DE102013214150B4 - Machine tool and machine bed for a machine tool - Google Patents

Abstract

A machine tool with a machine bed (1 '), which has a plurality of erecting elements (3, 3') which are provided on a lower side (2) of the machine bed (1 '), comprises: first set-up elements (3) whose relative Alignment with respect to the underside (2) of the machine bed (1 ') fixed during operation of the machine tool, and whose inherent rigidity is constant; and second set-up elements (3 '), which are configured adjustable in height relative to the underside (2) of the machine bed (1'), and whose inherent rigidity is adjustable.

Description

The invention relates to a machine tool and a machine bed for use in a machine tool.

Machine tools usually have three or more mounting elements, which are arranged on a lower side of a machine bed of the machine tool. When the machine tool is placed on the floor of a workshop, the entire weight of the machine tool rests on the erection elements, since these represent the only load-bearing connection elements between the machine bed and the floor. If the number of set-up elements is three ("three-point installation"), and the three set-up elements are triangular, there is the advantage that the machine bed of the machine tool does not deform or deform only slightly when installed on uneven ground. When using the three-point installation thus the working accuracy of the machine tool does not depend or only to a very small extent on the flatness of the soil. This makes it possible to spend a machine tool with three-point installation from one installation site to another installation location, without a new adjustment of the installation elements would be absolutely necessary. An advantage of this is in particular that no or only low requirements must be placed on the flatness of the soil in order to ensure a sufficient working accuracy or long-term stability of the machine tool.

A disadvantage of the three-point list, however, is that vibrations or vibrations of the machine tool, such as chatter vibrations, which can result, inter alia, in a heavy cutting, often can not be sufficiently damped by the erection elements.

DE 102 29 823 A1 shows a method for determining at least one coordinate of a structure in the measurement volume of a coordinate measuring machine mounted on variable tilt supports, comprising the steps of: detecting a measured value for the at least one coordinate, detecting a value for the inclination of the coordinate measuring machine. DE 102 29 823 A1 includes, as a further step, a correction of the measured value for the at least one coordinate as a function of the detected value for the inclination of the coordinate measuring machine.

The object underlying the invention is to design the machine tool in such a way that the working accuracy of the machine tool depends as little as possible on the accuracy of the installation (for example due to an uneven floor or an inaccurate adjustment of the installation elements), on the other hand vibrations or vibrations of the machine bed Machine tool can be damped as much as possible during operation.

To solve the problem, the invention provides a machine bed according to claims 1 and 9 and a machine tool according to claim 19 ready. Advantageous embodiments or developments of the inventive concept can be found in the subclaims.

According to one embodiment of the invention, a machine bed for a machine tool is provided, wherein the machine bed has a plurality of mounting elements, which are provided on an underside of the machine bed. The machine bed has first set-up elements whose relative orientation with respect to the underside of the machine bed is fixed during operation of the machine tool. This means, in particular, that the relative positions of the ends of the first set-up elements (adjustment position) facing away from the underside of the machine bed with respect to the underside of the machine bed are immutable during operation of the machine tool. The first set-up elements allow a defined height adjustment of the machine bed with respect to the ground due to their static inherent rigidity and the rigid attachment to the machine bed during operation of the machine tool. Furthermore, the machine bed on second set-up, which are configured infinitely adjustable in height, d. H. their relative orientation with respect to the underside of the machine bed is changeable. This means, in particular, that the relative positions of the ends of the second set-up elements (adjustment position) facing away from the underside of the machine bed are infinitely adjustable with respect to the underside of the machine bed. The static inherent rigidity of the second erection elements is adjustable.

In order to stabilize the machine bed, the second set-up elements are designed such that between a first state in which the ends of the second set-up elements do not touch a floor located below the machine bed, and a second state in which the end sections of the second set-up elements the floor touch, can be moved.

The second set-up elements are advantageously designed so that they are automatically moved, that must not be moved by manual intervention. The machine bed can be configured such that the second set-up elements can optionally be moved / adjusted in their rigidity during operation of the machine tool and / or outside of the operation of the machine tool. "During operation" means here In particular, during the individual steps of the machine tool such as milling, drilling or moving a carriage, and / or before, after or between respective steps are moved.

The second set-up elements can be designed so that they can be moved during operation of the machine tool, and / or before, after or between respective work steps. Likewise, the second set-up elements can be designed so that their inherent rigidity during operation of the machine tool can be changed, and / or before, after or between respective steps.

The advantage of this embodiment is that the machine tool can access the effect of additional set-up elements (the second set-up elements) as needed. If, for example, a work step in which the machine bed is not or hardly vibrated is switched in one step, in which the machine bed is set in strong oscillations, the second set-up elements can thus be selectively oriented relative to the underside of the machine bed method and / or be changed in their inherent rigidity, that the machine bed is additionally stabilized by the second set-up.

For example, after workpiece machining by heavy machining, during which the damping of the machine tool was set "soft" by means of the erection elements according to the invention, the workpiece is finished in a further processing step during which the damping of the machine tool is set "hard" by means of the positioning elements according to the invention, without the workpiece, as hitherto customary, must be re-clamped for the different processing steps. This allows a more efficient processing in the course of the re-tension, because the workpiece does not need to be re-measured and readjusted if necessary.

For example, the second set-up elements can be moved with respect to the underside of the machine bed such that a pressure which the second set-up elements exert on the ground in the second state causes no or only negligible deformation or tensioning of the machine bed. This can be effected, for example, by setting the static inherent rigidity of the second set-up elements sufficiently low prior to the method. This ensures that the method of the second set-up elements from the first state to the second state, d. H. when adjusting the second set-up, no adverse effects on the machine bed has.

The ends of the second set-up elements need not necessarily touch the ground in the second state, it is also possible, depending on the application, to move the ends of the second set-up elements relative to the bottom, that in the second state a small gap between the ends and the bottom consists. This gap can be chosen so that sit at low vibrations of the machine bed, the ends of the second erection elements on the ground and thus stabilization effects are effective.

The second set-up elements may be designed such that they can be transferred from the second state into a third state in which, compared with the second state, the internal inherent rigidity of the second set-up elements is increased. This can be effected, for example, by increasing the static inherent rigidity of the second set-up elements.

This makes it possible to decouple the process of adjusting the second set-up elements from the process of adjusting the rigidity of the second set-up elements. For example, the second set-up elements can be transferred to the second state so that they touch the ground but still do not cause any stabilization of the machine bed (low rigidity) or the pressure which the second set-up elements exert on the machine bed is selected such that just no deformation of the machine bed is created. The stabilizing effect of the machine bed unfolds only when the rigidity of the second set-up is increased accordingly. Thus, it is possible to bring the second set-up elements "preemptively" already in the required positions, and then to selectively develop their effect as needed within a very short time interval, by increasing their rigidity. This allows a rapid response to undesirable effects such as vibrations of the machine bed, that is, unexpected, spontaneously occurring vibrations can be compensated directly, although the second set-up elements are not initially "sharp" (stiff).

The second set-up elements can advantageously be hydraulic cylinders which each have a piston movable relative to the underside of the machine bed. The method of the piston can be effected, for example, by pressurizing the piston with a pressurized fluid. For this purpose, the hydraulic cylinder, for example, have a pressurized fluid supply line via which the pressure fluid can be fed to the piston. Advantageously, the pressure fluid supply line to a valve, via which the pressure fluid supply line can be closed or opened. The transition from the second state to the third state may in this embodiment be effected in that the valve is transferred from an open state to a closed state, and thus the pressure fluid supplied to the piston is enclosed in the hydraulic cylinder. This embodiment has the advantage that only the switching of a valve is required for transferring the second set-up elements from the second state to the third state, ie for increasing the rigidity. The switching of the valve usually takes very little time, thus allowing a quick response of the machine tool to vibrations of the machine bed. Furthermore, this embodiment has the advantage that the rigidity can be reduced just as quickly by reopening the valve (or a specially provided other valve), whereby the effect of the second set-up can be quickly canceled.

On the underside of the second set-up elements or within the second set-up elements, a layer of elastic material may be provided. This can help to additionally improve the vibration damping effect of the second erection elements.

Advantageously, the machine tool can be provided with a control device which controls the method and / or the setting of the rigidity of the second set-up elements. For example, the control device can be configured such that the second set-up elements are transferred from the third state to the first state or the second state at specific time intervals, and, starting from the first or second state, back to the third state. In other words, by means of the control unit, the height position and rigidity of the second set-up elements can be adjusted or increased or decreased as required. This makes it possible to automatically ensure at regular intervals that the second erection elements still touch the ground, and to prevent that due to deformations of the soil or in the machine bed, the second set-up elements no longer touch the ground.

In order to determine whether the second set-up elements have already been successfully transferred from the first state to the second state, for example a suitable sensor can be provided.

The number of first set-up elements can be three. This ensures the advantages of the three-point installation already described. By three-point installation, for example, it is meant that two of the first set-up elements are located at a first end of the machine bed, and one of the first set-up elements at a second end of the machine bed, for example centrally (can also be arranged off-center) arranged to the other two set-up , is located.

According to one embodiment of the invention, a machine bed for a machine tool is provided which has a plurality of set-up elements on a lower side. First positioning elements are provided, the relative orientation of which is fixed relative to the underside of the machine bed during operation of the machine tool. Furthermore, additional second set-up elements are provided, which are infinitely height-adjustable with respect to the underside of the machine bed during operation of the machine tool. The advantage of this embodiment is that the installation of the machine bed during operation of the machine tool can be optimized for the respective operating state. D. h., The second erection elements may be configured so that they are moved during the individual steps of the machine tool such as milling, drilling or moving a carriage, and / or before, after or between respective steps. However, the second set-up can also, if appropriate, be moved outside the operation of the machine tool. The machine bed according to this embodiment or according to one of the following embodiments may be configured according to one of the embodiments described above. In particular, the second set-up elements may be designed in the same way as the set-up elements described in the preceding embodiments. However, it is also possible to use other setup elements.

The second set-up elements may be adjustable in height during operation of the machine tool such that when the machine tool / machine bed is loaded, local deformation of the machine bed that would be caused by the loading is prevented or reduced. Alternatively or additionally, during the operation of the machine tool, the second set-up elements can be adjusted in height so that vibrations of the machine bed, which are generated by the operation of the machine tool, are damped. Alternatively or additionally, during operation of the machine tool, the second set-up elements can be adjusted in height so that the machine bed is specifically locally deformed. Alternatively or additionally, during operation of the machine tool, the second set-up elements may be adjustable in height in such a way that deformations of the machine bed due to a temporal change in the height profile of the floor or due to unevenness of the floor are avoided or reduced. For example, the second set-up during operation of the Machine tool are adjusted in height so that a) they are brought into operative connection with the ground below the machine bed, and b) the active compound is dissolved again after a certain period of time, the steps a) and b) are repeated as often as desired, such that deformations of the machine bed due to a temporal change of the height profile of the soil can be compensated or reduced. The method of the second set-up can also be done in these embodiments, where appropriate, outside the operation of the machine tool. "Active connection" in this context means that the second set-up elements are in contact with the ground and exert a force on them (and vice versa), at least when the machine bed and floor move relative to each other.

Preferably, during operation of the machine tool, the second set-up elements can be configured to be height-adjustable automatically by means of a drive unit (ie the drive unit does not have to be operated manually). By way of example, the machine bed can comprise sensors by means of which operating parameter values such as deformations or vibrations of the machine bed can be detected, wherein the control unit determines the second set-up elements individually as a function of detected operating parameter values (which are determined by the sensors or active process observers), such as vibration velocity or geometric measured variables (e.g. geometric dimensions of a component) automatically height-adjusted / loaded with force. Alternatively, the drive unit can also be operated manually. For example, the drive unit may have a user interface in which a certain height adjustment of the second set-up elements can be activated during operation of the machine tool at the push of a button.

The machine bed or the machine tool can have a memory unit in which assignment data are stored, which assign operating states of the machine tool to respective settings of the second set-up elements, wherein in a specific operating state of the machine tool the drive unit adjusts the second set-up elements according to the assignment data. The current or future operating state can be detected using (passive) sensors such. As vibration or velocity sensors, or using active, intelligent process observers such. As cameras that determine the geometry of a workpiece and judge.

The inherent rigidity of the first erection elements can be constant, wherein the inherent rigidity of the second erection elements can be adjustable.

The invention further provides a machine tool having a machine bed according to the invention.

The invention will be explained in more detail below with reference to the figures in an exemplary embodiment. Show it:

1 a schematic perspective view of a machine bed of a conventional machine tool;

2 a schematic perspective view of a machine bed of a machine tool according to an embodiment of the invention;

3 a schematic cross-sectional view of different states second set-up in a machine bed of a machine tool according to an embodiment of the invention; and

4 a schematic representation of a second set-up according to an embodiment of the invention.

In the figures, identical or corresponding areas, components or component groups are identified by the same reference numerals. The drawings are schematic in nature, d. H. not necessarily true to scale.

1 shows a conventional machine bed 1 , at the bottom 2 several installation elements 3 are provided. The erection elements 3 are arranged in a three-point arrangement: a first set-up element 3 ₁ is located centrally with respect to a connecting line between a second and a third positioning element 3 ₂ , 3 ₃ , wherein the first raising element 3 ₁ at a first end 4 of the machine bed 1 , and the second and third positioning element 3 ₂ , 3 ₃ at a second end 5 of the machine bed 1 is arranged. In the 1 shown geometry of the three-point lineup 3 is merely exemplary and not mandatory; For example, the first installation element needs 3 ₁ not necessarily centered with respect to the connecting line between the second and the third positioning element 3 ₂ , 3 _{3 be} arranged. The erection elements 3 constant in their rigidity. The relative orientation of the positioning elements 3 with respect to the bottom 2 of the machine bed 1 (ie the relative position of the machine bed 1 groundbreaking ends of the erection elements 3 with respect to the bottom 2 of the machine bed 1 ) can be changed manually, for example by means of screws, in this embodiment, the relative position of the erection elements 3 is changeable with respect to a Z-direction.

A disadvantage of the in 1 shown machine bed 1 is that the erection elements 3 Vibrations in the machine bed 1 can only compensate inadequately.

2 shows a machine bed 1' according to a first embodiment of the invention, which eliminates this disadvantage. The machine bed 1' corresponds in its construction to the in 1 shown machine bed 1 , In addition, however, are second set-up 3 ' provided with respect to the bottom 2 of the machine bed 1 are designed movable in height, ie, the relative positions of the machine bed 1 groundbreaking ends 15 the second erection elements 3 ' with respect to the bottom 2 of the machine bed 1 are by moving the second set-up 3 ' changeable. The rigidity of the second set-up elements 3 ' is independent of the height position of the second set-up elements 3 ' adjustable. The rigidity of the second set-up elements 3 ' can be infinitely or incrementally adjustable. The erection elements 3 ' are movable in this embodiment with respect to the Z-axis, but the invention is not limited thereto. For example, it would also be possible to use the second set-up elements 3 ' to move with respect to an axis which is inclined at an arbitrary angle with respect to the Z-axis.

The second set-up elements 3 ' can, as in 2 shown at the end 15 with an elastic layer 6 be provided, ie with a layer of a material whose elasticity, compared with the other components of the second set-up 3 ' , is increased.

3 shows a schematic cross-sectional view of in 2 shown second mounting elements in different states according to an embodiment of the invention. In a first state A, there are the second set-up elements 3 ' in a position relative to the Z-axis, in which it is below the machine bed 1 located ground 7 do not touch. The second set-up elements 3 ' are convertible from the first state A in a second state B, in which these the ground 7 touch. The second set-up elements 3 ' are in this case movable so that a pressure, the second set-up 3 ' in the second state B on the ground 7 exercise, no or only negligible deformation / distortion of the machine bed 1 causes. In other words, the rigidity of the second erection elements 3 ' with respect to the machine bed 1 is very low in the second state B; a slight pressure on the ends 15 the second erection elements 3 ' would be enough to move these along the z-axis back towards the machine bed 1 to press. The second set-up elements 3 ' are further from the second state B in a third state C can be converted, in which, compared to the second state B, the rigidity of the erection elements 3 ' is increased. In other words, in the third state C, the pressure, in the second state B, a pushing back of the second set-up 3 ' in the direction of the machine bed 1 would not be enough for this.

In the second state B, the second installation elements 3 ' still no support of the machine bed 1 However, in the third state C already, ie vibrations of the machine bed 1 be through the second set-up 3 ' in the third state C at least partially compensated, but not in the second state B.

The second set-up elements 3 ' are switchable in any manner between the states A, B and C back and forth. Thus, for example, at regular intervals from the third state C in the first state A are returned by the second set-up elements 3 ' in the direction of the machine bed 1 be moved, then, starting from the first state A, again in the second state B and from this to the third state C to be transferred. In this way, for example, in the meantime resulting bumps in soil 7 or deformations in the machine bed 1 leading to unwanted gaps between the ends 15 the second erection elements 3 ' and the floor 7 lead, be eliminated, thus ensuring that at any time a support of the machine bed 1 done by the second set-up. Conversely, as a result, can also arise in the meantime arches of the soil 7 to the machine bed 1' leading to deformation / distortion of the machine bed 1' lead, be balanced by the ends 15 the second erection elements 3 ' a little further to the machine bed 1' be drawn.

4 shows a schematic representation of a second set-up 3 ' according to an embodiment of the invention. In this embodiment, the second erecting element 3 ' as a hydraulic cylinder 8th designed, one relative to the bottom 2 of the machine bed 1' movable piston 9 having. The piston 9 is moved, in which this with a pressurized fluid 10 is applied to the hydraulic cylinder 8th via a pressure fluid line 11 is supplied. In the pressure fluid line 11 is a valve 12 provided, via which the pressure fluid line 11 can be opened or closed. Will the second installation element 3 ' is transferred from the first state A to the second state B, the hydraulic cylinder 8th over the pressure fluid line 11 pressure fluid 10 fed, causing the piston 9 in the direction of the ground 7 emotional. The pressure with which the pressurized fluid 10 the piston 9 is applied in state B is so low that the lower end 15 of the piston 9 when putting on the ground 7 neither the ground 7 still the machine bed 1 deformed, ie the of the piston 9 on the hydraulic cylinder 8th applied force is too low to deformation / strain in the machine bed 1' at which the hydraulic cylinder 8th is fixed to evoke. Will the second installation element 3 ' transferred from the second state B in the third state C, the valve 12 closed, bringing that into the hydraulic cylinder 8th located pressure fluid 10 no longer via the pressure fluid line 11 from the hydraulic cylinder 8th can move out. This allows the piston 9 even when subjected to a high force on the ends 15 only to a small extent from the ground 7 in the direction of the hydraulic cylinder 8th be moved, ie the rigidity of the hydraulic cylinder 8th is increased from the second state B. In order to return from the third state C to the first state A or to the second state B, a valve 13 are opened, which is closed in the first state A and in the second state B, which over the pressure fluid line 14 Pressure fluid from the hydraulic cylinder 8th is dissipated. Then the valve can 13 closed, and the valve 12 be opened.

As has become clear from the foregoing description, embodiments of the invention make it possible to retain the advantage of the three-point installation by continuing to place the machine tool on three first set-up elements 3 stands. In addition, however, supportive installation elements 3 ' such as hydraulic cylinders 8th with retractable pistons 9 on the machine bed 1' appropriate. These pistons 9 be with a defined pressure on the ground 7 extended, the pressure can be so low that the bed is not or only minimally deformed. Subsequently, the valve 12 in the hydraulic supply line 11 closed and the pressurized fluid (eg oil) in the hydraulic cylinder 8th locked up.

The embodiments according to the invention are based on the following considerations of the inventors: Experiments with machines with more than three set-up points have shown that the working accuracy of a machine tool is reduced if the preload of the set-up elements is not adjusted exactly or if subsidence phenomena occur in the floor or in the set-up elements comes. On the other hand, an installation of the machine tool at more than three set-up points (i.e., the use of more than three set-up elements, so-called multipoint installation) has the advantage that the machine bed is better supported, whereby vibrations of the machine bed can be better damped or completely suppressed. In particular, in heavy cutting the multipoint installation has great advantages, since chatter vibrations can form only to a small extent.

In order to combine the advantages of the three-point installation and the multipoint installation, the combination of three rigid and several passive elastic erection elements was examined. It turns out, however, that even elastic erection elements must be made with a great force if they are to have a sufficient supporting effect on the machine bed. As a result, the machine bed is also deformed by elastic mounting elements. The conflict with the use of additional elastic erection elements is therefore that they must be stiff on the one hand in order to support the machine bed sufficiently, but on the other hand they must have sufficient elasticity, so subsidence in the ground or an incorrect setting of the rigid erection not Change forces on the machine bed.

Furthermore, the use of additional pure damping elements without static inherent rigidity was examined by the inventors, such. B. hydraulic cylinder. Such elements yield when the floor is lowered, but do not exert any static forces on the machine bed and therefore can not deform it. Their supportive effect they develop only by the fact that these occurring vibrations oppose damping forces. The disadvantage of using purely damping elements is that their ends must be firmly connected to the floor and the machine bed so that they can develop their vibration-damping effect. An attachment to the ground by gluing or Verübeln is always associated with damage to the foundation.

The conflict outlined above is due to the in 8th embodiment shown canceled: When extending the piston 9 A small force acts on the machine bed 1' not deformed after closing the valve 12 is the piston 9 very stiff (high static rigidity), leaving the machine bed 1' is well supported.

• – Das Maschinenbett 1' kann nicht durch eine falsche Einstellung der ersten Aufstellelemente 3 verformt werden;
• – Es ist kein Ausrichten des Maschinenbetts 1' notwendig, da es zunächst immer auf den drei festen, starren ersten Aufstellelementen 3 steht und die Kolben 9 erst anschließend mit geringer Kraft ausgefahren werden. Auch beim Versetzen der Werkzeugmaschine bleibt die Arbeitsgenauigkeit der Werkzeugmaschine ohne erneutes Ausrichten der starren ersten Aufstellelementen 3 erhalten;
• – An die Genauigkeit und das Setzverhalten des Fundaments (des Bodens 7 sowie der ersten Aufstellelementen 3) werden keine besonderen Anforderungen gestellt;
• – Die Ventile 12 der Hydraulikzylinder 8 können nach jedem Bearbeitungsschritt oder zwischen den Bearbeitungsschritten kurz geöffnet und nachgespannt werden, so dass die Aufstellung auch langfristig stabil bleibt;
• – Es ist keine dauerhafte Befestigung der Kolben 9 am Boden 7 notwendig.
• – Eine optionale schwingungsdämpfende Schicht 6 am Ende 15 des Kolbens 9 verringert zwar die Steifigkeit des Aufstellelements 3', die höhere Dämpfung wirkt sicher aber teilweise besser auf das Zerspanverhalten der Werkzeugmaschine aus. Zudem geht die Vorspannung im Kolben 9 nicht so leicht verloren, wenn der Aufstellfuß, d. h. das Ende 15 des Aufstellelements 3', eine gewisse Elastizität besitzt.

Compared to the multipoint constellations described above, this arrangement has many advantages:

• - The machine bed 1' can not be due to an incorrect setting of the first set-up elements 3 be deformed;
• - There is no alignment of the machine bed 1' necessary, since it always first on the three fixed, rigid first set-up elements 3 stands and the pistons 9 only then be extended with little force. Even when moving the machine tool, the working accuracy of the machine tool remains without re-aligning the rigid first erection elements 3 receive;
• - To the accuracy and setting behavior of the foundation (the soil 7 as well as the first set-up elements 3 ) no special requirements are made;
• - The valves 12 the hydraulic cylinder 8th can be opened and retensioned briefly after each processing step or between the processing steps, so that the setup remains stable over the long term;
• - There is no permanent attachment of the pistons 9 on the ground 7 necessary.
• - An optional vibration damping layer 6 at the end 15 of the piston 9 Although reduces the rigidity of the positioning element 3 ' , the higher damping certainly has a better effect on the machining behavior of the machine tool. In addition, the bias in the piston 9 not so easily lost when the foot, ie the end 15 of the erection element 3 ' , has a certain elasticity.

In large machines with more than 70 installation elements, the combination of three-point installation described in the preceding embodiments (three first installation elements 3 ) and second erection elements 3 ' be used several times. Because the machine bed 1 However, machine tools of this size are no longer intrinsically rigid and have a very high rigidity of all set-up elements 3 . 3 ' advantageous.

Claims (19)

Machine bed ( 1' ), for a machine tool attached to a lower side ( 2 ) a plurality of positioning elements ( 3 . 3 ' ), wherein first set-up elements ( 3 ) are provided whose relative orientation with respect to the underside ( 2 ) of the machine bed ( 1 ) fixed during operation of the machine tool, and whose inherent rigidity is constant, and wherein additional second set-up elements ( 3 ' ) are provided with respect to the underside ( 2 ) of the machine bed ( 1' ) are infinitely adjustable in height and whose inherent rigidity is adjustable, characterized in that the second set-up elements ( 3 ' ) between a first state (A) in which this one below the machine bed ( 1' ) ( 7 ) and a second state (B), in which the ground ( 7 ), are movable. Machine bed ( 1' ) according to claim 1, wherein the second set-up elements ( 3 ' ) are movable such that a pressure, the second set-up elements ( 3 ' ) in the second state to the ground ( 7 ), no or negligible deformation of the machine bed ( 1' ) causes. Machine bed ( 1' ) according to one of claims 1 or 2, wherein the second set-up elements ( 3 ' ) can be converted from the second state (B) into a third state (C), in which, compared to the second state (B), the rigidity of the second set-up elements (FIG. 3 ' ) is increased. Machine bed ( 1' ) according to one of claims 1 to 3, wherein the second set-up elements ( 3 ' ) Hydraulic cylinder ( 8th ), each one relative to the underside ( 2 ) of the machine bed ( 1' ) movable piston ( 9 ), the method of the piston ( 9 ) by applying the piston ( 9 ) with a pressurized fluid ( 10 ) is feasible. Machine bed ( 1' ) according to claim 4, wherein the hydraulic cylinders ( 8th ) a pressurized fluid supply line ( 11 ), over which the piston ( 9 ) the pressurized fluid ( 10 ) can be supplied, wherein the pressure fluid supply line ( 11 ) a valve ( 12 ), via which the pressure fluid supply line ( 11 ) can be closed or opened, and wherein the transition from the second state (B) to the third state (C) takes place in that the valve ( 12 ) is closed and thus the piston ( 9 ) supplied pressurized fluid ( 10 ) in the hydraulic cylinder ( 8th ) is included. Machine bed ( 1' ) according to one of claims 1 to 5, wherein at the bottom ( 2 ) at least one of the second set-up elements ( 3 ' ) a layer ( 6 ) is provided made of elastic material. Machine bed ( 1' ) according to one of claims 1 to 6, wherein the number of first set-up elements ( 3 ) is three, wherein two of the first set-up elements ( 3 ) at a first end ( 5 ) of the machine bed ( 1' ), and one of the first set-up elements ( 3 ) at a second end ( 4 ) of the machine bed ( 1' ) are arranged. Machine bed ( 1' ) according to one of claims 3 to 7, having a control device which controls the second set-up elements ( 3 ' ) is controlled so that these at intervals from the third state (C) in the first or second state (A, B), and starting from the first or second state (A, B), again in the third state (C) be transferred. Machine bed ( 1' ), for a machine tool attached to a lower side ( 2 ) a plurality of positioning elements ( 3 . 3 ' ), wherein first set-up elements ( 3 ) are provided whose relative orientation with respect to the underside ( 2 ) of the machine bed ( 1 ) is fixed during operation of the machine tool, and wherein additional second set-up elements ( 3 ' ) are provided during operation of the machine tool with respect to the underside ( 2 ) of the machine bed ( 1' ) are infinitely adjustable in height, characterized in that the second set-up elements ( 3 ' ) between a first state (A) in which this one below the machine bed ( 1' ) ( 7 ) Not touch and a second state (B) in which they hit the ground ( 7 ), are movable. Machine bed ( 1' ) according to claim 9, wherein the second set-up elements ( 3 ' ) are adjustable during operation of the machine tool so that upon loading of the machine tool local deformation of the machine bed, which would be caused by the loading, is prevented or reduced. Machine bed ( 1' ) according to claim 9 or 10, wherein the second set-up elements ( 3 ' ) are adjustable during operation of the machine tool so that vibrations of the machine bed, which are generated by the operation of the machine tool, are damped. Machine bed ( 1' ) according to one of claims 9 to 11, wherein the second set-up elements ( 3 ' ) are adjustable during operation of the machine tool so that the machine bed is deliberately locally deformed. Machine bed ( 1' ) according to one of claims 9 to 12, wherein the second set-up elements ( 3 ' ) are adjustable during operation of the machine tool so that deformations of the machine bed due to a temporal change in the height profile of the soil or due to unevenness of the soil are avoided or reduced. Machine bed ( 1' ) according to claim 13, wherein the second set-up elements ( 3 ' ) are adjusted during operation of the machine tool so that a) they are brought into operative connection with the ground below the machine bed, and b) the active compound is dissolved again after a certain period of time, wherein the steps a) and b) are repeated periodically, such that deformations of the machine bed due to a temporal change of the height profile of the soil are compensated or reduced. Machine bed ( 1' ) according to one of claims 9 to 14, wherein the second set-up elements ( 3 ' ) are automatically adjustable during operation of the machine tool by means of a drive unit. Machine bed ( 1' ) according to claim 15, wherein the machine tool has sensors by means of which operating parameter values such as deformations or vibrations of the machine bed are detectable, wherein the drive unit controls the second set-up elements ( 3 ' ) depending on detected operating parameter values. Machine bed ( 1' ) according to claim 15 or 16, with a memory unit in which allocation data are stored, the operating states of the machine tool respective settings of the second set-up elements ( 3 ' ), wherein in a certain operating state of the machine tool, the drive unit, the second set-up elements ( 3 ' ) adjusts the assignment data accordingly. Machine bed ( 1' ) one of claims 9 to 17, wherein the inherent rigidity of the first set-up elements ( 3 ) is constant, and wherein the inherent rigidity of the second set-up elements ( 3 ) is adjustable. Machine tool, with a machine bed ( 1' ) according to one of the claims 1 to 18.

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