are pyramidal pointed absorbent bodies. In the space between the floor B and the additional floor. By means of this arrangement, the reflection of the electromagnetic waves used to irradiate technical objects on the floor B of the absorption hall is prevented.

In the example of FIG. 2, a separate central shaft W, movable in a vertical direction, with the respective lifting means HM is simply mounted directly on the floor B of the absorption hall. Again, the stroke range is again represented by a double arrow. In the event that a replacement of the DR plate is to be carried out in the case of the replacement of the technical subject under test according to the EMV test, the separate central shaft W is retracted from the fasteners KQ on the underside U. and replace it with another DR plate fitted with the test item.

In the embodiment shown in FIG. 2, of course, there can be provided a receiving shaft AS, into which the separate central shafts W and respective lifting means HM are embedded in part. In this case, the depth of the receiving shaft AS is preferably on one side and the lengths of the lifting means HM a. of the separate central shaft W, on the other hand, aligned with one another such that the stroke range shown symbolically in FIG. 2 with a double arrow, lies entirely within the AS shaft. In this case, again, the receiving shaft AS can be similar to the embodiment of FIG. 1, sealed to the floor surface B by electrically conductive contact springs KF.

Claims (7)

1. A rotary table for the establishment of technical articles which, in order to test their electromagnetic compatibility, are irradiated from all sides, in particular by high-frequency electromagnetic waves, characterized in that it consists of: (a) separate plates (DR) provided with fasteners (KO) on the underside (U) approximately at the center of gravity, in particular in the axis of rotation (Z), I (b) a separate central shaft (W) which, by means of lifting devices (HM, M2), can be vertically driven into and out of the coupling means (KO) on the underside (U); (c) anti-friction means (LK) provided on the underside (U) of the plate (DR), so that the separate plate (DR) is free to slide on the floor (B, ZB) when the central shaft (W) is extended; d) a drive (M1, RA) for rotating the plate (DR) when the central shaft (W) is driven into the coupling means (KO). Rotary table according to claim 1, characterized in that the separate central shaft (W) with the lifting means (HM, M2) is located in a receiving shaft (AS) recessed in the floor (B) (Fig. 1). Rotary table according to claim 1 or 2, characterized in that the rolling elements (LK) are further dimensioned such that the plate (DR) is non-tilting on the floor (B, ZB) in the locked-in state of the central shaft (W). 13 Rotary table according to one of the preceding claims, characterized in that air cushions are provided as rolling elements (LK) on the underside (U) of the plate (DR). . Rotary table according to one of the preceding claims, characterized in that: a) in the head part of the central shaft (W) to which the fasteners (KO) on the underside (U) of the plate (DR) are facing, there are arranged fasteners (AM, K), in particular for power supply and / or transmission of control. signals for at least one technical object mounted on the rotatable; table and b) on the upper side (0) of the plate (DR) there are means (D) provided in the axis of rotation (Z) which allow access? to the coupling means (AM, K) at least in the state of the central shaft (W) to the coupling means (KO). A rotatable table according to any one of the preceding claims, characterized in that:. that (a) the separate plate (DR) shall be circular in shape; and b) a drive (M1, RA) for rotating the action on the edge (R) of the plate (DR). (Fig. 1). A rotary table according to any one of claims 1 to. 5, characterized by that (a) the fasteners (KO) on the underside (U) of the plate (DR) permit non-rotatable engagement with the central shaft (W) in the engaged condition; and b) the drive (M1) for rotating the plate (DR) acts on the central shaft (W), in particular being integrated therein (FIG. 2).