SE465715B - Locating device - Google Patents

Abstract

A locating device for locating a releasable part 1, such as a fixture plate, relative to a fixed part 6, such as a machine bench, comprises an essentially cylindrical locking body 3 with a first guide surface 8 cooperating with a bore in the machine bench 6, and a second guide surface 12 cooperating with the fixture plate 1. The first guide surface 8 is cylindrical and rigid, while the second guide surface 12 is made up of a number of sectional surfaces 4, 5 which are elongate with their longitudinal direction parallel to the axial direction of the locking body 3 and distributed about the periphery of the locking body 3. The locking body 3 has a central bore used, on the one hand, for receiving a screw 13 in the area of the first guide surface 8 for securing the locking body 3 in the machine bench and, on the other hand, a threading with a conical threaded pin 22 for expansion of the sectional surfaces. <IMAGE>

Description

SE-B-459 030 previously discloses a guide and locking pin of an expanding type, which can be characterized as an approximately cylindrical guide device with alternating slots extending from each end, which extend from the mantle surface into a central conical bore. In this conical bore a cone is arranged which, under the action of a screw, is pulled in the axial direction for expansion of the guide device.

Because the conical bore and the cone extend substantially along the entire length of the guide device, this will expand cylindrically over the entire length. If, for example, the center distance between the bores of the fixture plate were incorrect, the guide device will be inclined so that its axis direction deviates from the shaft direction for both the seat of the machine table and the bore of the fixture plate. The result of this is an uncertainty in the location or increased demands on precision, mainly for the fixture plate, from which cost increases follow.

Non-expandable guide pins are also previously known, which at one end have a cylindrical surface for co-operation with a corresponding bore in the machine table or the clamping cube. At the other end, this guide pin has a number of circumferentially distributed strip-shaped guide surfaces or bars, two or four in number, which are intended for co-operation with the fixture plate.

By orienting the guide pin with two booms so that the abutment of these booms against the bore of the fixture plate becomes "approximately parallel" to the connecting line between the two bores in the fixture plate, the requirements for an accurate distance between these bores are reduced. Despite this, the repetitive accuracy of repeated tensioning is not good enough without the precision having to be driven so far that the costs rise sharply.

PROBLEMS The present invention has for its object to provide a locating device of the type mentioned in the introduction, which locating device is designed in such a way that the precision and repeater accuracy in the clamping is very good at the same time as the precision requirements mainly on the fixture plate but to some extent also on the locator itself and the locator seats in the machine table or clamping cube can be kept reasonable. The invention also has for its object to provide a locating device which can be easily and conveniently mounted on a machine table and which allows quick and easy replacement of fixture plate.

TROUBLESHOOTING The object underlying the invention is achieved if the locator initially indicated is characterized in that the first guide surface is substantially cylindrical and rigid, that the second guide surface is formed by a number of band-shaped, circumferentially extending longitudinally of the locking body and that the sub-surfaces are expandable outwards from the center of the locking body.

In order to allow easy attachment of the locating device to a machine table, according to the invention it also suitably applies that the locking body has a central bore with a shoulder in the area of the first guide surface, the shoulder being arranged for co-operation with a fastener for axial position fixation of the locking body relative to the machine table.

In order to provide the expansion possibility for the second guide surface in a simple manner, according to the invention it is also suitable that between the sub-surfaces in the circumferential direction of the locking body parallel slots are arranged with the axial direction of the locking body, which traverse the locking body and which in the longitudinal direction and further that the bore has a threaded portion for co-operation with a one-piece expansion member having a conical portion for co-operation with a corresponding conical portion of the bore in the area of the second guide surface. 465 715: 4 If the conicity of the bore is selected in the range 1: 10-1: 30, preferably 1:20, the self-locking ability of the expanding member is achieved in one piece by the expansion means being produced in one piece. Additional advantages are achieved according to the invention if the locating device is also given one or more of the features according to any one of claims 5, 7-9. SUMMARY OF DRAWINGS The invention will now be described in more detail with reference to the accompanying drawings. In these: Fig. 1 shows a fixture plate which is attached to a machine table using locators according to the invention, Fig. 2 a section through the fixture plate and a part of the underlying machine table according to the section marking Fig. 3 a section through the fixture plate and a part of it behind the machine table according to the section marking Fig. 4 is a section corresponding to Fig. 2 through the locating device according to Fig. 2, Fig. 5 is an end view of the locating device at the section marking BB in Fig. 1 and Fig. 6 is an end view of the locating device at the section marking A-A in Fig. 1. 1 \ J ... å LH PREFERRED EMBODIMENT Fig. 1 shows at the reference numeral 1 a detachable part which may be, for example, a fixture plate, which is attached to an underlying machine part, for example a machine table or a clamping cube. In general, the detachable part can be any part to be located with good reporter accuracy and good precision relative to the underlying part. In the upper right corner of the fixture plate 1, the end surface of a first type of locator 2 according to the invention is shown and at the upper left and lower right corners a second type of locator 3 according to the invention is shown. Of these two locators 3 of the second type, only one is used at each clamping occasion, so Fig. 1 illustrates alternative locations of the clamping device 3.

The locator 2 has, as will be described in more detail below, a guide surface for co-operation with a corresponding guide surface on the fixture plate or a bushing inserted therein, the guide surface of the locator 2 being formed by a number, in this case four, circumferentially spaced sub-surfaces. Correspondingly, the locating device 3 of the second type has a guide surface which is formed by only two sub-surfaces 5, which will also be described in more detail below.

The drawing shows that the partial surfaces 4 of the locating device 2 are arranged diagonally between the X and Y directions (it is then assumed that the Z direction is perpendicular to the plane of the drawing in Fig. 1). The sub-surfaces 5 of the locating device 3 when placed at the lower right corner of the fixture plate are arranged in the X-direction, while the sub-surfaces of the locating device 3 'when placed' at the upper left corner of the fixture plate are oriented in the Y-direction.

The described orientation of the different sub-surfaces is based on the fact that the locating device 2 of the first type is intended to accurately determine the position of the fixture plate in the plane XY, while the sub-surfaces 5 of the locating means 3 in the two alternative locations are intended to locate the fixture plate in the turn 465 715 6 direction according to the arrows C and D defined by the center axis of the locator 2 of the first type.

Figures 2 and 6 show in more detail the design of the locating device 3 of the second type. From these figures it can be seen that behind, in Fig. 2 under the fixture plate 1, there is a fixed part, in this case for instance a machine table 6 in which a bushing 7 with an internal cylindrical guide surface 8 is arranged. radially inwardly directed guide pin 9 which engages in an axially directed groove or recess 10 in the peripheral surface of the inner end of the locator.

The drawing shows that the locating device has two recesses 10 arranged at an angle of 90 °, so that the locating device 3 can thereby be fastened to the machine table 6 in two alternative positions.

Correspondingly, the fixture plate 1 has a bushing 11 with an internally arranged cylindrical guide surface 12.

The locator 3 itself can be described in rough outline as an externally substantially cylindrical locking body which has an inner or first guide surface for co-operation with the guide surface 8 of the bushing 7 and an outer or second guide surface 5 for co-operation with the inner guide surface 12 of the bushing 11. it further appears that from the inner end of the locking body along its axis extends a screw 13 which fixes the locking body in the machine table 6.

The inner or first guide surface of the locking body is ground to a cylindrical shape and can be considered as substantially rigid or non-expandable. Correspondingly, the inner guide surface 8 of the bushing 7 is ground to a nominally cylindrical shape. The tolerances and tolerance positions (for example J7, g6) selected for the guide surface of the bushing 7 and the first guide surface of the locking body are such that on average a very small clearance is formed, in the order of 15 / Ll at a nominal diameter of the locking body of 25 mm.

7E Correspondingly, the outer or second guide surface 5 of the locking body 5 is ground to a nominal cylindrical shape in the same way as the bushing 11 has its inner guide surface 12 ground to a nominal cylindrical shape. For these two cooperating guide surfaces, the tolerances and tolerance positions are chosen in such a way (for example F7, g6) that, when the guide surfaces are in the unexpanded state, there is on average a clearance of the order of 45 / X at the same nominal diameter of the locking body. Due to this larger mean play in the non-expanded state, it is gained that a larger deviation in the nominal dimension between the bores can be accepted without the precision in the position of the fixture plate after expansion having to be compromised.

To facilitate mounting of the locking body in the bushing 7 and mounting of the fixture plate 1 on the locking body, the locking body at its opposite ends has entry surfaces 14 and 15, respectively, which have a diameter which is reduced by approximately 1% relative to the nominal outer diameter of the locking body.

As indicated above, the first guide surface 5 of the locating device 3 is formed by a number of strip-shaped parts extending along the axis direction of the locking body and divided parts or bars distributed along the circumference of the low body. In this embodiment, two sub-surfaces are used which have a 180 ° pitch in the circumferential direction and whose width in the circumferential direction is in the order of 25-40%, preferably about 30%, of the diameter of the locking body. In the circumferential direction between these sub-surfaces 5, the locking body in the area of the fixture plate 1 has radially inwardly displaced surfaces 16 which, as can be seen from Fig. 6, can be flat but which can also be arched. Their shape is irrelevant according to the invention because they do not come into contact with the bushing 11.

In order to provide the possibility of expanding the second guide surface 5, the locking body has a continuous axially directed slot 22 and a central, axially directed bore 17 with a conical portion 18 in the area of the fixture plate 1. In the conical portion an expanding member 19 with a conical portion 20 which 465 715 8 cooperates with the conical portion 18 of the bore. If the conicity is selected in the range 1: 10-1: 30, preferably about 1:20, the conical portion 20 becomes self-locking in the conical part 18 of the bore 17. The expanding member 19 further has a thread 21 which engages a corresponding thread in the bore 17 so that thereby the expanding member, which is made in one piece, can be screwed axially back and forth in the locking body. In this case, the two conical portions 18 and 20 come into interaction with each other so that thereby the second guide surface on the locking body can be expanded by screwing in the expanding member. The friction that arises between the conical part 20 of the expander and the surrounding conical bore 18 also contributes to the self-locking as the entire expander is rotated like a rigid body.

In order to enable the above-mentioned expansion of the second guide surface 5 on the locating device, this has in the embodiment according to Figs. 2, 4 and 6 as indicated above the continuous axially directed groove 22, which lies in a diameter plane of the locking body. From Fig. 6 it can be seen that the groove 22 is positioned in such a way that the two guide surfaces 5, when the expansion member 19 is tightened, can expand in the direction away from each other, out from the center of the locking body.

At the inner end of the groove 22, a transverse bore 23 is further arranged, which has the primary purpose of eliminating the stresses which might otherwise arise at the bottom of the groove 22.

As can be seen from Fig. 2, the bore 23 in the longitudinal direction of the locking body is located within the area of the first or inner guide surface of the locking body. This means that when expanding the second guide surface, the expansion will also to some extent extend over the first guide surface. Since the conical part 20 is short and covers only an outer part of the locking body, this will not expand cylindrically but rather approximately conically. However, a cylindrical and rigid part of the inner guide surface always remains. As shown in Fig. 4, the bore 17 in the area of the first guide surface has a shoulder against which the skull rests on the screw 13 used for fixing the locating device in the machine table 6.

The embodiment according to Figs. 3 and 5 differs from the embodiment described above only in that the first guide surface has only one recess 10 for the guide pin 9 in the bushing 7 of the machine table 6. Furthermore, the second guide surface 4 is divided into four different sub-surfaces with radially arranged therebetween inwardly displaced surfaces 16. Finally, this embodiment does not have a continuous groove 22 but two grooves which intersect at approximately right angles and which run through the radially recessed surfaces 16. The partial surfaces in this embodiment are arranged with the same angular pitch, ie 90 °. The width of the sub-surfaces in the circumferential direction is in the range 25-40%, preferably about 30%, of the diameter of the locking body.

As an alternative to four sub-surfaces 4 on the locator 2, other numbers may also be considered, for example three or five, six or more.

The invention may be further modified within the scope of the following claims.

Claims (9)

465 715 10 P A T E N T K R A V Locating means for locating a detachable part (1), such as a fixture plate, relative to a fixed part (6), such as a machine table or the like, comprising a substantially cylindrical locking body with a first guide surface for co-operation with the machine table and a second guide surface for co-operation with the detachable part, characterized in that the first guide surface is substantially cylindrical and rigid, that the second guide surface is formed by a number of band-shaped parts extending along the axis direction of the locking body and distributed along the circumference of the locking body (4, 5) and that the sub-surfaces are expandable outwards from the center of the locking body. Locator according to claim 1, characterized in that the locking body has a central bore (17) with a shoulder in the area of the first guide surface, the shoulder being arranged for co-operation with a fastening means (13) for axial position fixation of the locking body. relative to the machine table (6). Locating device according to Claim 1 or 2, characterized in that between the sub-surfaces (4, 5) in the circumferential direction of the locking body, parallel slots (22) are arranged with the axial direction of the locking body, which traverse the locking body and which in the longitudinal direction of the locking body has approximately the same or slightly greater extent than the partial surfaces (4, 5). Locating device according to Claim 2 or 3, characterized in that the bore (17) has a threaded portion for co-operation with a one-piece expansion member (19) with a conical portion (20) for co-operation with a corresponding - conical portion (18) of the bore in the area of the second guide surface (4, 5). .ß m m -a ... à (fi 11 Locator according to claim 4, characterized in that the conical portions (18, 20) have a conicity of the order of 1: 10-1: 30 whereby the expansion member (19) is self-locking. Locating device according to one of Claims 1 to 5, characterized in that both the first and the second guide surface (4, 5) have entry surfaces (14 and 15, respectively) at the opposite ends of the locking body and that the entry surfaces have a diameter dimension. , which is approximately 1% below the nominal diameter of the locking body. Locating device according to one of Claims 1 to 6, characterized in that surfaces (16) which are recessed in the radial direction from the sub-surfaces (4, 5) in the circumferential direction of the locking body are arranged. Locating device according to one of Claims 1 to 7, characterized in that the locking body has four sub-surfaces (4) with equal angular division and that the first guide surface has a recess (10) for locating the locking body in the direction of rotation. Locating device according to one of Claims 1 to 7, characterized in that the locking body has two partial surfaces (5) with an angular pitch of 180 ° and that the first guide surface has two recesses (10) for locating the reading body in the direction of rotation in two alternative , 90 ° relative to each other rotated positions.