JPH07112849B2 - Controller for impulse sealer - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a control device in an impulse sealer that heat-welds and bonds a resin sheet or the like.

2. Description of the Related Art FIG. 4 is a circuit diagram of a conventional impulse sealer. In FIG. 4, a power supply is connected between the input terminals 111a and 111b, and the input terminal 111a is a power switch (hereinafter referred to as PSW) 11
2. Connected to one end of the primary winding of the heater transformer 115 through the series circuit of the micro switch (hereinafter referred to as MSW) 113 and the bidirectional thyristor 114, and the other end of the primary winding is connected to the input terminal 111b. Has been done. Also, heater transformer
Both ends of the secondary winding of 115 are connected to a heater 116 for heating. In addition, a resistor 11 is placed across the bidirectional thyristor 114.
7, the output terminal of solid state relay (hereinafter referred to as SSR) 118, and the series circuit of resistor 119 is connected
A connection point between one of the output terminals and the resistor 119 is connected to the gate terminal of the bidirectional thyristor 114. In addition, MSW11
The connection point between 3 and the resistor 117 is connected to the power input section of the heating timer 120, and the power output section of the heating timer 120 is connected to the input terminal 111.
connected to b. Further, the heating timer 120 is connected to the input terminal of the SSR 118 and is configured to control the bidirectional thyristor 114 via the SSR 118.

The connection point between PSW112 and MSW113 is the solenoid drive circuit.
The output portion of the solenoid drive circuit 121 is connected to the input portion of 121, and is connected to the solenoid 122 that drives the pressure bonding lever that pressure bonds the resin sheet to the heater 116. Further, a cooling timer 123 is interposed between the heating timer 120 and the solenoid drive circuit 121, and is configured to raise the pressure bonding lever after a certain cooling time after heating and accommodating the resin sheet.

With the above configuration, the operation will be described below. The power supply voltage is applied between the input terminals 111a and 111b, and when the PSW112 is first turned on, power is supplied to the solenoid drive circuit 121,
The solenoid 122 is turned on by the solenoid drive circuit 121 and the crimping lever begins to descend. By the lowering of the crimping lever, the resin sheet to be heat-sealed is crimped to the heater 116. At this time, the MSW113 is turned on in conjunction with this crimping operation of the crimping lever, the heating timer 120 works, and S
The bidirectional thyristor 114 is turned on via SR118. As a result, the heater 116 is energized and heated via the heater transformer 115, and heating and welding of the resin sheet is started.

On the other hand, the heating timer 120 varies depending on the thickness and material of the resin sheet, but for example, the heating time is 1.6 sec (normally 0 to
1.6sec), which is the time to heat-bond and optimally bond the resin sheet. After the elapse of this heating set time, the heating timer 120 times up and turns off the bidirectional thyristor 114 via the SSR 118.
A signal is output to the cooling timer 123 to activate the cooling timer 123. The cooling timer 123 varies depending on the thickness and material of the resin sheet, but is set to, for example, a cooling time of 3.0 sec, which is a time period after the resin sheet is heat-welded and the resin sheet is sufficiently welded.

After the elapse of the cooling time of 3.0 sec, the cooling timer 123 times up and outputs a signal to the solenoid drive circuit 121 to turn off the solenoid 122 via the solenoid drive circuit 121. When the solenoid 122 is turned off, the crimping lever is raised and the heat welding of the resin sheet is completed.

However, in the above-described conventional configuration, in order to optimally heat-weld and bond the resin sheet, the energization time to the heater 116 is controlled by the time management by the heating timer 120. As shown in FIG. 5, since the heating time t _0, which is the time for energizing the heater 116, is always constant, the temperature T ₁ during the _first heating and the temperature T ₂ after several tens of continuous heating are: Due to the effect of heat storage, the temperature T ₂ after continuous heating for several tens of times becomes considerably higher than the temperature T ₁ at the time of the first heating. Therefore, at the same heating time t ₀ , the resin sheet such as a film is excessively melted and the adhesiveness is deteriorated, so that there is a problem that it is necessary to change the setting of the heating time each time.

Further, since the cooling time is also constant, as shown in FIG. 5, the temperature at the end of cooling is high between the cooling end temperature Tal of the first cooling and the cooling end temperature Ta8 of the eighth cooling, for example. If the temperature at the end of this cooling rises, the pressure bonding lever will rise and the adhesiveness will deteriorate without fully solidifying after heating and welding the resin sheet, so it is necessary to change the setting of the cooling time each time. Had a problem.

The present invention solves the above-mentioned conventional problems, and provides a control device for an impulse sealer capable of obtaining stable and good adhesiveness without having to change the setting of heating time and cooling time each time of adhering. The purpose is.

Means for Solving the Problems In order to solve the above problems, the control device in the impulse sealer of the present invention is a temperature detecting means for detecting the welding temperature provided in the vicinity of the welding means for welding the resin, and a temperature detecting means from the temperature detecting means. First comparing means for comparing the detected value with the heating end reference value, second comparing means for comparing the detected value from the temperature detecting means with the cooling end reference value, and the heating end from the first comparing means Control means for shutting off power supply to the welding means by output, and reset means for resetting to an initial state by output from the second comparing means at the end of cooling after shutting off power supply by the control means. It is a thing.

With the above configuration, when the resin is heat-welded and bonded, the temperature detecting means detects the welding temperature in the vicinity of the welding means, and the first comparing means compares the detected value from the temperature detecting means with the heating end reference value. At the same time, the second comparison means compares the detected value from the temperature detection means with the cooling end reference value,
Further, the control means cuts off the power supply to the welding means by the heating end output from the first comparison means, and at the end of cooling after this power supply cutoff, the reset means outputs the second comparison means. Because it resets to the initial state,
Unlike the conventional case, it is not necessary to change the setting of the heating time and the cooling time each time the resin is bonded, and stable and good adhesiveness can be obtained.

Embodiment An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a circuit diagram of an impulse sealer showing an embodiment of the present invention. In FIG. 1, one terminal of a power plug 1 to which AC power of 100 VAC is supplied is connected to one end of a push button switch (hereinafter referred to as PSW) 3 via a safety fuse 2, and the other end of PSW3 is connected to a micro switch (hereinafter referred to as a micro switch). It is connected to one end of 4). The other end of the MSW4 is connected to one end of the primary winding of the heater transformer 6 via the bidirectional thyristor 5, and the other end of the primary winding is connected to the other terminal of the power plug 1, and the secondary winding is further connected. A heater 7 for heating is connected to both ends of the wire. A series circuit including a resistor 8, one of the output terminals of the SSR9, the other of the output terminals of the SSR9, and a resistor 10 is connected to both ends of the bidirectional thyristor 5, and the other of the output terminals of the SSR9 and the resistor 10 are connected. The connection point of is connected to the gate terminal of the bidirectional thyristor 5. One of the input terminals of the SSR9 is connected to the DC power source via the resistor 11, the other of the input terminals is connected to the collector of the transistor 12, and the emitter of the transistor 12 is grounded. The power supply circuit 13 that supplies power to the heater transformer 6 is configured as described above.

The other end of the MSW4 is connected to the other terminal of the power plug 1 through a series circuit of the resistor 14 and the photodiode 15a of the photocoupler 15, and the collector of the phototransistor 15b of the photocoupler 15 is connected to the DC power source. And the emitter of the phototransistor 15b is grounded at one end.
6 and the other end of capacitor 17 and resistor 1
It is connected to both of the input ends of the NOR gate 19 via 8. The output terminal of the NOR gate 19 is connected to one of the input terminals of the NOR gates 20 and 21, respectively.

On the other hand, the thermocouple 22 as a temperature sensor is provided via a glass tape located below the heater 7. Further, a Teflon is provided above the heater 7, and a resin sheet is sandwiched between the Teflon and the silicone rubber provided below the pressure bonding lever to perform pressure bonding. At this time,
The pressure bonding lever is lowered by driving the solenoid 23 to heat-weld and bond the resin sheet, and in conjunction with this, the MSW 4 is turned on.

Both ends of the thermocouple 22 are connected to the capacitor 24 and also to the input terminal T1 and the input terminals T13, 14 of the amplifying IC 25. The output terminals T8 and 9 of the amplification IC25 are comparators.
It is connected to the negative side terminal of 26 and the positive side terminals of the comparators 27 and 28, respectively. Further, a resistor 29, a variable resistor 30, and a series circuit of resistors 31 and 32 are interposed between the DC power supply and the ground, and a series circuit of the variable resistor 33 and the resistor 34 is further connected between the connection point of the resistors 31 and 32 and the ground. The negative terminal of the comparator 27 is connected to the variable terminal of the variable resistor 30 and the heating end reference value is input to the negative terminal of the comparator 27.
The negative terminal of the comparator 28 is connected to the variable terminal of the variable resistor 33, and the cooling end reference value is input to the negative terminal of the comparator 28. The output terminal of the comparator 27 is connected to the other input terminal of the NOR gate 20 through the resistor 35 and the diode 36, and one end of the capacitor 37 whose other end is grounded.
The output end of the NOR gate 20 is connected to the power supply circuit via the resistor 38.
It is connected to both the base of the transistor 12 of 13, the base of the transistor 40 via the resistor 39, and the input end of the NOR gate 41. The output end of the NOR gate 41 is connected to the other input end of the NOR gate 20 via the resistor 42. The output end of the comparator 28 is connected to the other input end of the NOR gate 21, and the output end of the NOR gate 21 is connected to the collector of the transistor 40 via the resistor 43.
The 40 emitters are grounded.

Further, a series circuit of a resistor 44 and a variable resistor 45 is interposed between the DC power supply and the ground, and the positive terminal of the comparator 26 has a variable resistor 45.
Is connected to the variable terminal of. The output terminal of the comparator 26 is a resistor
46, and further connected via a diode 47 to the other input end of the NOR gate 20, and the other input end of this NOR gate 20 is connected via a diode 48 to the other end of the resistor 18.

In this way, the temperature control circuit 49 for controlling the power supply circuit 13 to which the temperature data output from the amplification IC 25 is input and which supplies power to the heater 7 is configured.

The DC power supply is connected to both the input ends of the NOR gate 52 via the resistor 51, and further via the parallel circuit of the resistor 53 and the capacitor 54, the foot switch (hereinafter referred to as FSW) 55.
Is connected to one end of the FSW55 and the other end of the FSW55 is grounded. The manual operation start signal generation circuit 56 is configured as described above.

The DC power supply is grounded via the variable resistor 56 and
57, a variable resistor 58 and a capacitor 59 are grounded via a series circuit. The variable terminal of the variable resistor 56 is connected to the negative side terminal of the comparator 60, and the positive side terminal of the comparator 60 is connected to the connection point of the variable resistor 58 and the capacitor 59 and also to the collector of the transistor 61. Transistor
The emitter of 61 is grounded, and the capacitor 62 is connected between the emitter and base of the transistor 61. The automatic operation start signal generation circuit 63 is configured as described above.

One of the switching contacts of the changeover switch (hereinafter referred to as SSW) 64 is connected to the output end of the comparator 60 of the automatic operation start signal generation circuit 63, and the other of the switching contacts of the NOR gate 52 of the manual operation start signal generation circuit 56. It is connected to the output terminal and switches between the automatic operation start signal and the manual operation start signal. The common contact of the SSW64 is connected to the terminal T12 of the amplification IC 25 via the resistor 65.

The common contact of this SSW64 is connected to one of the input terminals of the NOR gate 66 via the resistor 65, and the other input terminal of the NOR gate 66 is connected to the base of the transistor 61 of the automatic operation start signal generating circuit 63 via the resistor 67. Connected to the output terminal of the NOR gate 68 and the other end of the capacitor 69 grounded.
Is connected to one end of. The output terminal of the NOR gate 66 is connected to one of the input terminals of the NOR gates 68 and 70.
The other of the input terminals of is connected to the collector of the transistor 40 of the temperature control circuit 49 and further to the output terminal of the NOR gate 21 via the resistor 43. The other input end of the NOR gate 70 is connected to the capacitor 71 whose other end is grounded, one end of the resistor 72, and the anode of the diode 73. Further, the other end of the resistor 72 is connected to the cathode of the diode 73 and also to the emitter of the phototransistor 15b in the photocoupler 15 of the temperature control circuit 49. The flip-flop circuit 74 is configured as described above.

The output terminal of the NOR gate 68 is connected to the transistor 76 via the resistor 75.
On the other hand, the DC power supply is connected to the anode of the photodiode 78a of the photocoupler 78 via the resistor 77, the cathode of the photodiode 78a is connected to the collector of the transistor 76, and the emitter of the transistor 76 is grounded. ing. Similarly, the output terminal of the NOR gate 70 is connected to the base of the transistor 80 via the resistor 79,
On the other hand, the DC power supply is connected to the anode of the photodiode 82a of the photocoupler 82 via the resistor 81, the cathode of the photodiode 82a is connected to the collector of the transistor 80, and the emitter of the transistor 80 is grounded.

On the other hand, one terminal of the power plug 1 has a fuse 2,
Diode forming a diode bridge via PSW3
It is connected to the connection point of the anode of 83 and the cathode of the diode 84, and the other terminal of the power plug 1 is connected to the cathode of the diode 86 forming the diode bridge via the fuse 85. The cathode of the diode 86 is connected via a thyristor 87 to the anode of a diode 88 forming a diode bridge, and the cathode of the diode 88 is connected to the cathode of the diode 83. The anode of the diode 84 is connected to the anode of the diode 86 via the thyristor 89. A series circuit of resistors 90 and 91, a resistor 92 and a photocoupler 78 are provided at both ends of the thyristor 89.
Is connected to the series circuit of the phototransistor 78b. The connection point of resistors 90 and 91 is the gate terminal of thyristor 89,
It is connected to the collector of the capacitor 93 and the transistor 94. Similarly, a resistor 9 is placed across the thyristor 87.
A series circuit of 5, 96 and a series circuit of the resistor 97 and the phototransistor 82b of the photocoupler 82 are connected.
The connection point of the resistors 95 and 96 is connected to the gate terminal of the thyristor 87, the capacitor 98 and the collector of the transistor 99. The solenoid control circuit 100 is configured as described above.

The connection point of the cathodes of diodes 83 and 88 and diode 84
A solenoid 23 is connected between the anode and a connection point of the anode of the thyristor 89 to supply full-wave rectified or half-wave rectified power. Incidentally, 101 is a DC power supply.

With the above configuration, the operation will be described below with reference to the time chart of FIG. First, the manual operation will be described. First, when the PSW3 is turned on and the power is turned on, the DC power supply 101 operates and outputs DC power to each unit. At this time, the NOR gate of the flip-flop circuit 74
Input terminals k1 and k2 of 66 are both low level, and NOR gate 66
A high level is output from the output terminal k3 of the NOR gate 6
Since the output terminals j3 and 13 of 8 and 70 are both at the low level and the thyristors 87 and 89 are off, the solenoid 23 is not supplied with power. In the temperature control circuit 49, a photo coupler
Since the phototransistor 15b of 15 is not turned on, the output terminal a3 of the NOR gate 19 becomes high level and the NOR gate 19
20 and 21 are supplied to input terminals b1 and d1 and output terminal B of NOR gate 20
3 becomes low level and transistor 1 of power supply circuit 13
2 remains off, the bidirectional thyristor 5 remains off, and the heater 7 is not supplied with power. At the same time, the output end c3 of the NOR gate 41 becomes high level and the input end b2 of the NOR gate 20 is held at high level. Furthermore, the comparator 26
The reference voltage is supplied from the DC power supply 101 to the positive side terminals of the comparators 27 and 28 and the negative side terminals of the comparators 27 and 28, and the output terminals of the comparators 26, 27 and 28 are both at a low level at this time. Further, the PSW3 is turned on and the DC power source is activated, and the input ends i1 and 2 of the NOR gate 52 of the manual operation start signal generation circuit 56 are both at the high level and the output end i3 of the NOR gate 52 is at the low level.

Next, when the FSW 55 of the manual operation start signal generating circuit 56 is turned on, both the input ends i1 and 2 of the NOR gate 52 become low level and the output end i3 of the NOR gate 52 becomes high level. The high level signal from the output terminal i3 of the NOR gate 52 is SSW64
Is input to terminal T12 of IC25 for amplification via IC25 for amplification
And is input to the input terminal k2 of the NOR gate 66 of the flip-flop circuit 74, whereby the output signal from the output terminal k3 of the NOR gate 66 changes from the high level to the low level. Therefore, the output terminals of NOR gates 68 and 70
The output signals from j3 and 13 become high level and turn on the transistors 76 and 80. When the transistors 76 and 80 are turned on, the transistors 94 and 99 are turned off and the thyristors 89 and 87 are turned on through the photocouplers 78 and 82, respectively. As a result, the full-wave rectified electric power is supplied to the solenoids 23, the respective 23 operate, and the crimping lever starts to move down.

By lowering the crimping lever in this manner, the MSW4 is turned on in conjunction with the operation of the crimping lever sandwiching the resin sheet to be heat-welded and adhered. With this MSW4 turned on, the photo coupler
The phototransistor 15b of 15 also turns on, and first, the input terminals a1 and a2 of the NOR gate 19 both become high level, the output terminal a3 thereof becomes low level, and the input terminals of the NOR gates 20 and 21 become.
Low level signals are input to b1 and d1. At this time, since the output terminals of the comparators 27 and 28 are both low level, the input terminals b2 and d2 of the NOR gates 20 and 21 are both low level, and the output terminals b3 and d3 of the NOR gates 20 and 21 are both high level. Becomes The high level signal from the output terminal b3 of the NOR gate 20 turns on the transistor 12 of the power supply circuit 13 to cause the SSR9
The input terminals are connected to each other and the trigger is input to the bidirectional thyristor 5 via the output terminals of the SSR9, and the bidirectional thyristor 5 is turned on. As a result, electric power is supplied to the heater transformer 6 so that the heater 7 is energized and heated. Further, the transistor 40 is turned on by the high level signal from the output terminal b3 of the NOR gate 20, and the high level signal from the output terminal d3 of the NOR gate 21 is short-circuited by the transistor 40, so that the input of the NOR gate 68 of the flip-flop circuit 74 is input. It is not input to the end j1 and is not reset.

Further, when the phototransistor 15b of the photocoupler 15 is turned on, power is supplied to the time constant circuit composed of the resistor 72 and the capacitor 71 of the flip-flop circuit 74, and after a predetermined time delay, a high level signal is input to the input terminal 12 of the NOR gate 70. To be done.
As a result, the NOR gate 70 is reset to the NOR gate.
A low level signal is output from the output terminal 13 of 70, and the transistor 80 of the solenoid control circuit 100 is turned off. When the transistor 80 is turned off, the phototransistor 82b of the photocoupler 82 is also turned off, the transistor 99 is turned on, and the thyristor 87 is turned off. Thereby, the solenoid 23 is supplied with the half-wave rectified power. With this half-wave rectified power source, the required pressure force of the solenoid 23 to the resin sheet is secured, and power is saved.

On the other hand, the heater 7 is energized and heated, and its temperature rises.
This is detected by the thermocouple 22 as a temperature sensor, the temperature signal is amplified by the amplifying IC 25, and then the voltage output corresponding to the temperature signal is output from the output terminals T8, 9 of the amplifying IC 25 to the comparators 26, 2
Output to 7 and 28 terminals respectively. First, in the comparator 28, the cooling end reference voltage input from the variable resistor 33 and the
When the voltage output from the IC 25 is compared and becomes higher than the cooling end reference voltage, a high level signal is output to the input end d2 of the NOR gate 21, and the output end d3 of the NOR gate 21 becomes low level.

Next, the heater 7 is further heated and the output voltage from the amplification IC 25 increases, and the comparator 27 compares the heating end reference voltage input from the variable resistor 30 with the voltage output from the amplification IC 25 to heat it. When it becomes higher than the termination reference voltage, a high level signal is output to the input terminal b2 of the NOR gate 20, and the output terminal b3 of the NOR gate 20 becomes low level. This allows
The transistor 12 of the power supply means 13 is turned off, the bidirectional thyristor 5 is also turned off, and the power supply to the heater 7 is cut off.
At this time, the transistor 40 is also off and the NOR gate
The output from the output end of 21 can be input to the input end j1 of the NOR gate 68 of the flip-flop circuit 74.

Further, the heater 7 is not energized at this time, the temperature drops, and the output voltage from the amplifying IC 25 also drops. In the comparator 28, the cooling end reference voltage input from the variable resistor 33 and the amplifying reference voltage are used.
At the end of cooling when the voltage output from IC25 is compared and becomes lower than the cooling end reference voltage, a low level signal is output to the input end d2 of NOR gate 21 and the output end of NOR gate 21
d3 goes high and outputs a reset signal to the input terminal j1 of the NOR gate 68 of the flip-flop circuit 74. As a result, the output terminal j3 of the NOR gate 68 of the flip-flop circuit 74 becomes low level, the transistor 76 of the solenoid control circuit 100 is turned off, the transistor 94 is turned on through the photocoupler 78, and the thyristor 89 is turned off. When the thyristor 89 is turned off, the power supply to the solenoid 23 is cut off and the crimp lever is raised.

Furthermore, MSW4 is turned off by raising the crimp lever,
Phototransistor 15b of photocoupler 15 when MSW4 is off
Is also turned off, the output end a3 of the NOR gate 19 becomes high level, the output end b3 of the NOR gate 20 remains low level, and thus the output end c3 of the NOR gate 41 remains high level, and the phototransistor of the photocoupler 15 Since 15b is off, diode 48 is on and resistors 42, 18, 1
6, the input terminal b2 of the NOR gate 20 becomes low level. Further, the output end d3 of the NOR gate 21 becomes low level because the output end a3 of the NOR gate 19 is at high level, and the transistor 40 is still off at this time as well, but the input end j1 of the NOR gate 68 in the flip-flop circuit 74 is also at low level. become. Also, the phototransistor 15b of the photocoupler 15
Is off, the input terminal 12 of the NOR gate 70 in the flip-flop circuit 74 also becomes low level via the time constant circuit. As a result, MSW4 is turned off and the initial state when PSW3 is turned on is restored. Where FSW5
When 5 is turned on again, the above operation is repeated and the resin sheet is heat-welded at the optimum temperature and adhered.

Next, automatic driving will be described. When SSW64 is switched to the automatic operation side, the comparator of the automatic operation start signal generation circuit 63
An operation start signal is output from the output terminal of the device 60 at predetermined time intervals, and the same operation as the above-described manual operation is performed. That is, when PSW3 is turned on, the DC power supply operates and the voltage on the positive side input terminal of the comparator 60 gradually rises due to the time constant circuit consisting of the resistor 57, the variable resistor 58 and the capacitor 59. The automatic operation start signal is output from the output terminal of the comparator 60 when the voltage input to the positive input terminal exceeds the reference voltage by comparing with the reference voltage input from the variable terminal to the negative input terminal. It will be. further,
The high level signal from the output terminal of the comparator 60 is input to the input terminal k2 of the NOR gate 66 in the flip-flop circuit 74 via the SSW 64, the output terminal k3 of the NOR gate 66 becomes low level, and the output terminal of the NOR gate 68 is output. j3 goes high. The high level signal from the output terminal j3 of the NOR gate 68 turns on the transistor 61 of the automatic operation start signal generation circuit 63 to short-circuit the electric charge accumulated in the capacitor 59 and reset it. Further, after a predetermined time set by the time constant circuit, the next automatic operation start signal is output. During this time,
When the solenoid 23 is operated and the resin sheet is pressure-bonded to the heater 7 by the pressure-bonding lever, MSW4 is turned on in synchronization with this to start the heat-welding of the resin sheet, and when the thermocouple 22 detects an appropriate temperature. Finish heating. further,
When the temperature of the heater 7 drops to a predetermined temperature, the end of cooling is detected and the solenoid 23 is turned off. When the solenoid 23 is turned off, MSW4 is also turned off and the initial state is restored, waiting for the next automatic operation start signal. It will be. This is repeated and automatic operation is carried out.

Next, the safety device will be described. Safety device is thermocouple 22
This is for preventing the bidirectional thyristor 5 from being turned on when the wire is disconnected. That is, the reference voltage input from the variable terminal of the variable resistor 45 to the positive side input terminal of the comparator 26 is set to be smaller than the amplified output voltage that the thermocouple 22 output at room temperature is amplified by the amplification IC 25, Therefore, the comparator 26
The output terminal of always becomes the low level and the normal heating operation is performed.However, when the thermocouple 22 is disconnected, the amplified output voltage from the thermocouple 22 is higher than the reference voltage set by the variable resistor 45 input to the positive side input terminal. Becomes small, and the output terminal of the comparator 26 becomes high level. This high level signal is input to the input end b2 of the NOR gate 20, and the output end b3 of the NOR gate 20 becomes low level to turn off the transistor 12 of the voltage supply circuit 13. As a result, the bidirectional thyristor 5 is also turned off to cut off the power supply to the heater 7.

Therefore, in order to optimally heat-weld and bond the resin sheet, the energization time to the heater 7 is not made constant by the conventional time management as shown in FIG. heating ends at a temperature T _3, are reset to the initial state by further cooling to a predetermined proper cooling end temperature T _4. At this time, since the temperature is controlled at an appropriate temperature, the heating time t _{a1 to} t _aN is _gradually shortened at the beginning due to the effect of heat storage, and the cooling time t _{b1 to} t _bN is _gradually increased at the beginning, which is the same as the conventional method. Problems such as poor adhesion due to excessive melting of resin sheet such as film are solved, and it is not necessary to change the heating time and cooling time setting each time when the resin sheet is optimally heat-welded and bonded. .

EFFECTS OF THE INVENTION As described above, according to the present invention, when the resin is heat-welded and adhered, the temperature is controlled at an appropriate temperature. The heating is completed at the proper heating end temperature, and the cooling is completed at the proper cooling end temperature, so that stable and good adhesiveness can be obtained.

[Brief description of drawings]

FIG. 1 is a circuit diagram of an impulse sealer showing an embodiment of the present invention, FIG. 2 is a time chart showing waveforms of main parts in FIG. 1, and FIG. 3 is an impulse sealer showing an embodiment of the present invention. 4 is a temperature control curve diagram in FIG. 4, FIG. 4 is a circuit diagram of a conventional impulse sealer, and FIG. 5 is a temperature control curve diagram in the conventional impulse sealer. 5 ... Bidirectional thyristor, 7 ... Heater, 9 ... SS
R, 12, 40 ... Transistor, 15 ... Photocoupler, 15a
...... Photodiode, 15b …… Phototransistor, 1
9, 20, 21, 41 …… Noah gate, 22 …… Thermocouple, 27, 28
…… Comparator, 30, 33 …… Variable resistance.

Claims (1)

[Claims] 1. A temperature detecting means provided near a welding means for welding a resin to detect a welding temperature, a first comparing means for comparing a detection value from the temperature detecting means with a heating end reference value, and the temperature. Second comparing means for comparing a detection value from the detecting means with a cooling end reference value; control means for cutting off power supply to the welding means by a heating end output from the first comparing means; and the control means The control device in the impulse sealer, comprising: resetting means for resetting to an initial state by the output from the second comparing means at the end of cooling after the power supply is cut off.