JPH02134671A - Drum heater - Google Patents

Abstract

PURPOSE:To shorten a time lag continuing until a change is compensated by allowing an infrared ray absorbing coating applied on the interior of a photosensitive drum to absorb infrared rays emitted from an infrared heater. CONSTITUTION:The infrared heater 1 is provided so that it is fixed on the rotational, central axis of photosensitive drum 4. Its internal surface is coated with the infrared ray absorbing coating 2, and a temperature sensor 5 composed of a thermistor, etc., is provided to be close to the external surface of the drum as much as possible. The infrared ray emitted from the infrared heater 1 absorbed greatly by the infrared ray absorbing coating 2 applied on the internal surface of the photosensitive drum 4, whereby heat is efficiently and speedily propagated from the infrared heater 1 to the photosensitive drum 4. As a result, when the temperature of the external surface of the photosensitive drum 4 changes, the time lag until its correction is completed can be shortened.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a drum heater device. More specifically, the present invention relates to a drum heater device provided in a photosensitive drum of an electronic copying machine, a printer, or the like.

Conventional technology Photoreceptor drums for electronic copying machines have traditionally been coated with selenium-tellurium (Se-Te) on the outer surface of the aluminum drum tube.
A vapor-deposited alloy is used. Recently, arsenic-selenium (As) has been developed which has several times higher sensitivity to light than photoreceptor drums made by vapor-depositing this selenium-tellurium alloy.
Photoreceptor drums (hereinafter referred to as "arsenic drums") formed by vapor-depositing -Se) alloys have come into use. However, when an arsenic drum is used, if the temperature is not kept constant due to the nature of the arsenic-selenium alloy that serves as the photoreceptor, the sensitivity to light will vary depending on the temperature, resulting in image unevenness in copies.

On the other hand, when a lamp heater is installed on the central axis of rotation of the photoreceptor drum as a heater for the photoreceptor drum, the air layer between the drum rough tube and the lamp heater acts as a heat conduction medium, causing the photoreceptor to move. The drum is heated. That is, the air around the lamp heater is first heated by the lamp heater, convection occurs, and the heated air heats the photoreceptor drum. In addition, to some extent, the drum tube may be directly heated by light, but since the light is reflected on the inner surface of the aluminum drum tube, the drum tube is heated by heat conduction using air as a medium, as described above. The proportion of people who do so is much larger.

However, in this method of using air as a heating medium, it takes a long time for heat conduction, so when the outer surface temperature of the photoreceptor drum changes and when the lamp heater is controlled to start or stop operating, There will be a time lag between.

Due to this time lag, when a temperature lower than the set temperature is detected and the lamp heater is activated, the outer surface temperature of the photoreceptor drum will drop too much, and when a temperature higher than the set temperature is detected, the lamp heater will stop operating. In some cases, the outer surface temperature of the photoreceptor drum rises too much, resulting in over-shorting, which causes the problem of image unevenness, especially when the arsenic drum is used as the photoreceptor drum.

Therefore, in order to reduce the above-mentioned time lag and reduce the over-shorting of the outer surface temperature of the photoreceptor drum, an oscillation means for generating clock pulses is provided in the temperature control means, and the clock pulses from this oscillation means and the temperature A device has been proposed in which the power consumption of the heating means is finely and intermittent controlled according to the logical product with the output of the sensor (see Japanese Utility Model Publication No. 62103052).

Problems to be Solved by the Invention However, even if the temperature control means is configured as described above, as long as air is used as the heating medium, a time lag will occur, and a delay in temperature rise, especially at startup, is unavoidable. . Furthermore, a heater device that uses the air inside the photoreceptor drum as a heating medium has a complicated structure because the photoreceptor drum, which is a rotating body, is hermetically sealed so that the air inside the photoreceptor drum does not come into contact with outside air.

Furthermore, if the heater is provided so as to be in contact with the inner surface of the photoreceptor drum, the above-mentioned time lag will be reduced, but if the heater is connected to the power supply to the contact provided on the drum flange to supply power, The structure becomes complicated, such as the need to provide a sliding member such as a brush. Furthermore, when such sliding members are used, electrical noise may generate malfunctions in control devices such as microcomputers, and the sliding members may wear out, requiring periodic replacement. Problems such as .

The present invention has been made in view of these points, and an object of the present invention is to provide a drum heater device that can directly heat a photoreceptor drum using light.

Means for Solving the Problems In order to achieve the above object, the drum heater device of the present invention has the following features:
A drum heater device for warming a photoreceptor drum having a photoreceptor applied to its outer surface, the device comprising: an infrared heater disposed rotatably on the central axis of the photoreceptor drum; and an infrared heater applied to the inner surface of the photoreceptor drum. Controls electric power given to the infrared absorbing paint, a temperature sensor for detecting the outer surface temperature of the photoreceptor drum, and the infrared heater according to a signal from the temperature sensor? ff1l control means.

According to the structure of the present invention, the infrared rays emitted from the infrared heater provided on the central axis of the photoreceptor drum are absorbed by the infrared absorbing paint on the inner surface of the photoreceptor drum, so that the infrared rays are absorbed by the infrared heater. Heat conduction to the body drum is performed efficiently and quickly. Therefore, for example, when the outer surface temperature of the photoreceptor drum changes, the time lag until the correction is completed can be shortened. Furthermore, the temperature of the photoreceptor drum rises quickly at the time of startup.

Embodiments Hereinafter, embodiments of the present invention will be described based on the drawings.

FIG. 1 is a sectional view showing an embodiment of the drum heater device of the present invention. .

The infrared heater (1) is rotatably provided on the central axis of rotation of the photoreceptor drum (4), and is installed on the terminal (12a) located on the front side plate (lla) and on the rear side plate (llb). A solid-state relay (7) for connecting to a power source, which will be described later, is connected to the electrodes at both ends via the terminal (12b).
It is connected to the. The photoreceptor drum (4) is a drum tube (3) whose inner surface is coated with infrared absorbing paint (2).
, drum flanges (9a) (9b) provided as drum holding members at both ends of the drum rough tube (3), and the parts that contact each other on the circumferential surface of the central protrusion of the drum flanges (9a) (9b). Bearings provided (8
a) Consists of (8b). Photosensitive drum (4
) are supported from the outside of the bearings (8a) (8b) via flanges (16a) (16b) installed on the front side plate (lla) and the rear side plate (llb), respectively. Further, the infrared heater (1) has the flanges (16) at its ends (10a) and (10b), respectively.
a) Supported by (16b). A temperature sensor (5) made of a thermistor or the like is provided on the photoreceptor drum (4) as close as possible to the outer surface of the photoreceptor drum (4). Furthermore, outside the photoreceptor drum (4), there is a control circuit (
6), an AC type solid state relay (hereinafter referred to as rssR) that intermittently supplies power from the AC power source (15) to the infrared heater (1) according to signals output from the AC type [(15) and the control circuit (6); ) (7) is provided.

The infrared heater (1) may be any infrared heater that can stably, preferably uniformly radiate infrared rays to the inner surface of the drum tube (3), and its type and shape are not particularly limited. Further, it may be one that emits infrared rays having either a specific narrow range of wavelengths or a wide range of wavelengths, such as far infrared rays, and can be appropriately selected and used.

The infrared absorbing paint (2) is preferably one that absorbs infrared rays emitted from the infrared heater (1) with high efficiency. For example, black-colored materials are advantageous in terms of absorption efficiency. Further, it may be one that absorbs only a specific narrow range of wavelengths or a wide range of wavelengths, and in this regard, it can be selected and used as appropriate. The methods for applying the infrared absorbing paint (2) to the inner surface of the drum tube (3) include brush coating, spray coating, roller coating, vapor deposition, masking other than the inner surface and dipping it in the coating liquid, etc. Any method for applying the paint may be used, and there are no particular limitations on the drying method. The coating film of the infrared absorbing paint (2) is preferably as uniform as possible so that the outer surface temperature of the photoreceptor drum (4) is stabilized. Further, the thickness of the coating film is appropriately adjusted depending on the wall thickness of the drum tube (3), the type of the infrared heater (1), etc.

The drum tube (3) preferably has good thermal conductivity, but may be made of commonly used materials such as aluminum, and is not particularly limited.

The thinner the wall thickness of the drum rough tube (3) is, the shorter the response time of the temperature of the outer surface of the photoreceptor drum (4) to the operating state of the infrared heater (1) is, so it is preferable, but this is also particularly limited. It's not a thing. Further, the outer surface of the photoreceptor drum (4) is usually around 35 to 40°C, preferably 37°C.
However, it is adjusted as appropriate depending on the type of photoreceptor to be deposited on the drum tube (3).

In this embodiment, an arsenic-based drum is used as the photoreceptor drum (4), and this is because the arsenic-based drum can form an electrostatic latent image on the photoreceptor with relatively low exposure energy when exposed to light. If this is only an advantage and the point does not matter, a photoreceptor drum (4) made of a selenium-tellurium alloy may be used.

The means for rotating the photoreceptor drum (4) is not particularly limited to this, but for example, as shown in FIG. 1, a drive gear (13a) rotated by a motor (14a) installed on the rear side plate (llb); A gear (17a) provided on the side peripheral surface of the drum flange (9b) to mesh with the drive gear (13a).

Examples of the temperature sensor (5) include a thermistor, but when the detection part of the temperature sensor (5) comes into contact with the outer surface of the photoreceptor drum (4), damage to the temperature sensor (5) etc. can be kept to a minimum. It is preferable to appropriately provide a shock-absorbing member such as a sponge for protection and a heat-resistant and abrasion-resistant member such as Teflon for preventing wear.

As the control circuit (6), a commonly used microcomputer or the like can be used. Control circuit (6)
may be used to control the temperature of only the drum heater device of this embodiment; The circuit may be shared with that used for controlling other components of the M photocopier. Control circuit (
6) inputs the signal output from the temperature sensor (5), and if the signal is a signal when the outer surface temperature of the photoreceptor drum (4) is higher than a predetermined temperature, the AC power source (1)
5) sends a signal to stop the power supply from SSR(
7), and if the signal is lower than the specified temperature,
The signal that causes the AC aOS+ to supply power is S.
Output to SR (7).

In addition, in this embodiment, the photoreceptor drum (4) is directly heated with infrared rays without using the air inside the photoreceptor drum (4) as a heating medium (although air may serve as a heating medium, the effect is small). The photosensitive drum (4)
There may be some air leakage inside the photoreceptor drum (4).
) should be relatively loosely sealed.

FIG. 2 is a vertical sectional view showing the main parts of another embodiment of the drum heater device of the present invention, and FIG.
It is a cross-sectional view of a line. The embodiment shown in FIG. 2 has the same structure as the embodiment shown in FIG. 1, except for the points described below. That is, in FIG. 2, a bearing (8a) is arranged in a hole provided in the front side plate (lla), and a part of the drum flange (9a) is inserted into the inside of the bearing, so that the photoreceptor drum (4) is moved into the bearing (8a). ) to the front side 4N (
lla). Although not shown, the rear side plate (llb) has a similar structure. Also the first
Instead of the gear (17a) being provided on the side circumferential surface of the drum flange (9b) in the embodiment shown in the figure, in the embodiment shown in FIG. is provided, and the gear (17b) is connected to the driving gear (13b) and the driving gear (13b).
A motor (14b) for rotating the is provided. A heater terminal (18) inserted through the end (10a) of the infrared heater (1) and coupled to an electrode within the infrared heater (1).
is the protective rib (19) installed on the front side plate (Ila)
It is fixedly supported by screws (19") and connected to the connector (20").
)It is connected to the.

Further, the infrared heater (1) is supported by heater terminals (18). The connector (20) is connected to the connector (2o) on the SSR (7) side shown in Figure 1, and power supply is controlled in the same way as in Figure 1. .

According to the present invention, the infrared rays emitted from the infrared heater are absorbed by the infrared absorbing paint provided on the inner surface of the photoreceptor drum, thereby directly heating the photoreceptor drum. As a result, the temperature rises quickly at startup, and when the outer surface temperature of the photoreceptor drum changes, it is possible to shorten the time lag until the change is compensated. For a photoreceptor drum having a photoreceptor whose sensitivity to light fluctuates, the outer surface temperature of the photoreceptor drum is maintained stably, thereby preventing image unevenness from occurring.

Furthermore, in addition to the above effects, the present invention does not require complicated control, a complicated structure for sealing the photoreceptor drum, a complicated structure for supplying electric power, etc., and therefore can be constructed at low cost. It is possible.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing an embodiment of the drum heater device of the present invention. FIG. 2 is a sectional view showing the main parts of another embodiment of the drum heater device of the present invention, and FIG.
-A sectional view. (1) - an infrared heater; (2) - an infrared absorbing paint. (3)...Drum tube, (4)--Photosensitive drum. (5) -Temperature sensor, (6) -Control circuit (7)
-3S R, (8a) (8b) -- Hair ring (9a
) (9b)-m-drum flange, (10a) (
10b) - One end. (lla) - one anterior lateral plate, (llb) - posterior lateral plate. (12a) (12b) -m one terminal, (13a) (
13b) - Drive gear. (14a) (14b)-11 Motor, (15)-AC power supply (16a) (16b)--Flange, (17
a) (17b) - Gear (18) - - Heater terminal,
(19) - Protective ribs. (19') - screw, (20) - connector.

Claims (1)

[Claims] (1) A drum heater device for warming a photoreceptor drum having a photoreceptor on its outer surface, which includes an infrared heater disposed rotatably on the central axis of the photoreceptor drum, and an infrared heater placed on the inner surface of the photoreceptor drum. A drum heater device comprising: an infrared absorbing paint coated with an infrared absorbing paint, a temperature sensor that detects the outer surface temperature of the photoreceptor drum, and a control means that controls electric power given to the infrared heater according to a signal from the temperature sensor.