EP0344178A1

EP0344178A1 - Winding device for spring winding machines with exchangeable, preadjustable elements.

Info

Publication number: EP0344178A1
Application number: EP88901031A
Authority: EP
Inventors: Gerhard Baisch
Original assignee: Individual
Current assignee: Individual
Priority date: 1987-01-16
Filing date: 1988-01-09
Publication date: 1989-12-06
Anticipated expiration: 2008-01-09
Also published as: JPH01503216A; EP0344178B1; WO1988005352A1; US5127247A; DE3701088A1; JPH04737B2; DE3863546D1

Abstract

Le dispositif décrit requiert des logements de broches d'enroulement (13/14) et des fixations de broches d'enroulement (9/10) qui renferment toutes les vis de réglage nécessaires au réglage initial ainsi qu'aux réglages ultérieurs. Si tel est le cas, un préréglage peut être effectué dans un dispositif de réglage approprié, et des réglages fins peuvent également être effectués ultérieurement dans la machine elle-même. Sans cette possibilité de réglages fins, le système ne pourrait pas marcher car les différentes duretés des fils métalliques usuels du ressort le rendraient impraticable. Les broches d'enroulement (16) doivent être capables de tourner avec leurs logements (13/14) et de coulisser dans le sens longitudinal, et ces unités doivent à leur tour pouvoir, au moyen de la fixation de broches d'enroulement (9/10), pivoter et faire varier leur hauteur par rapport au coulisseau de réglage. Le dispositif de pré-réglage mesure les variations angulaires sur un axe de mesure (41) et les affiche sur un dispositif de mesurage d'angle (45). Un comparateur à cadran (55) est prévu pour les réglages dans le sens axial. Le réglage effectué dans le dispositif de réglage peut être transféré à la machine sans altérations. Cette reproductibilité simplifie et accélère non seulement le réglage de base mais permet également un processus de remplacement par diverses fixations.The device described requires winding pin housings (13/14) and winding pin fixings (9/10) which contain all the adjustment screws necessary for the initial adjustment as well as for subsequent adjustments. If this is the case, a preset can be made in an appropriate adjuster, and fine adjustments can also be made later in the machine itself. Without this possibility of fine adjustments, the system could not work because the different hardnesses of the usual metal wires of the spring would make it impractical. The winding pins (16) must be able to rotate with their housings (13/14) and slide in the longitudinal direction, and these units in turn must be able, by means of the fixing of the winding pins (9 / 10), rotate and vary their height in relation to the adjustment slide. The presetting device measures angular variations on a measuring axis (41) and displays them on an angle measuring device (45). A dial indicator (55) is provided for adjustments in the axial direction. The setting made in the adjuster can be transferred to the machine without alteration. This reproducibility not only simplifies and speeds up the basic setting but also allows a process of replacement by various fasteners.

Description

Winch device for spring winch machines with interchangeable, pre-adjustable elements

The invention relates to a winch device for spring coiling machines with interchangeable, presettable elements. The applicability is given in one and two-finger winch systems in the manufacture of helical springs made of endless wire.

With the help of suitable quick-release wind pin holders and a matching adjustment device, the main adjustment work should be carried out outside the machine. This achieves a better degree of utilization of the production machine, the reproducibility of an already existing setting and the machine operation by less qualified personnel.

This is not the case with the previously known winch systems, because they mostly work with holders permanently installed in the machine, in which round winch pins are inserted in a hole. By turning them around their own axis, these wind pins can be brought into the required working position and clamped. There are no adjustment aids here, even though finding the correct inclination is of the greatest importance in the overall setting and requires extraordinarily well-trained specialists.

Smaller readjustments are almost a matter of luck with this system, because each time the clamp has to be opened without the previous position being fixed and thus being found again. For this reason, it is not possible to reproduce previous settings, although this would be extremely important for spring winding machines for reasons of utilization, because spring production can only start when it is on some test springs, all post-processing operations such as tempering, setting, grinding, deburring and force testing are completed. This often means hours of waiting for a machine set up for production. For extremely small or extremely large spring diameters, the wind pins, the axis of which normally runs parallel to the adjustment device of the slider carrying them, must be able to be pivoted. There are corresponding pivot points in the known systems, but also only for an uncontrolled adjustment.

The invention is based on the object of realizing interchangeable wind pin holders which can be preset outside the machine and in which the wind pin can be rotated in a controlled manner about its axis and moved in its longitudinal axis and perpendicular to it. In addition, it must be possible to pivot the longitudinal axis of the wind pins, which generally runs parallel to the direction of adjustment of the adjustment slides carrying the wind pin holders, into the negative or positive angular range. An adjustment device must make it possible to carry out the above-mentioned four settings outside of the machine on the basis of the values derived from the winch ratio and the wire thickness of the springs to be produced, whereby no undesired change may result from the installation in the machine.

Since spring steel wires can fluctuate in their hardness and thus in their spring deflection behavior, a controlled readjustment in the machine must be possible.

This object is achieved according to the invention in that the wind pegs can be displaced in the longitudinal direction, controllably rotated and pivoted in a controlled manner by means of the wind peg holder and can be changed in height with respect to the adjusting slide, can be removed individually and can be preset in an adjusting device by means of the adjusting screws arranged on these elements outside the machine . The controlled twistable Windstiftaufnähme is achieved in that adjusting screws are arranged on both sides of the axis of rotation, which are set against a reference surface. This reference surface is part of the wind pin holder carrying the wind pin holder. By setting one and opening the other set screw, the wind pins are twisted. The required working position of the wind pins is fixed by tightening both setscrews. If the wind pin holder is to be removed from the wind pin holder, it is sufficient to open a set screw. After reinserting, only the same screw needs to be tightened again to get the last position precisely again. The reproducibility of a once-held attitude is thus given.

This option is also used when presetting in the setting device outside the machine. For this purpose, the wind pin located in the wind pin holder is inserted into a suitable hole arranged in the measuring axis. By properly setting both screws against a reference surface, the required rotation is achieved, which can be read on a measuring device. When the correct setting is reached, a screw is opened, the wind pin holder is removed, inserted into the wind pin holder and fixed in the required working position by tightening the same screw.

The controlled pivoting movement of the wind pin holder is achieved using the same principle. The reference surface for this can be integrated directly into the bearing pin of the swivel axis or can be attached as an additional surface at another point on the adjustment slide. The only important thing here is the position of the set screws on both sides in relation to the swivel axis. The same procedure is followed when presetting the wind pin holder in the setting device. The reference surface for the set screws is not fixed here, but a Part of the rotatable swivel axis, the angular movement and thus the setting value indicates the measuring device. The positioning of the Windestifthal ter in the direction of the swivel axis is achieved by means of a spacing screw with which the distance to the adjustment slide level is adjusted according to the wire thicknesses to be processed and the desired pretension. The setting is also carried out in the setting device by means of a suitable length measuring device. This is also used for the length adjustment of the wind pins, the wind pin receptacles being accommodated in a sleeve which can be adjusted in the longitudinal direction.

After the pre-setting and positioning on the swivel axis have been completed, the wind pin holder is attached to the adjustment slides by screwing, the spacer screw serving as an end stop. If a screw is powerful enough, a threaded hole in the swivel axis is advantageous.

In the case of small and medium-sized spring coiling machines, round, square and rectangular coiling pins can be used with the appropriate design of the coaster holder. In the case of large spring coiling machines on which thick wires are processed, the coiled pin holders are expediently designed in such a way that inserts similar to inserts can be screwed on.

With small spring coiling machines that have to process the finest wires, the space is naturally very limited. Here it is advisable to do without the crayon holder and to store round crayons directly in the crayon holder. So that a controlled adjustment and presetting is possible here, a sleeve containing the two necessary adjusting screws is pushed over and fixed. It is of great importance and as an important prerequisite for the practical application of this experience that the solutions described provide a readjustment of all settings within the machine. This ensures that the described winch device can be used in accordance with the task and the required requirements such as better machine utilization, simpler and faster machine setup and reliable reproducibility are achieved. An additional effect is obtained if several wind pin holders are used with the appropriate tools. During the further treatment of sample springs, the wind pin holders used in their manufacture can then be removed and kept unchanged until they are released with the correct setting. In. During this time, the machine can produce other springs with other pens.

The measuring device of the adjusting device can be designed mechanically or electronically. In the former case, the rotary movement of the measuring axis is transmitted via a lever linkage to an analogue indicating protractor, while the longitudinal adjustment is carried out via fixed stops or by means of a dial gauge. In the case of an electronic version, an angle encoder would be attached to the measuring axis, the impulses of which would be made visible on a display of a display device.

The invention will now be described in more detail with reference to exemplary embodiments shown in the drawing. Show it:

Fig. 1 shows an embodiment of a two-finger winch system with integrated in the pivot axis reference surface, a wind pin holder is shown in section AB

Fig. 2 shows an embodiment of a single-finger winch system with an external reference surface and an insert-like winch tool

Fig. 3 shows an embodiment with a directly mounted round wind pin with slid-over adjustment sleeve Fig. 4 shows an embodiment of a setting device for presetting with a mechanical display, the side view showing the twisting of a wind pin holder and the length setting of the wind pin, while the top view shows the setting of a wind pin holder.

In the two-finger winch system, there are two adjustment slides 1/2 arranged at 90 ° to each other. On each of them, a bolt 3/4 fixed perpendicular to the slide plane is firmly anchored. These bolts have a threaded hole 5 in the center and, perpendicular to the direction of movement, a reference surface 6 as a support for the adjusting screws 7/8 which serve for the controlled pivoting movement and which are located in the mirror-pin-shaped windscrew holders 9/10.

With the stop screws 11, the distance from the slide level is changed and with the screws 12 the fixed connection between the adjusting slide 1/2 and the wind pin holder 9/10 is achieved. The wind pin holders 13/14 are provided with a square hole 15. As a wind pin 16 is a rectangular. Cross section with supplement 17 used. Clamp with screw 18 and longitudinal adjustment with screw 19. The screws 20/21, which are supported against the surface 22, are used for controlled twisting.

In the single-finger winch system, the cutting mandrel 23 is used as a deflection aid. FIG. 2 shows an embodiment in which a turning tool similar to an insert with a hexagonal hard metal piece 24 is used.

The adjusting slide 25 is provided with an external reference surface 26 for the controlled pivoting movement which is achieved with the screws 27/28. The wind pin holder 29 is designed so that these screws engage on both sides of the pivot axis 30. When a round wind pin 31 is directly supported, the cuff 32 is attached at the end. It contains the two screws 33/34 required for controlled turning, a clamping screw 35 and a screw 36 for longitudinal adjustment. With the small forces occurring here, it is sufficient if the feet 37 of the square screws 33/34 are supported in a groove 38 in the reference surface 39.

The adjusting device for presetting consists of a base plate 40 in which a bolt 41 serving as a measuring axis is rotatably mounted. The rotary movement of this bolt is transmitted via a lever linkage 42/43/44 to an analog mechanical protractor 45, which is secured against rotation with the tab 46 on the base plate. For adjustment, the wind pin holder 10 is pushed from above over the bolt 41 in such a way that its boundary furthest away from the measuring axis lies against the bar 47, while the mirror-image wind pin holder 9 is allowed to rest on the opposite bar 48. This ensures a position that prevents rotation. The bolt 41 is formed at its upper end so that a reference surface 49 is provided for the screws 7/8 provided for the controlled pivoting movement. By properly adjusting these screws, the bolt 41 is rotated clockwise or counterclockwise, which can be read on the protractor 45.

In the measuring axis of the pin 41 there is a square hole 50 which serves as a receptacle for the wind pins 16 located in the wind pin receptacles 13/14. A plate 52 which can be inserted into the slot 51 of the base plate provides the reference surface for those used for controlled rotation

Screws 20/21, with which the presetting is effected. To adjust the height of the wind pin holder 9/10 with the spacer screw 11 and for longitudinal adjustment of the wind pin 16 with the adjusting screw 19, the adjusting device has a dial gauge 55 which can be pivoted into the measuring position on a bracket 53 around the axis 54. The height adjustment of the wind pin holder 9/10 takes place with the help of the dial gauge 55 in the same position as in the controlled adjustment of the pivoting movement. For this purpose, the pintle receptacles 13/14 are inserted into a special sleeve 56 which is adjustable in the longitudinal direction.

Claims

1. Winch device for spring coiling machines with interchangeable, presettable elements, characterized in that the wind pins (16/14) can be rotated in a controlled manner, displaced in the longitudinal direction and pivoted in a controlled manner by means of the wind pin holder (9/10) by the wind pin receptacles (13/10) in the vertical position Adjusting slide, changeable and pre-adjustable by arranging the adjusting screws for these adjustments on the interchangeable elements.

2. Wind pen holder according to claim 1, characterized in that the controlled pivoting movement by two sides of the pivot axis (3/4 or 30) arranged, against one with the adjusting slide (1/2 or 25) rigidly connected surface (6 or 26) supporting screws (7/8 or 27/28) is generated.

3. Wind pen holder according to claim 1 and 2, characterized in that an adjustment in the direction of the pivot axis is effected by at least one spacer screw (11) arranged in the axial direction.

4. Wind pen holder according to claim 1 to 3, characterized in that a support surface (22) for the screws for the controlled rotation of the wind pins is arranged at one end of the bore provided for mounting the wind pin receptacles.

5. Wind pen holder according to claim 1, characterized in that the controlled rotation by two arranged on both sides of the axis of rotation against a located on the wind pin holder surface (22) supporting screws (20/21) is generated.

6. crayon mount according to claim 5, characterized in that in the center a square hole (15) for receiving round, square and with the help of an insert (17) also rectangular wind pins (16) is available.

7. Winding tool according to claim 5, characterized in that one end for receiving insert-like wind pins (24) is formed.

8. Winding tool according to claim 5, characterized in that a round winch pin (31) is mounted directly in the bore of the winch pin receptacle and can be rotated in a controlled manner via a slid-on sleeve with two screws (34/33) arranged on both sides of the axis of rotation (34/33) is displaceable in the longitudinal direction with a screw (36).

9. Adjusting device according to claim 1, characterized in that with the two screws (7/8) intended for controlled pivoting in the case of fixed wind-pin holders (9/10) the measuring axis (41) provided with an actuating surface (49) is moved and the angle value is adjusted to one Measuring device (45) is transmitted.

10. Adjusting device according to claim 1 and 9, characterized in that with its wind pin (16) in the center of the measuring axis (41) fixed wind pin holder (13/14) with the two screws for controlled rotation (20/21) by turning against a reference surface (52) moves the measuring axis and the angle value is displayed on a measuring device (45).

11.) adjusting device for winch tools on spring coiling machines, with an adjustable tool holder (13 or 14; 32) in which a winch tool (16; 31) in the direction of its longitudinal axis at least crossing the longitudinal axis of the spring to be produced by means of an adjusting screw (19; 36) is adjustable; with a tool holder (9 or 10; 29), which carries the tool holder, which, by means of a pair of set screws (20 and 21; 33 and 34), is rotatably supported on both sides of the tool on the workpiece holder (surface 22; reference surface 39) this is stored; and with an adjusting slide (1 or 2; 25) which can be displaced transversely to the spring axis and on which the tool holder is arranged so as to be pivotable about its longitudinal axis parallel to the spring axis by means of a bolt (3 or 4); wherein the tool holder by means of an adjusting screw (7 or 3; 27 or 28) on one side of it

Pivot axis supported on a slide-proof device part (bolt 3 or 4; reference surface 26) (according to DE-C-892 133); characterized in that the tool holder (13 or 14; 32) can be rotated about the longitudinal axis of the tool (16; 31) by means of the set screw pair (20, 21; 33, 34); that the longitudinal axes of the bolt (3 or 4) or the tool (16; 31), which may be attached to the adjusting slide (1 or 2; 25), always cross each other perpendicularly; that an adjusting screw (11) is mounted parallel to the longitudinal axis of the bolt (3 or 4) on the tool holder (9 or 10; 29) and is supported on the adjusting slide (1 or 2; 25); and that a second pair of setscrews (7 and 8; 27 and 28) is provided, which is on both

Supports sides of the pivot axis of the tool holder (9 or 10; 29) on the slide-proof device part (bolt 3 or 4; reference surface 26); wherein the tool holder (13 or 14; 32) with the received tool (16; 31), the adjusting screw (19, 36) for longitudinal adjustment thereof and the first pair of adjusting screws (20, 21; 33, 34) one from the tool holder in the longitudinal direction of the tool without Another separable first structural unit and the tool holder (9 or 10; 29), if necessary with bolts, the adjusting screw (11) for adjusting the tool holder parallel to the spring axis and the second pair of adjusting screws (7, 8; 27, 28) one from the adjusting slide (1 or 2 ; 25) in the longitudinal direction of the bolt (3 or 4) after releasing a lock (head of the screw 12; 30) forms a separable second structural unit which, like the first unit, can be preset in a separate adjusting device (FIG. 4) by adjusting its adjusting screws and on the one hand with the first unit and on the other hand with the adjusting slide (1 or 2; 25) can be joined axially.

12.) Adjustment device for the first and second structural

Unit with adjusting screws of the adjusting device according to claim 11; with a base plate (40) corresponding to the setting slide (1 or 2; 25) with pin (3 or 4) and the slide-proof part (pin 3 or 4; reference surface 26) with pin (41) or one about its vertical axis rotatable bearing part (bolt 41) with a reference surface (49) for supporting the second pair of setscrews (7,8; 27,28) of the tool holder (9 or 10; 29) mounted on the base plate (40) on both sides of the axis of rotation of the bearing part (Bolt 41); with a plate-fixed support surface (plate 52) for the first set of screws (20, 21; 33, 34) of the tool holder (13 or 14; 32) with the tool (16; 31) picked up, which itself (16) or by means of an insert (17 ) has a cross-sectional profile that deviates from the circular shape and can be inserted into a correspondingly non-circular hole (50) in the plate-fixed bolt (41); and with a protractor (45), coupled to the rotatable bearing part (bolt 41), of fractions of a bearing part revolution.

13.) Adjustment device according to claim 12, (according to CH-A-415236) with an axis perpendicular to the base plate (40)

(54), on which a plate-parallel arm (53) with a length meter (dial gauge 55) is axially displaceably mounted, characterized in that the arm (53) can be pivoted about the axis (54) until the length meter (55) is above one the plate-fixed bolt (41) rotatably arranged tool holder (9 or 10; 29); and that the base plate (40) in the pivoting range of the boom (53) is a sleeve

(56) for storing a tool holder (13 or 14; 32) with the tool (16; 31) in the vertical position.

A n e ce ration based on PCT Rule 6. 2 B

The reference numerals in parentheses in the claims may not be used to restrict the claims; see EPC Rule 29 (7).