EP0102519A1 - Paving stone or brick splitting device - Google Patents

Abstract

1. Paving-stone-splitting and brick-splitting device having an upper tool (10) which is driven in oscillating manner in a frame (12) and which interacts with a lower tool (16), with the upper tool (10) being driven hydraulically and the upper and lower tool in each cas comprising several individual splitting wedges (38 and 40) respectively) which can be moved relative to one another in the splitting direction and which are preferably supported hydraulically, a worktable (14) which is movably supported in resilient manner in the splitting direction in the frame (12) and which has a slot-shaped opening for the passage of the lower tool (16), in such a way that the worktable (14) moves downwards when the stone material is being split and moves upwards again after the splitting in accordance with the return movement of the upper tool (10) into its upper initial position, so that the lower tool (16) is located beneath the working surface of the worktable (14), and having a hydraulic control appliance (35) which, for displacing the upper tool (10), is connected before the hydraulic operating cylinder (22) allocated to the upper tools (10), and with which the pressure medium which is used for the feed of the upper tool (10) can be supplied in vibrating or pulsating manner to the feed side of the operating piston (23) allocated to the upper tool (10).

Description

The invention relates to a paving and brick splitting device according to the preamble of claim 1.

From US-PS 4 203 414 a paving and masonry splitting device is known with an oscillatingly driven upper tool in a frame, which interacts with a lower tool, the upper and lower tools each comprising a plurality of individual splitting wedges which can be moved relative to one another in the splitting direction are hydraulically supported. The upper tool is fed hydraulically. The known device has an extremely complicated positioning device for the rock to be split between the upper and lower splitting wedges. The positioning device comprises stationary fingers, vertically and horizontally movable fingers and lateral centering devices. The positioning fingers are used to lift the incoming rock slightly and to carry it between the lower and upper riving knife. Such a measure is also necessary in the known device since a work table serving as an abutment is missing. For this reason, the lateral centering device is also required.

The interaction between the various positioning fingers and the side centering device only allow a limited working speed. There is also the risk that after each splitting process the split rocks fall uncontrollably from the positioning fingers onto the floor and possibly injure an operator. There is also no guarantee that the rock to be split will be held in the desired position on the positioning fingers. Bad splits and splinters cannot be excluded.

To avoid these disadvantages, the inventor in the older German patent ... (German patent application P 31 19 693.4-25) proposed to arrange a flexible work table with a slot-shaped opening for the passage of the lower tool within the splitting device Support of the work table via hydraulically, pneumatically or hydro-pneumatically controlled piston-cylinder units should take place in such a way that the work table moves downwards when the stone material is split and after the split the upper tool moves back into its upper starting position in accordance with the return movement , so that the lower tool is under the work surface of the work table.

From US Pat. No. 3,161,190, it is known per se in a manually operated seal breaking device to provide a spring-supported work table which has a slot-shaped passage for a lower splitting or breaking tool. However, this known device is only suitable for relatively easy to split material. At Splitting forces of approx. 35 to 50 p, such as occur when splitting granite, the resilient support of the work table would be unsuitable, even dangerous. The elasticity of the compression springs that is released after splitting would result in rock being thrown up or thrown away, resulting in an increased risk of injury to the operating personnel.

In addition, the resilient support of the work table is disadvantageous for very non-uniform stones, since the table then assumes an undesired inclined position due to the corresponding non-uniform load, which leads to an undesirable fractured surface.

Compared to the prior art, the proposal described in the German patent ... (German patent application P 31 19 693.4-25) is extremely convenient and safe to use. By arranging a flat work table above the lower tool, the rock to be split can be positioned well and securely between the upper and lower tools.

• - der Form des zu spaltenden Gesteins und
• - des Gewichts bzw. der Gewichtsverteilung des zu spaltenden Gesteins.

However, the proposed support of the work table is of great importance. Thanks to the forced control of the up and down movement of the work table, a controlled splitting process is achieved independently of

• - the shape of the rock to be split and
• - The weight or the weight distribution of the rock to be split.

A controlled, parallel lowering of the work table during the splitting process is ensured even with very irregularly shaped and thus unevenly weighted rock. The desired fracture surface is ensured. The controlled lowering of the work table is also independent of the weight of the stone to be split. With very different stone weights, for example, a mere deactivation of the hydraulic support ele Mente lead to the risk that the table sinks prematurely with very heavy stones, the stone to be split tilts to one side over the lower tool and thus an uncontrolled splitting process takes place.

Finally, the proposed support of the work table prevents elasticities from being released after splitting, which result in the throwing up of rocks and thus an increased risk of injury to the operator.

The present invention is based on the object of additionally increasing the splitting power of the splitting device described in the German patent ... (German patent application P 31 19 693.4-25) while maintaining the advantages of the proposed splitting device.

With regard to the solution of this problem, reference is made to the claims.

In-house experiments by the inventor have shown that the measures according to claims 1 to 5 enable extremely precise fracture surfaces to be achieved with a relatively low initial pressure for the advance of the upper tool, and the fracture times can also be considerably reduced as a result. Particularly high splitting powers are obtained when the pressure medium pulsation is in the resonance range of the rock to be split. Preferably the pressure medium frequency can be varied, e.g. in the structural embodiment according to claim 2 by changing the speed of the rotary piston drive.

The device according to claims 6 to 14, possibly in combination with the measures according to claims 1 to 5, is preferably suitable for breaking up very large pieces of rock, the device preferably being part of an automatically operating stone crushing line the crushing line according to FIG. 2 of US Pat. No. 4,203,414.

The device according to claims 6 to 14 is characterized by an extremely high directional stability, in particular of the oscillating upper tools, and thus a high gap precision. The rough adaptation to the structure of the top of the stone to be split takes place by means of the upper tools arranged next to one another and displaceable relative to one another in the splitting direction; the fine adjustment by means of the individual riving knives that can be moved relative to each other in the splitting direction in each upper tool. The adaptation of the upper tools and the individual riving knife assigned to them takes place spontaneously according to the invention, with regard to the constructive solution for the spontaneous adaptation of the individual riving knife to different surface structures of the stones to be split to the German patent ... (German patent application P 31 19 694.2- 25) is referred to, the content of which is expressly explained in relation to the disclosure content of this application.

• Fig. la einen hydraulischen Schaltplan für den hydraulischen Antrieb des bzw. der Oberwerkzeuge einer Spaltvorrichtung mit hydraulisch abgestütztem Arbeitstisch,
• Fig. lb ein den den Oberwerkzeugen der Spaltvorrichtung zugeordneten Arbeitszylindern vorgeschaltetes Steuergerät zur Erzeugung einer vibrierenden Verstellung der Oberwerkzeuge in Spaltrichtung im Längsschnitt,
• Fig. lc das Steuergerät nach Fig. lb im Querschnitt,
• Fig. 2 einen Teil einer Mehrfach-Spaltvorrichtung in Frontansicht, und
• Fig. 3 die Spaltvorrichtung gemäß Fig. 2 im Schnitt längs Linie 111-111 in Fig. 2.

A preferred embodiment of the splitting device according to the invention is described below with reference to the accompanying drawing. Show it:

• La is a hydraulic circuit diagram for the hydraulic drive of the upper tool or tools of a splitting device with a hydraulically supported work table,
• 1b shows a control device connected upstream of the working cylinders assigned to the upper tools of the splitting device for producing a vibrating adjustment of the upper tools in the splitting direction in longitudinal section,
• 1c the cross-section of the control device according to FIG.
• Fig. 2 shows a part of a multiple splitting device in front view, and
• 3 shows the splitting device according to FIG. 2 in section along line 111-111 in FIG. 2.

The splitting device shown schematically in Figures 2 and 3 consists of a portal frame 12 with upper and lower cross members 28 and 30, which are designed as truss girders. The frame 12 is a welded construction of a conventional type.

Upper and lower tools 10 and 16, which are assigned to one another, are arranged next to one another on the upper and lower cross members, with only the upper tools 10 being able to oscillate back and forth in the illustrated embodiment, or being movable toward and away from the stationary arranged lower tools 16 . The upper tools each have a common linear bearing 18 on the sides facing each other, each consisting of an upright or extending in the gap direction guide profile 24 attached to the underside of the upper crossmember 28, the guide strips or guide bars arranged on the mutually facing sides of adjacent upper tools 10 plates 26, 26 'cooperate. the guide profile 24 is in the present case by two with their open sides facing U-profile sections 32, 32 ', so that the associated, in the U-profile sections 32, 32' with clearance fit guide strips or plates 26, 26 ' support each other on their facing sides, preferably slide directly against each other (Fig. 2).

The outer sides of the respective outer upper tools 10 are slidably mounted in longitudinal guides 20 attached to the frame 12, these longitudinal guides being designed in a manner corresponding to the linear bearings 18. When executing 2, the two longitudinal guides 20 have laterally outwardly open U-profile sections 34, into which guide strips or guide plates 25, which are arranged on the outer sides of the outermost outer tools, project with a clearance fit. The length of the linear bearings 18 and lateral longitudinal guides 20 corresponds approximately to the maximum displacement distance of the upper tool 10. In this way, sufficient stability is ensured even when the upper tool is fully extended.

In a departure from the illustrated embodiment, the common linear bearing can also be arranged by interlocking guide elements, e.g., arranged on the mutually facing sides of adjacent upper tools 10, e.g. Dovetail guide or T-guide - which, in any conceivable relative position of the upper tools 10 to one another, engage with one another over a length of at least one third of the maximum displacement distance of the upper tools in order to ensure sufficient stability of the upper tools on all sides, even on strongly inclined surfaces of the stones to be split.

The upper tools 10 are each attached to the underside of a piston rod 21 which is assigned to a working piston 23 (FIG. 1) which can be pushed back and forth in the working cylinder 22. Each upper tool 10 can be moved up and down individually or together, whereby between the individual! Working cylinders 22 have a fluid connection, so that the upper tools can adapt spontaneously to the surface of the top of the stone to be split. If necessary, individual upper tools can be deactivated by decoupling them from the hydraulic drive.

A correspondingly designed lower tool 16 is assigned to the upper tools 10 that can be moved up and down is arranged below a work table 14. In the area of the lower tool 16, the work table 14 has a slot-shaped opening 36 (FIG. 3). The work table is supported on the frame 12 by means of hydraulically controlled piston-cylinder units. When a stone pushed into the area between the upper tools 10 and the lower tools 16, the hydraulic support units are deactivated, as a result of which the work table is moved downward by the pressure exerted on the stone by the upper tools 10, so that the lower tools 16 pass through the Slots 36 in the work table 14 can be effective. With regard to the control of the up and down movement of the work table, reference is also made to the German patent ... (German patent application P 31 19 693.4-25).

The upper and lower tools assigned to one another each have individual riving wedges 38 and 40 which are movable relative to one another in the splitting direction and are preferably hydraulically supported. This enables the splitting tools to be optimally adapted to rough, uneven stone surfaces. The individual riving knives are slidably mounted in a common cylinder body, which is part of the upper or lower tool, in the splitting direction or direction of action of the splitting tool, the cylinder spaces associated with the individual riving knives and preferably filled with oil being fluidly connected to one another. With regard to the structural design of the fluid connection and of the upper and lower tools, reference is made to the already mentioned German patent ... (German patent application P 31 19 694.2-25).

The lowering movement of the work table 14 inevitably takes place in time with the upper tools 10 which can be moved vertically up and down, such that the work table 14 is raised when the upper tools 10 are returned. The stone material can then easily be moved on the table top and positio be kidneyed. Because of this kinematics, the device according to the invention can also be coupled very well with an automatic stone material feed, this stone feed preferably working in the same cycle as the upper tools.

The hydraulic drive of the upper tools will be discussed in more detail below. It should be mentioned in advance, however, that the hydraulic drive of the upper tools 10 is designed so that when a predetermined reaction force acting on them in the direction of the upper tools is exceeded, i. give way up or dodge. The hydraulic system can preferably also be designed such that, in the event of a sudden increase in pressure, the immediate return stroke movement of the upper tools is initiated, specifically individually, i.e. of those upper tools that are affected by an excessive reaction force. This measure largely prevents the tool cutting of the upper and lower tools from breaking if the reaction forces are too great (overload protection). Constructively, the above problem can be solved in the event of a common return stroke of the upper tools 10 in the event of an overload in that a hydraulic valve is provided in the derivation of the piston-cylinder unit (hydraulic cylinder 22) assigned to at least one upper tool 10, which is used for the return stroke of the upper tools 10 can be brought into a reverse position, the switchover taking place as a function of the pressure prevailing in the hydraulic system (pressure switch possibly with electrical signal conversion).

In general, it should also be said about the hydraulic control unit that the positioning movement of the upper tools 10 preferably takes place in the low pressure range and only the actual splitting work in the high pressure range up to approximately 500 bar, while the return stroke movement of the upper tools generally takes place in the low pressure range. Likewise, the work table 14 is raised after the splitting process also by low pressure (coupling with the drive hydraulics for the upper tools).

The hydraulic system is also designed so that if the pressure suddenly drops, the return stroke movement of the upper tools 10 is also initiated. A sudden drop in pressure means that the stone material is broken or that there is a defect in the hydraulic system.

The guide plates 26, 26 'and 25 as well as the associated guide profiles 20, 24 consist of wear-resistant material, preferably sintered material with a self-lubricating effect. Furthermore, the guide profiles 24 and longitudinal guides 20 are preferably composed of a plurality of plates and strips such that, depending on the wear of one or the other part of the guide profile or the longitudinal guide, can be selectively replaced. The U-profile sections 32, 32 'and 34 are thus formed by three elongate plates which are independently fastened or screwed to frames 12 (at the lower ends of fastening brackets 58 arranged on the underside of the upper cross member 28).

The embodiment of the hydraulic drive for the upper tools and the work table 14 is explained in more detail below with reference to FIGS.

In order to adjust the working pistons 23 in the working cylinders 22 assigned to the upper tools 10, the working cylinders 22 are preferably preceded by a hydraulic control device 35, the function of which will be explained in more detail below with reference to FIGS. 1 a to 1 c. The hydraulic control unit 35 is intended to ensure that the pressure medium used to advance the working piston 23 vibrates into the working cylinder 22, of which only one is shown in FIG. 1 a, on the sides of the working piston facing away from the upper tools 10 or is introduced. According to FIGS. 1b and 1c, the control unit 35 comprises a rotary piston 39 which is rotatably mounted in a control housing 37 and can be connected to an external rotary drive (not shown), the connection being identified by the reference number 61 in FIG. 1b.

The control housing 37 has a pressure medium inlet 33 which is divided into three inlet channels 41, 42 and 43. These three inlet channels each communicate with an annular groove 44, 45 and 46 along the circumference of the rotary piston 39. The annular grooves 44, 45 and 46 each have four lateral recesses 44 ', 44 ", 44"', 44 arranged uniformly distributed along the circumference "" or 45 ', 45 ", 45"', 45 "" or 46 ', 46 ", 46"', 46 "", through which a pulsating fluid connection between the annular grooves 44, 45, 46 with the pressure medium outlet 47 leading outlet channels 53, 54, 55 can be produced. Each annular groove 44, 45, 46, as shown and as can be seen very well in FIG. 1c, is assigned four lateral recesses arranged uniformly distributed over the circumference, the recesses of the individual annular grooves being offset from one another in such a way that the angular distance between all the recesses is the same is. In this way, in the embodiment according to FIGS. 1b and 1c, the pressure medium flow is divided into twelve partial flows when the rotary piston 39 rotates. With one revolution of the rotary piston 39, 12 pressure pulses are thus obtained at the pressure medium outlet 47.

According to Fig. La, the hydraulic control unit (pulse generator) 35 is arranged so that the pressure medium outlet 47 is fluidly connected to the cylinder spaces 48 opposite the piston rods of the working pistons 23. The pressure medium inlet 33 of the control device or pulse generator 35 is fluidly connected via a line 62 to the high-pressure part 64 of a hydraulic pump 66. The control device 35 can be bypassed by a by-pass line 67, in which a pressure-controlled valve 68 is arranged.

The working pistons in the working cylinders 22 can be acted on from both sides, the cylinder spaces 49 respectively assigned to the piston rod 21 and the upper tool 10 being connected via a line 69 to the low-pressure part 63 of the pressure medium pump 66 or, depending on the circuitry, of a multi-way valve 71 arranged in this line Pressure medium reservoir 70 are fluidly connectable.

A further line 72 opens into the cylinder chambers 49 facing away from the piston rod 21 and is connected directly to the reservoir 70 via a hydraulically switched check valve 73. The line 62 arranged parallel to it can also be fluidly connected directly to the reservoir 70 via a hydraulically switched check valve 74, the hydraulically switched check valve 74 and the line 62 connected to the high pressure part 64 of the pressure medium pump 66 being arranged.

Between the high-pressure line 62 and the aforementioned connecting line 75 leading to the reservoir 70, two further fluid connections are provided, one safety valve 46 and one switching valve 77 being arranged in the one, which is closed in the high-pressure phase and in the low-pressure phase is opened. _D a-mit can continue to work unchanged in the low pressure phase of the high pressure part 64 of the pressure medium pump 66. The pressure medium under high pressure is then pumped back directly into the reservoir via the switching valve 77. The safety valve 76 opens at 400 bar.

The portion of the line 69 lying between the multi-way valve 71 and the low-pressure part 63 of the pressure medium pump 66 can be fluidly connected directly to the reservoir '70 via a line 78, a pressure-controlled valve 79 being arranged in the connecting line 78 in such a way that during the High pressure phase is opened. Then can rend the high pressure phase, ie when the working piston 23 or the piston rods 21 or the upper tools 10 attached to them in the direction of arrow P, the low pressure part 63 of the pressure medium pump 66 continues to work unchanged. The low pressure pressure medium is then pumped back directly into the reservoir 70 via the line 78.

Measuring points M1 and M2 are provided in the low-pressure line 69 and high-pressure line 62 for determining defects in the hydraulics. At low pressure, the working pressure is about 30 bar, while the operating pressure is preferably 350 bar.

The functioning of the hydraulics is now as follows: when the working pistons 23 or the piston rods 21 or the upper tools 10 attached to them are pulsating, the switching valves 68 and 77 are closed while the valve 79 is open. Furthermore, the drive of the rotary piston of the control unit 35 is in operation. The multi-way valve 71 is switched so that the low-pressure line 69 is connected to the reservoir 70 via the line 75. High-pressure pressure medium is then introduced through the high-pressure part 64 of the pressure medium pump 66 via the high pressure line 62 into the pressure medium inlet 33 of the control unit 35. It arrives pulsating from the pressure medium outlet 47 of the control device 35 into the working cylinders 22 in each case on the sides of the working pistons 23 facing away from the piston rods 21 or upper tools 10. The working pistons 23 are then moved pulsating in the direction of the arrow P. The pressure medium located on the other side of the working piston 23 is discharged into the reservoir 70 via the low pressure line 69, the multi-way valve 71 and the connecting line 75. If the pressure in the high-pressure line 62 becomes too high, the safety valve 76 opens and creates a direct connection to the reservoir 70.

If the upper tools 10 or the piston rods 21 or working pistons 23 assigned to them are to be moved back into their upper starting position, the valves 68 and 77 are opened and the valve 79 is closed. The high-pressure pressure medium passes directly through the switching valve 77 back into the reservoir 70. The multi-way valve 71 is simultaneously switched so that the low-pressure line 69 coming from the low-pressure part 63 of the pressure medium pump 66 is in fluid communication with the parts 49 of the working cylinders 22 facing the piston rods 21 stands so that the working piston 23 can be moved back with low pressure. Since the return movement is to take place very quickly, the pressure medium must be able to escape quickly from the working cylinders 22 on the sides facing away from the piston rods 21. This takes place via the by _- pass line 67 and the additional line 72, the check valves 73, 74 each being opened hydraulically. Via the two lines 67, 72 and the line 75 leading to the reservoir, the pressure medium on the sides facing away from the piston rods 21 can be discharged very quickly from the working cylinders 22.

During the return stroke of the upper tools 10 or the working pistons 23 assigned to them, the drive for the rotary piston of the control unit 35 is switched off.

In order to avoid that the low-pressure part 63 of the pressure medium pump 66 is inadvertently subjected to high pressure when the safety valve 76 is opened via the multi-way valve 71 and the low-pressure line 69, a check valve 78 is arranged in the latter, which ensures a backflow in the low-pressure line 69 to the low-pressure part 63 the pressure medium pump 66 prevented.

A connecting line 51 to the hydraulic support units 50 of FIG. 1 is also connected to the low-pressure line 69 between the multi-way valve 71 and the working cylinders 22

Fig. La only schematically shown work table 14 connected. A pressure-controlled valve 52 is arranged in this connecting line 51, which allows the work table 14 to be lowered in a controlled manner in the direction of the arrow A during the high pressure phase, that is to say when the upper tools 10 move in the direction of the arrow P. The valve 52 thus serves as a throttle for the backflow of pressure medium from the hydraulic support units 50 into the reservoir 70 via the multi-way valve 71 and the connecting line 75. In the reverse direction of flow, that is to say in the low-pressure phase, the valve 52 acts as a barrier. The low-pressure pressure medium then flows bypassing the valve 52 via a by-pass line 56 and a check valve 57 back into the hydraulic support units 50, as a result of which the work table 14 is raised back to its starting position in the direction of the arrow A. The Lifting the work table 14 and the return movement of the upper tools 10 into their upper starting position are thus carried out synchronously.

A measuring point M3 is also provided in the connecting line 51 for determining any defects.

As stated at the beginning, the throttling action of the valve 52 assigned to the hydraulic support units 50 can preferably be varied, in particular as a function of the high pressure acting on the working piston 23. This ensures that when switching to the high-pressure phase, the work table 14 does not suddenly fall off, so that the stone to be split tilts uncontrollably before the action of the upper tool or tools 10 over the cutting edge or cutting of the lower tools, as a result of which undesirable fractured surfaces would be obtained.

All features disclosed in the documents are claimed as essential to the invention, insofar as they are new compared to the prior art, individually or in combination.

Claims (14)

1. paving and masonry splitting device with an upper tool oscillatingly driven in a frame, which interacts with a lower tool, the upper tool being driven hydraulically and the upper and lower tools each comprising a plurality of individual splitting wedges which can be moved relative to one another in the splitting direction, preferably hydraulically are supported, and with a flexibly supported in the frame in the splitting direction supported work table with a slit-shaped opening for the passage of the lower tool such that the work table when splitting the stone material down and after splitting itself in accordance with the return movement of the upper tool in its upper starting position moved upwards so that the lower tool lies under the work surface of the work table,
characterized in that for adjusting the upper tool (10) the associated hydraulic working cylinder (22) a hy draulic control device (35) can be connected upstream, by means of which the pressure medium serving to advance the upper tool (10) or the working piston (23) associated therewith can be supplied in a vibrating or pulsating manner. 2. Apparatus according to claim 1, characterized in that the control device (35) comprises a rotary piston (39) rotatably mounted in a control housing (37) which can be coupled to an external rotary drive. 3. Apparatus according to claim 1 or 2, characterized in that the control housing (37) of the control device (35) has a pressure medium inlet (33) and a pressure medium outlet (47), the pressure medium inlet (33) in at least two inlet channels (41, 42 , 43) that these inlet channels each communicate with an annular groove (44, 45, 46) arranged on the circumference of the rotary piston (39), and that the annular grooves each have at least one lateral recess (44 ', 44 ", 44"' , 44 "" or 45 ', 45 ", 45"', 45 "" or 46 ', 46 ", 46"', 46 ""), via which a fluid connection with outlet channels leading to the pressure medium outlet (47) ( 53, 54, 55) can be produced. 4. Device according to one of claims 1 to 3, characterized in that the control device (35) can be optionally switched on. 5. Device according to one of claims 1 to 4, characterized in that the work table (14) via hydraulically, pneumatically or hydro-pneumatically controlled piston-cylinder units (50) on the frame (12) is supported, wherein the support from the Vibrating adjustment of the upper tool (10) in the working or splitting direction (P) is unstable is flowing, ie the work table (14) moves continuously downward even when the upper tool (10) vibrates on the rock to be split, but when the upper tool (10) is reset, it raises the work table (14) synchronously with it. 6. The device, in particular according to one of claims 1 to 5, characterized in that in the frame (12) at least two mutually associated upper (10) and lower (16) tools are arranged side by side, the upper tools (10) to the sides facing each other each have a common linear bearing (18). 7. The device according to claim 6, characterized in that the common linear bearing (18) by an between adjacent upper tools (10) on the frame (12) attached upright guide element (24) is formed, with complementary guide elements (guide strips or plates 26th , 26 ') cooperates on the mutually facing sides of the upper tools (10). 8. The device according to claim 7, characterized in that the guide element (24) attached to the frame (12) is an upright or in the working direction (P) of the upper tools (10) extending guide profile (U-profile sections 32, 32 'or hollow profile) is engaged in the upper tools (10) which are arranged on the sides facing one another and which also extend in the working direction (P) and have guide fits (guide plates 26, 26 '). 9. The device according to claim 8, characterized in that the guide strips (26, 26 ') on their mutually facing sides support each other, preferably sliding directly against each other. 10. Device according to one of claims 6 to 9, characterized in that the outer sides of the respective outer upper tools (10) in the frame (12) fixed longitudinal guides (20) are slidably mounted. 11. The device according to claim 10, characterized in that the longitudinal guides (20) corresponding to the between adjacent upper tools (10) arranged linear bearings (18) are formed and with on the outer sides of the upper tools (10) arranged complementary guide elements (guide strips or - plates 25) work together. 12. Device according to one of claims 6 to 11, characterized in that the common linear bearings (18) and possibly lateral longitudinal guides (20) forming guide profiles (32, 32 'and 34) on the upper cross member (28) of the preferably as a portal frame trained frame (12) are attached such that they are always effective over at least a third of the maximum displacement distance of the upper tool or tools, ie are in engagement with the complementary guide elements arranged on the upper tools. 13. Device according to one of claims 1 to 12, characterized in that the frame (12) in addition to the upper cross member (28) also comprises a lower cross member (30) on which the lower tools (16) are attached and the work table (14) is mounted, and that both the upper and the lower cross member are each designed as a truss. 14. The apparatus according to claim 6, characterized in that the common linear bearing (18) arranged on the mutually facing sides of adjacent upper tools (10), extending in the working direction (P) of the upper tools (10), interlocking guide elements (eg dovetail guide or T-guide) is formed, which are in engagement with each other at every conceivable relative position of the upper tools (10) over a length of at least one third of the maximum displacement distance of the upper tools.

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