DE3813477C1 - Apparatus for holding an object - Google Patents

Abstract

The invention relates to an apparatus (1) for holding an object (6) in an essentially weightless state, having the following features: a carrier-device part (2) with a constantly vertical axis (14), a positioning-device part (4), which is coupled to the carrier-device part (2) and can be adjusted vertically in relation to the carrier-device part (2), and moreover can be displaced in a horizontal plane, and it also exhibits a load-bearing securing means (5) for attaching the object (6), a constantly horizontal, first linear guide part (43), for the horizontal adjustment of the load-bearing securing means (5) in relation to the carrier-device part (2), and a constantly horizontal axis (47) about which the object (6) can rotate. Said apparatus (1) is to be configured such that the object (6) can be held and manipulated in a simple and manageable manner. This is achieved by the following features: the positioning-device part (4) exhibits a second linear guide part (21), by means of which, in relation to the carrier-device part (2), the load-bearing securing means (5) can be displaced horizontally and essentially transversely with respect to the adjustment direction of the first linear guide part (43). <IMAGE>

Description

The invention relates to a device according to the preamble of claim 1.

Such devices are used, for example, to dock heavy test computers on chip handlers.

Under "docking" the interlocking of the connector should between the chip handler and the test computer be understood. The plug connections point in usually a variety of plug contacts on and are sensitive. The docking must in particular In view of the inertia of the heavy test computer with great care and caution to the plug clock not to damage.

At a 11 of the EP 237 698 A2 known device consists of the carrier device part from a base plate with support feet on which a column is arranged. In the pillar a first always vertical axis can be moved vertically arranged. The column also contains the weight compensation system. Always vertika at the top of the first len axis are attached to slide guides in which two parallel guide rods mounted horizontally are. The two guide rods are on one End attached to a common plate, the one Rod end carries. In the sliding head is around a second one a swivel link is always pivotally mounted on the vertical axis, which in turn is the fork-shaped support bracket for the test computer. The carrying bracket is additional  Lich on the swivel link by an always horizontal Axis rotatable.

The known device has six degrees of freedom, namely three rotary and three translational. The first rotational degree of freedom is through the first or second always vertical axis defined. The second rotational degree of freedom is through the Always define the horizontal axis around which the support bracket is rotatable on the pivot member. The third rotary Degree of freedom is defined by an axis of rotation that between the two fork ends of the fork-shaped support brackets tion runs, and around which the test computer can be rotated is. The first translational degree of freedom is through the direction of displacement of the guide rods in the slide guided tours defined. The second translational freedom grad is always due to the movability of the first vertical axis defined in the carrier part. The third translational degree of freedom is through the rotation of the support bracket always around the first vertical axis defined, to compensate for the Angle of rotation about the second always vertical axis corresponding rotation in the opposite direction must be done. However, with every translational Movement towards the third translational free inevitably a translatory movement towards the first translational degree of freedom connected, which in turn are balanced must have a corresponding translational countermovement of the guide rods in the slide guides in the direction the first translational degree of freedom becomes. The weakness of the known device exists that is, that a translational shift in Direction of the third translational degree of freedom inevitably with a rotatory and additional  associated with a translatory compensatory movement must be around the test computer or, generally speaking to bring the object into the desired position.

It is obvious that the above-mentioned compensatory movements The manipulation with the device was difficult shape. The known device now has the following Another disadvantage: moving the test computer towards the first translational degree of freedom, by moving the guide rods into the slide guides only make sense for docking if the support bracket so aligned with the sliding head is, or with respect to the second always vertical axis has such a swivel position that the always horizontal Axis in the direction of the first translational freedom straight runs, i.e. parallel to the guide rods. However, if this condition is not met, then it may be when undocking the test computer to the chip handler damage to the plug connections. Here it should be remembered that it is because of the above rotational compensatory movement is the normal case that the support bracket is not aligned so that the horizontal axis parallel to the guide rails runs.

The last disadvantage described is with another known device no longer exists, which in DE-OS 36 15 942 A1 is described. With this further known device is the first always vertical Height also adjustable in the axis of the carrier device partially arranged and with a weight compensation device connected part. Always at the top of the first A swivel link is arranged in the vertical axis is pivotable about the first vertical axis. The pan link carries a horizontal crossbar, which is opposite the swivel link around an always vertical second axis  is pivotable. There are always two horizontal ones on the traverse Fixed guide rods on which one with sliding guides provided carriage is slidably disposed. At the carriage is the support bracket for the test computer arranged rotatable about an always horizontal axis. This known device ensures that the horizontal axis is always parallel to the guide rails runs. That means that after making the rotational compensation movement on the swivel link can be ensured that by moving the Test computers on the guide rods the plug contacts be aligned with each other so that damage cannot occur. Nevertheless, this too known device in a by pivoting the first vertical axis adjustment towards the third translational degree of freedom a rotational compensatory movement around the second always vertical axis and a translational compensation movement by moving the test computer to the Guide rods are made.  

A device with the features of the preamble of claim 1 is known according to US-PS 42 29 136. This known device has a base frame, on one of which is rotatable about an always vertical axis Guide rod is arranged, which is a vertical guide for a carriage that can be moved on it. Between the slide and the guide rod is a pneumatic one Weight balancing system effective. With the sledge a box-shaped slide guide is connected, in which a guide rod can be moved horizontally is. At the end of this guide rod there is one another box-shaped slide guide in which one further guide rod can be moved horizontally, namely perpendicular to the displacement of the above called guide rod. At the end of the latter The guide rod sits around a horizontal axis of rotation sliding fork head, in which a holder for a gripper is rotatably mounted about a vertical axis is. The gripping pliers themselves are in the holder a horizontal axis swiveling. With the gripper the object can be gripped. Overall, that points System three translatory and four rotary free degrees. The known device is as a result their special construction not to be manipulated suitable for heavy objects because of the construction through the widely protruding guide rods for twisting and bending tends to reduce precision is affected.

Starting from the known Vorrich described last tion, the invention has for its object to improve in that they can be manipulated  of heavy objects and at the same time the disadvantages of the two known first described Avoid devices.

The task is in a generic device by the in the characterizing part of the patent characteristics specified resolved. It was in this Context mentions that according to US-PS 35 11 462 a manipulator device is known in which a Slide can be moved horizontally in a fork head is arranged. However, there are no linear guide bearings here provided and the guide surfaces between the fork thighs and the sled are not horizontal Offset direction.

The invention is based on one in one Drawing shown preferred embodiment explained in more detail. It shows

Fig. 1 a according to the invention embodied apparatus for holding a test computer in Perspecti vischer representation;

Figure 2 shows the device in plan view.

Fig. 3 shows the section III-III in Fig. 2.

The main parts of the device, generally designated 1 in FIG. 1, are a columnar stand 2 designed as a support device part, optionally with feet 3 only shown in FIG. 2, and a positioning part 4, which is supported for height adjustment by the stand 2 , with a support arrangement 5 for the object, here the Testcom computer 6 ( Fig. 2). The device 1 is used to handle and position the test computer 6 held with the support arrangement 5 for the purpose of defining it on a device 7 for testing electronic components in such a way that the existing mechanical and electrical connec tion elements interlock.

The stand 2 consists of a column guide 8 in which a column 9 shown in FIG. 3 is height-adjustable (see double arrow 11 ). The column 9 can be locked in its respective adjustment position by a clamping lever (not shown). In the Säulenfüh tion 8 is also a support arrangement, not shown, is integrated, which allows the height adjustment of the column 9 and the positioning device part 4 in a user-friendly manner and with little effort. It is e.g. B. a so-called air spring with pressure compensation.

At the upper end of the column 9 is on a pin 12 which represents the free end of the column 9 , a fork head 13 about an always vertical first axis 14 , namely the central axis of the column 9 or the column guide 8 , and in the respective pivot position by a Fork head 13 arranged clamp lever 15 mounted lockable. As an embodiment of such a joint 16, it is also possible to mount the column 9 rotatably about the first vertical axis 14 in the column guide 8 , as a result of which the rotatability of the fork head 13 around the pin 12 could be omitted. When viewed from the side, the fork head 13 is U-shaped with two horizontal fork legs 17 , which overlap a carriage 18 which is connected to a support frame 19 of the support arrangement 5 . The carriage 18 is supported by a horizontal line bearing 21 at the top and bottom of the fork legs 17 and can be determined in the respective shift order by a clamping device 22 arranged on the fork head 13 . The clamping device 22 consists of a clamping bolt 23 encompassing the upper fork leg 17 with a clamping lever 24 on the upper side, the lower end of the clamping bolt 23 encompassing a clamping strip 26 screwed onto the slide 18 in a longitudinal groove 27 and engaging behind the clamping strip 26 with a bolt head 28 . In the present exemplary embodiment, the bolt head 28 is immersed in a longitudinal groove 29 in the slide 18 . The clamping effect is achieved by tightening the clamping bolt 23 by means of the clamping lever 24 , the clamping strip 26 being clamped between the bolt head 28 and a pressure piece 31 arranged on the upper fork leg 17 . The horizontal linear guide bearings 21 run transversely, in particular perpendicularly, to the direction in which the test computer 6 is to be docked on the device 7 .

Each horizontal linear guide bearing 21 has a pair of guide surfaces 32, 33; 34, 35 on. The pair of guide surfaces 34, 35 of the lower linear guide bearing 21 is offset in relation to the pair of guides 32, 33 of the upper linear guide carrier 21 . The degree of displacement is denoted by v . As a result, the fork head 13 and the carriage 18 can absorb relatively large torques which are exerted on them by the test computer 6 to be handled. The guide surfaces 32 to 35 are roof-shaped and on correspondingly shaped guide strips 36, 37 are provided, which are fastened to the fork legs 17 and to the carriage 18 and between which the rolling elements run. Below the first pair of guide surfaces 32, 33 , a support element in the form of a roller bearing 38 is arranged on the lower fork leg 17 , on which the underside of the carriage 18 rests. The support element is arranged in the center and is thus effective in the entire guide area, preventing the slide 18 from tipping out of the guide surfaces 32 to 35 . The support bearing is held on a support piece 39 which is received and fastened in the lower fork leg 17 in the present exemplary embodiment.

The support frame 19 consists of a support web 41 and arranged at its free ends horizontal support arms 42 which are mounted in the 43 at the free ends of the support web 41 NEN guides slidably mounted and can optionally be determined in the respective shift position. The guides 43 are formed by a slide or roller guide. To determine a clamping device 44 is preferably in the form of a clamping screw 45 with a relatively large head, so that it can be operated by hand. The clamping screw 45 acts indirectly or directly against the associated support arm 42 , the support arms 42 being round rods in the present exemplary embodiment. The guides 43 are horizontal and parallel to one another and extend from the supporting web 41 in the direction of the object to be handled, here the test computer 6 .

The support frame 19 is pivotable about a horizontal axis 47 which extends parallel to the support arms 42 and is arranged centrally to the latter.

This always horizontal axis 47 having pivot bearing is generally designated 48 and formed by a bearing pin 49 ( Fig. 3), which is non-rotatably received in a blind bore 51 in the support web 41 by means of the support web 41 and 52 with a tapered diameter Bearing pin 53 rotates through a bearing bore 54 in the carriage 18 . The axial securing is ensured on the one hand by the shoulder 55 of the bearing pin 49 and on the other hand by a securing ring 56 engaging behind the slide 18 .

The supporting frame 19 can optionally be locked in its respective pivot position by a clamping device, generally designated 57 . The clamping device 57 is formed by an arranged on the bearing pin 49 clamping ring 58 which is mounted on the carriage 18, which is indicated at 59, and clamped by a clamping lever 61 on the bearing pin 49, whereby the determination of the bearing pin 49 in the bearing bore 54 can be done.

Near the free end of each support arm 42 , a disk-shaped or cheek-shaped support piece 62 is pivotally mounted on the associated support arm 42 about an axis 63 , which extends at right angles to the always horizontal axis 47 and parallel to the support web 41 . On the support pieces 62 , the test computer 6 is attached in an unspecified manner. The test computer 6 is thus mounted on the support arms 42 with the support pieces 62 so as to be pivotable about the axis 63 and can optionally be locked in the respective pivot position by means of clamping device 64 provided on at least one support arm 42 . The clamping device 64 is formed by a clamping screw 65 with a screw head 66 which can be rotated by hand and which passes through the associated support arm 42 and interacts in a clamping manner with a clamping plate 67 which is connected to the associated support piece 62 and is thus rotatable about the axis 63 . The clamping screw 65 is in a circular arc around the axis 63 curved groove 68 in the clamping plate 67 , whereby despite the penetration of the clamping screw 65 a determinable by the length of the groove 68 Schwenkbe is rich. This pivotability mainly serves to align the plug contacts of the test computer 6, generally designated 71 in FIG. 2, parallel to the linear guide 72 formed by the guides 43 and to be able to fix them in the aligned position.

As can also be seen from FIG. 2, centering pins 73 are also arranged on the test computer 6 , which with centering not shown in the device 7 , z. B. a chip handler, interact. With the Posi tion characters 74 and 75 effective between the test computer 6 and the device 7 and not described for simplification reasons docking elements are designated.

The device 1 enables the following degrees of freedom of the test computer 6 relative to the device 7 , which enable the positioning of the test computer 6 on the device 7 .

First degree of freedom: height adjustment of the positioning device part 4 on the stand 2 .

Second degree of freedom: lateral adjustment of the positioning device part 4 by pivoting about the always vertical axis 14 of the stand 2 .

Third degree of freedom: lateral adjustment of the support bracket 5 or the support frame 19 as part of the Positioniervorrich device part 4 with the transverse to the support arms 42 he extending carriage 18th

Fourth degree of freedom: pivoting of the support frame 19 about the always horizontal axis 47 extending parallel to the support arms 42 .

Fifth degree of freedom: linear or horizontal adjustment of the support frame 19 in the direction of the device 7 or back, namely arms 42 parallel to the horizontal guide.

Sixth degree of freedom: pivotability of the test computer 6 with the support pieces 62 about the axis 63 .

It can thus be the test computer 6 in a simple and easy-to-use manner with respect to the Steckele elements of the device 7 and in the plug-in direction, ie along the support arms 42 or along the linear guide 72 bring in or out of contact with the plug elements.

Claims (2)

Device ( 1 ) for holding an object ( 6 ) in a substantially weightless state, such that gravity has no influence, with the following features:

• a) a carrier device part ( 2 ),
• b) the carrier device part ( 2 ) always has a vertical axis ( 14 ),
• c) a positioning device part ( 4 ),
• d) the positioning device part ( 14 ) is coupled to the carrier device part ( 2 ),
• e) the Positioniervorrichtungsteil (4) is vertical with respect to the carrier device part (2) adjustable bar,
• f) the positioning device part ( 4 ) is also adjustable in a horizontal plane,
• g) the positioning device part ( 4 ) has a support bracket ( 5 ) for attaching the object ( 6 ),
• h) a weight balancer part,
• i) the weight balance device is coupled to the part Positioniervorrichtungsteil (4) with the thereto to move to the Positioniervorrichtungsteil (4) is interrupted th object (6) in a substantially weightless condition,
• j) the positioning device part ( 4 ) has an always horizontal first linear guide part ( 43 ) for horizontal adjustment of the support bracket ( 5 ) with respect to the carrier device part ( 2 ),
• k) the positioning device part ( 4 ) has an always horizontal axis ( 47 ) about which the object ( 6 ) can be rotated,
• l) the positioning device part ( 4 ) has a second linear guide part, by means of which the support bracket ( 5 ) can be adjusted horizontally and essentially transversely to the adjustment direction of the first linear guide part ( 43 ) with respect to the support device part ( 2 ),
• m) the second linear guide part has a slide guide and a slide ( 18 ) displaceable therein,

characterized by the following features

• n) the slide guide is formed by a fork head ( 13 ) with essentially horizontal fork legs ( 17 ),
• o) the carriage ( 18 ) is supported by a linear guide bearing ( 21 ) on each of the two fork legs ( 17 ),
• p) the linear guide bearing ( 21 ) connecting the slide ( 18 ) to the lower fork leg ( 17 ) is at a greater distance from the always vertical axis ( 14 ) than the linear guide bearing ( 21 ) connecting the slide ( 18 ) to the upper fork leg ( 17 ) ),
• q) the carriage ( 18 ) is connected on the open side of the fork head ( 13 ) to the support bracket ( 5 ) via a pivot joint ( 48 ) which always forms the horizontal axis ( 47 ).