JPH1055121A - Electrophotographic printer and controlling method for its heater - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent a high rush current from flowing through a heater lamp by suppressing the heat generation from a resistor by means of lightening the burden of rush current limiting resistor and also accurately performing the time control of rush current limitation without making a device large-sized in the heater lamp controlling method of an electrophotographic printer. SOLUTION: This device is provided with a heater 2 heating a fixing heat roll 1, and the feed and the nonfeed of a current made to flow through theater 2 are controlled by detecting the temperature of the heater by a thermistor 3, and also control to limit the rush current is performed by making a heater current low by using the rush current limiting resistance 5 at the beginning of the feed whenever the feed is made. A CPU 14 variably controls time when the heater current for the rush current limitation executed at the beginning of feeding the heater 2 is made low in accordance with nonfeed time just before the feed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a method for controlling a heater current in an electrophotographic printing apparatus such as a printer or a copying machine.

[0002]

2. Description of the Related Art In an electrophotographic printing apparatus such as a laser beam printer, a sheet is transferred (transferred) onto paper.
Since the toner is fixed using the heat roll, temperature management control is performed such that the heat roll is kept constant.

A conventional heater drive circuit and a conventional heater control (heater current control) method for controlling the temperature will be described with reference to FIGS. The operation up to the operation of keeping the temperature constant at the temperature to be controlled will be described as an example.

FIG. 3 is a configuration diagram of a conventional heater drive circuit.
A heater lamp is used as a heater 2 for heating the heat roll 1, and a thermistor 3 for detecting the temperature of the heat roll 1 is arranged in proximity to the heater lamp 2 in addition to the power supply 4 as an element for controlling the driving of the heater lamp 2. is, the comparator 1 in addition, for comparing the voltage dividing resistors 8 taken out temperature detection signal V _T of the thermistor 3, dividing resistors 9, 11 to form the reference voltage value V _R, the reference resistor V _R and the temperature detection signal V _T
0, NAND gate 12, inrush current limiting resistor 5, resistor 5
6 for switching the power supply to the heater lamp 2 and the power supply to the heater lamp 2 for non-power supply control.
R) 7, an inverter 13 for controlling the relay 6, and a CPU 14 serving as a controller for controlling the heater lamp.

FIG. 4 is a time chart showing a conventional operation of the heater drive circuit and an explanatory diagram showing a current waveform flowing through the heater. In order to prevent an inrush current, a logic "1" is effective for the heater DRV-P signal. , Soft-start-N signal is valid at logic "0".

First, immediately after turning on the power of the printing apparatus, the CPU 1
When a "1" to the heater DRV-P signal outputted from the 4, the voltage V _T and the resistor 9 and the resistor 11 divided by the resistance value RT and the resistance 8 of the thermistor 3 for low resistance of the thermistor 3 relationship divided reference voltage V _R is a V _T> V _R. At this time, the output from the comparator 10 becomes “1”, the output from the NAND gate 12 becomes “0”, the SSR 7 operates, and a current limited by the rush current limiting resistor 5 flows through the heater lamp 2.

Here, the current limited by the rush current limiting resistor 5 is a current flowing for the purpose of preventing the rush current until the heater lamp 2 is heated to increase the resistance value of the heater lamp 2. Therefore, as shown in the timing chart of FIG. 4, during the set time T1 (sec) after the heater DRV-P signal is set to “1”, the current passing through the inrush current limiting resistor 5 flows through the heater lamp 2, and thereafter. CPU1
4 is set to "1".

When the soft start-N signal is set to "1", the relay 6 is operated, whereby the heater lamp 2 is turned on.
The restriction on the current flowing through the heater lamp 2 is released, and a current flows through the heater lamp 2 without passing through the inrush current limiting resistor 5. Then, when a current flows through the heater lamp 2, the heat roll 1
Heat.

[0009] Heating the heat roll 1, the resistance value of the thermistor 3 as the temperature of the heat roll 1 is increased magnitude of the voltage V _T and reference voltage V _R when the heat roller 1 reaches a temperature to be controlled is reversed, the V _T <V _R.

When the voltage V _R increases, the comparator 10
Is inverted to "0", the output of the NAND gate 12 becomes "1", the operation of the SSR 7 stops, and the power supply to the heater lamp 2 stops. When power supply to the heater lamp 2 is stopped, also decreases the resistance value of the thermistor 3 for the temperature of the heat roll 1 is lowered, the relationship of the voltage V _T and the voltage V _R is reversed again.

Then, the same operation as immediately after the power is turned on is performed, and the power supply to the heater lamp 2 is restarted. However, here
The time from when the heater DRV-P signal becomes "1" to when the soft start-N signal becomes "1" (time for limiting the inrush current) was T1 (sec) immediately after the power was turned on. After the heat roll 1 has warmed up, T1
It is constant at T2 (sec) shorter than (sec).

[0012] As described above, the relationship between the voltage V _T and reference voltage V _R which changes the resistance value of the thermistor 3 is repeated inversion, the current flowing through the relay 6 and SSR7 operating according this relationship to the heater lamp 2 Control Then, the temperature of the heat roll 1 is controlled to be constant.

[0013]

In THE INVENTION Problems to be Solved by the conventional heater control (heater lamp control), only through the inrush current limiting resistor 5 predetermined time T ₂ after the power is turned to the printing apparatus each time the power supply to the heater lamp Although an attempt is made to supply a low-limited current, the amount of heat generated by the rush current limiting resistor 5 increases, and the resistance increases and the price increases.

Further, during non-printing (during printing standby) after the heat roll is warmed up, the heat roll does not immediately drop because the heat is not absorbed by the heat roll by the paper. The time of non-power supply by temperature control tends to be longer,
Since the resistance value of the heater lamp is greatly reduced and the inrush current cannot be limited even when the power is supplied to the heater lamp thereafter, a large inrush current flows and the regulation value for flicker cannot be satisfied. There was something to do.

The present invention has been made in view of the above points, and an object of the present invention is to reduce the load of an inrush current limiting resistor by controlling a heater in an electrophotographic printing apparatus, thereby suppressing heat generation of the resistor and increasing the size of the resistor. Another object of the present invention is to prevent a large inrush current from flowing through the heater lamp by accurately performing time control for limiting the inrush current.

[0016]

In order to achieve the above object, the present invention proposes the following heater control method.

That is, a heater is provided for applying heat to the fixing heat roll, and the temperature of the heater is detected to control power supply and non-power supply of the current flowing through the heater. In a heater control method for an electrophotographic printing apparatus which performs control to limit a rush current by lowering a heater current using a resistor, a heater current for rush current limitation executed when power is supplied to the heater is controlled. It is characterized in that the time to be reduced is variably controlled according to the non-power supply time immediately before the power supply.

Further, as an apparatus for executing this control method, a heater for applying heat to a heat roller for fixing, a temperature of the heater is detected to control power supply and non-power supply to a current flowing through the heater, and power is supplied to the heater. In the electrophotographic printing apparatus having a heater drive circuit for performing control such that the heater current is reduced by using the rush current limiting resistor to reduce the rush current at the beginning of power supply, the power supply immediately before the power is supplied to the heater Time measuring means for measuring the non-power supply time, and rush current limit time control means for variably controlling the time for reducing the heater current for restricting the rush current when supplying power to the heater according to the non-power supply time immediately before the power supply. And the one with

According to these means for solving the problems, when the temperature of the heater is detected to control the power supply and non-power supply of the current flowing through the heater to control the fixing heat roll, the non-power supply time immediately before power supply is reduced. By measuring in advance, it is possible to know from the length of the non-power supply time how much the resistance value of the heater itself has decreased due to the temperature drop, and to limit the rush current according to the length of the non-power supply time. Therefore, it is possible to accurately determine how long the low current should be applied to the heater.

[0020]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described with reference to FIGS.

FIG. 1 shows a timing chart of a method for controlling a heater of an electrophotographic printing apparatus according to an embodiment of the present invention, and shows a current waveform flowing through the heater lamp and a temperature waveform of a heat roll. In FIG. 1, when inrush current limitation is performed, the heater DRV-P signal is valid at logic "1" and the soft start-N signal is valid at logic "0". FIG. 2 is a heater control circuit diagram. The difference from the circuit of FIG. 3 is that the CPU 14 includes a non-power supply time measuring unit 14A immediately before power is supplied to the heater lamp 2.
In addition to controlling the power supply and non-power supply of the heater lamp 2, the CPU 14 sets the time for reducing the heater current for limiting the rush current when supplying power to the heater lamp 2 according to the non-power supply time immediately before the power supply. It also functions as rush current limit time control means for variably controlling.

FIG. 5 is an example showing a characteristic graph of the resistance value of the heater lamp and the time when the current is turned off from the state where the temperature of the heater lamp is controlled. FIG. 6 is an example showing a characteristic graph of the resistance value of the heater lamp and the time when a constant current flows from a state where the heater lamp is at room temperature.

1 and 2, when the heater DRV-P signal output from the CPU 14 is set to "1" immediately after the power of the printing apparatus is turned on, the resistance value of the thermistor 3 is low because the resistance value of the thermistor 3 is low. relationship divided reference voltage V _R and a voltage divided V _T by the resistor 8 by the resistor 9 and the resistor 11 is in the V _T> V _R. At this time, the output from the comparator 10 becomes “1”, the output from the NAND gate 12 becomes “0”, the SSR 7 operates, and a current limited by the rush current limiting resistor 5 flows through the heater lamp 2. Next, after the lapse of Tpon (sec), the CPU 1
The soft-start-N signal output from 4 becomes “1”, and at this time, the relay 6 operates, and a current that does not pass through the inrush current limiting resistor 5 flows through the heater lamp 2.

Here, during Tpon (sec), the heater lamp 2 is heated to increase the resistance value of the heater lamp 2 to prevent an inrush current flowing when the soft start-N signal becomes "1". Is the same as the conventional control method.

When the temperature of the heat roll 1 reaches a predetermined temperature, for example, 185 ° C. after the soft start-N signal becomes “1” (= when the voltage of the thermistor 3 becomes a voltage equivalent to 185 ° C.) CPU14 recognizes that the voltage V _T is V _T <V _R, the heater DRV-P signal, and the soft-start -N signal to "0". Thus, the heater DR
When the VP signal and the soft start-N signal are inverted and no current flows through the heater lamp 2, the temperature of the heat roll 1 gradually decreases. As the temperature of the heat roll 1 decreases, the heater lamp 2 also cools and the resistance decreases. In this example, after the temperature of the heat roll 1 reaches 185 ° C.,
It is designed so that it will not turn on again unless the temperature drops to 175 ° C.

As shown in "non-printing time" in FIG. 1, in the case of non-printing time, since the heat of the heat roll 1 is not taken away by the paper, it takes a long time for the temperature of the heat roll 1 to drop by 10 ° C. It costs. During this time, the resistance value of the heater lamp 2 also decreases, but the resistance value of the heater lamp 2 decreases more sharply than the temperature decrease of the heat roll 1.

As an example, in the case of a laser printer for medium-speed continuous paper, it takes 90 (sec) for the heat roll 1 to drop by 10 ° C. during non-printing. As shown in FIG.
After the current stops flowing through the heater lamp 2, 90 (se
c) After that, the resistance value of the heater lamp 2 becomes about 3.5 (Ω), and the rush current flowing through the heater lamp 2 is reduced to 20 (A).
If the supply voltage is not more than 200 (V), the resistance of the heater lamp 2 is required to be about 3 (Ω) or more when the supply voltage is 200 (V).
(Sec), the current limited by the rush current limiting resistor 5 in this case is passed through the heater lamp 2 for 3 (sec) (here, T _NP1, T _NP2 and T _NP3 ) and then the rush current limiting resistor It is necessary to heat the heat roll 1 by supplying a current that does not pass through the heat roll 5.

[0028] C by a non-feeding time voltage V _T until the thermistor 3 as described above becomes 175 ° C. from 185 ° C.
When the PU 14 monitors and measures the time, the PU 14 operates and controls the heater DRV-P signal and the soft start-N signal.

Next, in the case of printing, it does not take a long time for the temperature of the heat roll 1 to drop by 10 ° C. In the case of a medium speed continuous paper laser printer, during printing, heat roll 1
The time required for the temperature to drop by 10 ° C. (non-power supply time) is 0.
5 (sec), and the resistance value of the heater lamp after 0.5 (sec) is maintained at about 20 (Ω). If it is sufficient that the inrush current flowing through the heater lamp should be suppressed to 20 (A) or less, in this case, since it is not necessary to limit the inrush current by the inrush current limiting resistor 5, as shown in "at the time of printing" in FIG. Even if the DRV-P signal and the soft start-N signal are simultaneously set to "1", a current of 20 (A) or more does not flow to the heater lamp.

Therefore, according to the present embodiment, it is possible to accurately capture the time required to always flow through the rush current resistor.

[0031]

According to the present invention, since the time control of the current to be supplied to the heater via the inrush current limiting resistor is accurately performed by taking the resistance value of the heater from the immediately preceding non-power supply time, the inrush current can be accurately controlled. Since it can be suppressed well, it is effective in preventing flicker. In addition, when it is not necessary to supply an inrush current or when there is no problem in controlling the inrush current (when the immediately preceding non-power supply time is short), the inrush current time is flexibly controlled in response to the inrush current. Since the heat generated by the resistor is suppressed, the size and cost of the resistor can be reduced.

[Brief description of the drawings]

FIG. 1 is a time chart showing a heater control operation according to an embodiment of the present invention.

FIG. 2 is a circuit diagram of a heater control system of the electrophotographic printing apparatus according to the embodiment of the present invention.

FIG. 3 is a time chart showing a conventional heater control operation.

FIG. 4 is a circuit diagram of a heater control system of a conventional electrophotographic printing apparatus.

FIG. 5 is an explanatory diagram showing the resistance characteristics of the heater lamp itself when the current flowing through the heater lamp is cut off.

FIG. 6 is a characteristic diagram showing a resistance rise curve of the heater lamp itself when a constant current is applied to the heater lamp.

[Explanation of symbols]

1. Heat roll, 2. Heater (heater lamp), 3.
Thermistor (temperature detecting means), 5 ... inrush current limiting resistor,
6 relay, 7 SSR, 14 CPU (heater control means, inrush current limit time control means).

Claims (3)

[Claims] A heater for applying heat to a fixing heat roll is provided, and the temperature of the heater is detected to control power supply and non-power supply of a current flowing through the heater. In a heater control method for an electrophotographic printing apparatus that performs control to limit a rush current by lowering a heater current using a resistor, a time for reducing the heater current for limiting the rush current when power is supplied to the heater. Is variably controlled according to a non-power supply time immediately before the power supply. 2. The electrophotographic printing apparatus according to claim 1, wherein the time for reducing the heater current for limiting the rush current is a time selected so that the rush current to the heater is equal to or less than a specified value. Heater control method. 3. A heater for applying heat to a heat roller for fixing, detecting a temperature of the heater, controlling power supply and non-power supply of a current flowing through the heater, and, at each time of power supply, a rush current limiting resistor at the beginning of power supply. An electrophotographic printing apparatus including a heater driving circuit that performs control to reduce a rush current by lowering a heater current by using a time measuring unit that measures a non-power supply time immediately before power is supplied to the heater. Rush current limiting time control means for variably controlling the time for reducing the heater current for limiting the rush current when supplying power to the heater in accordance with the non-power supply time immediately before the power supply. Electrophotographic printing device.