EP1197319A1 - Wedge drive - Google Patents

Abstract

Key comprises an upper guide part containing a sliding element (20) and a sliding guide element (10) held together by at least one guide clip (30) and a lower guide part containing a driving element. An Independent claim is also included for a method for reproducible adjustment of a key in a tool. Preferred Features: At least one guide clip connects the sliding element and the sliding guide element. The guide clip engages in a form-locking manner in the sliding guide element and/or the sliding element.

Description

The invention relates to a wedge drive with an upper guide part, comprising a slide element and a slide guide element, and containing a lower guide part a driver element.

Such wedge drives are known. You will be particular in tools in metalworking e.g. used in presses. Connected to the wedge drives are usually which enable punching or other shaping Institutions. The wedge drives are on the part of the slide guide element through a generally vertical one Press force applying drive moves. On the part of the driver element are the wedge drives in the tool or Press attached to a base plate, on which this too machining workpiece directly or via a corresponding Support device is placed. For example, going out DE-197 53 549 C2 such a wedge drive for deflecting a vertical pressing force that a driver element with has a prismatic surface. The flanks of the prismatic surfaces are sloping outwards educated. In addition, forced return clips are on two opposite sides in respective grooves of the Slider element and the driver element arranged. hereby in the event of a break, the slide element a spring element returning to its starting position Return of the slide element ensured in the event of spring breakage, thereby tearing out screwed-on punching elements to avoid. The slide element is on the Slide guide element over angle strips and retaining screws attached and can face along the angle ledges the slide guide element are moved.

Another wedge drive emerges from US Pat. No. 5,101,705 but also the slider element on angle strips depends or by means of which attached to the slide guide element is. It is necessary that the each other lying panels or elements required for attachment be precisely ground in between the slide element and slide guide element required running play to guarantee. The one disclosed in this document Wedge drive and also with the other known wedge drives, in which slide guide element and slide element over Angle strips and screws are connected together, proves it is disadvantageous that all tensile forces in the Screws are introduced, which in particular in the Moment when an expansion of the screws or this surrounding material takes place, the running game of yourself mutually moving slide guide elements and slide elements is affected. This leads to poor stability because of wear and tear the clamping of the tool in this area in particular is increased. It also turns out to be disadvantageous that the slide element is not laterally when heated can stretch as it is from the corner moldings in this regard is concentrated. This can also lead to increased wear of the tool or, in the worst case, lead to a such reduced running play that moving slide element and slide guide element against each other almost impossible becomes.

The present invention is therefore based on the object to overcome these disadvantages and to provide a wedge drive, whose service life is considerably longer than with the wedge drives of the state of the art and with as little impairment as possible of the running game can occur.

The task is for a wedge drive according to the generic term of claim 1 solved in that the upper guide part can be held together by at least one guide bracket and / or is held together. Developments of the invention are defined in the dependent claims.

This creates a wedge drive, in particular Slide element and slide guide element by means of at least held together in a guide bracket. Thereby it is not necessary to add additional angle strips or other devices connecting these two elements exactly loop in to guarantee the required running play. In addition, the running game is also when the Wedge drive or the tool is not affected as not only manufacturing tolerances, but also those that occur Expansion of the material through the connection via a Guide bracket can be caught. The stability the wedge drive is therefore no longer affected or shortened. Even in the absence of grinding high running accuracy can be achieved. In addition, the cost of the wedge drive can be significantly reduced because not only is less material required, but also less effort in assembling of slide guide element, slide element and driver element is required.

Preferably the guide bracket or brackets are can be positively engaged in the slide guide element or intervenes there with a positive fit. The Slider element thus hangs on the guide brackets Slide guide element on this positive engagement. So it is no longer necessary to stop to provide the slide guide element via screws that on the one hand, they are prone to wear and, on the other hand, they are already mentioned impairment of the running play when heated can cause. This can advantageously be significantly higher Holding forces between slide element and slide guide element be achieved than in the prior art is possible. In addition, the life of the wedge drive can can be increased many times over.

The at least one guide clip preferably has holding projections by means of which they are in a part of the slide guide element engages, the holding projections a Show bevel. The holding projections can, for example nose-shaped on an essentially flat base body be formed on the guide bracket. In another preferred Embodiment they are considered in the longitudinal direction of the Guide bracket directed from the flat base of the Protruding wedges formed. Point particularly preferably the retaining projections have a slight bevel, in particular a bevel of approximately 1 ° towards the driver element on. This bevel is preferably only provided and enabled on one side of the holding projections it, the at least one guide bracket in the stroke direction to move the wedge drive linearly and in parallel. hereby is preferably a linear adjustment of the leadership game and / or an adjustment of the sliding play between the upper and lower guide part through the guide bracket or Allows guide brackets. Guide clips are particularly preferred and the upper guide part so interlocking, that a linear displacement of the guide bracket in the stroke direction the wedge drive to a change in the leadership game transverse to the direction of action of the driver element at essentially constant linearity of the leadership game leads. So it changes through the linear adjustment or Move the guide bracket in the stroke direction of the wedge drive the guide play transverse to the direction of action of the driver element, due to the slight bevel of in particular 1 °, without the leading game in his Linearity changed. The possibility of to achieve a linear adjustment of the leadership game, wear that occurs during continuous operation quickly and thus be counteracted inexpensively.

Each item made on the tool generally shows has its own tolerance field, the slide guide element in this area to achieve the required Accuracy only a sliding play of 0.02 mm in particular may have. This can be achieved with the wedge drives the prior art, in which a screwing of Slide element and slide guide element is provided, very complex and cost-intensive, as constant reworking paired with permanent installation and removal required is. With the advantageous use of a guide bracket can slide play by simply moving them in parallel can be advantageously changed, making the individual previously required operations become superfluous, namely measuring and grinding in the individual elements of the wedge drive. Manufacturing tolerances can thus be advantageous to be offset, resulting in significantly lower manufacturing costs of the individual parts to be manufactured.

Preferably have slide element and slide guide element essentially the same width. Also point it prefers essentially parallel surfaces on which which can be attached at least one guide bracket. This proves to be advantageous because a wedge drive is not only in the Area of its lower guide part with a constant Sliding play of e.g. 0.02 mm should be guided but also to the sides, what happened to the wedge drives of the prior art proves to be very complex. By Providing guide brackets in connection with slide element and slide guide element of essentially the same width can on the one hand a complex grinding of the adjacent or sliding surfaces are eliminated. Secondly, it doesn't matter how big the actual one is Width of slide element and slide guide element is as long as both elements are essentially the same are wide. To achieve the required running game or Gliding becomes only two, namely the two each other opposite parallel surfaces are provided, on which the guide bracket is attached. hereby is due to the investment of the essentially flat Basic body of the guide bracket on the outer surfaces of Slide element and slide guide element an adjustment of the two elements, which in turn leads to the desired one Run accuracy results, even in the case where either the guide bracket or slide element or slide guide element replaced or exchanged for a replacement part become. On the one hand, this can be an inexpensive Manufacturing and the other one is also cheaper Operation of the wedge drive can be achieved.

The lower and / or upper guide part preferably has a prismatic part and / or at least a prismatic part Surface for guiding the slide element and / or to absorb lateral forces to generate a high Accuracy. Because the work surface of the Wedge drive extends over the entire width of the wedge drive, can be advantageous to drive in the lower guide part and / or for guiding the upper guide part of the prismatic Part and / or the prismatic surface provided become. The larger the prismatic part / the prismatic part Surface, the lighter and therefore better the upper guide part thereon or in particular the slide element driven and guided on the driver element. The slide guide element and / or slide element can have prismatic surfaces, especially one on top of the other sliding or joinable surfaces. Preferably is the prismatic part / the prismatic surface depending on the dimensions, especially the width and the other design of the slide element dimensioned. Here, the wedge drive preferably has its entire length Width extension essentially uniform Spread out. It is therefore possible to use the prismatic Part / the prismatic surface in terms of width ideally dimension the slide element, which is an enormous Influence on the running and service life of the wedge drive exercises. A driver element or slide guide element or Slider element with a particularly large prismatic surface or a particularly large prismatic part advantageously able to withstand greater press forces in vertical To take direction, lateral thrust through its V-shape intercept better and thus increase the running accuracy. An increased running accuracy in connection with larger ones Pressing forces are a goal of a wedge drive. Also can be better by providing prismatic surfaces constant adjustment. The actual width the wedge drive influences the degree of stability of the Driver element. It can be done by using the prismatic Part / of the prismatic surface is therefore another Improvement of the running and service life of the wedge drive achieved can be, in particular, by using the guide brackets achieved compactness of slide guide element and slide element even better for effective machining of a workpiece can be used.

A spring element, in particular a gas pressure spring, is preferably provided for retrieving the slide element, that by means of a securing element, in particular one Locking screw, secured in the slide element and can be disassembled. By using two guide brackets can enable a compact design of the wedge drive become. This in turn enables one to be retrieved of the slide element used gas pressure spring or another spring element in the installed state effortlessly and, without having to completely dismantle the wedge drive switch. Because in particular a gas spring, but also others Spring elements as wearing parts more often during the Operating a press, punch or other Tool in which the wedge drive is installed, replaced this easy assembly proves to be and disassembly as particularly advantageous since now no more a complete removal of the wedge drive from the tool and a subsequent disassembly of the wedge drive is required. A securing screw can be loosened particularly advantageously and removed, whereupon the spring element also can preferably be dismantled in this direction. on the other hand are advantageous no further security measures required to secure the spring element in the wedge drive, except the provision of the locking screw. This spares you not only material costs and manufacturing effort, but also leads to an even more compact design of the Cotter key.

The individual ones preferably slide on one another Wedge drive elements made of a material combination of bronze and hardened steel, especially in combination with a Lubricant, especially a solid lubricant. in this connection are the wear parts that are to be changed more frequently anyway made of soft bronze, the faster wears out as hardened steel, for example. Thereby takes place in the actual wedge drive, i.e. the elements slide guide element, Slider element and driver element over essentially no wear for a long time instead of. Only those on the need to be exchanged Parts provided for sliding surfaces, such as sliding plates etc. Adjusting the guide brackets can be caused by wear increased sliding play can be compensated again. Especially This means that no expensive grinding in is advantageous Renewable wear parts are required more. This condition is extremely important especially for the service life, because a wedge drive is usually extremely high Pressing forces are loaded or operated and thus the Sliding surfaces or sliding plates are exposed to high wear are.

Forced return devices are preferred for preventing the Action of lateral moments on the wedge drive between Driver element and slide element provided. Here is particularly preferably the slide element with the driver element slidably connectable or connected that a lift off from the prismatic part / surface of the driver element essentially only in the starting position is possible. Providing two to each other arranged forced return devices, in particular as brackets between slide element and driver element are executed, even if they occur a jamming or stopping of the wedge drive for one to ensure smooth further operation without the need for lateral Act moments on the wedge drive. Especially with the automatic Stroke rates of 13 to 25 strokes / min are manufactured. achieved, which is why a temporary disruption due to persistence or jamming the wedge drive to an expensive one Would become problem. The fact that the slide element so is used on the driver element that the slide element First of all, a commute to work in the starting position must travel before it from the prismatic surface can be lifted, it is avoided that the slide element in the advanced working position from the driver element can be pulled up, which generally leads to Breakage of the shaping device, in particular a punch, would lead. The forced return device can be formed like a bracket and in a corresponding guide link engage the driver element, wherein they in the slide element preferably in a groove or the like Recess or recess engages. To the appearance to exclude one-sided moments is preferably the Wedge drive in the relevant area, especially that of slide element and driver element, with forced return devices on both sides Mistake.

A fixed surface for producing a reproducible is preferred Starting position of the wedge drive between the slide guide element and slide element provided. For reproducible Adjust the wedge drive, which has an inclined surface has, which over two more sloping sliding surfaces can be moved, the inclined fixed surface can be in one tool between the wedge drive and its receiving element, be chosen as the adjustment surface, a spacer whose Dimensions the desired distance between one in one fixed angle to the sloping surface of the wedge drive and the adjustment surface correspond to the Adjustment surface are placed, and the wedge drive in this Position fixed or fastened in the tool. A such a fixed surface can be an inner surface of the slide guide element be on which the spacer is added and Slider element with spring element can be moved against. The adjustment surface preferably initially serves as reproducible Fixed surface during initial assembly in the tool. As special the fixed surface also proves to be advantageous for constant checking and, if necessary, changing the position of the wedge drive. This may be particularly necessary if the wedge drive keeps moving forward and during operation is retracted, especially if the wedge drive a punch or a mold jaw moves because the wedge drive then always to a reproducible point or one reproducible area can be traced and adjusted can. This makes a reproducible starting position created. This leads to a considerable reduction in workload compared to adjusting a wedge drive, as described in the prior art. The necessary Assembly times for adjusting and assembling the wedge drive can vary by using this method Shorten 80%, which is also a significant amount of cost reduction represents. Another adjustment of slide element and slide guide element with each other does not have to more take place because when using the invention Guide brackets these two elements through their use already adjusted to each other. It occurs here also no additional adjustment effort when using the Guide brackets.

Figur 1

eine Draufsicht auf den erfindungsgemäßen Keiltrieb mit zwei Führungsklammern,

Figur 2

eine Schnittansicht durch den Keiltrieb gemäß Figur 1, worin das Schieberelement auf dem Treiberelement in die Arbeitsposition verfahren ist,

Figur 3

eine Schnittansicht des Keilantriebs gemäß Figur 2, worin das Schieberelement auf dem Treiberelement in der Ausgangsposition ruht,

Figur 4

ein Ablaufdiagramm der Verfahrwegsverhältnisse bei der Bewegung von Schieberführungselement, Schieberelement und Treiberelement gemäß Figur 2 und 3,

Figur 5

eine Schnittansicht durch Schieberelement und Treiberelement mit Zwangsrückholeinrichtungen, und

Figur 6

eine Draufsicht auf Schieberführungselement, teilweise geschnitten, und Treiberelement.

For a more detailed explanation of the invention, the following exemplary embodiments are described in more detail with reference to the drawings. These show in:

Figure 1

a plan view of the wedge drive according to the invention with two guide clips,

Figure 2

2 shows a sectional view through the wedge drive according to FIG. 1, in which the slide element has moved into the working position on the driver element,

Figure 3

3 shows a sectional view of the wedge drive according to FIG. 2, wherein the slide element rests on the driver element in the starting position,

Figure 4

3 shows a flowchart of the travel path relationships during the movement of slide guide element, slide element and driver element according to FIGS. 2 and 3,

Figure 5

a sectional view through slide element and driver element with forced return devices, and

Figure 6

a plan view of slide guide element, partially cut, and driver element.

Figure 1 shows a plan view of a first embodiment of a wedge drive 1 according to the invention Slide guide element 10 and a slide element 20, which are interconnected by two guide brackets 30 are. To move the slide element against the Slide guide element is also a spring element 50 intended. The spring element 50 is embedded in the Slider element and in particular a gas pressure spring. This supports how Figure 2 and 3 can be better seen on the one Side on the slide guide member 10 and the other Side on the slide element 20.

The guide clips 30 each have retaining projections 31 on. The holding projections 31 are each with a bevel 32 provided towards the driver element is directed, which can be better seen in Figure 2. The Bevel is in particular at an angle of 1 ° to Driver element directed. This leads to one too Material expansion secure hold on slide guide element and slide element, a constant running game or Gliding play and thus the possibility of a constant linear parallel displacement of the guide brackets Slide guide element and slide element to occur Compensate for wear and other occurring tolerances can. The holding projections 31 engage in corresponding grooves 11, 21 of slide guide element and slide element a, whereby the guide brackets form-fitting in at least the groove 11 of the slide guide element in the clamp direction sit. For further attachment of the guide brackets to the Slide guide element these are by screws 33 together connected. These can be done either by others Fasteners are replaced or completely eliminated. They preferably stop moving the guide clips to adjust them, as better seen in Figure 2 can be.

For a better sliding of slide element and slide guide element Ensuring each other is between the two Elements inserted a slide plate 12, which means Screws 13 is attached to the slide guide element. Slide guide element and slide element point in the area the guide brackets 30 are essentially the same Wide, making them flat on the outer surfaces of Slider guide element and slider element can rest. Also in the area outside the grooves 11, 21, slide guide elements have Slider element and the outer surfaces of the Guide brackets have a substantially equal width or form an essentially flat surface. Through the Assembly of the two guide brackets on the opposite one another parallel outer surfaces of slide guide element and slide element can even be a very low sliding play or running play of slide guide element and slide element can be achieved against each other, in particular a sliding play of 0.02 mm. This is particularly so also apparent from Figure 2. This figure shows one Sectional view through the wedge drive 1, with the difference to the illustration in FIG. 1 also driver element 40 is shown. In this respect, FIG. 1 represents a top view corresponding to the arrow X. In the representation according to FIG 2 the wedge drive is shown in the working position. Here, the slide element, which has an inclined surface 23 along which it lies against the sliding plate 12, which is also arranged diagonally in the room along the Driver element 40 moved to the working position. In this can, for example, punch or deform a Workpiece are executed, for this purpose on the Page 22 of the slide element 20 a corresponding additional Device is attached. The page 22 and the form inclined surface 23 against which the spring element 50 rests an angle α, for example a value of 40 ° can accept. This angle is dependent on the applied pressing force and depending on the angle chosen for the connection surface to the driver element. He can therefore also assume a value deviating from α = 40 °.

The obliquely arranged spring element 50 is supported on a to the sliding plate 12 substantially vertical inner surface 14 of the slide guide element 10 and is on the opposite side via a bearing plate 51 and a thereon mounted bearing piece 52, which in the slide element is screwed, mounted in the slide element 20. The Spring element serves to slide the slide element back into the Starting position, which is shown in Figure 3 to withdraw. A return force can, for example 800 Newtons, with the pressing force that over Slide guide element exerted on the slide element will be 3 tons. This pressing force is a corresponding drive device, which is not in Figure 2 is shown, on the top 15 of the slide guide element initiated. For this purpose there is a recess 16 and two outer through holes 17 are provided. This can be seen from the top view in FIG. 6. By providing a connection of the slide guide element and slide element by means of the guide brackets 30 and resulting advantage of the possibility of a narrower upper guide part, the slide guide element and the Slider element includes, even larger ones Forces are diverted. For example, at a width of the upper guide part 10, 20 of 80 mm a pressing force from 20 t to 26 t, whereas the stand technology with a width of 140 mm only a deflection of 3 t is possible. In addition, the upper guide part only have a width of 50 mm, for example in order to be integrated into a system, in which there is little space for the wedge drive. This is not possible with the wedge drives of the prior art, provided for these space-intensive screw connections are that require a certain minimum width of the wedge drive.

To replace the spring element, only the bearing plate has to be 51 by loosening the screw provided on it 53 released and the spring element can be removed. this happens preferably from direction X, which is indicated in Figure 2 is. In the same direction, a new spring element inserted and through the bearing plate with the screw 53 be secured again in the slide element.

The driver element 40 can be seen in FIGS. 2 and 3, along the surface of which the slide element is displaced becomes. To secure both elements together, especially to the effect of lateral moments on the entire wedge drive to prevent in this area are bilateral Forced return devices 60 are provided. The forced return devices, as can be better seen in FIG. 5, are bracket-like and both grip the slide element as well in the driver element with appropriate Retaining projections 61. With the slide element they are firmly connected by screws 62. Is in the driver element a driving link 41 is formed, along which the lower holding projection 61 of the respective forced return device 60 is moved by the movement of the slide element. Lifting off the upper guide part, consisting of a slide guide element and slide element from the lower guide part, the driver element 40, is therefore only in the Starting position, namely the position shown in Figure 3 of the slide element possible. Here the lower one Retaining projection of the forced return device 60 the driving backdrop 41 leave, which is why a lifting of the upper guide part from the lower guide part in this position is possible. This advantageously results in damage a deformed on the side 22 of the slide element or punching device avoided in the working position is inserted into a workpiece for machining and in this position if the option is left a direct decrease could be destroyed. The weight loosing of the upper guide part is, for example, when it occurs a malfunction is required to resolve this as soon as possible to be able to fix.

In order after such a possible removal of the upper guide part from the lower guide part again exact positioning and adjustment within the tool To achieve, a fixed surface 2 is preferably in Tool defined on the basis of which an adjustment of the wedge drive during initial assembly and later installation and removal can be done. Both in Figure 2 and in Figure 3 this fixed surface 2 and other lines are indicated that parallel to other slopes, horizontal and vertical Surfaces of the upper and lower guide part of the wedge drive are arranged. The fixed surface 2 is preferably on the Stop surface of the spring element or the slide element. You can in principle also on the opposite Side of the spring element in the slide guide element 10 lie, but then the end of the spring element serves as striking part, not the slide element 20 itself Base area 42 of the driver element is used during operation not shifted in height. Like comparing the Figures 2 and 3 can be seen, however, will Slider guide element during operation with regard to its altitude compared to the horizontal line 3 shifted. The side 22 of the slide element changes during the Operation only their distance to the vertical line 4. In addition, one is parallel to the inclined surface 23 Line 5 formed. The distance of the surface 23 to the line 5 changed preferably not during operation. All Lines 3, 4, 5 meet in a so-called tooling point 6, which is a standardization part. For the first adjustment of the Wedge drive is a not shown in Figures 2 and 3 Used spacer that has parallel walls, whose distance is the distance between an adjustment or Fixed surface 2, and the outer surface 18 of the slide element 20 corresponds in the starting position. The spacer is on the inclined fixed surface 2 with respect to the outer surface 18th created and enables the wedge drive in this position, so parallel to the fixed surface 2 to adjust. Just due to the height of those to be redirected by the wedge drive Forces should be precisely adjusted here.

The travels that occur during the deflection of the forces from the individual components of the wedge drive, are shown in Figure 4. Here, the length a gives the Travel path around which the slide guide element and slide element are shifted against each other, the length b den Travel distance by which the slide guide element is exerted Pressing force moves this vertically in height and the length c indicates the travel by which the slide element is then moved along the driver element. The Travel lengths a, b, c can be chosen arbitrarily, whereby especially another aspect ratio with each other compared to that shown can.

FIG. 5, already mentioned above, shows a top view on the slide element and part of the driver element in the direction of arrow Y according to Figure 2. As already mentioned, slide element and driver element are by the Forced return devices 60 connected. It also works Slider element on a prismatic part 43 of the driver element. On this prismatic part 43 are to be created better sliding properties added sliding plates 24, which is mounted on the underside of the slide element 20 are. The two sliding plates 24 are supported on the two Flanks 44 of the prismatic part 43. The two flanks 44 are arranged at a relatively flat angle to one another, so that there is a relatively large width of Tread results. This allows accurate guidance of the Slider element can be achieved on the driver element. There although the driver element is narrower in the case shown is as the slide element, but this essentially has the same width as the slide guide element, and the slide element symmetrically on the driver element or its prismatic part is seated, no shifts occur the balance of forces on the two flanks 44 on, so that even here a very good smooth running property can be achieved. Lateral thrust can also occur intercepted very well and larger pressing forces very well also be recorded in the vertical direction. by virtue of the provision of the two guide brackets on both sides of slide guide element and slide element and the Spring element centered in the body of the slide element can those introduced into the slide guide element Pressing forces evenly distributed over the entire wedge drive be, so that the running accuracy and smoothness when Moving the slide element on the prismatic part of the driver element can be optimized.

Because the side forces that act on the wedge drive Can hinder or at least worsen moving, are the fixed surface 2 in another embodiment and / or the opposite surface 19 is designed as a prism. Such a prism is particularly good at higher ones Absorb forces. In addition, the other sliding surfaces, in particular sliding surface 18 and surface 23, prismatic Have shape.

A possible impression of the proportions of the slide guide element and driver element can the cut Top view can be seen in Figure 6. Here is in the upper Part of the slide guide element and in the lower part Top view of the driver element can be seen. The one in this Figure indicated section A-A is in Figures 2 and 3 shown.

The surfaces running on one another preferably consist of a material combination of a hard and a soft Material, especially from a combination of softer Bronze and hardened steel, preferably between a lubricant on both surfaces, especially a grease or solid lubricant is used, especially oil and Graphite. Since the wear parts made of soft bronze or should be made of a soft material, the sliding plates 18, 24 made of this material, however Driver element and slide element preferably made of hardened Steel. The guide clips 30 preferably also exist made of bronze, especially to give a good grip enable and on the other hand a desired adjustability to provide, if necessary, the sliding play again accordingly adjust.

In addition to those shown and described in the previous figures Embodiments are numerous others Embodiments of wedge drives possible, each of which the upper guide part, in particular containing slide guide element and slide element, by means of guide clips is held together. The arrangement and other physical Formation of the wedge drive can be chosen as long as thereby the advantages that the connection of its Elements of the upper guide part by means of guide brackets does not get lost. For example the slide guide element also by a horizontal Pressing force are actuated, the slide element then is moved vertically. Providence also proves here of the guide brackets as advantageous. They can do this however, a different orientation in space and a different one Have shape, preferably on the respective Individual case is adjusted. Guide brackets can thus be independent of the other design and position of the Wedge drive can be provided. They don't just allow one special stability of the wedge drive, but also a small one Design, high running accuracy and the recording and generation high press forces. In addition, these wedge drives with guide brackets inexpensive to produce, in particular no reworking as with the prior art for adjustment purposes What is required is what is regular in the prior art with numerous extensions and installations of the wedge drive and its Individual parts, such as slide guide element and slide element, connected is.

1

Keiltrieb

2

Fixfläche

3

waagerechte Linie

4

senkrechte Linie

5

schräge Linie

6

Tooling-Punkt

10

Schieberführungselement

11

Nut

12

Gleitplatte

13

Schraube

14

Innenseite

15

Oberseite

16

Ausnehmung

17

Durchgangsbohrung

18

Gleitfläche

19

Fläche

20

Schieberelement

21

Nut

22

Seite

23

schräge Fläche

24

Gleitplatte

30

Führungsklammer

31

Haltevorsprünge

32

Anschrägung

33

Schraube

40

Treiberelement

41

Fahrkulisse

42

Grundfläche

43

prismatischer Teil

44

Flanken

50

Federelement

51

Lagerplatte

52

Lagerstück

53

Sicherungsschraube

60

Zwangsrückholeinrichtung

61

Haltevorsprung

62

Schraube

α

Winkel im Schieberelement

a

Verfahrweg

b

Verfahrweg

c

Verfahrweg

LIST OF REFERENCE NUMBERS

1

cotter

2

Fixfläche

3

horizontal line

4

vertical line

5

oblique line

6

Tooling point

10

Cam guiding element

11

groove

12

sliding plate

13

screw

14

inside

15

top

16

recess

17

Through Hole

18

sliding surface

19

area

20

slide element

21

groove

22

page

23

sloping surface

24

sliding plate

30

guide bracket

31

retaining projections

32

bevel

33

screw

40

driving element

41

driving backdrop

42

Floor space

43

prismatic part

44

flanks

50

spring element

51

bearing plate

52

stock items

53

locking screw

60

positive-

61

retaining projection

62

screw

α

Angle in the slide element

a

traverse

b

traverse

c

traverse

Claims (15)

Wedge drive with an upper guide part containing a slide element (20) and a slide guide element (10) and a lower guide part containing a driver element (40),
characterized in that
the upper guide part (10, 20) can be held together and / or held together by at least one guide clip (30). Wedge drive according to claim 1,
characterized in that
which connects at least one guide bracket (30) slide element (20) and slide guide element (10). Wedge drive according to claim 1 or 2,
characterized in that
the guide clip / guide clips (30) can be positively engaged or engages in the slide guide element (10) and / or the slide element (20). Wedge drive according to one of the preceding claims,
characterized in that
which has at least one guide clip (30) holding projections (31), by means of which it engages in a part (11) of the slide guide element (10), the holding projections having a bevel (32). Wedge drive according to claim 4,
characterized in that
the retaining projections (31) have a slight bevel (32), in particular a bevel of essentially 1 ° in the direction of the driver element (40). Wedge drive according to claim 4 or 5,
characterized in that
a linear adjustment of the guide play and / or an adjustment of the sliding play between the upper (10, 20) and lower guide part (40) is provided by the guide clamp / guide clamps (30), in particular guide clamp / guide clamps (30) and the upper guide part (10, 20) are so interlocking that a linear displacement of the guide bracket / guide brackets in the stroke direction of the wedge drive (1) leads to a change in the guide play transverse to the direction of action of the driver element (40) with essentially the same linearity of the guide play. Wedge drive according to one of the preceding claims,
characterized in that
the slide element (20) and the slide guide element (10) have essentially the same width and in particular essentially parallel surfaces, to which the at least one guide clip (30) can be fastened. Wedge drive according to one of the preceding claims,
characterized in that
the lower and / or guide part (10, 20, 40) has a prismatic part (43) and / or at least one prismatic surface for guiding the slide element (20) and / or for absorbing lateral forces in order to produce high running accuracy. Wedge drive according to one of the preceding claims,
characterized in that
the wedge drive (1) has a substantially uniform width over its entire width. Wedge drive according to one of the preceding claims,
characterized in that
one or more fixed surfaces (2) for generating a reproducible starting position of the wedge drive between the slide guide element and slide element is or are provided. Wedge drive according to one of the preceding claims,
characterized in that
a spring element (50), in particular a gas pressure spring, is provided for retrieving the slide element (20), which is secured in the slide element by means of a securing element, in particular a securing screw (53), and can be removed therefrom. Wedge drive according to one of the preceding claims,
characterized in that
the individual elements sliding on one another consist of a pair of materials bronze and hardened steel, in particular in combination with a lubricant, in particular a solid lubricant. Wedge drive according to one of the preceding claims,
characterized in that
Forced return devices (60) are provided to prevent lateral moments from acting on the wedge drive between the driver element (40) and slide element (20). Wedge drive according to claim 13,
characterized in that
the slide element (20) is slidably connectable or connected to the driver element (40) in such a way that lifting off the prismatic part (43) is essentially only possible in the starting position. Method for reproducibly adjusting a wedge drive (1), in particular according to one of the preceding claims, with an inclined surface (23), which can be moved back and forth over two further inclined sliding surfaces (18, 44), in one tool,
characterized in that an inclined fixed surface (2) between the wedge drive (1) and its inclusion in the tool is selected as the adjustment surface, a spacer, the dimensions of which correspond to the desired distance between an inclined surface (19) of the wedge drive which is at a fixed angle to the inclined surface (23) and the adjustment surface (2), is placed on the adjustment surface, and the wedge drive (1) is fixed in this position or fastened in the tool.

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