DE10104051B4 - Cutting device for laminator films - Google Patents

Abstract

Laminator foil cutter with a movable cutting blade for cutting the laminator film, characterized by a plurality of selection switches (SW1, SW2, SW3, SW4, SW5, SW6) for selecting one of a plurality of predetermined cutting sizes, over the Length that Cutter is movable, and by a microprocessor control unit (MCU) for controlling the moving speed of the cutting blade in pulse width modulated way.

Description

The The present invention relates to a laminator film cutter according to the preamble of Claim 1. She is able to paper or foil the most common Sizes that used throughout the world, automatically as an answer on a switch operation a control panel, such as 1,800 mm, A0, A1, A2, A3 and A4.

conventional Cutting devices have a low cutting speed because each of the cutting devices has a cutting blade which over a predetermined distance moves regardless of the size of the trimming foil or paper. It also has a conventional Cutting device difficulties in this regard, a film or a paper with the sizes of A0 to A4 to crop.

In the prior art is next to the DE 697 11 243 T2 a cutting device for so-called recording paper known with a control panel, in which there are possibilities for selecting one of a plurality of predetermined cutting sizes over the length of the associated cutting blade is movable.

Of these, The present invention is based on the object, to provide a laminator film cutter which is faster and works more efficiently especially with changing cutting sizes.

The The object is achieved by a laminate film cutting device with the Characteristics of claim 1 solved.

With The selector switch can be of any international standard size such as 1,800 mm, A0, A1, A2, A3 and A4 are selected as cutting size, preferably a Light emitting diode is provided to the selected trim size on a Control panel. By that, finally, the microprocessor-integrated Circuit is provided to a speed of movement of a To control the cutting blade in a pulse width modulation mode, Is it possible, that a cutting process is precise and performed efficiently can be.

The The present invention will become more detailed in the following description of exemplary embodiments with the attached Drawings, closer explained, show here

1 a schematic circuit diagram of a laminator film cutting device in accordance with the present invention;

2 a detailed circuit diagram of a main control circuit in accordance with the present invention;

3 a detailed circuit diagram of a photo interrupter in accordance with the present invention; and

4 a front view of a control panel in accordance with the present invention.

1 Fig. 10 is a schematic circuit diagram of a laminating film cutting apparatus in accordance with the present invention. As shown in this drawing, a voltage terminal VDD of + 5 volts is connected through a resistor R31 to a common connection point of a key input terminal KEY, to one end of a resistor R32, and to a switch SW1, which is in turn connected to a ground terminal. The other end of the resistor R32 is connected to a common connection point of one end of a resistor R33 and a switch SW2, which in turn is connected to ground. The other end of the resistor R33 is connected to a common connection point of one end of a resistor R34 and a switch SW3, which in turn is connected to ground. The other end of the resistor R34 is connected to a common connection point of one end of a resistor R35 and a switch SW4, which in turn is connected to ground. The other end of the resistor R35 is connected to a common connection point of one end of a resistor R36 and a switch SW5, which in turn is connected to ground. The other end of the resistor R36 is connected to one end of a switch SW6 whose other end is connected to ground.

A terminal CN8 has a pin 1 which is connected to a common connection point of the voltage terminal VDD of + 5 volts and a terminal 1 a variable resistor VR1, further comprising a terminal 2 Includes with a pen 6 of the connector CN8, and a terminal 3 that is connected to the earth. A pen 2 of the connector CN8 is connected to one end of a light emitting diode (LED) A LD1 whose other end is connected to the ground through a resistor R38. A pen 3 of the plug CN8 is connected to one end of an LED B LD2, the other end of which is connected to ground via a resistor R39. A pen 4 of the connector CN8 is connected to one end of an LED C LD3 whose other end is connected to the ground through a resistor R40. A pen 5 of the connector CN8 is connected to one end of a LED D LD4 whose other end is connected to the ground through a resistor R41. A pen 7 of the connector CN8 is connected to the key input terminal KEY and a pen 8th of the plug is connected to earth.

2 FIG. 12 is a detailed circuit diagram of a main control circuit in accordance with the present invention. FIG. As shown in this drawing, a connector CN3 has a pin 1 which is connected to the voltage terminal VDD of + 5 volts, a pin 2 which is connected to earth via a resistor R7, and a pin 3 which is connected to a base of a transistor Q5. The transistor Q5 also has an emitter connected to ground and a collector connected to the voltage terminal VDD through a resistor R6 and directly to a pin 1 an inverter U2 / A is connected, the further a pin 2 that includes with a pen 25 a microprocessor control unit (MCU) U3 is connected.

A connector CN4 has a pin 1 on which is connected to the voltage terminal VDD, a pin 2 which is connected to ground via a resistor R14 and a pin 3 which is connected to a base of a transistor Q10. The transistor Q10 also has an emitter connected to ground and a collector connected to the voltage terminal VDD via a resistor R13 and directly to a pin 3 an inverter U2 / B is connected, the further a pin 4 that includes with a pen 26 the MCU U3 is connected.

A connector CN6 has a pin 1 on which is connected to the voltage terminal VDD, a pin 2 which is connected to earth via a resistor R20, and a pin 3 which is connected to a base of a transistor Q15. Transistor Q15 also has an emitter connected to ground and a collector connected to voltage terminal VDD via resistor R18 and directly to a pin 5 an inverter U2 / C is connected, the further a pin 6 that includes with a pen 27 the MCU U3 is connected.

A plug CN9 has a pin 1 on which is connected to the voltage terminal VDD, a pin 2 which is connected to earth via a resistor R29, and a pin 3 which is connected to a base of a transistor Q18. The transistor Q18 also has an emitter connected to ground and a collector connected to the voltage terminal VDD through a resistor R28 and directly to a pin 11 an inverter U2 / E is connected, the further a pin 10 that includes with a pen 28 the MCU U3 is connected.

The pencil 1 or VDD of the connector CN8 is as described above with reference to FIG 1 is described - with a pen 20 the MCU U3 connected, the pin 2 or the LED A thereof is with a pen 15 the MCU U3 connected, the pin 3 or the LED B of this is with a pen 16 the MCU U3 connected and the pin 4 or the LED C thereof is with a pen 17 connected to the MCU U3. Besides, the pen is 5 or the LED D of connector CN8 with a pin 18 the MCU U3 connected and the pin 6 or the speed port SPEED of this is with a stylus 2 connected to the MCU U3. One connector CN7 has pins 1 and 2 which are connected to a footswitch. The pencil 1 of the connector CN7 is also connected to the voltage terminal VDD via a resistor R21 and directly to a pin 9 connected to an inverter U2 / D, which further has a pin 8th which has a pen 12 the MCU U3 is connected. The pencil 2 connector CN7 is also connected to ground.

A connector CN1 has pins 1 and 2 , each with pins 2 and 4 a bridge diode BD1 are connected, which further has a pin 3 includes, which is directly connected to the earth, and a pen 1 which is connected to earth via an electrolytic capacitor EC3. The pencil 1 The bridge diode BD1 is also connected to a collector of a transistor Q3 through resistors R1 and R3 and directly to a collector of a transistor Q2 and a source of a field transistor (FET) Q1. A signal terminal PWM is connected through resistors R4 and R5 to ground and through resistor R4 to a base of transistor Q3, which in turn has an emitter connected to ground. The collector of the transistor Q3 is commonly connected to bases of the transistor Q2 and a transistor Q4 through the resistor R3. The transistor Q2 further has an emitter connected to a gate of the FET Q1 through a resistor R2 and directly to an emitter of the transistor Q4, which in turn has a collector connected to ground.

The MCU U3 also has a stylus 21 which is connected to the ground via resistors R15 and R16 and via the resistor R15 to a base of a transistor Q8 which further includes an emitter connected to the ground and a collector connected through resistors R11 and R9 to a base Signal connection terminal MV and is connected via the resistor R11 to a gate of the FET Q6. The MCU U3 also has a stylus 22 connected to ground through resistors R17 and R19 and via resistor R17 to a base of a transistor Q9 which also has an emitter connected to ground and a collector connected to resistors R12 and R10 through resistors R12 and R10 Signal terminal MV and is connected via the resistor R12 to a gate of the FET Q7. The MCU U3 also has a stylus 23 which is connected to a base of a transistor Q16 further including an emitter connected to ground and a collector connected to the signal terminal MV through a resistor R22 and to a base of a transistor Q13 through a resistor R101 connected is. Transistor Q13 also has an emitter connected to signal terminal MV and a collector connected to ground through resistors R24 and R26 and connected through resistor R24 to a gate of FET Q11.

The MCU Q3 has a stylus 24 which is connected to a base of a transistor Q17 further including an emitter connected to ground and a collector connected to the signal terminal MV through a resistor R23 and to a base of a transistor Q14 via a resistor R102 is. The transistor Q14 further has an emitter connected to the signal terminal MV, and a collector connected to ground through resistors R25 and R27 and to a gate of a FET Q12 through the resistor R25.

Of the FET Q6 also points a drain connection, which together with an anode of the diode D7, a cathode of a Diode D9, a connector CN5, a motor M and a drain terminal of the FET Q11 is connected. The FET Q7 also has a drain terminal which together with the plug CN5, the motor M, an anode of the diode D8, a drain of the FET Q12 and a cathode of a diode D10 is connected. The FET Q11 also points a source common to an anode of the diode D9, a Source of FET Q12, an anode of diode D10 and one end of a Power switch PSW 1 is connected, the other end with the Earth is connected.

3 Fig. 10 is a detailed circuit diagram of a photointerrupter U1 in accordance with the present invention. A connector CN4 has a pin 1 on which is connected to the voltage terminal VDD, a pin 2 which is connected to ground via a resistor R14 and a pin 3 which is connected to a base of a transistor Q10. The transistor Q10 also has an emitter connected to the ground terminal, and a collector connected to the power terminal VDD through a resistor R13 and a pin 3 an inverter U2 / B is connected, the further a pin 4 that includes with a pen 26 the MCU U3 is connected. As shown in this drawing, the photointerrupter U1 includes a photodiode having an anode and a cathode connected to a stylus 2 of a connector CON1, and a phototransistor having a base optically connected to the photodiode, an emitter connected to a stylus 1 Connected to the connector CON1, and a collector, which shares a pin 3 of the connector CON1 and the anode of the photodiode is connected.

4 Figure 11 is a front view of a control panel in accordance with the present invention. As shown in this drawing, a plurality of push button switches are arranged on the control panel, each corresponding to trim sizes of 1,800 mm, A0, A1, A2, A3 and A4, LEDs A, B, C and D and a speed adjustment knob.

following the function of the laminator film cutter with the aforementioned construction in accordance described with the present invention.

1. Function of selecting the Cutting size and the Turning on the LED

The pushbutton switches, which are each assigned to internal forces of 1,800 mm, A0, A1, A2, A3 and A4, and in 4 are respectively corresponding to the switches SW1, SW2, SW3, SW4, SW5 and SW6 1 , When one of the switches SW1 to SW6 is depressed, a corresponding voltage is applied to the key input terminal KEY 1 at. For example, in the case where a selected cut size is 1,800 mm, the switch to be pushed is SW1 and a voltage of 0 volt reaches the key input terminal KEY. This is defined as Relation 1.800-SW1-0V.

Similarly, the following relationships can be defined among the other internal forces, selectors, and voltages: A0-SW2-0.45V, A1-SW3-0.9V, A2-SW4-1.429V, A3-SW5-1.914V, and A4- SW6-2,436V. It can be seen from these relationships that a voltage applied to the key input terminal KEY in 1 occurs, depends on the average size selections by the switches SW1-SW6.

The voltage at the key input terminal KEY is applied to the pin 7 of the connector CN8 from the 1 and 2 Transfer and then on a pen 3 the MCU U3 off 2 ,

The MCU U3 gives voltages to its pins 15 . 16 . 17 and 18 according to a program previously stored herein, to activate respective LEDs to emit light.

in the Case that the switch SW1 has been pressed to the cutting size of 1,800 to select mm, are for example the LEDs A and D are activated to emit light (SW1-1.800 LED's A and D).

In similar Way you can the following relations among the other selector switches, internal forces and LED's defined be: SW2-AO-LED's A and C, SW3-A1 LED's A and B, SW4-A2 LED's B and D, SW5-A3 LED's B and C and SW6-A4 LEDs C and D.

The LEDs A, B, C and D are on the control panel according to 4 installed to emit light in the above manner, so that an operator can easily recognize a selected cutting size.

With each of the average size selection switches SW1-SW6 being pressed, the MCU sends U3 to its pin 13 a pulse width modulated (PWM) signal which is a pulse signal of 24 kHz. This PWM signal has a duty cycle that is changeable within the range of 30 to 90% according to the settings by the knob serving to set a moving speed of a cutting knife.

2. Function of the setting the speed of movement of a cutting knife

The variable resistor VR1 in 1 is set with respect to the resistance value by setting the speed setting button on the control panel in FIG 4 , This variable resistor VR1 is connected to the pin 2 the MCU U3 through the connector CN8 from the 1 and 2 connected. When the footswitch is down, the MCU releases U3 on its pin 13 according to the pre-stored program, a PWM pulse signal of 24 kHz whose duty cycle varies within the range of 30 to 90% with a change of the resistance of the variable resistor VR1. This PWM signal is voltage divided by the resistors R4 and R5 and is transmitted to the base of the transistor Q3, resulting in the resulting signal which occurs at the collector of the transistor Q3 and is commonly transmitted to the bases of the transistors Q2 and Q4. Then, a signal of the common emitter of the transistors Q2 and Q4 is transferred to the gate of the FET Q1.

When Result, a signal appears at the drain terminal of the FET Q1 with a voltage of about 40 volts, one frequency of 24 kHz and a duty cycle that is within the range from 30 to 90% according to the setting of the variable resistor VR1 varies.

3. Function of the drive motor for normal movement of the cutting knife

In 2 gives the MCU U3 voltages on their pins 21 . 22 . 23 and 24 to normally drive the motor M, to drive it in the opposite direction or to stop it immediately.

Normal Drive: When the footswitch is depressed, the MCU U3 will provide voltage signals to its pin 21 or its terminal A and pin 24 or terminal D off. The voltage signal at terminal A causes a signal at the collector of transistor Q8 to activate FET Q6. As a result, the PWM signal at the drain terminal of the FET Q1 is transmitted to the motor M through the FET Q6 and the connector CN5. The voltage signal at terminal D causes a signal to appear at the collector of transistor Q17, causing a signal to appear at the collector of transistor Q14. This signal at the collector of transistor Q14 is transferred to the gate of FET Q12 causing the drain terminal of FET Q12 to be connected to ground. By transmitting a ground voltage to the motor M through the connector CN5, the motor M rotates in the normal direction, and thus the cutter blade cuts an inserted film during the normal movement.

4. Function of stopping the movement of the cutting knife

As in 4 is indicated, the moving cutting blade traverses on its travel up to 4 positions A, B, C, D, each having the usual paper sizes corresponding distances to each other and thus form the breakpoints for the cutting blade. By suitable juxtaposition of the trajectories between position A and B, between position B and C and between position C and D results - as in 4 is indicated - for each of the mentioned common paper sizes the corresponding travel length. Thus, when one of the cutting size selection switches SW1 to SW6 is depressed, the motor is controlled by the MCU U3 to move the cutting blade between the positions corresponding to the selected paper size (as shown in FIG 4 are indicated) moves. The reaching of the end position is monitored by the fact that in the positions A, B, C and D respectively a photo interrupter U1 (see 3 ) is arranged. Now the photo interrupter by the moving edge Covered knife when reaching the respective position A, B, C or D, so the associated photo interrupter U1, which thus acts as a scanning device for the position of the Schneidemessers generates an output signal and passes this to the connector CON1 on.

The output signal from connector CON1 is transmitted along the following paths: SNA-Q5-U2 / A-U3 / pin 25 when the cutting knife is stopped in position A, SNB-Q10-U2 / B-U3 / pin 26 in position B, SNC-Q15-U2 / C-U3 / pin 27 in position C and SND-Q18-U2 / E-U3 / pin 28 in position D.

As a result, the MCU U3 can provide output voltage signals on its pin 23 or the terminal C and pin 24 or output the terminal D according to the pre-stored program to immediately stop the motor M. Alternatively, the MCU U3 can provide output voltage signals on its pin 22 or the terminal B and pin 23 or output the terminal C according to the pre-stored program to rotate the motor M in the reverse direction to resume the movement of the cutting knife.

The Cutting knife can be stopped in the manner shown below become.

In 2 The MCU U3 gives voltage signals to its pin 23 or the terminal C and pin 24 or the terminal D to immediately stop the motor M. Thereafter, the voltage signal at the terminal C is transferred to the gate of the FET Q11 through the transistors Q16 and Q13, thereby making the FET Q11 conductive. Likewise, the voltage signal at terminal D is transferred to the gate of FET Q12 through transistors Q17 and Q14, thereby making FET Q12 conductive. Consequently, both terminals of the motor M pass through the connector CN5 and the FETs Q11 and Q12, thereby generating a back electromotive force that stops the motor M. As a result, the motor M is immediately stopped, whereby the cutter blade is stopped immediately.

5. Function of the drive motor to the backward movement of the cutting knife

The MCU U3 gives voltage signals to its pin 22 or the terminal B and pin 23 or terminal C to move the cutter backwards. The voltage signal at terminal B is transferred to the gate of FET Q7 through transistor Q9, thereby making FET Q7 conductive. As a result, the PWM signal at the drain terminal of the FET Q1 is transferred to the motor M through the FET Q7 and the connector CN5.

For the rotation of the motor M in the rearward direction the conducting state of the FET Q7 inverts one polarity of the corresponding one terminal of the motor M in the opposite value, compared to the value, resulting from the conductive state of the FET Q6 for the normal rotation of the motor M yields.

On the other side is the voltage signal on the pin 23 or the terminal C of the MCU U3 is transferred to the gate of the FET Q11 through the transistors Q16 and Q13, thereby making the FET Q11 conductive. As a result, ground voltage is transmitted to the motor M through the FET Q11 and the connector CN5. Similarly, for the rearward rotation of the motor M, the conductive state of the FET Q11 inverts a polarity of the corresponding terminal of the motor M to the opposite value as compared with that resulting from the conductive state of the FET Q12 for the normal rotation of the motor M. , Accordingly, in the reverse rotation of the motor M, the PWM pulse signal and the ground voltage are transmitted to the motor M in the opposite directions as compared with those for the normal rotation of the motor M. This causes the blade to move normally the first time , the second time in the opposite direction. In other words, the cutting knife cuts an inserted film for the first time in a normal movement and a second time in a backward movement, resulting in a significant reduction of the cutting time.

According to the present invention, the selection switches SW1 to SW6 included in the 1 and 4 are provided to select a cutting size of 1,800 mm, A0, A1, A2, A3 and A4, and the LEDs are provided to select the selected cutting size on the control panel 4 display. When the footswitch has passed, the cutter blade cuts the selected size during normal motion with normal rotation of the motor M and then stops. When the foot switch is depressed again, the cutter blade cuts the selected size during a backward movement upon a rearward rotation of the motor M. In addition, the cutter blade can be freely adjusted in moving speed by adjusting the resistance of the variable resistor VR1. Thus, the present laminator film cutter can have a high cutting efficiency.

In summary, the aspects essential to the invention can be seen in the fact that one has a certain cutting size can select by pressing a switch, whereupon the cutting blade automatically moves only along the corresponding length of the travel, so the process of the cutting blade stops when reaching a predetermined position. In contrast, in the conventional laminator film cutting an always constant process of the cutting blade over the maximum travel path length is provided, which of course leads to an unnecessary delay of the processing operation, especially for small cutting sizes. Responsible for this timely stopping of the cutting blade upon reaching the predetermined cutting size length is the arrangement of several scanning devices along the travel of the cutting blade, which are formed by photo interrupters. Now covers the cutter a photo interrupter in a selected by the associated selector switch position corresponding to the predetermined cutting size length, the photo interrupter generates a signal which is sent to the Mikroprozes sorsteuereinheit, whereby this motor M and thus the cutting blade stops in this position. As a rule, the cutting knife will return from there to the starting position and thereby cut the laminator film a second time.

Claims (4)

Laminator foil cutting device with a movable Cutting knife for cutting to length the laminator film, characterized by a plurality of selection switches (SW1, SW2, SW3, SW4, SW5, SW6) to select one of several preset ones Cutting sizes over which Length that Cutter is movable, and by a microprocessor control unit (MCU) for controlling the moving speed of the cutting blade in pulse width modulated way. Laminator film cutting device according to claim 1, characterized by a plurality of light emitting diodes (LED A, B, C, D) to indicate the cutting size by one of the selector switches (SW1 to SW6) can be selected on a control panel. Laminator film cutting device according to at least one of the preceding claims, characterized in that along the travel of the over a Motor (M) drivable cutting knife multiple scanners (U1) are provided that the scanning devices in the specified Corresponding cutting sizes Positions (A, B, C, D) are arranged, and that by the scanning devices (U1) upon detection of the cutting blade, a signal to the microprocessor control unit (MCU) is generated to stop the motor (M) of the moving Cutting knife. Laminator film cutting device according to claim 3, characterized in that the scanning devices (U1) by Photo breakers are formed when interrupting the on them directed light through the passing on them cutting blade generate the signal to stop the motor (M).