EP3498441A1 - Food slicer - Google Patents

Abstract

The present invention relates to a cutting machine for separating slices of, in particular, strand-like material to be cut. The cutting machine comprises a machine housing. The cutting machine comprises a drive motor and a cutting blade driven by the latter in a cutting plane in order to cut off slices. A stop plate is movable parallel to the cutting plane and serves to set a desired slice thickness. The cutting machine comprises a parallel to the cutting plane movable back and forth slide. The carriage comprises a support plate and an abutment wall. The support plate and the abutment wall form a holding device for the material to be cut. The carriage comprises a pivoting device, by means of which the support plate can be moved between a starting position and a pivoted-up position. In the starting position and in the swung-up position but also in the swivel range between the support plate forms a right angle with the cutting plane. The cutting machine further comprises a fixing plate, which is arranged at right angles to the support plate. The fixation plate is rigidly connected to the support plate. The fixing plate has a link, wherein the link comprises at least two interventions.

Description

The present invention relates to a cutting machine for separating foods, which has a carriage with a pivotable support plate.

Cutting machines for separating slices of stranded cutting material are known from the prior art.

The DE 20 2008 006 020 U1 shows a cutting machine for food whose Schneidgutauflage can be pivoted or inclined by means of an adjusting mechanism.

The object of the invention is to improve a cutting machine of the type mentioned and in particular to allow a better fixation of the carriage.

This object is achieved by a cutting machine according to claim 1.

According to the invention, a cutting machine for separating slices of, in particular, strand-like material to be cut is proposed. The cutting machine comprises a machine housing. The cutting machine comprises a drive motor and a cutting blade driven by the latter in a cutting plane in order to cut off slices. A stop plate is movable parallel to the cutting plane and serves to set a desired slice thickness. The cutting machine comprises a parallel to the cutting plane movable back and forth slide. The carriage comprises a support plate and an abutment wall. The support plate and the abutment wall form a holding device for the material to be cut. In one embodiment, the Platen and the investment wall arranged at right angles to each other. The carriage comprises a pivoting device, by means of which the support plate can be moved between a starting position and a pivoted-up position. In one embodiment, the support plate is in the starting position on the carriage foot. In the starting position and in the swung-up position as well as in the swivel area in between, the support plate forms a right angle with the cutting plane. The cutting machine further comprises a fixing plate, which is arranged at right angles to the support plate. The fixation plate is rigidly connected to the support plate. The fixation plate has a backdrop, wherein the backdrop is provided with at least two interventions. In the context of the invention, the fixing plate is also an element which has a gate, but is not formed as a continuous plate, but rather in the inner, non-functional part, has a recess. In one embodiment, the backdrop has three interventions. The cutting machine comprises a locking element, which, depending on the position of the carriage, can be brought into engagement and holds the carriage by means of the fixing plate in position. In one embodiment, the interventions in the scenery are arranged so that the carriage when it is fixed in the first engagement is pivoted by 0 °, when it is fixed in the second engagement is pivoted by 18 ° and when it is fixed in the third engagement to 35 ° is pivoted. This cutting machine has the advantage that it can be used very flexibly due to the pivoting of the carriage and the position of the carriage is secure by the locking device. The carriage is also not slowly moved by the weight of particular heavy items to be cut by gravity to the starting position, since the locking element, which engages in one of the interventions of the fixing plate, can absorb this weight.

In one embodiment, the link with the interventions is attached to an outer edge of the fixation plate. This is particularly advantageous because the fixation element can be easily introduced into the interventions. In one embodiment, the gate is attached to the outer edge of the fixing plate which is remote from the platen.

In one embodiment, the carriage is connected to the machine housing via a carriage foot. The carriage foot includes a support frame or a support plate. Under support frame or support plate is a component to understand, which is preferably arranged substantially perpendicular to the cutting plane and the end portion of the carriage foot forms or attached to the end of the carriage foot. This component extends in the plane perpendicular to the cutting plane and serves the support plate as a stop and the mechanical connection of the support plate with the carriage foot. In the initial position of the support plate it rests on the carriage foot, in particular on the support frame of the carriage foot on.

In one embodiment, the locking element, which can engage in the interventions of the gate and holds the fixing plate stationary, a lever. Depending on the carriage position, that is, depending on the pivot position of the support plate, the lever can engage in one of the interventions of the fixing plate. If the lever is mounted in engagement and thus holds the fixation plate stationary, the lever can be moved out of engagement by movement. In one embodiment, a handle is attached to the lever for these movements of the lever. In one embodiment, the lever is pivotable in a plane parallel to the plane of the support frame. In one embodiment, on a device that pivotally supports the lever, there is a spring or spring element that urges the lever into engagement with the fixation plate. That is, the lever is pressed by the spring in the plane parallel to the plane of the support frame to a certain point. An operator can swing the lever in this plane away from this location by counteracting the spring force. By moving the platen of the carriage by the operator also moves the fixing plate. The positions of the interventions in the scenery in the room shift. Is an engagement at the position to which the lever is pressed by the spring force, the lever can be pressed by the spring force into the engagement or in that an operator leads the lever into engagement. The lever thus fixes the fixing plate at this point and the position of the pivoting device and thus the position of the support plate. The spring or spring element causes the lever remains pressed into the engagement and does not slip out of engagement by itself. Thus, the position of the platen is fixed by means of the lever until an operator swings the lever out of engagement against the spring force. Only then can the support plate be swiveled.

In one embodiment, the pivoting device comprises at least one radial bearing. The axis of the radial bearing runs at right angles to the cutting plane. The pivoting device is connected to the support plate in the area in which the abutment wall is connected to the support plate. In other words, in the cross-section of the carriage, there is an area where the platen, the abutment wall and the pivoting device meet. This embodiment also includes a solution in which the pivoting device engages the support plate and also engages the abutment wall to the support plate without touching the pivoting device and investment wall directly. This embodiment also includes a solution in which the pivoting device engages the abutment wall and also engages the support plate on the abutment wall without touching the pivoting device and support plate directly. However, all embodiments have in common that the points of contact are in a spatially narrow range, which is formed by an edge of the support plate and a corresponding edge of the abutment wall.

In one embodiment, the support frame comprises a displacement device. The displacement device mechanically connects the pivoting device to the support frame. The Pivoting device is movable by means of the displacement device parallel to the plane of the support frame.

In one embodiment, the fixing plate comprises a slotted guide. A pin or bolt engages in the slotted guide. The pin or bolt is firmly connected to the support frame. The pivoting of the support plate leads to a movement of the fixing plate, which carries the slotted guide. Through the stationary pin or bolt and through the slotted guide the fixing plate is forced to a certain path relative to the support frame. This causes a movement of the pivoting device in the displacement device. In one embodiment, the bolt comprises a ball bearing to better slide in the slotted guide. This construction causes the axis of the pivot bearing of the pivoting device to move in a plane parallel to the plane of the support frame during pivoting of the support plate. When the support plate is pivoted, the support wall connected at right angles to it is also pivoted. If the carriage is brought to the starting position remote from the blade, then the abutment wall and in particular a lateral handguard plate attached to the abutment wall is approximately flush with the edge of the abutment plate. If the carriage without the displacement device in a raised position, so would arise at this starting position, a gap between the plant wall / side hand guard plate and the stop plate. An operator could grab his hand into this gap and injure himself as he moves the carriage in the cutting direction to separate a slice from the rope-shaped food. By moving the pivoting device in the displacement device of this gap is avoided when swung carriage. This can cause no risk of injury. By moving the pivoting device is further avoided that in the carriage end position, the plant wall no longer covers the cutting blade. Thus, even in the raised position a cutting material can be cut with a large diameter, without that the stop of the slide end position must be moved further to the rear. As a result, the machine housing of a known cutting machine does not need to be revised in order to realize the invention.

In one embodiment, a bushing supports a shaft. The bush is movable parallel to the plane of the support frame by means of a linear guide of the support frame. The shaft is aligned perpendicular to the cutting plane and is part of the pivoting device. At least one radial bearing is rotatably mounted on the shaft and fixedly connected to the support plate. The shaft thus forms the fulcrum for the pivotal movement of the support plate. Thus, the pivot point for the pivotal movement of the support plate is movable parallel to the support frame. In one embodiment, one end of the shaft is linearly guided in a guide rail. The guide rail is part of the support frame. Thus, the shaft is linearly guided in its linear movement in two places, the bushing and the guide rail and is thus protected against rotations against the direction of the axis of the shaft. In one embodiment, the shaft is screwed in the bush or held against rotation by a press connection with a screw. In this embodiment, the shaft is also protected against rotation about the axis of the shaft. In one embodiment, a wheel or ball bearing is mounted at the end of the shaft at the location that runs in the guide rail of the support frame. This facilitates the movement of the shaft in the guide rail. In one embodiment, a radial bearing is located between the sleeve and an end piece that is bolted to the shaft. The tail has a larger diameter than the radial bearing. An axial movement of the radial bearing is prevented on the one hand by the tail and on the other side by the socket. The threaded connection in the bushing prevents the shaft from moving in the axial direction in the bushing. Thus, a movement of the radial bearing on the shaft in both axial directions is prevented and the Platen of the carriage can not move in a direction perpendicular to the cutting plane of the shaft.

In one embodiment, the pivoting device comprises a rotary damper. The support plate is, if the lever is not spent in one of the interventions of the fixing plate, pulled by gravity down and fall into the starting position. Then the support plate strikes on the support frame. The rotary damper counteracts this force. In one embodiment, the rotational damper counteracts both directions of movement of the pivoting movement. In one embodiment, the rotary damper counteracts only the pivotal movement carried out by gravity. In one embodiment, the rotary damper presses by means of a spring a rotationally fixed brake element against a radial bearing, which is firmly connected to the support plate. In one embodiment, the brake element is applied as a brake ring on the shaft and is pressed by the spring against one side of a radial bearing and brakes the support plate so from. The spring is also applied to the shaft in this embodiment and is fixed on the side remote from the brake element with a stop. In one embodiment, the spring directly counteracts with its spring force acting on the platen weight force. In this case, the spring force is applied to a radial bearing fixedly connected to the support plate.

In one embodiment, the carriage comprises a detent button which engages in a detent. The carriage can be tilted by releasing the locking knob about a carriage axis.

In one embodiment, the cutting machine is a vertical cutting machine. That is, the cutting plane is a vertical plane and the support plate is aligned in the starting position parallel to the horizontal plane. In one embodiment, the support plate is oriented in the pivoted position at an angle between 30 ° and 40 °, preferably 35 ° to the horizontal plane. In a Embodiment, the support plate is aligned in an intermediate position at an angle between 12 ° and 23 °, preferably 18 ° to the horizontal plane.

In one embodiment, the cutting machine is an oblique cutting machine. This means. The cutting plane is tilted with respect to the vertical, so that cut slices fall into a product depositing area due to gravity.

Fig. 1

eine erfindungsgemäße Schneidemaschine ausgeführt als Vertikalschneidemaschine,

Fig. 2

einen Schlitten einer erfindungsgemäßen Schneidemaschine,

Fig. 3

einen Schlitten einer erfindungsgemäßen in einer Ausgangslage,

Fig. 4

einen Schlitten einer erfindungsgemäßen Schneidemaschine während des Verschwenkens der Auflageplatte,

Fig. 5

einen Schlitten der erfindungsgemäßen Schneidemaschine in einer mittleren Schwenkposition,

Fig. 6

einen Schlitten der erfindungsgemäßen Schneidemaschine in einer Ansicht von unten,

Fig. 7

ein Feststellelement der erfindungsgemäßen Schneidemaschine,

Fig. 8

eine Verschwenkvorrichtung der erfindungsgemäßen Schneidemaschine in einem axialen Schnitt,

Fig. 9

eine erfindungsgemäße Schneidemaschine ausgeführt als Schrägschneidemaschine.

Some embodiments of the invention are shown by way of example in the drawings and described below. They show, in a schematic representation in each case:

Fig. 1

a cutting machine according to the invention designed as a vertical cutting machine,

Fig. 2

a carriage of a cutting machine according to the invention,

Fig. 3

a carriage of an inventive in a starting position,

Fig. 4

a carriage of a cutting machine according to the invention during the pivoting of the support plate,

Fig. 5

a carriage of the cutting machine according to the invention in a middle pivoting position,

Fig. 6

a slide of the cutting machine according to the invention in a view from below,

Fig. 7

a locking element of the cutting machine according to the invention,

Fig. 8

a pivoting device of the cutting machine according to the invention in an axial section,

Fig. 9

a cutting machine according to the invention designed as an inclined cutting machine.

Fig. 1 schematically shows an embodiment of a cutting machine 1 for separating slices of particular strandförmigem cutting material. It is a food cutting machine 1, which has a machine housing 2, on the following components are supported: A drive motor and a cutting blade 11 driven by this in a cutting plane for cutting individual slices of the cutting material and a stop plate 21 movable parallel to the cutting plane for setting a desired pane thickness.

The machine housing 2 of the cutting machine 1 has a substantially rectangular base, on which a motor tower (not shown) projects upwards. In this engine tower of the drive motor is added. The drive motor is connected via a gear with the cutting blade 11 and drives this. The cutting blade 11 is formed as a circular blade. At the top of the motor tower, a control unit and an input / output unit for operating the cutting machine 1 is arranged.

The cutting blade 11 is covered in the region of the cutting edge by a C-shaped blade guard ring 22 to prevent inadvertent contact with the cutting edge of the cutting blade. The front of the cutting blade 11 is secured with a flat blade cover 23. In the illustrated cutting machine 1 is a so-called vertical cutter, ie, the cutting blade 11 is formed as a circular blade, which rotates in a vertically oriented cutting plane. The cutting area of the cutting blade 11 is defined by the area left clear by the blade protection ring 22. In front of the cutting area, the stop plate 21, which is displaceable parallel to the cutting blade 11, is arranged. The stop plate 21 can over a knob 25 are adjusted to set a desired slice thickness.

In the area in front of the cutting blade 11, a slidable carriage 3 is arranged parallel to the cutting plane, that is to say along a carriage axis. The carriage 3 has a carriage foot 32, which is mounted in the machine housing 2 on a linear guide. The carriage 3 has a detent button 31 which engages through the carriage foot 32 in a lock in the machine housing 2. The carriage 3 can be tilted by loosening the locking button 31 about the carriage axis. Furthermore, the carriage comprises a hand guard 33.

Further, the carriage 3 comprises a support plate or support frame 34, which is aligned in the horizontal direction. The support frame 34 forms the conclusion of the carriage foot 32. The carriage 3 further comprises a support plate 35 and a support wall 36, which are mounted perpendicular to each other. On the other side of the support plate 35, the carriage 3 comprises a carriage rear wall 37, which is also mounted at right angles to the support plate 35. The material to be cut is placed on the support plate 35 and applied to the abutment wall 36. The support plate 35 is pivotally mounted with respect to the support frame 34 via a pivoting device 38. A first working position for cutting food is preferably in the starting position, in which the support plate 35 is aligned horizontally. A second working position, the raised position, for cutting food is preferably in the position in which the support plate 35 is pivoted between 30 ° and 40 °, preferably 35 °, to the support frame 34. A third working position, the middle position, for cutting food is preferably in the position in which the support plate 35 is pivoted to the support frame 34 in the range between 12 ° and 23 °, preferably 18 °.

The support plate 35 is fixedly connected to a fixing plate 39. The fixing plate 39 is attached at right angles to the support plate 35. The fixing plate 39 indicates the lower side remote from the platen 35 has a gate which comprises three interventions 40, 41, 42. The interventions 40, 41, 42 are designed in such a way that a lever 43, which can be pivoted in a plane parallel to the support plate 35, can engage in an engagement 40, 41, 42. The lever 43 serves as a fixing element of the support plate 35 and holds the support plate 35 stationary when it is inserted into one of the interventions 40, 41, 42. In which engagement 40, 41, 42, the lever 43 can engage, depends on the position of the fixing plate 39 and thus from the pivot position of the support plate 35 from. The lever 43 can engage in this engagement 40, 41, 42, which is located in the plane in which the lever 43 is pivotable. In the initial position of the support plate is a first engagement 40 of the fixing plate 39 in the pivoting plane of the lever 43. Thus, the lever, when it is introduced into the first engagement 40, fix the support plate 35 in the starting position. In a middle position of the platen 35, a second engagement 41 of the fixing plate 39 lies in the pivot plane of the lever 43. Thus, the lever 43, when inserted in the second engagement 41, can fix the platen 35 in the middle position. In a raised position of the platen 35, a third engagement 42 of the fixing plate 39 is in the pivoting plane of the lever 43. Thus, the lever 43, when inserted in the third engagement 42, can fix the platen 35 in the middle position. By a movement, that is, by pivoting the lever 43, it can be led out of an engagement 40, 41, 42 of the fixing plate 39 and thus a pivoting movement of the support plate 35 is made possible.

Fig. 2 shows another view related to Fig. 1 already described a carriage 3, in which the support plate 35 is arranged in the starting position. Fig. 2 shows the pivoting device 38, which includes a first radial bearing 51, a second radial bearing 50, a bush 52, a shaft 53, an end piece 54 and a rotary damper 55. A Guide rail 56 is shown, which is part of the support frame 34 and the shaft 53 in its movement parallel to the plane of the support frame 34 leads. The operation of the pivoting device 38 is associated with Fig. 8 more precisely.

Fig. 3 shows the carriage 3 when the support plate 35 is in the starting position. That is, the platen 35 is aligned parallel to the support frame 34. The lever 43 is located in the third engagement 42 of the fixing plate 39. This prevents the support plate 35 can be pivoted. The slide guide 45 is located in this view on the rear side of the fixing plate 39 and is indicated by dashed lines to illustrate the mechanism. Likewise, the bolt 44, which determines the position of the fixing plate 39 by means of the guide slot 45.

Fig. 4 shows the carriage 3 at a time during pivoting from the starting position to the middle or pivoted position. The lever 43 has been pivoted to unlock the fixing plate 39 in its pivot plane, that is, in a plane parallel to the plane of the support frame 34. In this position it is still and therefore has no direct points of contact with the fixing plate 39. For this reason, the support plate 35 (including the abutment wall 36 and the carriage rear wall 37) can be pivoted by means of the pivoting device 38. This is done by an operator manually moving the platen 35, for example, by gripping the carriage back wall 37 and pulling it upwards. In this unlocked illustration, it can be seen that the lever 43, which is in Fig. 7 is described in detail, a handle 57 and a locking surface 58 includes.

The dashed lines guide 45 shown on the rear side of the fixing plate 39 in operative connection with the bolt 44 which is rigidly secured to the support frame 34, causes the pivoting of the support plate 35, the pivot point of the support plate 35, that is, the pivoting device 38, by means of a linear guide in the drawing is moved to the right. In this position, a guide rail 56 is seen, which is mounted in the support frame 34 and which serves to guide the pivoting device 38 in this movement.

Fig. 5 shows the carriage 3, the support plate 35 is pivoted to the middle position and is held by means of the lever 43 and the second engagement 41 of the fixing plate 39 in this position. The linear displacement of the pivoting device 38 in the plane parallel to the plane of the support frame 34 is shown. In addition, it can be seen that the bolt 44, which is connected to the support frame 34, is located at a different location in the slotted guide 45 on the rear side of the fixing plate 39. Of the guide rail 56 which is mounted in the support frame 34, more can be seen in this position, since the pivoting device 38 in the guide rail 56 in comparison to Fig. 4 has moved on.

Fig. 6 shows the sled from a view from below. The embodiment of the support frame 34 is shown. The support frame 34 comprises a displacement device 61, 62 on the basis of which the pivoting device 38 along a displacement direction B in a plane parallel to the plane of the support frame is displaceable. The displacement device 61, 62 consists of a cylindrical sleeve 62 which extends in the support frame 34 along displacement direction B and a rod 61 which slides in the cylindrical sleeve 62. The rod 61 holds the sleeve 52 of the pivoting device 38 linearly displaceable, wherein the sleeve 52 in turn supports the shaft 53 of the pivoting device 38. The support frame 34 supports a lever housing 60 of the lever 43, which serves to fix the fixing plate 39 by means of which interventions 40, 41, 42. The lever 43 includes a handle 57, by means of which the operator can move the lever and a latching surface 58, which engages in the interventions 40, 41, 42 of the fixing plate 39. The lever 43 is rotatably mounted via a lever shaft 59 in the lever housing 60 in a plane parallel to the plane of the support frame 34. Fig. 6 shows the slotted guide 45, which is mounted on or in the inner side of the fixing plate 39. The bolt 44 is rigid and thus fixedly connected to the support frame 34 and allows only a mechanically defined movement of the fixing plate 39. Upon pivoting of the support plate 35 by means of the pivoting device 38, the sleeve 52 of the pivoting device 38, which supports the shaft 53 and thus defines the axial position of the pivoting device 38, along the displacement direction B by means of the displacement device 61, 62 consisting of cylindrical sleeve 62 and Staff 61, forced to move. The shaft 53 is taken in a defined direction in the sleeve 52 of the pivoting device 38, due to which the end of the shaft 53 also moves in the guide rail 56 along the direction of displacement B.

Fig. 7 shows the lever 43 in section. The lever housing 60 is attached to the support frame 34. In the lever housing 60, the lever shaft 59 is rotatably mounted in a bearing 63. The lever shaft rotates about the axis G of the bearing. A spring 64 forms a restoring force which presses the lever 43 in a rest position. The rest position of the lever 43 is the position in which the lever engages in one of the interventions 40, 41, 42 of the fixing plate 39. If an operator wants to release the fixing plate 39, he pivots the lever 43 against the restoring force from the engagement 40, 41, 42 and can thus pivot the support plate 35. Is the lever 43 in an engagement 40, 41, 42 of the fixing plate 39, so prevents the spring 64 and the restoring force exerted by it, that the lever from the engagement 40, 41, 42 can slip out. The movement of the lever 43 in the direction of the restoring force is limited by a stop, which also represents the rest position of the lever 43.

Fig. 8 shows a section through the pivoting device 38. To keep the shaft 53 in the axial direction fixed, it is secured in the socket 52 by a screw 65. The screw may be screwed directly into the shaft 53 or engage in a notch of the shaft 53. The shaft 53 does not have to be rotatably supported in the bushing 52. The first radial bearing 51, which is rigidly connected to the support plate 35, is fixed between the sleeve 52 and an end piece 54 in the axial direction. The axial position of the second radial bearing 50 on the shaft 53 is rigidly defined, since the second radial bearing 50 is also rigidly connected to the support plate 35. A rotary damper 55 brakes the second radial bearing 50 during a pivoting movement of the support plate 35. A rotationally fixed brake element 66 of the rotary damper 55 is pressed by means of a spring 67 against a lateral surface of the second radial bearing 50 in order to achieve the damping effect. The shaft 53 is guided at its end, which is opposite to the end piece, through the guide rail 56 of the support frame 34. A roller or a ball bearing 68 facilitates the movement of the end of the shaft 53 in the guide rail 56th

Fig. 9 shows a cutting machine according to the invention in the embodiment as an oblique cutter. In a diagonal cutter, the cutting plane formed by the knife 11 is twisted with respect to the vertical. The oblique cutter also comprises a stop plate 21, a machine housing 2, knife guard ring 22, a Schlittenfuß 32, a latch button 31, a support plate 35 and a bearing wall 36, for their description Fig. 1 is referenced. A fixation plate 39 is mounted at right angles to the support plate 35. A lever 43 for fixing the fixing plate 39 is pivotable in a plane parallel to the support frame, wherein the support frame rests on the Schlittenfuß 32. For the function, reference is made mutatis mutandis to the previous description.

Claims (15)

Cutting machine (1) for separating slices of, in particular, strand-like material to be cut, comprising: a machine housing (2), a drive motor and a cutting blade (11) driven by the latter in a cutting plane in order to cut off slices, a movable parallel to the cutting plane stop plate (21) for setting a desired slice thickness, a slide (3) which can be moved back and forth parallel to the cutting plane and has a support plate (35) and a bearing wall (36), and wherein the support plate (35) and the abutment wall (36) form a holding device for the material to be cut, wherein the carriage (3) comprises a pivoting device (38) by means of which the support plate (35) can be moved between a starting position and a raised position, wherein the support plate (35) in the starting position and in the pivoted-up position with the cutting plane a right Angle forms, characterized, in that a fixing plate (39) is arranged at right angles to the support plate (35) and rigidly connected to the support plate (35), and that the fixing plate (39) has a slotted link, wherein the slotted link has at least two interventions (40, 42), in particular three interventions (40, 41, 42) for a locking element (43). Cutting machine according to claim 1, characterized in that the link is attached to an outer edge of the fixing plate (39). Cutting machine according to claim 1 or 2, characterized
that the carriage (3) via a carriage base (32) to the machine housing (2) is connected, and
that the carriage base (32) includes a support frame (34), wherein the support plate (35) in the starting position on the carriage base (32), in particular on the support frame (34) of the slide foot (32) rests. Cutting machine according to one of claims 1 to 3, characterized
in that the locking element is a lever (43) which, depending on the carriage position, can engage in one of the interventions of the fixing plate (39) or can be brought out of this engagement, and in that the lever (43), in particular in a plane parallel to the plane of the support frame (34), movable, in particular pivotable, is. Cutting machine according to claim 4, characterized in that the lever (43) is pressed with a spring into engagement of the fixing plate (39). Cutting machine according to one of claims 1 to 5, characterized
in that the pivoting device (38) comprises at least one radial bearing (50, 51) whose axis is perpendicular to the cutting plane, and in that the pivoting device (38) is connected to the support plate (35) in the region in which the abutment wall (36) engages the support plate (35) is connected. Cutting machine according to one of claims 3 to 6, characterized
in that the support frame (34) comprises a displacement device (61, 62) which mechanically connects the pivoting device (38) to the support frame (34), and in that the pivoting device (38) is parallel to the plane of the support frame by means of the displacement device (61, 62) (34) is movable. Cutting machine according to claim 7, characterized in that the fixing plate (39) comprises a slotted guide (45), in which a bolt (44) engages, wherein the bolt (44) is fixedly connected to the support frame (34), and that the pivoting the support plate (35) mechanically enforces a movement of the pivoting device (38) in the displacement device (61, 62) through the slotted guide. Cutting machine according to one of claims 7 to 8, characterized
in that a bushing (52) is movable parallel to the plane of the support frame (34) by means of a linear guide (61, 62) of the support frame (34), and in that the bushing (52) supports a shaft,
the at least one radial bearing is rotatably mounted on the shaft and fixedly connected to the support plate (35), and wherein one end of the shaft (53) in a guide rail (56) of the support frame (34) is linearly guided. Cutting machine according to one of claims 1 to 9, characterized
in that the swivel device (38) comprises a rotational damper (55). Cutting machine according to claim 10, characterized in that
in that the rotary damper (55) presses a rotationally fixed brake element (66) against a radial bearing (50) by means of a spring (67), wherein the radial bearing (50) is firmly connected to the support plate (35). Cutting machine according to one of claims 1 to 11,
characterized,
in that the carriage comprises a detent button (31) which engages in a detent, and the carriage (3) can be tilted about a carriage axis by releasing the detent button (31). Cutting machine according to claims 1 to 12, characterized
that the cutting machine is a vertical cutting machine and the support plate (35) is aligned in the starting position parallel to the horizontal plane. Cutting machine according to claim 13, characterized in that
that the support plate (35) is aligned in the pivoted position at an angle between 30 ° and 40 ° to the horizontal plane. Cutting machine according to claims 1 to 12, characterized
that the cutting machine is an inclined cutting machine.

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