JPH0416918B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a tube wall temperature control device for a fluorescent lamp used in an image forming apparatus such as a copying machine.

Image forming devices such as copying machines and facsimile machines have
Fluorescent lamps are often used as instruments for illuminating manuscripts. As an example of a fluorescent lamp is shown in FIG. 1, the amount of light fluctuates depending on the temperature of the tube wall, and the value is greatest in a predetermined temperature range A (32 to 37 degrees Celsius in the figure). Therefore, for example, in some types of copying machines, preheating of the fluorescent lamp starts from the moment the power is turned on.
The start of copying work is prohibited until the tube wall temperature rises to a predetermined temperature.

FIG. 2 shows the appearance of a fluorescent lamp used in such a copying machine. Tube wall 1 of fluorescent lamp 1
A is the area where light is emitted onto the document surface and temperature detector 2
With the exception of area 3 provided for mounting the
It is covered with a planar lamp heater 4. In a conventional copying machine, when the copying machine is powered on, the temperature detector 2 starts detecting the temperature at the center of the tube wall 1A. Then, the lamp heater 4 is heated continuously until the detected temperature reaches the temperature range A (range of 100% relative light amount). Thereafter, the copying machine is set to a copyable state, and the reference temperature within this temperature range A is compared with the temperature of the tube wall 1A to perform on/off control of the lamp heater 4.

However, such a fluorescent lamp tube wall temperature control device has a drawback in that the tube wall temperature is relatively roughly controlled. In other words, the lamp heater 4 is turned on until the temperature of the tube wall 1A reaches the optimum temperature range A.
Since 100% of the allocated power is supplied to the device, even if the power supply is cut off, the temperature continues to rise for a while, resulting in a large deviation from the optimum temperature range A (overshoot).

Such a copying machine is equipped with a fan for cooling the fluorescent lamp, and the fan is driven when the tube wall temperature exceeds a certain temperature.
However, since the fluorescent lamp also generates heat by itself when it is on, it has not been possible to quickly lower the tube wall temperature, and it has been impossible to prevent such temperature fluctuations. If the tube wall temperature fluctuates greatly, the exposure amount of the original inevitably fluctuates to a considerable degree, which has an adverse effect on the image quality of copies and the like.

In view of these points, an object of the present invention is to provide a fluorescent lamp tube wall temperature control device for an image forming apparatus that can control the tube wall temperature with high precision.

In the present invention, there is provided a temperature detecting means for detecting the temperature of the tube wall of the fluorescent lamp for exposure, and a first temperature detecting means which is the lower limit of the temperature at which the tube wall temperature of the fluorescent lamp for exposure can be copied.
a first temperature setting means for setting the tube wall temperature of the exposure fluorescent lamp to a temperature higher than the first temperature and lower by a predetermined temperature than the temperature at which the maximum amount of light is emitted; a heater for heating the exposure fluorescent lamp; a rated power is supplied to the heater until the temperature detection means detects the first set temperature; 1
The image forming apparatus includes a power control means that gradually reduces the amount of power supplied to the heater after detecting the second temperature, and stops power supply to the heater when the temperature detection means detects a second temperature. be equipped with a fluorescent lamp tube wall temperature control device.

Then, the rated power is supplied to the heater until the temperature detecting means detects the first set temperature so that the amount of light that can be copied in a short time can be output, and from then on, the amount of power supplied to the heater is gradually reduced. The above-mentioned object is achieved by stopping the power supply to the heater after the temperature decreases and reaches a second temperature that is lower by a predetermined temperature than the temperature at which the maximum amount of light is emitted.

The present invention will be explained in detail with reference to Examples below.

FIG. 3 shows the basic structure of the electric circuit of a copying machine that implements this fluorescent lamp tube wall temperature control device. Detection signal 5 output from temperature detector 2
is supplied to the temperature converter 6, and a tube wall temperature signal 7 proportional to the tube wall temperature is created. The tube wall temperature signal 7 is supplied to a comparison section 8 and compared with a reference temperature signal 11 output from a reference temperature setting section 9. The reference temperature signal 11 is the temperature at 90% of the relative light intensity shown in Figure 1.
This is a signal representing t ₁ .

Comparison unit 8 compares both temperature signals 7 and 11 and outputs full power supply signal 12 until the tube wall temperature of fluorescent lamp 1 rises to temperature t ₁ . The power control unit 13 receives the pipe wall temperature signal 7 and the total power supply signal 12, and when receiving the total power supply signal 12, it outputs 100% of the allocated power (rated power). is supplied to the lamp heater 4. That is, the lamp heater 4 rapidly heats the fluorescent lamp 1 from when the copying machine is powered on until the tube wall temperature rises to _t1 . Up to this point, the control is no different from the control of conventional fluorescent lamp tube wall temperature control devices.

When the tube wall temperature reaches temperature _t1 , the copying machine is set to a copy ready state. If the exposure fluctuation is within 10%, the image quality of the copied image will be only slightly inferior to the normal one, and this will shorten the waiting time (warm-up time) until copying starts. .

When the tube wall temperature exceeds temperature _t1 , the power control section 13
monitors the tube wall temperature signal 7, and continuously reduces the amount of power supplied to the lamp heater 4 as the tube wall temperature approaches the lower limit temperature _t2 of the optimum temperature range A. Since the heating amount of the fluorescent lamp 1 is gradually reduced by such control, the tube wall temperature does not rise unduly. Note that the fluorescent lamp 1 generates heat when turned on. Therefore, when the tube wall temperature is about to exceed the optimum temperature A, a fan (not shown) is driven to air-cool the fluorescent lamp 1.

FIG. 4 embodies an electric circuit that realizes such control. Copy machine power terminal 21,
22 is connected to a commercial power source (AC100V) via a power switch (not shown).
Power line 2 connected to power terminals 21 and 22
3 and 24 are connected to a circuit power supply 25.
Between the DC line 26 connected to the DC output terminal DC of the circuit power supply 25 and one power line (earth line) 24, there is a variable resistor (1) in a parallel circuit of a thermistor 27 and a capacitor 28 for noise prevention. 29 connected in series, (2) amplifier 31 and
(3) A trigger circuit 33 for triggering the bidirectional thyristor 32 is connected in parallel. The thermistor 27 is a temperature detector attached to the tube wall 1A of the fluorescent lamp, and changes its resistance value according to the tube wall temperature. Further, the variable resistor 28 is connected to the temperature t ₁
This is a temperature setting element for setting the temperature.

Now, when the copying machine is powered on, a temperature display signal 34 at a voltage level divided by the variable resistor 29 and thermistor 27 is input to the amplifier 31. The temperature display signal 35 amplified by this is
It is supplied to one input terminal _I1 of the trigger circuit 33. The other input terminal I ₂ of the trigger circuit 33 is supplied with a reference voltage signal 37 from a reference voltage generator 36 . This reference voltage generator 36 is supplied with a zero-crossing point detection signal 39 from a zero-crossing detector 38 . The reference voltage generator 36 thereby generates a sawtooth wave that starts falling at each zero-crossing point Z of the AC waveform, as shown in FIG. This is the reference voltage signal 3 in this example.
It is 7. On the other hand, the temperature display signal 35 exhibits a temperature characteristic as shown in FIG. 6 because the thermistor 27 has a negative temperature coefficient.

Trigger circuit 33 compares temperature display signal 35 and reference voltage signal 37 and generates trigger signal 41 when the voltage level of reference voltage signal 37 falls below that of temperature display signal 35. When the copier is powered on, such as on a winter morning, the tube wall temperature of the fluorescent lamp is often lower than temperature _t1 . When the temperature is lower than t ₁ , the reference voltage signal 37 is always at a lower level than the voltage level V ₁ of the temperature display signal 35, as shown in FIG.

At this time, the trigger circuit 33 generates a trigger signal 41 at each zero cross point Z as shown in FIG. 7a. The bidirectional thyristor 32 is then triggered at each zero-crossing point, energizing the lamp heater 4 with all phases of the AC power supply, as indicated by hatching in FIG. 7b. The tube wall 1A of the fluorescent lamp is thereby rapidly heated.

When the tube wall temperature exceeds temperature _t1 , temperature display signal 3
5 voltage level is below _V1 . Accordingly, the phase in which the trigger signal 41 is generated shifts. For example, as shown in FIG. 6, assume that the tube wall temperature changes to a temperature t' slightly higher than the temperature t ₁ (however, t'<t ₂ ), and the voltage level of the temperature display signal 35 becomes V'.
At this time, as shown in FIG. 7c, the trigger signal 41
The phase in which this occurs is delayed, and the amount of power supplied to the lamp heater 4 decreases (the shaded area in FIG. 7d). After the tube wall temperature becomes higher than the temperature _t1 in this manner, the degree of heating by the lamp heater 4 decreases in accordance with the degree. When the tube wall temperature rises to temperature _t2 and the voltage level of temperature display signal 35 drops to _V2 , bidirectional thyristor 32 becomes non-conductive and heating of lamp heater 4 stops. As a result, the tube wall temperature does not rise excessively.

Note that when the fluorescent lamp 1 is turned on and copying is being performed, the tube wall temperature rises due to self-heating of the fluorescent lamp 1. This can be countered by driving a fan to air-cool the tube wall 1A, as has been conventionally done. Since the lamp heater 4 is heated when the tube wall temperature falls below the temperature _t2 , the tube wall temperature is always maintained within the optimum temperature range A.

As described above, according to the present invention, not only can the warm-up time be shortened, but also the tube wall of the fluorescent lamp is not heated unnecessarily, so that wasteful power consumption can be eliminated.

[Brief explanation of drawings]

Fig. 1 is a characteristic diagram showing an example of the relationship between tube wall temperature and relative light amount of a fluorescent lamp, Fig. 2 is a perspective view showing the external appearance of the fluorescent lamp, and Figs. This is for explaining one embodiment, and FIG. 3 is a basic block diagram of an electric circuit realizing the fluorescent lamp wall temperature control device of the present invention, and FIG. 4 is a block diagram embodying this. FIG. 5 is a waveform diagram of the reference voltage signal, FIG. 6 is a characteristic diagram showing voltage changes of the temperature display signal, and FIG. 7 is various voltage waveform diagrams for explaining heating control of the lamp heater by the trigger circuit. 1... Fluorescent lamp, 2... Temperature detector, 4... Lamp heater, 8... Comparison section, 13... Power control section,
27... Thermistor, 32... Bidirectional thyristor, 33... Trigger circuit, 36... Reference voltage generator.

Claims (1)

[Scope of Claims] 1. Temperature detection means for detecting the tube wall temperature of the exposure fluorescent lamp, and a first temperature that is the lower limit of the temperature at which a light amount capable of copying the tube wall temperature of the exposure fluorescent lamp is emitted. a first temperature setting means for setting the tube wall temperature of the exposure fluorescent lamp to a second temperature higher than the first temperature and lower by a predetermined temperature than the temperature at which the maximum amount of light is emitted; a second temperature setting means for heating the exposure fluorescent lamp; a heater for heating the exposure fluorescent lamp; supplying rated power to the heater until the temperature detecting means detects the first set temperature; and power control means that gradually reduces the amount of power supplied to the heater after detecting the first temperature, and stops the power supply to the heater when the temperature detection means detects a second temperature. A fluorescent lamp tube wall temperature control device for an image forming apparatus, characterized in that: