JP4510544B2 - Cutting machine - Google Patents

Description

  The present invention relates to a cutting machine, and more particularly, to a cutting machine that positions a plurality of stacked cut objects such as paper and bookbinding on a table and cuts them in a pressed and fixed state.

  Conventionally, as this type of cutting machine, a table for placing a workpiece to be cut, a pressing fixing portion (also referred to as a “clamp”) for pressing and fixing the workpiece to be positioned and placed from above, and pressing 2. Description of the Related Art There is known a pressing drive mechanism that moves a fixed portion in the vertical direction, a knife that cuts an object to be cut, and a cutting drive mechanism that moves the knife in the vertical direction. Further, this cutting machine is provided with a cutting instruction switch (operation button), and when this switch is operated, a series of cutting processes, that is, (1) a process of lowering the pressing fixing portion by the pressing drive mechanism, ( 2) In a state where the object to be cut is pressed and fixed, a process of lowering the knife by the cutting drive mechanism is sequentially performed.

  In particular, the control device for the cutting machine has a timer for measuring a predetermined time, and the timing for starting to lower the knife is managed by the timer. That is, the knife starts to descend after a certain period of time (time required for pressing and fixing the object to be cut by the pressing fixing portion) elapses after the operation of the pressing drive mechanism starts.

  By the way, when the thickness of the material to be cut is the thinnest (that is, the moving distance of the pressing fixing portion is constant) so that the material to be cut can always be cut and fixed regardless of the thickness of the material to be cut. Set to the longest). For this reason, when the thickness of the material to be cut is large, the moving distance of the pressing and fixing portion is short, and although the material to be cut can be pressed and fixed in a relatively short time, it remains constant after the cutting instruction switch is operated. Until the time passed, the knife was not lowered, resulting in a series of processing times that were longer than necessary. Also known is a cutting machine that visually recognizes the height of the material to be cut to eliminate time loss, and allows the timer setting time to be adjusted manually according to the height of the material to be cut. However, according to this, trouble is required in the adjustment work, and there is a concern about a cutting error accompanying an adjustment error. In particular, when the height of the object to be cut is frequently changed, the burden on the worker is further increased and the work efficiency is greatly reduced.

  Therefore, in order to solve the above problems, Patent Document 1 includes a pulse generator that outputs a pulse signal in conjunction with the lowering operation of the pressing and fixing unit, and after the cutting instruction switch is operated, A cutting machine is disclosed that controls the knife to begin to descend when the output pulse signal is interrupted, i.e., when the pressure fixing part reaches the object to be cut and can no longer be moved. Yes. Further, this Patent Document 1 further includes a timer, and when a certain time (that is, a time corresponding to the case where the thickness of the object to be cut is thin) elapses after the cutting instruction switch is operated, an output from the pulse generator is performed. It is also disclosed that the knife starts to descend even if the pulse signal being stopped is not stopped, that is, even if the pressing and fixing portion is descending.

On the other hand, there is also known a cutting machine including an operation pedal for moving only the pressing fixing portion downward so that the pressing state and the positioning state can be confirmed while pressing and fixing the object to be cut on the table. According to this, it becomes possible to keep the object to be cut pressed and fixed by performing a stepping operation.For example, even when the object to be cut is displaced and a positioning error occurs when the object is pressed and fixed, By removing the foot, the pressing and fixing is released, and the positioning operation can be performed again. This cutting machine is also provided with a cutting instruction switch. When the cutting instruction switch is operated with the object to be cut pressed and fixed, the knife is lowered by the cutting drive mechanism.
JP 2000-254892 A

  However, in the cutting machine provided with the operation pedal, even if the method disclosed in the above-mentioned Patent Document 1 is applied, the working efficiency cannot be improved, and the processing time is still lost. That is, when the cutting instruction switch is operated, first, a signal for lowering the pressing fixing portion by the pressing drive mechanism is output from the control device. However, when the operation pedal is depressed, that is, the pressing fixing portion is In a state where the workpiece to be cut is pressed and fixed, even if the cutting instruction switch is operated, the pressing and fixing portion does not move, and therefore the pulse generator cannot output a pulse signal. For this reason, the knife cannot be lowered until a certain time (a relatively long time set corresponding to the case where the thickness of the object to be cut is thin) elapses after the cutting instruction switch is operated. There was waste.

  Therefore, in view of the above situation, the present invention makes it possible to reduce the time from the operation of the cutting instruction switch to the cutting by the knife even in the cutting machine including the operation pedal, and to increase the working efficiency. The issue is to provide a cutting machine.

The cutting machine according to the present invention includes: “a pressing fixing portion that presses and fixes a workpiece placed on a table from above, a pressing drive mechanism that moves the pressing fixing portion in the vertical direction, and the workpiece to be cut. A cutting drive mechanism for moving the knife in the vertical direction, a movement signal output means for outputting a signal indicating a moving state during the movement of the pressing fixing portion, and pressing fixing and cutting of the workpiece to be cut A cutting instruction switch for instructing to execute the process as a series of processes, a manual operation part for moving only the pressing fixing part downward by manual operation, and the pressing drive mechanism when the cutting instruction switch is operated. After that, when the signal output from the movement signal output means stops, the first cutting control means for starting the operation of the cutting drive mechanism and the cutting instruction switch are operated. Even certain time has elapsed since said when the signal from the movement signal output means is not outputted, the deemed to be cut object is pressed and fixed by the pressing fixing unit, the operation of the cutting drive mechanism And a second cutting control means to start ".

  Here, the “pressing drive mechanism” and the “cutting drive mechanism” are, for example, a drive source, a transmission member that transmits the power of the drive source to the press fixing unit and the knife, and sliding the press fixing unit and the knife in the vertical direction. It can comprise from the supporting member supported so that it is possible. The “power source” is not particularly limited, and for example, a hydraulic device such as a hydraulic cylinder or an electric motor such as a servo motor can be used. Moreover, the signal output from the “movement signal output means” may be a signal determined as a signal indicating the movement state of the pressing and fixing portion, and may be either a pulse signal or a direct current signal. The “cutting instruction switch” may be directly opened / closed or may be opened / closed via an operation of a push button or the like. In addition, when a push button is provided, it may be arranged at a site that can be operated by hand, or may be arranged at a site that can be stepped on with a foot. Further, examples of the “manual operation unit” include an operation pedal operated by a foot or an operation lever operated by a hand. In addition, the “manual operation unit” may directly drive the pressing and fixing unit and the pressing drive mechanism by human power, or may indirectly drive using hydraulic pressure or electricity. The “up and down direction” described above includes not only the vertical direction but also an oblique vertical direction.

  According to the present invention, when the object to be cut is positioned on the table and the cutting instruction switch is operated without operating the manual operation unit, the pressing drive mechanism operates to lower the pressing fixing unit. As a result, the object to be cut placed on the table is pressed and fixed by the pressing and fixing portion, and no positional deviation occurs. A signal is output from the movement signal output means as the pressing and fixing portion descends, but the signal is no longer output when the pressing and fixing portion comes into contact with the object to be cut.

  Therefore, in the present invention, when the signal output from the movement signal output means stops, the operation of the cutting drive mechanism is started and the knife is lowered. That is, regardless of the thickness of the material to be cut, the knife is quickly lowered after the material to be cut is pressed and fixed.

  On the other hand, as described above, when the manual operation unit is operated, no signal is output from the movement signal output means, but in the present invention, when the cutting instruction switch is operated, the time measurement is started and a certain time has elapsed. However, if the signal is not output from the movement signal output means, that is, if the press fixing part is already lowered and the object to be cut is pressed and fixed by the operation of the manual operation part, the cutting drive mechanism is immediately operated. Start and lower the knife.

  By the way, the shorter the time required for recognizing that no signal is output from the movement signal output means, the shorter the waiting time is lost, and the work efficiency can be increased. However, when a series of processing is performed continuously, there is an electrical control delay or an operation delay of the press drive mechanism from when the cutting instruction switch is operated until the press fixing part actually moves and starts outputting a signal. As a result, a certain delay time (for example, 0.1 second) is generated. Therefore, when the above-mentioned fixed time is extremely shortened, the object to be cut is pressed and fixed even though the pressing and fixing part can be moved. May be malfunctioned. That is, the cutting process may be performed before the object to be cut is pressed and fixed.

  Therefore, in the cutting machine according to the present invention, “the predetermined time in the second cutting control means is a delay from when the cutting instruction switch is operated until the pressing fixing portion actually moves and the signal starts to be output. It is preferable to adopt a configuration that is set to be longer than time.

  According to this, it is possible to prevent the cutting process from being performed due to a malfunction even though the object to be cut is not pressed and fixed, and to prevent a cutting error due to misalignment.

  As described above, in the cutting machine of the present invention, even when the object to be cut is pressed and fixed by the operation of the manual operation unit using an operation pedal or the like, it is possible to quickly lower the knife, and the cutting instruction The time from when the switch is operated until the cut object is cut can be greatly reduced.

  Hereinafter, the cutting machine which is one Embodiment of this invention is demonstrated based on FIG. 1 thru | or FIG. 1 is a front view showing a schematic configuration of the cutting machine, FIG. 2 is a rear view showing a configuration in the vicinity of a rotary encoder in the cutting machine, FIG. 3 is a side view showing a configuration of a main part, and FIG. FIG. 5 is a block diagram showing a configuration of a control device and a hydraulic circuit, FIG. 5 is a timing chart showing a series of operations in time, and FIG. 6 is a flowchart showing a flow of processing.

  The cutting machine of this example is a device that cuts a plurality of sheets of paper, bookbinding, rubber, wood, carbon, or the like in a stacked state. As shown in FIG. 1 and FIG. A pressing and fixing portion 4 that presses and fixes the workpiece 3 placed thereon from above, and the pressing and fixing portion 4 is moved in the vertical direction and pressed against the workpiece 3 by a downward biasing force. A pressing drive mechanism 5 for cutting, a knife 6 for cutting the workpiece 3 pressed and fixed, and a cutting drive mechanism 8 for moving the knife 6 and the knife holder 7 holding the knife 6 in an obliquely vertical direction. Yes. Further, below the main body 9 on which the table 2 is disposed, an operation pedal 10 that is stepped on by an operator's foot is provided so as to protrude forward. The table 2 is provided with a resin-cut trimming tree 12 facing the tip of the knife 6. Here, the operation pedal 10 corresponds to the manual operation unit of the present invention.

  The above configuration will be described in detail. As shown in FIG. 2, the pressing and fixing portion 4 is composed of a plate-like member having a substantially rectangular front shape, and a pair of sliding portions 14 are formed at both ends thereof, and the lifting guide fixed to the main body 9. 15 is attached to be slidable in the vertical direction. Further, one sliding portion 14 is integrally provided with a rack 17 having a tooth portion formed on the outer surface, and meshes with a pinion 18 that is rotatably supported by the lifting guide 15. The rotary encoder 16 is connected to the pinion 18 so that the rotational amount of the pinion 18, that is, the rotational momentum according to the linear motion of the rack 17 is output from the rotary encoder 16 as a pulse signal. . That is, in this example, the output of the rotary encoder 16 is monitored to determine whether or not the pressing and fixing unit 4 is moving. Here, the rotary encoder 16 corresponds to the movement signal output means of the present invention.

  As shown in FIG. 1, the pressing drive mechanism 5 includes a mechanism for moving the pressing fixing portion 4 upward and a mechanism for moving the pressing fixing portion 4 downward. The former mechanism includes a sprocket 20 pivotally supported by the main body 9, a chain 21 having one end connected to the upper surface of the press fixing portion 4 and stretched via the sprocket 20, and a return connected to the other end of the chain 21. The spring 22 and the elastic force of the return spring 22 urge the pressing and fixing portion 4 upward via the chain 21. On the other hand, the latter mechanism urges the pressing and fixing portion 4 downward against the elastic force of the return spring 22 and presses the movement of the hydraulic cylinder 27 and the piston rod (not shown) of the hydraulic cylinder 27. It consists of a pair of transmission mechanisms 23 that transmit to both ends of the bottom surface of the fixed portion 4. Note that the transmission mechanism 23 includes an arm 25 having one end connected to a piston rod and pivotally supported by a rotating shaft 26, and a link 24 connecting the other end of the arm 25 and the pressing fixing portion 4.

  On the other hand, the cutting drive mechanism 8 includes a servo motor 36 (see FIG. 4) and a transmission mechanism 33 that converts the rotational motion of the servo motor 36 into a linear motion and transmits the linear motion to the knife holder 7. The transmission mechanism 33 includes a crank 35 connected to the rotation shaft of the servo motor 36 via a speed reducer (not shown), and a link 34 connecting the crank 35 and the lower end corner of the knife holder 7. ing. In other words, when the crank 35 rotates once around the shaft 35a by driving the servo motor 36, the knife holder 7 and the knife 6 are lowered via the link 34, and are again raised after passing through the bottom dead center. ing. In particular, in the cutting machine 1 of this example, the knife 6 and the knife holder 7 are reciprocated obliquely in the vertical direction in order to easily cut the workpiece 3. Specifically, a guide groove 32 extending obliquely in the vertical direction is formed on the back surface of the knife holder 7, and a slide piece 31 is slidably fitted in the guide groove 32. Since the slide piece 31 is pivotally supported by the slide support plate 30 of the main body 9, the knife holder 7 is guided in an obliquely vertical direction while being regulated by the slide piece 31. The cutting drive mechanism of the present invention is not limited to the above-described configuration. For example, the cutting drive mechanism includes a flywheel and a clutch brake, and is controlled by the clutch brake, or a pair of cranks 35 are provided on the left and right. The present invention can also be applied to a cutting machine provided with only one set of the guide groove 32 and the slide piece 31 and the like, and can be changed as appropriate.

  Incidentally, as shown in FIG. 4, in the cutting machine 1, a tank 46 and a pump 39 are connected to the hydraulic cylinder 27 via a hydraulic circuit 38 in order to control the hydraulic pressure applied to the hydraulic cylinder 27. The hydraulic circuit 38 includes a supply circuit 40 that supplies high-pressure liquid to the hydraulic cylinder 27, a pressure control circuit 41 that causes the liquid to flow to the pressure control valve 45, and a drive circuit 42 that is parallel to the pressure control valve 45. An electromagnetic valve 43 and a cam operation valve 44 are interposed in 42. The solenoid valve 43 is maintained in an open state when not energized, and is closed by energization, and the cam operation valve 44 is maintained in a fully open state when the operation pedal 10 is not operated. The opening degree is reduced through the cam in accordance with the operation of the operation pedal 10. That is, when the solenoid valve 43 is not energized and the operation pedal 10 is not operated, the drive circuit 42 is conducted, so that no pressure is applied to the hydraulic cylinder 27 and the hydraulic cylinder 27 is inactive. That is, the pressing and fixing portion 4 is held at the upper limit position by the elastic force of the return spring 22. On the other hand, when the solenoid valve 43 is energized, the solenoid valve 43 is closed and the drive circuit 42 is closed, so that pressure is applied to the hydraulic cylinder 27 with the set pressure of the pressure control valve 45, and the hydraulic cylinder 27 operates. That is, the pressing and fixing portion 4 is moved downward against the elastic force of the return spring 22. Even if the solenoid valve 43 is not energized, when the opening degree of the cam operation valve 44 is reduced by depressing the operation pedal 10, the pressure applied to the hydraulic cylinder 27 gradually increases and the hydraulic cylinder 27 starts to operate.

  As shown in FIG. 4, the cutting machine 1 is provided with a control device 50 for performing a series of cutting processes. The control device 50 includes a cutting control unit 52 including a timer 51 and a CPU. A cutting instruction switch 53 and a rotary encoder 16 are connected to an input port of the cutting control unit 52. Here, the cutting instruction switch 53 is used to instruct the pressing and cutting of the workpiece 3 to be executed as a series of processes, and is configured to be operated via a push button (not shown). Yes. On the other hand, an electromagnetic valve drive circuit 55, a motor drive circuit 56, and the like are connected to the output port of the cutting control means 52. The electromagnetic valve driving circuit 55 controls opening / closing of the electromagnetic valve 43 based on the output of the cutting control means 52, and the motor driving circuit 56 controls rotation of the servo motor 36 based on the output of the cutting control means 52. It is. Here, the cutting control means 52 corresponds to the first cutting control means and the second cutting control means of the present invention. Although not shown, normally, the cutting machine 1 is provided with a pressure control valve between the solenoid valve 43 and the cam operation valve 44 in order to keep the pressing and fixing pressure during manual operation low for safety reasons. Alternatively, the pressure control valve 45 is switched for use.

  Next, the flow of processing in the cutting control unit 52 will be described with reference to FIGS. In FIG. 5, (a) shows a series of cutting steps, which are started by turning on the cutting instruction switch 53, and are ended after a predetermined time. (B) shows a change in the position of the pressing and fixing portion 4 and is lowered by the hydraulic cylinder 27 when the cutting instruction switch 53 is operated. It should be noted that a certain delay time t1 (for example, 0.1 second) occurs after the cutting instruction switch 53 is operated until the pressing and fixing portion 4 actually starts to move. On the other hand, as shown in FIG. 5A, even if the cutting instruction switch 53 is not operated, when the operation pedal 10 is operated, the press fixing portion 4 is lowered by the hydraulic cylinder 27.

  (C) shows the output of the rotary encoder 16, and a pulse signal of a predetermined cycle is outputted while the pressing and fixing portion 4 is moving. (D) shows the result of determining whether or not the press fixing part 4 presses and fixes the workpiece 3 based on the output of the rotary encoder 16. That is, when the pulse signal is output from the rotary encoder 16, it is determined that the workpiece 3 is not pressed and fixed because the pressing and fixing portion 4 is moving (descent), and the pulse signal is constant. When the time t3 (for example, 0.05 seconds) is not detected, it is determined that the pressing and fixing portion 4 has stopped by contacting the object 3 to be cut. In particular, the timer for determining the stop of the pulse signal, that is, the timer for measuring the above-mentioned fixed time t3 is always timed and is configured to be reset by the pulse signal output from the rotary encoder 16. . For this reason, this timer is timed up not only when the pulse signal is interrupted but also when no pulse is generated from the beginning. Therefore, before the cutting instruction switch 53 is operated, when the operation pedal 10 is stepped on and the pressing fixing portion 4 is lowered, that is, when the cutting process starts from the state in which the workpiece 3 is pressed and fixed. Also, it is determined that the workpiece 3 is pressed and fixed. Note that the shorter the predetermined time t3 is set, the faster the pressing and fixing state of the workpiece 3 can be determined. However, the delay time t1 described above, that is, the delay when the pressing and fixing portion 4 starts to move. Since it is shorter than the time, it is erroneously determined as being pressed and fixed although the pressing and fixing portion 4 moves (that is, even though the workpiece 3 is not pressed and fixed). Therefore, in this example, the pressing determination is not started for a certain time t2 (for example, 0.1 second) after the cutting instruction switch 53 is turned on. That is, by setting the length (t4) obtained by adding the time t2 and the time t3 to be longer than the delay time t1, erroneous determination due to the delay time is prevented.

  (E) shows a change in the position of the knife 6. When it is determined that the workpiece 3 is pressed and fixed, that is, when the signal shown in (d) changes from Lo to Hi, the servo motor 36. Will rise again after passing through the bottom dead center. That is, the workpiece 3 is cut by reciprocation.

  The cutting control means 52 stores a program for executing a series of cutting processes and performs processing as shown in FIG. That is, first, when the cutting instruction switch 53 is turned on (YES in step S1), the electromagnetic valve 43 is closed by the electromagnetic valve drive circuit 55 and the hydraulic pressure is supplied to the hydraulic cylinder 27 (step S2). As a result, the pressing and fixing portion 4 is lowered via the transmission mechanism 23 and the workpiece 3 is pressed and fixed. In addition, before the cutting instruction switch 53 is operated, when the press fixing part 4 is held on the workpiece 3 by the operation pedal 10, the state is maintained.

  Thereafter, the process waits until a predetermined time t2 (0.1 seconds) elapses. When the predetermined time t2 elapses (YES in step S3), it is determined whether or not a pulse signal is output from the rotary encoder 16 (step S4). ) When the pulse signal is not output for a certain time t3 (0.05 seconds) (YES in steps S4 and S5), the servo motor 36 is driven to reciprocate the knife 6 via the transmission mechanism 33 (step S4). S6). If it is detected that the knife 6 has passed the bottom dead center during the movement of the knife 6 (YES in step S7), the electromagnetic valve 43 is opened and the supply of hydraulic pressure to the hydraulic cylinder 27 is stopped (step S7). S8). Thereby, the press fixing part 4 is returned upward by the elastic force of the return spring 22, and a series of cutting processes is completed.

  Thus, according to the cutting machine 1 described above, not only when the pulse signal output from the rotary encoder 16 is interrupted, but also when the pulse signal is not output from the beginning, that is, by the operation of the operation pedal 10, the object to be cut 3 is cut. Can be quickly lowered even if is already pressed and fixed. For this reason, it is possible to greatly shorten the time from the operation of the cutting instruction switch 53 to the cutting of the material 3 to be cut, and to improve the work efficiency.

  Further, when it is determined that the pulse signal is not output from the beginning, a delay time from when the cutting instruction switch 53 is operated until the pressing and fixing unit 4 actually starts to move is taken into consideration. Although the object 3 is not pressed and fixed, it is possible to prevent the cutting process from being performed due to a malfunction, and to suppress the cutting error due to the displacement.

  The present invention has been described with reference to preferred embodiments. However, the present invention is not limited to these embodiments, and various modifications can be made without departing from the spirit of the present invention as described below. And design changes are possible.

  That is, in the cutting machine 1 according to the present embodiment, the rotary encoder 16 attached to the lifting guide 15 is configured to output a pulse signal indicating the movement state of the pressing and fixing unit 4. And a pulse signal may be output by movement of the piston rod. Further, the encoder is not limited to the direct acting type, but may be a wire type, an optical type or a magnetic type. Furthermore, instead of the rotary encoder 16, a pressure gauge may be provided, and a signal corresponding to the moving state of the pressing and fixing unit 4 may be output by detecting a change in pressure applied to the hydraulic cylinder 27. In other words, the movement signal output means of the present invention is not particularly limited as long as it outputs different signals depending on whether the pressing and fixing unit 4 is lowered or stopped, and the output signal is a direct current even if it is a pulse. It does not matter.

  Moreover, in the cutting machine 1 of this embodiment, in order to determine whether the to-be-cut object 3 was press-fixed, what provided the rotary encoder 16 was shown, but other control, for example, "Press fixing | fixed part 4 is shown. In a cutting machine equipped with an encoder for “control that changes the hydraulic pressure applied to the hydraulic cylinder 27 by detecting a change in the pulling force of the return spring 22 due to the height of the return spring 22”, the encoder may also be used. According to this, since it can implement | achieve without newly providing a movement signal output means, it becomes possible to perform a series of cutting processes rapidly, comparatively cheaply and without making a structure complicated.

  Further, in the cutting machine 1 of the present embodiment, the one provided with a timer for delaying the start of the press determination by a predetermined time t2 is shown in order to prevent erroneous determination due to the delay time t1 of the press fixing unit 4, but the pulse signal If the time t3 of the timer for recognizing the stop state is set to a time (for example, 0.2 seconds) longer than the delay time t1, it can be realized without providing a timer for delaying the start of the pressure determination. . That is, according to this, although the working efficiency is somewhat worse than that of the above embodiment, the configuration and control can be simplified because it can be realized by one timer. In the cutting machine 1 of the present embodiment, the total time (t2 + t3) of the two timers is set to be longer than the delay time t1, but the time t2 itself for delaying the start of the pressure determination is shown. Is set to be longer than the delay time t1, a timer for counting the fixed time t3 is started when the cutting instruction switch 53 is operated, and both timers are timed up. It can also be determined that the pressure is fixed.

It is a front view which shows schematic structure of the cutting machine which is one Embodiment of this invention. It is a rear view which shows the structure of the rotary encoder vicinity in a cutting machine. It is a side view which shows the structure of the principal part in a cutting machine. It is a block diagram which shows the functional structure of the hydraulic circuit and control apparatus in a cutting machine. It is a timing chart which time-sequentially shows a series of operation | movement in a cutting machine. It is a flowchart which shows the flow of the process in a cutting machine.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Cutting machine 2 Table 3 Cut object 4 Press fixing | fixed part 5 Press drive mechanism 6 Knife 8 Cutting drive mechanism 10 Operation pedal (manual operation part)
16 Rotary encoder (movement signal output means)
52 Cutting control means (first cutting control means, second border control means)
53 Cutting instruction switch t4 Fixed time

Claims (1)

A pressing and fixing portion that presses and fixes the workpiece to be cut placed on the table from above;
A pressing drive mechanism for moving the pressing fixing portion in the vertical direction;
A knife for cutting the material to be cut;
A cutting drive mechanism for moving the knife in the vertical direction;
Movement signal output means for outputting a signal indicating a movement state during movement of the pressing and fixing portion;
A cutting instruction switch for instructing that the pressing and cutting of the object to be cut and cutting be executed as a series of processes;
A manual operation unit for moving only the pressing and fixing unit downward by manual operation;
A first cutting control unit that operates the pressing drive mechanism when the cutting instruction switch is operated, and then starts the operation of the cutting drive mechanism when the signal output from the movement signal output unit stops; ,
If the signal is not output from the movement signal output means even after a certain time has elapsed since the cutting instruction switch was operated, it is considered that the object to be cut is pressed and fixed by the pressing and fixing unit, Second cutting control means for starting the operation of the cutting drive mechanism ,
The predetermined time in the second cutting control means is set to be longer than a delay time from when the cutting instruction switch is operated until the pressing and fixing portion actually moves and the signal starts to be output. <br/> A cutting machine characterized by that.

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