SE444042B - A coupling involving a male/female element presenting to each other as interacting wedge surfaces. - Google Patents

Abstract

The invention concerns a coupling, especially to facilitate the coupling of components which together create a column along which there is a movable boring tool. The coupling involves a male/female element presenting to each other interacting wedge surfaces (20, 21) which are moveable with respect to contact with each other primarily via the axial movement of the element relative to each other. The coupling involves a tool (37) which, by the dragging of the element forces the wedge surfaces into intimate contact with each other. A spring (29) is brought into the coupling which during the dragging of the coupling accumulates elastic force and thereafter tends to retain the contact between the element's wedge surfaces.<IMAGE>

Description

8105606-1 One such disadvantage is that the column is designed as a single continuous part of a certain given length. In cases where it was desired to clamp the unit not only in relation to the floor joist but also in relation to the roof joist, it has therefore been necessary to use provisionals in the form of plank stumps and the like which have had the task of extending the column up to the joist floor. It is suitable to eliminate the above-mentioned inconvenience by making the column composed of a plurality of interconnected parts, preferably of different lengths. The unit can thus include a variety of sections with predetermined module lengths which, by suitable choice, can be assembled into pillars whose lengths correspond to conventionally occurring ceiling heights in different buildings. The object of the invention is to develop a coupling suitable for coupling the above-mentioned parts to a pillar.

From the Swedish patent specification 157 300 a coupling according to the preamble of claim I is already known. In this known coupling there is a prestressed spring, which only has the task of maintaining a certain cohesion of the coupling in the event of unintentional loosening of an eccentric lock. With functional eccentric locking, the spring has no function. The spring tension of the spring is reduced when the coupling is tightened.

According to the present invention, on the other hand, the coupling comprises a spring arranged to accumulate the spring forces of the elements against each other when the coupling is tightened. As a result, the tightening device and the spring will function in "series" so that the tightening gives rise to the spring force. In the Swedish patent specification, on the other hand, the tightening device and the spring work in parallel.

With reference to the accompanying drawings, a more detailed description of a preferred embodiment of the invention follows below. In the drawings, Fig. 1 is a perspective, partly simplified view of the drilling unit according to the invention, Fig. 2 an enlarged section through the feed part of the unit, with the column and the drill part illustrated in partially cut condition, Fig. 3 a cross section through the coupling between two parts as together, the pillars of the drilling unit and Fig. 4 form a section IV-IV in Fig. 3.

The drilling unit shown in Fig. 1 comprises a bottom plate 1, a pillar 2, a drilling tool 3, a drilling machine part 4 driving it and a fastening or feeding part 5 on which the drilling machine part 4 is mounted.

The bottom plate 1 can in practice be made of light metal and on its underside have a conventional, endless sealing ring which delimits a space from which the air can be suitably evacuated in order to provide a vacuum by means of which the plate is sucked to and firmly anchored to the substrate, eg a floor joist.

The pillar 2 is connected to the base plate 1 via a connection of the type designated in its entirety by 6, which allows pivoting of the pillar 2 relative to the base plate as indicated by the dashed lines in the figure. More specifically, the connection 6 comprises two halves 7 and 8, of which the first-mentioned half 7 is fixedly connected to the base plate 1 via a bracket 9 and has a female conical recess (not visible) in which a correspondingly conically shaped fit is fitted, male projection on the latter half 8, which in turn is fixedly connected to a laterally projecting, hollow shaft part 10 arranged on the lower part 11 of the column. A tightening bolt 12 extends through the center of the shaft 10 and is threadedly connected to the female connection half 7. Through When the bolt 12 is tightened, the cones of the halves 7, 8 are brought into contact with each other while providing a frictional connection between the column and the bottom plate. By loosening the bolt 12, the pillar 2 is made free to pivot to any inclined position relative to the bottom plate and then the pillar can be fixed in this position by a simple tightening of the bolt 12. As previously mentioned, the pillar 2 is composed of a plurality of parts of which two are shown in Fig. 1, namely the parts 13 and 14. These parts are identically similar in shape except that the lengths of the same differ. Thus, each of the sections is made of square tubes with a comparatively strong wall thickness, for example of the order of 3-4 mm. Arranged along one of the walls of the square tube 4 is a rack 15 (see the section or tube 13), which extends all the way along the length of the sub-tube and together with a corresponding rack of the adjacent sub-tube (see the rack 15 'of the sub-tube 141 forms a continuous More specifically, the toothed path 15, 15 'is arranged substantially centrally along the pipe walls in question so that on either side of the toothed path flat running paths 16, 17 are formed for roller elements included in the feed part 5.

The sub-pipes 13, 14 are interconnected by means of a coupling illustrated in detail in Figs. 3 and 4, which comprises on the one hand a female element at the lower end of each column sub-pipe, and on the other hand a male element arranged at the upper end of each sub-pipe.

Reference is now made to Figures 3 and 4 which illustrate the nature of the coupling according to the invention. In the drawing, the male element included in the coupling is generally designated 18, while the female element has the designation 19. The male element 18 has a wedge surface in the form of an outer conical surface 20, while the female element 19 has an inner conical surface 21 with substantially the same conicity as the surface 20. The female element 19 consists of a pipe body which is welded or otherwise firmly fixed in the lower part of the column part in question, for example the pipe 14. The male element 18 comprises two parts movable relative to each other along the shaft 22, namely a first , the cone 20 having part 23 which is welded or otherwise anchored in, for example, the upper end of the column part tube 13, and a second movable part in the form of a head from whose underside 8105606-1 projects a drawbar 25 having a thread 26. On this is attached a nut 27 and between the nut and a downwardly directed abutment surface 28 of the part 23 there is a suitably strong disc spring 29 which strives to hold the head 24a against an upwardly directed annular abutment surface 30 of the part 23.

Both the female element 19 and the movable head 24 of the male element have holes which extend along the transverse axis 31. More specifically, the female element 19 has two diametrically opposite holes 32, 33 located on either side of the female recess of the element, the former having a larger diameter than the latter. In the head 24 there is the hole 34 which has an elongated cross-sectional shape. The holes 32, 33 are in the example shown delimited by bushings 35, 36. In the holes 32, 33, 34 an eccentric device denoted in its entirety by 37 is inserted, which has two cylindrical end portions 38, 39 located concentrically along the shaft 31 with different diameters for fitting into corresponding holes in the female element, and on the one hand an equally cylindrical portion 40 between the two end portions, the center axis of which is eccentric in relation to the axis 31 common to the end portions.

In the coarser end portion 38 of the eccentric device there is, for example, a square recess 41 for a control lever or key of a suitable type.

The described connection works as follows. Before the coupling of the two sub-pipes 13, 14 connected to the male and female elements, the eccentric device is separated from the other coupling parts. When coupling is to take place, the male and female elements are provisionally brought together so that the two transverse holes 32, 33 of the female element are substantially in line with the transverse hole 34 in the head of the male element 24. In this position the eccentric device 37 is inserted into the holes so that the front, pin-like the end portion 39 engages the hole 33. In this case, there is a fairly tight fit between the end portions 38, 39 and the corresponding holes 32, 33, 8105606-1 while the clearance between the intermediate portion 40 and the corresponding hole 34 in the head 24 can be quite large. Now the eccentric body is rotated about a quarter of a turn, for example by means of the control lever 42 shown in Fig. 1. This means that the two conical surfaces 20, 21 of the male and female elements are pressed together in intimate contact with each other while the spring 29 is tensioned by force transmission via the head 24, the drawbar 25 and the nut 27; which in turn means that the eccentric device 37 is reliably retained in the assumed rotational position.

It should be noted that the non-conical lower half of the first part 23 of the male element protrudes slightly above the upper end edge of the sub-tube 13, while the lower edge of the female element 19 is located slightly above the lower edge of the upper sub-tube 14. The outside of the part 23 is square. with the same cross-sectional shape as the two sub-tubes 13, 14, which means that the two sub-tubes are prevented from rotating relative to each other as the square section 23 'of the part 23 projects into the correspondingly square lower part of the sub-tube 14.

When loosening the coupling, proceed as follows. The eccentric 37 is rotated at least half a turn so that the eccentrically located intermediate portion 40 will act against the lower flat surface of the cross-sectionally elongated hole 34 in the head 24, which means that the head 24 depresses the underlying part 23 of the male element 18 so that the frictional engagement between the cones 20, 21 ceases. Then the eccentric device 37 is taken out of the holes, whereupon the male and female elements are free to eat.

It should be noted that all actuation of the eccentric device can take place from the side of the sub-tube 14, in that both the eccentric device and the holes in which it is inserted extend transversely in relation to the longitudinal extent of the sub-tubes.

By means of the coupling illustrated in Figs. 3 and 4, it is possible to build up a north-frame pillar composed of several parts in an extremely short time. Referring again to Fig. 1, it should be noted that not only the two parts or tubes 13 and 14 are interconnected by a coupling of the type described, as indicated by the eccentric device 37, but also the lower part 11 of the column and the subpipe 13 are interconnected. by means of such a coupling, as indicated at 37 'in Fig. 1.

As can be seen from Fig. 1, the previously described drilling machine part, designated in its entirety by 4, is composed of several components, namely a motor 43 indicated by dashed lines, a gearbox 44 and a frame part 45 to which the gearbox is attached. The drill part 4 is connected to the feed part 5 movable up and down along the column via a quick-locking device. The features of this quick-locking device are shown in more detail in Fig. 2, to which reference is now made.

In Fig. 2, the drill part or more specifically its frame part 45 is only hinted at on the left in the figure.

At its end facing the feed part 5, the frame part 45 is provided at the bottom with a ruler 46 of durable material. The ruler can be attached to the frame part by means of screws 47 indicated by dashed lines in the figure. The ruler 46 cooperates with an analog ruler 48 screwed to the feed part 5. This cooperation is provided via two inclined, wedged surfaces, namely a first wedge surface 49 present on the ruler 46 which extends obliquely outwards downwards from the frame part 45, and a second, on the ruler 48 existing wedge surface 50 which extends obliquely outwards-upwards from the feed part 5.

At the top, the frame part 45 has a portion inclined relative to the horizontal plane on which a plane and thus likewise inclined ruler 51 of abrasion-resistant material is arranged. This ruler cooperates with a clamping device arranged on the supply part 5 in the form of an eccentric device 52. In practice, the eccentric device 52 can consist of a cylindrical body, although at 53 partially planar ground body which at its two opposite ends is eccentrically mounted in the two supply part 5 8105606 -1 flanges or walls as indicated in Fig. 1 54, 55. The body 52 is rotatable by means of the lever 42 via the recessed projection 56.

The mounting of the drill part 4 on the feed part 5 takes place as follows: The eccentric body 52 is rotated to the position shown in dashed lines in Fig. 2 in which the planar ground surface 53 is turned downwards. In this condition, the frame part 45 is provisionally hooked onto the feed part 5 by hooking the two strips 46, 48 into each other. Thereafter, the frame part I is pivoted up in a clockwise direction around the pivot center established at the strips 46, 48 so that the frame part 45 assumes the position shown in Fig. 2 in which the front surface 57 of the frame part abuts against a corresponding vertical surface of the feed part. This suspension can take place without hindrance of the eccentric body 52, in that the strip 51 passes freely under the downwardly planar ground surface 53. Final clamping of the frame part is now ensured by turning the eccentric body 52 half a turn to the position shown in solid lines in Fig. 2. in which the eccentric body applies a frame portion 45 obliquely downwardly directed force.

The horizontal component of this force pushes the frame part inwards towards the feed part 5 and the vertical component is divided at the wedge surfaces 49, 50 in such a way that here too a horizontal force component is obtained which presses the lower part of the frame part towards the feed part 5. The two wedge surfaces 49, 50 thus fulfill the dual function of serving as a temporary bracket for the frame part during assembly work and of firmly wedging or pressing the frame part against the feed part.

Fig. 2 further shows how the feed part 5 is guided along the column 2 by means of a number of roller elements in the form of wheels or pulleys. More specifically, the feed member comprises four pairs of wheels 58, 59, 60, 61. Each such pair of wheels comprises two individual wheels separated by the respective wheel axle. The two first-mentioned pairs of wheels 58, 59 which are arranged on one side of the column 2 thus have the individual wheels in each pair located on opposite sides of the toothed track 15, the wheels being arranged to roll along the two running tracks 16, 17 according to Fig. 1. These two pairs of wheels 58, 59 are stationary mounted relative to the feed part 5, i.e. the wheels themselves are rotatable relative to the axis of rotation in question, but the axis of rotation is immovable in relation to the two side flanges or walls 54, 55 of the feed part.

The two other wheel pairs 60, 61 located on the opposite side of the pillar, on the other hand, are mounted on a common carrier in the form of a boom 62 which in turn is pivotally mounted relative to the feed part 5 itself via the shaft 63.

For the feeding of the feed part 5 along the pillar, a drive arrangement is arranged in a conventional manner comprising two interlocking gears 64, 65, the former of which is engaged in the tooth path 15, while the latter has a side projection 66 (see Fig. 1). to which the lever 42 can be connected.

The drilling assembly according to the invention is shown in Fig. 1 in a basic embodiment and the assembly in its practical embodiment comprises a further number of components. Thus, the assembly includes a series of pieces or tubes for the pillar 2 forming.

For example, these sub-pipes can be available in lengths of 1,500, 1,200, 1,000, 500 and 300 millimeters, which makes it possible to vary the length of the pillar in an appropriate manner so that it fits conventionally occurring ceiling heights in buildings. The pillar also includes a clamp (not shown) connectable to the top of the male element 18 to be used for clamping the pillar relative to the roof joist in question. The unit also includes a specially designed frame part which can be connected to the feed part 5 and which has the task of supporting a column 2 similar to a boom which can be arranged horizontally (or obliquely) in order to control a drilling machine and associated drilling tools when drilling holes in walls. . The advantages of the invention are obvious. Thus, assembly and disassembly of the unit according to the invention can be carried out very quickly and smoothly thanks to the coupling illustrated in Figs. 3 and 4.

It is a given that the invention is not limited only to the embodiment described and shown in the drawings. Thus, it is conceivable to apply and use the coupling described in connection with Figs. 3 and 4 in other contexts than just in connection with drilling units. For example, the coupling can be considered for pillar or tubular components of the type that occur in the construction of scaffolding, pipe components for providing racks of arbitrary types, for example truss-like building frames. For tightening the two male and female elements, in all applications, instead of an eccentric device of the type described, other devices can be used, for example wedges which are inserted or exited via transverse holes in the elements. Other modifications of the invention are also conceivable within the scope of the inventive concept.

Claims (3)

8105606-1 11 Patent claims Coupling comprising a female (19) and a male element (18) having cooperating wedge surfaces, in particular conical surfaces (20, 21), which are movable in respective out of contact with each other by substantially axial movement of the elements relative to each other , the coupling comprising a device (37), which is arranged to force the wedge surfaces (20, 21) of the elements into intimate contact with each other when tightened and which is received in transversely extending holes (32, 33; 34) in the female element (19). and a part (24) axially movable therein by means of the tightening means (37), which is arranged to transmit the tightening forces to the male element (18) when the coupling is tightened, characterized in that the axially movable part (24) is arranged connected to the male element (18) in order to be able to accompany the male element (34) after removal of the tightening member (37) from the part (34) of the part, its axial separation from the female element, the part (24) being arranged to and the female elements can reach a position where the hole (34) of the part is aligned with the hole (32, 33) of the female element, that the part (24) is axially displaceably movable along the male element (18) and that between the part (24) and the male element (18) a spring (29) arranged to be clamped during axial displacement of the part (24) relative to the male element (18) when the coupling is tightened and thereby accumulate spring force which acts on the wedge surfaces (20, 21) of the elements to engage with each other. Coupling according to Claim 1, characterized in that the tightening device (37) consists of an eccentric device (37), in that the female element (19) has two diametrically opposite holes (32, 33) located on opposite sides of the female recess of the element. which have different large diameters but are located along one and the same transverse geometric axis (31), that the part (24) has a through hole (34), preferably with an elongate cross-sectional shape, and that the eccentric device (37) has two cylindrical, end portions (38, 39) of different diameters present concentrically along a common center axis and intended to fit into corresponding holes (32, 33) in the female element (19), partly one between the two end portions (38, 39). 39) an existing, likewise suitably cylindrical portion (40) whose central axis is eccentric with respect to the axis common to the end portions. Coupling according to claim 1, characterized in that the male element (18) has an axial hole, in which a pull rod (25) is received, which at its one end is fixedly connected to the part (24), which is located at the end of the male element where its wedge surface (20) has the smallest cross-sectional dimension, and at its other end abuts a disc spring (29) abutting in turn against an axial abutment surface (28) on the male element.