KR20200071399A - Heater control device and method for fuser module of laser printer - Google Patents

Abstract

The present invention provides a device and a method for controlling a heater of a fuser module for a laser printer. The device for controlling a heater of the present invention comprises: an input unit receiving a voltage of a temperature sensor from the heater; and a control unit checking driving of the heater based on the received voltage, maintaining that power is turned on during a preset certain time while the heater is driven, and controlling the power to be turned on/off through a PWM signal of a preset frequency and duty ratio until the voltage reaches a target temperature upper limit after the certain time.

Description

Heater control device and method for fuser module of laser printer

The present invention relates to a laser printer, and more particularly, to a heater control apparatus and method for a laser printer fixing module that stably performs temperature control for a heater of a fixing module for laser printers at a low cost.

The laser printer fixing module is a laser printer engine that applies heat and pressure using a heating roller (fixing roller) and a pressurizing roller to statically fix (transfer or fuse) toner transferred onto printing paper. .

Most of the documents issued by contracts and government offices use 100% laser printers because the prints with the ability to preserve documents for more than 5 years are produced through the process of applying heat and pressure to fix the toner to the paper. For this print quality, it is necessary to heat the toner fused surface (fixed roller surface) to 180°C or higher, and a lot of energy is used in this process. Therefore, it is important to control the heater to improve the print quality and energy efficiency of the laser printer.

In general, a contact-type thermo-couple (TC) temperature sensor is frequently used to control the heater temperature of a laser printer, but has a disadvantage in that the reaction speed is slow in response to the temperature change of the heater. To overcome this, an additional non-contact infrared temperature sensor is used, or temperature is controlled based on an experimentally obtained database. However, this method has a problem that it is difficult to increase the cost or accurately control the temperature.

Korean Patent Publication No. 10-2014-0092990 (2014.07.25.)

Technical problem to be achieved by the present invention is to provide a heater control device and method of a fixing module for a laser printer that divides a voltage measured by a low-cost contact type temperature sensor into a predetermined area and performs temperature control of a heater suitable for each area. There is a purpose.

In order to achieve the above object, the heater control device of the fixing module for a laser printer according to the present invention checks the driving of the heater based on the input unit that receives the voltage of the temperature sensor from the heater and the input voltage, and the When the heater is driven, the power of the heater is kept on for a predetermined period of time, and after the specified period of time, the preset frequency and duty ratio until the voltage reaches the target upper temperature limit (V _H ). It includes a control unit for performing on / off (on / off) control of the power through the PWM signal of (duty ratio).

In addition, it characterized in that it further comprises a power switch for outputting a PWM signal according to the on/off control of the ADC and the ADC to convert the voltage input from the input unit to an analog signal to a digital signal and transmits it to the control unit.

In addition, the control unit controls the power off when the voltage reaches the target temperature upper limit while driving the heater, receives the voltage feedback, and turns the power on/off using the feedback voltage ( on/off) characterized by generating a PWM signal to control.

In addition, the controller is characterized in that it sets the upper and lower limits of the voltage, and generates the PWM signal so that the feedback voltage is maintained between the upper and lower limits.

In addition, when the feedback voltage is lower than the upper limit point and reaches the upper limit point, the controller generates a PWM signal in which the power is off, and when the feedback voltage is higher than the lower limit point and reaches the lower limit point, It characterized in that it generates a PWM signal that the power is on.

In addition, the control unit sets a voltage average point (V _AV ), and gives a preset delay to maintain the current power state based on the set average point, and when the given delay is completed, PWM opposite to the current power state It is characterized by generating a signal.

In addition, when the feedback voltage is lower than the average point and reaches the average point, the controller generates a PWM signal with the power on by a preset delay (on-delay), and the PWM with the power off when the delay is completed. A signal is generated, and when the feedback voltage is higher than the average point and reaches the average point, a PWM signal in which the power is off is generated by a preset delay (off-delay), and when the delay is completed, the power is in PWM It is characterized by generating a signal.

In addition, the heater is characterized in that it comprises a planar heating element formed of a nano-material.

In addition, the temperature sensor is characterized in that it is a contact-type thermo-couple (TC) temperature sensor in contact with the heater.

In the heater control method of the fixing module for a laser printer according to the present invention, a heater control device receives a voltage of a temperature sensor from a heater, and the heater control device confirms driving of the heater based on the input voltage, When the heater control device is driven, the step of maintaining the power of the heater for a predetermined period of time when the heater is driven, and until the voltage reaches the target temperature upper limit point when the heater control apparatus passes the specified time. And performing power on/off control through a PWM signal having a set frequency and duty ratio.

The heater control device and method of the fixing module for a laser printer of the present invention divides the voltage measured by the low-cost contact temperature sensor into a continuous area, a fixed pulse width modulation (PWM) area, and a feedback area to control the heater temperature according to each area. By performing, it is possible to stably control the temperature by solving the problem of delaying the reaction time of the contact temperature sensor.

In addition, since no additional parts are used, a cost reduction effect can be obtained.

1 is a schematic diagram for explaining a heater control device of a fixing module for a laser printer according to an embodiment of the present invention.
2 is a view for explaining temperature control for each region according to an embodiment of the present invention.
3 is a view for explaining temperature control in a feedback area according to an embodiment of the present invention.
4 is a view for explaining temperature control in a feedback area according to another embodiment of the present invention.
5 is a flow chart for explaining the heater control method of the fixing module for a laser printer according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, when adding reference numerals to the components of each drawing, it is noted that the same components have the same reference numerals as possible even though they are displayed on different drawings. In addition, in describing the present invention, when it is determined that a detailed description of a related known configuration or function is obvious to those skilled in the art or may obscure the gist of the present invention, the detailed description will be omitted.

1 is a schematic diagram for explaining a heater control device of a fixing module for a laser printer according to an embodiment of the present invention.

Referring to FIG. 1, the heater control device 100 of the fixing module for a laser printer divides a voltage measured by a low-cost contact type temperature sensor into a predetermined area and performs temperature control of a heater suitable for each area. Through this, the heater control device 100 can solve the problem of delaying the reaction time of the contact-type temperature sensor to stably control the temperature. Here, the voltage measured by the low-cost contact temperature sensor has the same meaning as the temperature, and means that the temperature is expressed in voltage. The heater control device 100 is connected to a switched mode power supply (SMPS) 200 and a heater 300.

The SMPS 200 supplies power to the heater control device 100. SMPS 200 uses a switch control method that converts AC power to DC power. The SMPS 200 includes a rectifier 210, a power factor corrector (PFC) converter 220 and a DC-DC converter 230.

The rectifier 210 performs a rectifying action to obtain DC power from AC power. That is, the rectifier 210 allows the AC power to pass current in only one direction.

The PFC converter 220 is a converter in which PFC is added to the converter input terminal. The PFC converter 220 improves the power factor by compensating for the power factor of the AC inlet.

The DC-DC converter 230 converts the voltage of the DC power received from the PFC converter 220 into the voltage of the DC power usable in the heater control device 100. Through this, the DC-DC converter 230 allows the heater control device 100 to stably receive DC power.

The heater 300 is connected to the fixing module 400, and cures the toner transferred to the printing paper by a developing module (not shown) of the laser printer. Here, the heater 30 may be formed in a roller shape and connected to the fixing module 400. The heater 300 may generate heat in various forms. Preferably, the heater 300 may generate heat by including a planar heating element formed of a nano material. The heater 300 may be provided with a temperature sensor (not shown) in part to measure temperature. In this case, the temperature sensor may be a contact-type thermo-couple (TC) temperature sensor contacting the heater 300. Here, the contact type thermo-couple temperature sensor has an advantage of low cost, but has a disadvantage of slow reaction speed.

The heater control device 100 controls the temperature of the heater 300. At this time, the heater control device 100 receives DC power from the SMPS 200 and performs temperature control of the heater 300 based on the voltage of the temperature sensor measured from the heater 300. The heater control device 100 includes an input unit 10 and a control unit 30, and further includes an analog-digital converter (ADC) 20, a power switch 40, and a low dropout (LDO) regulator 50. .

The input unit 10 receives the voltage of the temperature sensor from the heater 300. The input unit 10 may be designed as an OP-AMP.

The ADC 20 converts the voltage input to the input unit 10 from an analog signal to a digital signal. The ADC 20 transmits the converted digital signal to the control unit 30.

The control unit 30 controls the temperature of the heater 300 based on the input voltage. The controller 30 checks the driving of the heater 300 based on the input voltage. When the heater 300 is driven, the controller 30 performs a first control that maintains the power of the heater 300 in an on state for a predetermined time T _ON . Here, the specific time refers to a time when the heater 300 is heated to a temperature adjacent to the target temperature upper limit point V _H. The control unit 30 controls the second control to control the power on/off (on/off) through a fixed PWM signal at a preset frequency and duty ratio until a voltage reaches a target temperature upper limit after a specific time has elapsed. Perform. At this time, the control unit 30 controls the power off when the voltage reaches the target temperature upper limit while driving the heater 300, receives the feedback of the temperature sensor voltage, and turns on/off the power using the feedback voltage. (on/off) Performs a third control that generates a PWM signal to control. Detailed descriptions of the first control to the third control will be provided with reference to FIGS. 2 to 4.

The power switch 40 outputs a PWM signal according to on/off control of the control unit 30. The power switch 40 outputs a PWM signal that controls on/off of the driving voltage of the heater 300, and thereby controls the temperature of the heater 300.

The LDO regulator 50 generates an internal bias voltage of the heater control device 100 using DC power supplied from the SMPS 200. The LDO regulator 50 can output a stable voltage through feedback even if the voltage of the provided DC power is shaken.

2 is a view for explaining temperature control for each area according to an embodiment of the present invention, FIG. 3 is a view for explaining temperature control in a feedback area according to an embodiment of the present invention, and FIG. 4 is for the present invention A diagram for explaining temperature control in a feedback area according to another embodiment of the present invention.

1 to 4, the control unit 30 improves the problem caused by the delay of the reaction time for the heat generation of the heater 300 according to the slow reaction speed of the temperature sensor by performing temperature control in accordance with a predetermined area to improve it. . The control unit 30 sets a continuous-on region (step 1), a fixed PWM region (step 2), and a feedback control region (step 3), and controls the temperature to match the set region. To perform. Here, the continuous area is an area in which the power switch is continuously turned on for a specific time after reset to satisfy a heat-up rate specification of the heater 300. The fixed PWM region is a region for roughly controlling the upper limit of the target temperature until the temperature sensor stabilizes after the reaction time delay. The feedback area is an area that receives the voltage of the temperature sensor from the heater 300 and performs temperature control using the feedback voltage.

The control unit 30 performs the first control by continuously turning on the power switch 40 for a predetermined period of time in the initial stage of driving of the heater 300 in the sustain region. At this time, the control unit 30 controls the heater 300 to be driven in the feedback area immediately when the voltage of the temperature sensor exceeds a target upper temperature limit due to preheating or the like.

After a certain period of time, it is changed to a fixed PWM region, and the controller 30 generates a PWM signal having a preset frequency and a duty ratio until the voltage of the temperature sensor reaches a target temperature upper limit in the fixed PWM region. . The control unit 30 performs the second control by turning the power switch 40 on/off using the generated PWM signal. The frequency and duty ratio are preset based on the calculated value using the expected output voltage of the SMPS 200 and the resistance value for the planar heating element of the heater 300. When the voltage of the temperature sensor reaches the upper limit of the target temperature, the controller 30 determines that the reaction time delay has ended.

If the voltage of the temperature sensor reaches the target upper temperature limit during driving of the heater in the continuous area or the fixed PWM area, the control unit 30 determines that it is a feedback area, immediately turns off the power switch 40, and then the voltage of the temperature sensor, that is, the heater The temperature value of 300 is fed back, and a third control is performed to turn on/off the power switch 40 according to the fed back temperature.

That is, the control unit 30 controls the power off when the voltage reaches the target temperature upper limit while driving the heater 300, receives the voltage of the temperature sensor from the heater 300, and turns on the power using the feedback voltage. Generate PWM signal to control on/off. At this time, the control unit 30 may perform temperature control in the feedback area in two ways.

One of the two methods is a method of controlling by setting the upper and lower limits of the voltage. The control unit 30 sets the upper and lower limit points of the voltage, and generates a PWM signal so that the feedback voltage is maintained between the upper limit point V _H and the lower limit point V _L.

In detail, the control unit 30 generates a PWM signal whose power is off when the feedback voltage is lower than the upper limit point and reaches the upper limit point. In addition, when the feedback voltage is higher than the lower limit point and reaches the lower limit point, the controller 30 generates a PWM signal that is powered on. Through this, the control unit 30 can control the temperature of the stable heater 300 by maintaining the voltage between the upper and lower limits.

The other of the two methods is a method of controlling by setting the average point of the voltage (V _AV ). The controller 30 sets the average point of the voltage, and gives a delay to maintain the current power state based on the set average point. When the given delay is completed, the controller 30 generates a PWM signal opposite to the current power state. Here, the delay is set in consideration of the heat capacity of the heater, and may be different when the temperature rises or falls.

In detail, when the feedback voltage is lower than the average point and reaches the average point, the control unit 30 generates a PWM signal that is powered on by a preset delay (on-delay). When the delay is completed, the controller 30 generates a PWM signal whose power is off. In addition, when the feedback voltage is higher than the average point and reaches the average point, the controller 30 generates a PWM signal whose power is off by a preset delay (off-delay). When the delay is completed, the controller 30 generates a PWM signal that is powered on. Through this, the control unit 30 can stably perform temperature control by considering the delay of the reaction time of the temperature sensor.

5 is a flow chart for explaining the heater control method of the fixing module for a laser printer according to an embodiment of the present invention.

1 and 5, the heater control method divides the voltage measured by the low-cost contact-type temperature sensor into a continuous region, a fixed PWM region, and a feedback region, and performs temperature control of the heater according to each region to perform a contact-type temperature sensor. The reaction time delay problem can be solved to control the temperature stably. In addition, since the heater control method does not use additional parts, a cost reduction effect can be obtained.

In step S110, the heater control device 100 turns on the power switch 40. When the heater 300 is driven, the heater control device 100 turns on the power switch 40 so that the heater is heated.

In step S120, the heater control device 100 checks the voltage of the temperature sensor. The heater control device 100 receives a voltage related to temperature from a temperature sensor provided in a part of the heater 300. At this time, the temperature sensor may be a contact-type thermo-couple temperature sensor contacting the heater 300.

In step S130, the heater control device 100 determines whether the input voltage (V _TC ) is greater than the target temperature upper limit point (V _H ). The heater control device 100 performs step S140 when the input voltage is larger than the target temperature upper limit point, and performs step S150 when the input voltage is smaller than the target temperature upper limit point.

In step S140, the heater control device 100 performs the third control. The heater control device 100 determines that it is a feedback area, and performs third control suitable for the feedback area. That is, the heater control apparatus 100 preferentially controls the power off, receives the power, and generates a PWM signal that controls the power on/off using the feedback voltage. At this time, the heater control device 100 sets the upper and lower limit points of the voltage, controls the PWM signal to be generated so that the feedback voltage is maintained between the set upper and lower limit points, sets the average point of the voltage, and sets the average point It can be controlled so that the PWM signal is generated so that the voltage is maintained based on.

In step S150, the heater control device 100 determines whether the time T at which the heater 300 is driven is smaller than the specific time T _ON . The heater control device 100 performs step S160 when the time at which the heater 300 is driven is less than a specific time, and performs step S180 when the time at which the heater 300 is driven is greater than a specific time.

In step S160, the heater control device 100 performs the first control. The heater control device 100 maintains the power of the heater 300 in an on state.

In step S170, the heater control device 100 increases the time that the heater 300 is driven. After increasing the time, the heater control device 100 performs step S120. Through this, the heater control device 100 controls the heater 300 to maintain the power-on state for a specific time.

In step S180, the heater control device 100 performs the second control. The heater control device 100 performs on/off control of power through a PWM signal having a preset frequency and duty ratio. After performing the on/off control, the heater control device 100 performs step S120. Through this, the heater control device 100 may perform on/off control of power through a fixed PWM signal until the input voltage reaches a target temperature upper limit.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific preferred embodiments described above, and the technical field to which the present invention pertains without departing from the gist of the present invention claimed in the claims. Of course, various modifications can be made to anyone having ordinary knowledge, and such changes are within the scope of the claims.

10: op amp
20: ADC
30: MCU
40: power switch
50: LDO regulator
100: heater control device
200: SMPS
210: rectifier
220: PFC converter
230: DC-DC converter
300: heater
400: fixing module

Claims (10)

An input unit that receives a voltage of a temperature sensor from a heater; And
The operation of the heater is checked based on the input voltage, and when the heater is driven, the power of the heater is kept on for a predetermined period of time, and when the specified time passes, the voltage is the target temperature upper limit. A control unit that performs on/off control of power through a PWM signal of a preset frequency and duty ratio until a point V _H is reached;
Heater control device of the fixing module for a laser printer comprising a. According to claim 1,
An ADC that converts the voltage input from the input unit from an analog signal to a digital signal and transmits it to the control unit; And
A power switch outputting a PWM signal according to on/off control of the control unit;
Heater control device of the fixing module for a laser printer, further comprising a. According to claim 1,
The control unit,
When the voltage reaches the upper limit of the target temperature during driving of the heater, the power is turned off, the voltage is fed back, and the power is turned on/off using the feedback voltage. Heater control device of the fixing module for a laser printer, characterized in that for generating a PWM signal. According to claim 3,
The control unit,
A heater control device for a fixing module for a laser printer, wherein the PWM signal is generated so that the upper and lower limits of voltage are set and the feedback voltage is maintained between the upper and lower limits. The method of claim 4,
The control unit,
When the feedback voltage is lower than the upper limit point and reaches the upper limit point, the power is turned off to generate a PWM signal, and when the feedback voltage is higher than the lower limit point and reaches the lower limit point, the power-on PWM Heater control device of the fixing module for a laser printer, characterized in that for generating a signal. According to claim 3,
The control unit,
Setting the average point of voltage (V _AV ), giving a preset delay to maintain the current power state based on the set average point, and generating the PWM signal opposite to the current power state when the given delay is completed Heater control device of the fixing module for a laser printer, characterized by. The method of claim 6,
The control unit,
When the feedback voltage is lower than the average point and reaches the average point, the power-on PWM signal is generated by a preset delay (on-delay), and when the delay is completed, the power-off PWM signal is generated, When the feedback voltage is higher than the average point and reaches the average point, generating a PWM signal in which the power is off by a preset delay (off-delay), and generating the PWM signal in which the power is on when the delay is completed Heater control device of the fixing module for a laser printer, characterized by. According to claim 1,
The heater,
Heater control device of the fixing module for a laser printer, characterized in that it comprises a planar heating element formed of a nano material. According to claim 1,
The temperature sensor,
A heater control device for a fixing module for a laser printer, characterized in that it is a contact thermo-couple (TC) temperature sensor in contact with the heater. A step in which the heater control device receives the voltage of the temperature sensor from the heater;
Checking, by the heater control device, driving of the heater based on the input voltage;
When the heater control device drives the heater, maintaining the power of the heater in an on state for a predetermined period of time; And
The heater control device performing on/off control of power through a PWM signal of a preset frequency and duty ratio until the voltage reaches a target temperature upper limit point after the specific time has passed;
Heater control method of the fixing module for a laser printer comprising a.

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