KR950000748B1 - Temperature control circuit and method of a fixing device - Google Patents

Abstract

The circuit prevents the over heating by temperature control of the facsimile and the copy machine. The circuit includes resistors (R21-R22), a temperature detector, an open circuit sensing comparator (OP1), a temparature detection comparator (OP2), a printing temperature detection comparator (OP3), an over heating comparator (OP4), a micom (10) which outputs the selection control signal, a MUX (40) which outputs the selection control signal of micom (10), and an AND gate (AN1) which outputs on/off control signals.

Description

Fuser temperature control circuit and method

1 is a conventional fuser temperature control circuit diagram.

2 is a flow chart of a general fuser temperature control.

3 is a temperature control circuit diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

10: microcomputer 20: fuser drive unit

30: Fuser 40: MUX

OP1-OP4: Comparator AN1: Endgate

The present invention relates to a fuser temperature control circuit and method, and more particularly, to a fuser temperature control circuit and method for detecting the temperature of the fuser in an electronic device using an electrophotographic processor to prevent overheating by malfunction.

In general, electronic devices such as laser printers and copiers are configured to input a power supply voltage to perform a predetermined operation or an operation corresponding to the command in response to a command from the outside.

Office equipment such as copiers, printers, etc. have a heater for preparing the operating conditions of the system, the heater of the fixing unit to fix the developer on the copy (print) paper during copying or printing The temperature is always kept at a preset temperature. At this time, if the temperature of the fixing unit located inside the system is not preheated to the set temperature, the developer cannot be fixed on the copying paper, so the heater must be heated to heat the fixing unit. In this case, the driving of the heater should be stopped to lower the temperature of the fixing unit.

In the laser printer or the copier as described above, the temperature of the fixing unit is about 150 ° C. at the ready, and about 180 ° C. at the printing. The temperature of the fixing unit is controlled by a heater control circuit that controls the temperature of the heater to a temperature within the temperature range in response to the output of the temperature sensor for sensing the temperature of the fixing unit. Therefore, the office equipment having a heater as described above is a built-in temperature sensor for detecting the temperature inside the system for proper temperature control, the heater control circuit is a preset temperature in response to the output of the temperature sensor To control.

The system for controlling the temperature of the fixing unit by the output of the temperature sensor has a circuit for detecting the abnormality of the temperature sensor for accurate temperature control. In other words, if the temperature sensor is disconnected or disconnected from the connector, an abnormality in temperature detection may occur and the temperature of the fixing unit may overheat, causing a fire.

FIG. 1 is a circuit diagram of a disconnection detection circuit of a conventional temperature sensor. The resistor R21 and thermistor TH connected in series between the power supply voltage Vcc and the ground, and the resistor R22 connected in parallel to the thermistor TH are shown in FIG. The temperature detection unit detects and outputs the temperature of the fixing unit 30, and compares the preset disconnection detection voltage Vref1 with the temperature detection voltage output from the temperature detection unit to determine the disconnection detection voltage Vref1. The disconnection detecting comparator OP1 outputting the disconnection detection signal of the demister the TH when the detection voltage is greater than the detection voltage, the preset standby state detection voltage Vref2, and the temperature detection voltage output from the temperature sensing unit. Comparator OP2 for comparing and outputting a standby state detection signal, and comparator OP3 for outputting a print state detection signal by comparing a preset print detection voltage Vref3 with a temperature detection voltage output from the temperature sensing unit. And a comparator OP4 for comparing a preset overheat detection voltage Vref4 with a temperature detection voltage output from the temperature detector and outputting an overheat detection signal, the comparator OP1 and the comparator OP2 OP3. MICOM (10) for controlling the system by judging the disconnection of the temperature sensor TH and the temperature of the heater by inputting disconnection, standby, print, and overheat detection signals output from OP4) And a fuser driver 20 for driving the fuser 30 by the temperature control signal of the microcomputer 10.

At this time, the relationship between the set voltages is Vref1> Vref2> Vref3> Vref4. Reference numerals R23 to R26 denote pull-up resistors for pulling up the outputs of the comparators OP1, OP2, OP3, and OP4, and CN1 is a connector for connecting the thermistor TH. (TH) is a temperature sensor that has a property of decreasing resistance as the temperature increases, and is located near the heater.

Now, when the operating power supply voltage Vcc is applied to each part of FIG. 1, the temperature detection voltage Va by the demisters TH and the resistors R21 and R22 whose resistance values change in accordance with the temperature of the fixing unit 30 is It is output as in the following formula (1) and input to the inverting terminal (-) of the comparators OP1, OP2, OP3, and OP4.

As described above, when the temperature is increased, the demister (TH) is a device having a lower resistance value, and thus the temperature detection voltage Va is changed and output in response to a change in the temperature of the heater. That is, when the temperature of the heater in the fixing unit 30 rises, the detection voltage Va decreases.

On the other hand, in the state of inputting the reference voltages Vref1, Vref2, Vref3, and Vref4 corresponding to the temperatures of disconnection, standby, print, and overheating state to the respective non-inverting terminals (+), as shown in Equation (1). Comparators OP1, OP2, OP3, and OP4, which input the output temperature detection voltage Va to their inverting terminals (-), compare the signal voltages input to the two terminals and compare the result with the microcomputer (5). ).

For example, if the temperature of the current fixing unit 30 is below the standby temperature, the temperature detection voltage Va is lower than the disconnection detection voltage Vref1 and the ready state detection voltage Vref2 is set above the voltage level. Each of the comparators OP1, OP2, OP3, and OP4 inputs state signals of logic "high", "low", "low", and "low" to the microcomputer 5, wherein the microcomputer ( 5) recognizes the disconnection state of the thermistor TH and the temperature state of the fixing unit 30 by the outputs of the comparators. <However, the disconnection detection voltage Vref1 should be set higher than the temperature detection voltage Va output from the temperature sensing unit composed of the resistors R21 and R22 and the thermistor TH at room temperature.

At this time, if it is recognized that the temperature of the fixing unit 30 is lower than the temperature of the standby state, the microcomputer 5 controls the fixing unit driver 20 to heat the temperature of the fixing unit 30.

When the temperature of the fixing unit 30 is increased by the above operation, the temperature detection voltage Va output by the divided voltage is reduced in proportion to the temperature rise. When the temperature of the heater is raised to the temperature of the preparation for printing by the continuous driving of the heater in the fixing unit 30, the temperature detection voltage Va falls to a level below the preset preparation detection voltage Vref2, so that the comparator OP2 The output is output as "high". Subsequently, when the temperature of the heater is raised to be equal to or higher than the printing set temperature, the output of the comparators OP2 and OP3 is output as "high".

If the temperature of the heater is overheated and the temperature detection voltage Va falls below the overheat temperature detection voltage Vref4 set corresponding to the overheating temperature, the output of the comparator OP4 indicating that the temperature of the fixing unit 30 is overheated is " High ".

Therefore, the microcomputer 5 can know the current temperature of the fixing unit 30 by the outputs of the comparators OP1, OP2, OP3, and OP4, thereby controlling the temperature of the fixing unit 30.

The detailed operation of the microcomputer 5 that receives the output signals of the comparators OP1, OP2, OP3, and OP4 as described above with reference to FIG. 2 will be described with reference to FIG. 2. In step 2a, the comparator OP1 In response to the output signal of the &lt; RTI ID = 0.0 &gt;), &lt; / RTI &gt; the disconnection of the thermistor TH is performed.

If the demister is not disconnected, step (2b) is performed. In the step (2b), it receives the output signal of the comparator OP4 and checks whether the fixing unit 30 is in an overheat state, and if the fixing unit 30 is in an overheat state (2ｆ), it performs (2c) Perform the steps. In step (2c), the system checks whether the system is in the standby state, and performs step (2d) if it is in the standby state.

In step (2d), the output signal of the comparator OP2 is received to check whether the temperature of the fixing unit 30 is in the standby temperature state, and if the temperature is not in the standby temperature state, the control signal of the fixing unit 30 is generated in step (2e). do. However, if the temperature of the fixing unit 30 is in the standby temperature state in the step (2d), the off control signal of the fixing unit 30 is generated in the step (2ｆ). In step (2c), if the system is not in the standby state (2g), it is checked whether it is in the print state, and if it is in the print state (2ｈ), it is performed. In the step (2), if the temperature of the fixing unit 30 is in the printing temperature state, the control unit generates the off control signal of the fixing unit 30 in the printing temperature state (2ｊ). However, if the fixing unit 30 is not in the printing temperature state in the step (2ｈ), the temperature control signal of the fixing unit 30 is generated in the step (2i). In this way, the fuser driver 20 inputting the fuser temperature control signal from the microcomputer 5 drives the fuser 30 to be turned on / off. Here, the fuser driver 20 is configured as a relay. When the low signal, which is an on-control signal of the fuser 30 from the microcomputer 5, is applied to the fuser driver 20, the power supply voltage Vcc is applied to the coil L1. It flows through the switch (SW1, SW2) is operated in conjunction with all the on state. Therefore, when the switches SW1 and SW2 are turned on, AC power is supplied to the fixing unit 30 so that the heat lamp of the fixing unit 30 is turned on to perform heating. However, when the high signal, which is an off control signal of the fixing unit 30 from the microcomputer 5 is applied to the fixing unit driver 20, the power supply voltage Vcc does not flow through the coil L1 so that the switches SW1 and SW2 are operated. All are off. Therefore, when the switches SW1 and SW2 are turned off, since the AC power is not supplied to the fixing unit 30, the heat lamp of the fixing unit 30 is turned off to not perform heating.

As described above, the fuser 30 is software-configured so that the fuser 30 is not overheated by detecting the disconnection state, standby state, print state, and overheat state after comparing the voltage according to the temperature detection of the thermistor TH with the reference voltage. As a control, there is a problem that the fuser 30 is overheated when the contact failure or abnormal operation of the soft control occurs after turning on the fuser 30.

Accordingly, an object of the present invention is to provide a stopper temperature control circuit for solving the above problems.

SUMMARY OF THE INVENTION An object of the present invention is to provide a fuser temperature control circuit for controlling the fuser to prevent overheating when contact failure or software abnormal operation occurs after turning on the fuser. The present invention will be described in detail with reference to the accompanying drawings.

3 is a fuser temperature control circuit diagram according to the present invention, in which a resistor R21 is connected directly between a power supply voltage Vcc and ground, and a resistor R22 connected in parallel to a demister and a demister. And a disconnection detection voltage Vref1 compared to a preset disconnection detection voltage Vref1 and a temperature detection voltage output from the temperature detection unit. A disconnection detecting comparator OP1 for outputting a disconnection detection signal of the demister (TH), a preset standby detection voltage (Vref2), and a temperature detection voltage output from the temperature sensing unit. Compare the comparator OP2 for outputting the standby temperature detection signal, the preset print detection voltage Vref3, and the temperature detection voltage output from the temperature detection unit to compare the print state temperature detection signal. A comparator OP4 for comparing an output comparator OP3, a preset overheat detection voltage Vref4, a temperature detection voltage output from the temperature sensing unit, and outputting an overheat state temperature signal, and a comparator OP1 The system is controlled by determining the disconnection of the temperature sensor TH and the heater temperature by inputting the ready, print, and overheat temperature detection signals output from the comparators OP2, OP3, and OP4. The microcomputer (MICOM) 10 for outputting a selection control signal for selecting a standby state and a print state, and a standby state temperature detection signal and a print state temperature detection signal output from the comparators OP2 and OP3 are inputted. A MUX 40 for selectively outputting a signal by the selection control signal of (10), a signal selected and output from the MUX 40, an overheated state temperature signal which is an output of the comparator OP4, and the comparator OP1 Is the output of Logic multiplying the line-state temperature sensing signal consists of the AND gate (AN1) for outputting a fixing unit on / off control signal.

In the above configuration, the fuser driver 20 and the fuser 30 have the same configuration as the first degree.

One embodiment of the present invention based on the above-described configuration will be described in detail with reference to FIG.

The demister (TH) attached to the fixing unit 30 has a property of low resistance at high temperatures. Therefore, in the initial state in which the fixing unit 30 is turned off, the outputs of the comparators OP1-OP4 are all kept in the "low" state.

In this state, when the fuser 30 is turned on, the power supply voltage Vcc supplied through the resistor R21 flows through the thermistor TH, so that the voltage applied to the node a is gradually decreased to thereby provide a first voltage. The outputs of the fourth comparators OP1 to OP2 output the "high" signals at predetermined time intervals, respectively.

In this case, even when a malfunction of the program of the microcomputer 10 occurs, the hardware is operated as follows to prevent overheating of the fixing unit 30.

For example, if the temperature of the current fixing unit 30 is below the standby temperature and the temperature detection voltage is lower than the disconnection detection voltage Vref1 in which the voltage level is set to the highest and higher than the ready state detection voltage Vref2, the comparator Each of the operations OP1, OP2, OP3, and OP4 outputs logic signals of logic "high", "low", "low", and "low".

Since the output of the comparator OP1 is "high" and the comparators OP2-OP4 are "low", the AND gate AN1 outputs a low signal. When the output of the AND gate (AN) is in a low state, the fuser driver 20 is composed of a relay as shown in FIG. 1, and the power supply voltage Vcc flows to the coil L1 of the relay so that the switch SW1, Since both SW2) are on, the heat lamp in the fixing unit 30 is turned on.

At this time, if the output of the comparator OP1 outputs a low state, the circuit is disconnected, and the outputs of the comparators OP2-OP4 are high. As a result, the AND gate AN1 turns off the fuser 30 by applying a high signal to the fuser driver 20 because the outputs of the comparators OP1 and OP4 become high signals. Here, as shown in FIG. 1, when the one end of the coil L1 of the relay is high, the fuser driver 20 may turn off the switches SW1 and SW2 because the power supply voltage Vcc does not flow through the coil L1. do. Therefore, when the switches SW1 and SW2 are turned off, since the AC power is not supplied to the heater lamp of the fuser 30, the heater lamp of the fuser 30 is turned off.

<However, the disconnection detection voltage Vref1 must be set higher than the temperature detection voltage output from the temperature sensing unit composed of the resistors R21 and R22 and the thermistor TH at room temperature.

In addition, when it is recognized that the temperature of the fixing unit 30 is lower than the temperature of the standby state, the microcomputer 10 drives the fixing unit 30 to heat the temperature of the fixing unit 30.

When the temperature of the fixing unit 30 is increased by the above operation, the temperature detection voltage outputted by the partial pressure is reduced in proportion to the temperature rise. When the temperature of the fixing unit 30 rises to the printing standby temperature by the continuous driving of the fixing unit 30, the temperature detection voltage drops to a level below the preset preparation detection voltage Vref2, so that the output of the comparator OP2 is reduced. Outputs "high". At this time, the microcomputer 10 outputs a selection control signal so that the MUX 40 selects the signal input to the input terminal A. FIG.

Subsequently, when the temperature of the heater is raised to be equal to or higher than the printing set temperature, the output of the comparators OP2 and OP3 is output as "high". When the output of the comparators OP2-OP3 is high, the fixing unit driver 20 turns off the fixing unit 30.

If the temperature of the heater lamp in the fixing unit 30 is overheated so that the temperature detection voltage drops below the overheating temperature detection voltage Vref4 set corresponding to the overheating temperature, the comparator OP4 indicating that the temperature of the fixing unit 30 is overheated. Output goes high.

Therefore, the fuser driver 20 controls the temperature by turning off the fuser 30.

As described above, when an abnormal operation of the software occurs after the toner fixing heat lamp is turned on in an electronic device such as a facsimile or copier using an electrophotographic method, and the temperature control of the fixing unit is impossible, the temperature is controlled by hardware to control the overheating of the fixing unit. There is an advantage that can be prevented.

Claims (2)

In the fuser temperature control circuit, a demister (TH) is connected to a resistor (R21-R22) connected in series between the power supply voltage (Vcc) and the ground, and a connection node of the resistors (R21-R22) to fix the fuser (30). When the disconnection detection voltage (Vref1) is greater than the temperature detection voltage by comparing the temperature detection unit for detecting and outputting the temperature of the temperature detection unit and the preset disconnection detection voltage (Vref1) and the temperature detection voltage output from the temperature detection unit; The standby state detection signal is output by comparing the disconnection detection comparator OP1 outputting the disconnection detection signal of the thermistor TH with the preset standby detection voltage Vref2 and the temperature detection voltage output from the temperature detection unit. A comparator OP3 configured to compare the comparator OP2 with a preset print detection voltage Vref3 and a temperature detection voltage output from the temperature detection, and output a print state temperature detection signal, and a preset overheating. Comparator OP4 for comparing the output voltage Vref4 and the temperature detection voltage output from the temperature sensing unit to output an overheat state temperature detection signal, the comparator OP1 and the comparator OP2 OP3, OP4 Inputting the disconnection, standby, print, and overheat temperature detection signals output from the device to determine the disconnection of the thermistor (TH) and the temperature state of the fixing unit 30 to control the system and to select the standby state and the print state. A signal input by the selection control signal of the microcomputer 10 by inputting a microcomputer 10 for outputting a selection control signal for the microcomputer 10 and a standby state temperature detection signal and a print state temperature detection signal output from the comparators OP2 and OP3. MUX (40) for selectively outputting the result, the output signal of the MUX 40 and the overheat state temperature signal output from the comparator (OP4) and the disconnection state temperature signal output from the comparator (OP1) and the fuser ON /Five And an AND gate (AN1) for outputting a pre-control signal. Fusing unit temperature control method comprising a temperature sensing unit for sensing and outputting the temperature of the fixing unit, and a control means for controlling the system by judging the temperature state of the fixing unit and outputting a selection control signal for selecting a standby state and a print state The method may further include detecting a disconnection state detection signal by detecting a temperature of the fuser unit and comparing it with a set disconnection state temperature, and detecting a standby state detection signal by detecting a temperature of the fuser unit and comparing it with a set standby state temperature. Detecting a temperature of the fuser unit and detecting a print state detection signal by comparing with a set print state temperature; selecting one of the standby state detection signal and a print state detection signal by the selection control signal; Detection signal selected in the process and disconnection state detection signal detected during the detection process And the method comprising the steps of: outputting a fixing unit control signal conducts logic operation to the temperature condition detection signal, by means of a fixing unit control signal output method characterized by constituted by any process for controlling the fixing unit on / off.