JPH06105375B2 - Process head for electrophotographic device - Google Patents

Description

TECHNICAL FIELD The present invention relates to a process head used in an electrophotographic apparatus for performing various kinds of processing on an electrophotographic film.

[Conventional technology]

2. Description of the Related Art There is known an electrophotographic apparatus capable of recording an image on a predetermined frame of an electrophotographic film and projecting or copying the recorded image.

Further, a process head provided in an electrophotographic apparatus for subjecting an electrophotographic film to charging / exposure and development is known from JP-A-59-100479 and JP-A-59-162580.

The process head disclosed in the above publication includes a charging / exposure section, a developing section, a drying section and a fixing section. These parts are arranged adjacent to each other in the above-mentioned order along the feeding direction of the electrophotographic film, and the arrangement pitch of each part is a constant pitch equal to the frame pitch of the electrophotographic film.

In the charging / exposure section, the electrophotographic film (corresponding to one frame) located in this part is exposed by being exposed to the image light of the original after being charged. As a result, an electrostatic latent image corresponding to the image pattern of the original is formed on the electrophotographic film. In the developing section, a liquid developer is applied to the electrophotographic film exposed in the charging / exposure section to visualize the electrostatic latent image. In the drying section, dry air is blown to the electrophotographic film moistened with the liquid developer to remove moisture. In the fixing section, the image is fixed on the electrophotographic film by a fixing lamp or the like.

In this drying section, warm air heated by a heater is applied to the electrophotographic film to shorten the drying time of the electrophotographic film. The warm air flows in one direction, and the warm air applied to the electrophotographic film is discharged.

However, since the air warmed as warm air maintains its temperature for the time being, the ambient temperature (environmental temperature) is raised. That is, the environmental temperature is always fluid, and it is desired to control the temperature of the warm air that is not affected by the return temperature.

Here, it is possible to circulate the warm air, but the structure becomes complicated and the cost is increased.

[Problems to be solved by the invention]

In consideration of the above-described embodiment, the present invention needs to change the set temperature even when the environmental temperature changes, while reaching the drying section and reusing the warm air applied to the electrophotographic film to improve the drying efficiency. It is an object to obtain a process head for an electrophotographic apparatus, which can perform a temperature control without a temperature.

[Means for solving problems]

The present invention is a process head for an electrophotographic apparatus for developing by supplying a developer to an electrophotographic film in a developing section, comprising a wall surface facing a back surface of the electrophotographic film which has been developed in the developing section. In a drying section for drying the electrophotographic film by passing warm air heated by a heating means through a gap between a wall surface and the electrophotographic film, the electrophotographic film is arranged from one side of the electrophotographic film disposed in the drying section. Guide means for inverting the warm air that has flowed into the gap and flowing out from the opposite side of the one side, and is provided in the vicinity of the guide means for guiding to the surface of the photographic film,
A temperature sensor that detects the temperature of the warm air flowing out from the gap; and a control unit that controls the heating unit so that the detected temperature from the temperature sensor becomes the set reference temperature regardless of the environmental temperature. It is characterized by having.

[Action]

According to the present invention, when the electrophotographic film is arranged in the drying section, a gap is formed between the back side of the electrophotographic film and the wall surface of the drying section. For example, the electrophotographic film is dried by injecting warm air into the gap from the upper side of the electrophotographic film and letting it flow out from the lower side.

Here, the warm air that has flowed out from the lower side is inverted (U-turned) by the guiding means, and is again guided in the electrophotographic film direction. The inverted hot air moves to the surface of the electrophotographic film, so that the drying efficiency can be improved.

Further, a temperature sensor is provided in the vicinity of the guide means, that is, on the downstream side of the drying position of the electrophotographic film, and the temperature detected by the temperature sensor is compared with a preset temperature to control the temperature of the hot air. is doing. Since the difference between the temperature on the downstream side and the temperature at the actual drying position is smaller than the difference between the temperature on the upstream side and the temperature at the actual drying position, for example, even if the environmental temperature changes, The temperature does not change significantly and can be kept within the allowable temperature range.

〔Example〕

(Electrophotographic Device) FIG. 1 shows an embodiment of an electrophotographic device for a microfilm in which the process head according to this embodiment is arranged.

In the electrophotographic apparatus according to the present embodiment, a camera function of photographing a document and recording the image on the electrophotographic film, a reader function of enlarging and projecting a micro image recorded on the electrophotographic film onto a screen, and an electronic image It has a copy function of enlarging and copying an image recorded on a photo film onto a copy sheet.

The electrophotographic apparatus includes an electrophotographic apparatus main body 10 and a housing 11.
Copying device 12 that doubles as a stand for electrophotographic device body 10
And are integrated. When the copy function is not required, it is possible to use the electrophotographic apparatus main body 10 alone. The housing 14 of the electrophotographic apparatus main body 10 is composed of a portion 14A located on the left side and having a substantially rectangular parallelepiped shape, and a portion 14B located on the right side and having a stepped upper surface. The internal space communicates with the rear part.

On the outer side of the housing 14A, a transmissive screen 16 is provided which covers the front opening of the housing and is slightly tilted backward, and a document table 18 is provided on the upper part. On the document table 18, a transparent glass plate 22 (see FIG. 2 to be described later) is disposed below the document pressing plate 20 that can be opened and closed so as to close the upper opening of the housing. On the outer side of the housing 14B, a cassette loading section 26 for loading a cassette containing an electrophotographic film 24 (see FIG. 2 to be described later) is formed near the center of the upper portion, and an electrophotographic apparatus is provided on the upper front portion. A control keyboard 28 for performing various operations is provided.

Further, the housing 11 of the copying apparatus 12 is formed with an opening 32 through which the copied copy paper 30 (see FIG. 4 described later) is discharged.

(Optical System of Electrophotographic Apparatus) FIGS. 2 to 4 show an optical system of the electrophotographic apparatus.

As shown in FIG. 2, the photographing optical system includes the document table 18
The original illumination lamp 36 that illuminates the original 34 that is the subject set with the original surface facing down on the glass plate 22 of
A third mirror 38 on which the reflected light from 34 enters, a second mirror 40 on which the reflected light from third mirror 38 enters, and a first mirror 42 on which the reflected light from second mirror 40 enters , First
The main lens 44 connects the reflected light from the mirror 42 onto the surface of the electrophotographic film 24.

As shown in FIG. 3, the projection optical system includes a projection light source unit 46 for irradiating the electrophotographic film 24 and an electrophotographic film 24.
The main lens 44 that connects the light transmitted through the first mirror 42 to the first mirror 42;
The second mirror 40 on which the reflected light from the mirror 42 is incident, and the screen 16 on which the reflected light from the second mirror 40 is projected
It has and.

As shown in FIG. 4, the copying optical system includes a projection light source unit 46, a main lens 44, a first mirror 42, and a second mirror 40 which are the same as those described above.
In addition, the conversion lens 48 disposed between the main lens 44 and the first mirror 42 for slightly reducing the optical image formed on the first mirror 42, and the reflected light from the second mirror 40 The copying machine 12 is provided with a copy mirror 52 for reflecting it toward the copy paper 30 set on the exposure table 50 provided in the copying machine 12.

The main lens 44, the first mirror 42 and the second mirror 40 are commonly used in the above three optical systems. Main lens 44 and first mirror
42 is fixedly arranged in the housing 14B of the electrophotographic apparatus main body 10, and the second mirror 40 is fixedly arranged in the housing 14A.

Third mirror 38, copy mirror 52, convergence lens
48 and screen 16 are optionally used. The third mirror 38 and the copy mirror 52 are movably arranged in the housing 14A of the electrophotographic apparatus main body 10, and the conversion lens 48 is movably arranged in the housing 14B so as not to interfere with other optical systems. Has been Since the screen 16 does not interfere with other optical systems, it is fixedly arranged as described above.

Further, in the optical system of the electrophotographic apparatus, a shutter controlled by the automatic exposure control device is arranged between the main lens 44 and the first mirror 42.

(Process Head) FIGS. 5 to 13 show an embodiment of the process head according to the present invention arranged in the electrophotographic apparatus.

As shown in FIGS. 5 and 6, the process head 54
Is composed of a relatively flat main body 56 in the shape of a substantially rectangular parallelepiped and a pair of legs 58 located at the bottom of the main body 56, which are integrally molded of synthetic resin except for attachments. ing. The process head 54 is disposed between the main lens 44 shown in FIGS. 2 to 4 and the electrophotographic film 24, and as shown in FIG. The frame 6 arranged in the housing 14B of the device body 10
It is attached to 0.

As shown in FIGS. 5 and 7, the main lens 44 is assembled to the lens barrel 62 and attached to the back surface of the process head 54. The electrophotographic film 24 is composed of a transparent conductive layer, an intermediate layer and a photosensitive layer which are sequentially laminated on a support such as polyethylene, and the photosensitive layer is composed of a photoconductive layer and a protective layer for protecting the photoconductive layer. It is configured. Further, the electrophotographic film 24 is formed into a long tape shape and accommodated in the cassette case.

In the electrophotographic film 24, as shown in FIG. 6, the blip marks 24A are provided at the upper end at regular intervals along the longitudinal direction.
Is printed. The blip mark 24A is provided corresponding to one frame of an image recorded on the electrophotographic film 24. In this electrophotographic film 24, the surface of the photosensitive layer faces the front surface of the process head 54, and a film moving motor (not shown) is driven, whereby the width direction of the process head 54 (the horizontal direction in the drawing of FIG. 6). It is possible to move to). The transparent conductive layer of the electrophotographic film 24 can be electrically connected to the electrophotographic apparatus main body 10 when the cassette is loaded in the electrophotographic apparatus main body 10. It is needless to say that the electrophotographic film is not limited to the above-mentioned embodiment and a known one can be used.

As shown in FIGS. 5 to 7, the main body portion 56 of the process head 54 is provided with a charging / exposure portion 64, a developing portion 66, a drying portion 68 and a fixing portion 70 sequentially in the width direction of the electrophotographic film 24. It is formed by a constant pitch corresponding to the interval of one frame.

(Charging / Exposure Section) In the charging / exposure section 64, as shown in FIGS. 7 and 8, a charging / exposure chamber 72 is formed in the internal space on the back side of the front wall 74 of the process head 54. There is. The charging / exposure chamber 72 is opened in the front wall 74 of the process head 54, and a mask 76 slightly protruding from the front wall 74 is formed around this opening as shown in FIG. There is. This mask
The opening shape of 76 is a rectangular shape having a size corresponding to one frame of the electrophotographic film 24. The charging / exposure chamber 72 is provided with a corona unit 78, a proximity electrode 80 and a mask electrode 82.

As shown in FIG. 5, the corona unit 78 comprises a corona wire 84 and a synthetic resin holder 86 for holding the corona wire 84, and is inserted and arranged from the upper part of the process head 54. The proximity electrodes 80 are made of a narrow metal plate and are arranged on both sides of the corona wire 84. The mask electrode 82 is formed by bending a metal plate into a square shape and has a front wall.
It is arranged near the opening of 74. The corona wire 84 is connected to a high voltage power source, and the proximity electrode 80 and the mask electrode 82 are electrically connected. Normally, the proximity electrode 80 is directly connected to the ground and the mask electrode 82 is connected to the ground via an electric resistance, but different bias voltages may be applied from an external power source.

As shown in FIG. 7, the charging / exposure chamber 72 is provided with a film cooling air blowing port 88, and cold air is supplied from an air pump 89 through a pipe line 87. As described above, the main lens 44 assembled to the lens barrel 62 and attached to the back surface of the process head 54 has an optical axis of the mask 76.
It coincides with the center of the opening.

The charging / exposure unit 64 has a guide projection 77 protruding above the mask 76 in the lateral direction. This guide protrusion 77 is made to have the same height as the mask 76, and the electrophotographic film is
When the 24 is loaded into the cassette loading section 26 together with the cassette, the front wall 74 of the process head main body section 56 does not catch on the mask 76. Therefore, this guide protrusion 77
The upper and lower sides of the are slopes that gradually decrease in height.

(Developing Section) A mask 90 is formed in the developing section 66 as shown in FIGS. 5 and 6, and the mask 90 includes an upper frame 90A, left and right frames 90B, 90C, and a lower frame 90D. It stands up from the front wall 74. The protrusion height of the mask 90 is set to the same level as the mask 76 of the charging / exposure unit 64.

An outer frame 91 projects from the front wall 74 on the outer side of the mask 90, and a recess 92 is formed between the outer frame 91 and the mask 90. The protruding height of the outer frame 91 is the same as that of the mask 90, and the recess 92 surrounds the outside of the mask 90. The outer frame 91 is also the upper frame 91 like the mask 90.
A, left and right frames 91B and 91C, and a lower frame 91D, and a central portion of the upper frame 91A is a guide protrusion that extends horizontally from above the charging / exposure unit 64.
A narrow guide protrusion 93 is connected to the portion 77. Recess 92
The width dimension of is between the upper frame 90A and 91A, and the lower frame 90D and 91D
Between the left frames 90B and 91B and between the right frames 90C and 91C are wide.

The guide protrusion 93 also has the same role as the guide protrusion 77 of the charging / exposure unit 64. The width of the lower frame 91D of the outer frame 91 is larger than that of the upper frame 91A and the left and right frames 91B and 91C. Also, the guide protrusion 77 and the outer frame on the upper part of the developing unit 66
A groove 91E is formed between the upper frame 91A and the upper frame 91A, and the groove 91E is gradually deepened toward the upper frame 91A, and the deepest part thereof is deeper than the front wall 74.

The opening width of the mask 90 is made slightly smaller than the opening width of the mask 76. Further, the opening height of the mask 90, that is, the distance between the inner walls of the upper frame 90A and the lower frame 90D, the inner wall of the lower frame 90D is located lower than that of the mask 76,
It has been lengthened accordingly.

Inside the opening of the mask 90, as shown in FIG.
A developing electrode 96 is provided supported by 94. Development electrode
96 is connected to the bias power supply. The surface of the developing electrode 96 is located slightly inward from the end face of the mask 90, and the space surrounded by the developing electrode 96 and the inner wall of the mask 90 is a developing chamber 98. The upper and lower parts of the developing electrode 96 are opened,
They are a developer / squeeze air inlet 100 and a developer / squeeze air outlet 102, respectively.

The surface of the wall surface of the developing chamber mask 90 is smoothed so that the drainage efficiency is improved.

Air inlet 100 for developer / squeeze is process head 54
Is communicated with the passage 104 constituted by the internal space of the. The passage 104 is a developer opening on the back surface of the process head 54.
It communicates with the air outlet 112 for squeeze.

A part of the concave portion 92 located around the mask 90 serves as a seal pressure supply port 114 as shown in FIG.

As shown in FIG. 10, the seal pressure supply port 114 communicates with a passage 116 formed by the internal space of the process head 54. The passage 116 is adapted to supply sealing air to a sealing pressure supply opening 118 opened on the back surface of the process head 54.

As shown in FIG. 11, the developer supply port 106 is connected to a developer tank 126 via conduits 122 and 124 via a solenoid valve 120 in the middle. The developer tank 126 is located above the solenoid valve 120. The developer tank 126 is connected to a developer pumping pump 130 driven by a motor 128 by a pipe line 132. The developer pump 130 is arranged in the developer bottle 134. The developer bottle 134 contains a developer 136 in which toner particles are dispersed in a solvent.

The conduit 124 connecting the solenoid valve 120 and the developer tank 126.
In the middle of the process, a branch is formed, which serves as a return conduit 138 that opens to the developer bottle 134. Also, the developer tank 126
A return pipe line 140 that opens to the developer bottle 134 is connected to.

The squeeze air supply port 108 is connected to an air pump 144 through a pipe 142 to supply squeeze air.

The developer / squeeze air outlet 112 is connected to a return conduit 146 that opens into a gas / liquid separation box 135 of the developer bottle 134.

A conical dish plate 150 is mounted on the upper portion of the developer bottle 134, the lower end of the dish plate 150 slightly enters the developer bottle 134, and the lower surface of the dish plate 150 adheres to the upper end of the developer bottle 134 for development. The agent bottle 134 is blocked.

When the developer pumping pump 130 penetrating the central opening of the plate 150 is lifted by lifting the motor 128, the plate 150 is locked by the lower end of the developer pumping pump 130 and moves up, and the lower end of the plate 150 is stopped. Comes out of the developer bottle 134, and the developer bottle 134
It is a configuration that allows the replacement of.

The dish plate 150 has a cylindrical portion 154 that hangs down from the support plate 152 during this ascent.
It is designed to slide inside and rise, and the plate 150
11, the tapered elastic film 156 attached to the cylindrical portion 154 and the lower end protruding portion 158 come into contact with each other to seal the inside of the developer bottle 134 with the outside air.

The support plate 152 has a tubular body 160 through which the return conduit 140 communicates.
Is fixed and the gas-liquid separation box 1 adjacent to the cylinder 160
A communication hole 135A for communicating with the outside air is formed in the upper end side wall of 35, and a discharge pipe 135B protruding from the lower end penetrates the support plate 152 to return only the developing solution to the developer bottle 134.

The process head 54 is shown in a tilted state in FIG. 11 because the optical axis of the optical system is tilted with respect to the horizontal plane so as to be perpendicular to the screen 16 in which the optical head is tilted. .

(Drying Part) As shown in FIGS. 5 and 6, a frame wall 164 is formed in the drying part 68. The frame wall 164 is an upper frame of the developing unit 66.
An upper frame 164A that is a horizontal extension of 91A and this upper frame 164A
The right frame 164 that hangs from the end of the
The upper frame 164A and the right frame 164C have the same height as the outer frame 91 and the mask 90 of the developing section 66.
A lower frame 164D lower than these projects between the lower part of the right frame 90C and the lower part of the right frame 164C of the developing unit 66.

A portion surrounded by the upper frame 164A, the right frame 164C, the lower frame 164D of the drying unit 68 and the right frame 91C of the developing unit 66 is a drying unit 174, and its bottom wall 170 is below the drying unit 68 and the fixing unit 70. The height is the same as that of the front wall 168 depressed from the front wall 74.

The size of the frame wall 164 is larger than that of the development mask 90.

A guide protrusion 77 extending above the developing unit 66 is arranged above the upper frame 164A. The guide protrusion 77 has the same function as the guide protrusion 77 of the charging / exposure unit 64 and the guide protrusion 93 of the developing unit 66.

The width of the inside of the frame wall 164, that is, the space between the right frame 164C and the right frame body portion 91C of the developing unit 66 is made wider than the opening width of the mask 90. The lower surface of the upper frame 164A (the inner surface of the frame) is the developing unit.
It is located above that of the mask 90 of 66.

As shown in FIGS. 6 and 12, the lower portion of the upper frame 164A is opened to form a hot air outlet 176. Hot air outlet 1
As shown in FIG. 12, 76 communicates with a passage 178 formed by the internal space of the process head 54. Passage 178
Is a hot air supply port 180 on the back of the process head 54
It is in communication with. The hot air supply port 180 has a conduit 177 and a heater 17
The hot air is supplied by being connected to the air pump 181 via 9. Power supply to the heater 179 is controlled based on the value measured by the temperature sensor 182.

After passing through the hot air outlet 176, the warm air reaches the front surface (left side surface in FIG. 12) of the wall 170 and hits the electrophotographic film 24 facing the wall 170 at predetermined intervals. The electrophotographic film 24 is dried. The dry air applied to the electrophotographic film 24 is sent to the bottom of the wall 170.

Here, as shown in FIG. 12, on the lower frame 164D of the wall 170, a wind deflector 183 serving as guide means is disposed, and the warm air is downstream of the electrophotographic film 24, that is, the electrophotographic film 24. The hot air after being dried is turned over again in the direction of the electrophotographic film 24.

A temperature sensor 182 is disposed below the wall 170, and is located downstream of the electrophotographic film 24, that is, the electrophotographic film 24.
The temperature of the warm air that has been dried is measured. This temperature sensor 182 is connected to the heater 179.
The power supply is controlled based on the value measured in.

(Fixing Unit) As shown in FIGS. 5 to 7, the fixing unit 70 is formed between the right frame 164C of the frame wall 164 and the front wall 74 located at the right end. The fixing portion 70 has a front wall recess 168.
A frame portion 184 including a lower frame and left and right frames is formed at a position further depressed. A transparent glass plate 186 is fitted in the frame portion 184, and a space in front of the glass plate 186 serves as a fixing chamber 188.

As shown in FIG. 13, a xenon lamp 192 and a reflector 194 are arranged in the space 190 of the process head 54 formed on the back side of the glass plate 186. Space part 190
A cooling blower port 196 is opened in the air passage, and cold air is supplied from an air pump 195 through a pipe line 193. The space 190 and the fixing unit 188 communicate with each other at the upper part of the glass plate 186.

(Blip sensor) As shown in FIGS. 5 and 6, the process head 54
At the left side of the front wall 74, a blip sensor 196 is provided. The blip sensor 196 is located at a height at which the blip mark 24A of the electrophotographic film 24 moved along the front surface of the process head 54 passes, and when the blip mark 24A passes, the electrophotographic film 24 is sandwiched therebetween. It is designed to detect that the light from the sensor light source is blocked.

(Film pressing mechanism) As shown in FIGS. 7 and 14, the process head 54
A holding plate 198 is disposed in front of the front wall 74 of the. As shown in FIG. 15, the holding plate 198 is provided with a rectangular through hole 200 having a size slightly smaller than the opening shape of the mask 76 formed in the charging / exposure section 64. Presser plate 198
Are arranged so that the through holes 200 correspond to the mask 76.

As shown in FIG. 15A (a perspective view of the holding plate viewed from the opposite side of FIG. 15), the holding plate 198 has process heads at the upper and lower ends on the side where the through holes 200 are formed. Claws 202 and 204 protruding toward the 54 side are formed. Claws 202, 2
In 04, the inner surfaces facing each other are inclined surfaces 202A and 204A, and as shown in FIG. 14, the distance between the upper and lower claws 202 and 204 at the root is equal to the width of the electrophotographic film 24 ( Strictly wider than the width of the electrophotographic film 24)
Has been done. A column portion 206 is formed so as to project from the tip of the claw 204. The pawls 202, 204 are holes 20 formed in the front wall 74 of the process head 54 shown in FIGS. 5, 6 and 14.
It can be fitted into 8, 210.

A columnar portion 212 is formed on the back surface of the holding plate 198 facing the process head 54, and a notch portion 214A formed at one end of the arm 214 is engaged with the columnar portion 212. A retaining ring 212A is fixed to the tip of the columnar portion 212 to prevent the cutout portion 214A from coming out. arm
A boss portion 214B is formed at the other end of 214. Boss part 2
A shaft 216 is fixed to 14B.

The shaft 216 is rotatably inserted into and supported by a stand 218 provided upright on the frame 60 to which the process head 54 is attached, and the lower end of the shaft 216 projects from the back surface of the frame 60. A first lever 220 is fixed to the lower end of the shaft 216. A pin 222 is fixed to the tip of the first lever 220.

On the other hand, a shaft 224 is vertically provided on the back surface of the frame 60.
An intermediate portion of the second lever 226 is rotatably supported on the shaft 224. Notch 226 formed at one end of the second lever 226
The pin 222 is engaged with A. Second lever 226
One end of each of extension coil springs 228 and 230 for elastically supporting the second lever 226 by biasing the second lever 226 in opposite directions is locked in the elongated hole 226B formed at the other end of the Has been done.

The other end of the tension coil spring 228 is locked to a pin 232 that is vertically provided on the back surface of the frame 60, and the other end of the tension coil spring 230 is a pull-type solenoid 234 attached to the back surface of the frame 60. It is locked to the plunger 234A.

The holding plate 198 is separated from the process head 54 when the solenoid 234 is not excited. In this state, as shown in FIG. 14, the holding plate 198 has the column portion 206 fitted and supported in the hole portion 210 formed in the process head 54.

When the solenoid 234 is excited, the plunger 234A is actuated in the direction of arrow A, and the extension coil springs 228 and 230 are extended against the biasing force. This causes the second lever 226 to move the shaft 224.
Since it is rotated in the direction of arrow B about
220 is rotated in the direction of arrow C via pin 222, and rotates shaft 216 in the same direction. By the rotation of the shaft 216, the arm 214 is rotated in the arrow D direction and presses the holding plate 198 in the arrow E direction.

The column portion 206 of the holding plate 198 is guided in the hole portion 210 and moved in the direction of the arrow E to press the electrophotographic film 24 against the end faces of the masks 76 and 90 and the frame wall 164. When the position of the electrophotographic film 24 is displaced in the height direction when the holding plate 198 is moved, the inclined surfaces 202A and 204A of the claws 202 and 204 push down the upper edge of the electrophotographic film 24, Or it works to push up the lower edge.

When the electrophotographic film 24 is pressed and brought into contact with the process head 54, the holding plate 198 has the pawls 202 and 204 with holes 208 and 2.
It is fitted in 10 and is precisely positioned in the process head 54. Further, the holding plate 198 elastically presses the electrophotographic film 24 by the action of the tension coil springs 228 and 230 in this state.

When the solenoid 234 is demagnetized, it is urged by the tension coil spring 228 to rotate the second lever 226 in the direction opposite to the arrow B,
The arm 214 is rotated in the opposite arrow D direction, and the notch portion 214A presses the retaining ring 212A to move the holding plate 198 in the opposite arrow E direction.

(Operation of Embodiment) Next, the operation of this embodiment will be described.

In the electrophotographic apparatus, when the power switch is turned on, the cassette loading section 26 shown in FIG. 1 is raised, and the cassette containing the electrophotographic film 24 can be loaded. After the cassette loading section 26 is loaded with the cassette, when the cassette loading section 26 is manually pushed down to its original position, the cassette loading section 26 is restrained at that position. In this state, the electrophotographic film 24 is positioned as shown in FIG. 14, and can be moved along the front surface of the process head 54 by driving a film moving motor (not shown).

When the image of the original 34 shown in FIG. 2 is recorded on the electrophotographic film 24, a film moving motor (not shown) is moved, and a predetermined one frame freely selected from the frames not yet recorded. Are located in front of the mask 76 of the charging / exposure unit 64. This operation is performed by designating one predetermined frame with the control keyboard 28 shown in FIG. 1, and the stop position of the electrophotographic film 24 is determined by the number of passages of the blip mark 24A from the base point by the blip sensor 196. Controlled.

FIG. 16 shows a time chart in the case where after taking a picture by aligning a predetermined frame as described above, the continuous shooting is continuously performed corresponding to each frame continuous to this frame. ing. In the process head 54, when the frame located in the charging / exposure unit 64 is being charged / exposed, different processes are simultaneously performed on the frames located in the developing unit 66, the drying unit 68, and the fixing unit 70, respectively. However, in the following,
The explanation is given by focusing on one frame in which the photographing is started by pressing the photographing button at the position (I) in FIG.

The original 34 can be photographed by operating the button on the control keyboard 28 to select the camera mode. Simultaneously with this operation, the developing electrode 96 of the developing unit 66 is energized and a bias voltage is applied to the drying chamber 174. The heater 179 for heating the air blown to is energized to generate heat, and the capacitor of the xenon lamp 192 of the fixing unit 70 is energized to be charged.
These are connected while the camera mode is selected.

When the shooting button on the control keyboard 28 is pressed,
The corona wire 84 of the charging / exposure unit 64 is energized and a high voltage is applied to generate corona discharge between the proximity electrode 80 and the mask electrode 82. As a result, the surface of the photosensitive layer of the electrophotographic film 24 located in the opening frame of the mask 76 is electrically charged.

At the time when the photographing button is pressed, the solenoid 234 of the film pressing mechanism is continuously excited from the previous process, the electrophotographic film 24 is pressed by the pressing plate 198, and the masks 76, 90 of the process head 54 and The end faces of the frame wall 164 are pressed and contacted. The holding plate 198 has a through hole 200 formed in a portion corresponding to the mask 76.
Since the opening is smaller than the opening of 76, the electrophotographic film 24 located on the end surface of the mask 76 is pressed by the holding plate surface around the through hole 200. Therefore, the electrophotographic film 24
Is reliably brought into close contact with the end surface of the mask 76, so that the charging range is accurately regulated within the opening range of the mask 76.

Further, the mask electrode 82 provided in the charging / exposure chamber 72 is
By holding the charge potential of the electrophotographic film 24 at substantially the same potential as that of the charge, the peripheral edge of one frame of the electrophotographic film 24 located at the opening of the mask 76 is also charged to a value close to the potential of the center of the frame. The entire frame of the photo film 24 is uniformly charged. A bias voltage from an external power supply (not shown) may be applied to the mask electrode 82 by appropriately selecting the value of a resistor (not shown) interposed between the ground and the mask electrode 82 and electrically connected. Is applied, the mask electrode 82 can be maintained at a potential substantially equal to the charging potential of the electrophotographic film 24.

After the photographing button is pressed at the position (I), the original illumination lamp 36 is turned on after a predetermined time has passed, and the glass plate 22 of the original table 18 is turned on.
The original document 34 placed on it is illuminated. Further, after the button has been pressed, the power supply to the corona wire 84 is stopped after a lapse of a predetermined time, and the corona discharge ends.

At the same time when the power supply to the corona wire 84 was stopped, a shutter (not shown) (indicated by symbol A in FIG. 16) was opened and placed on the document table 18 by the optical system shown in FIG. The image light of the original 34 is applied to the electrophotographic film 24. At the same time, an automatic exposure control device (not shown) (indicated by symbol B in FIG. 16) starts integrating the light amount.

On the other hand, after the button is pressed, the eleventh
The motor 128 shown in FIG. 3A is driven to start the operation of the developer pumping pump 130, and the developer 136 in the developer bottle 134 is pumped up to the developer tank 126. Developer 136
Goes down from the developer tank 126 by its own weight and goes to the process head 54 through the line 124, but at this time, since the solenoid valve 120 is still closed, it is returned from the return line 138 to the developer bottle 134. . Further, when the liquid level of the developer 136 rises in the developer tank 126, the developer 136 is returned from the return pipe line 140 to the developer bottle 134.

In this way, the developer 136 circulates between the developer bottle 134 and the developer tank 126 until the solenoid valve 120 is opened, and is in a standby state at the position immediately before the valve of the solenoid valve 120. Due to this circulation, the developer 36 in the developer bottle 134 is agitated.

When the integrated value of the light amount of the automatic exposure control device (B) reaches the set value, the adjustment is stopped, the shutter (A) is closed at the same time, and the document illumination lamp 36 is turned off. At this point, the exposure process is completed, and one frame of the electrophotographic film 24 located in the opening of the mask 76 is electrostatically charged by the charge on the photosensitive layer being reduced according to the image pattern of the original 34. A latent image is formed. Since the variation of the image density due to the variation of the background density of the original 34 and the variation of the voltage applied to the original illumination lamp 36 is corrected by the automatic exposure control device (B), proper exposure is always performed. At this time, a predetermined time has elapsed since the button was pressed, and when the processing steps for the other frames are all completed, the solenoid 234 of the film pressing mechanism is immediately demagnetized. When the solenoid 234 is demagnetized at the position (IA) in FIG. 16, the holding plate 198 is separated from the electrophotographic film 24.

After the solenoid 234 of the film pressing mechanism has been demagnetized, a film moving motor (not shown)
(Indicated by symbol C in the figure) is driven, and the electrophotographic film is driven.
24 is moved one frame to the right in FIG. As a result, the frame located in the charging / exposure unit 64 is moved to the developing unit 66. The movement of one frame of the electrophotographic film 24 is controlled by the blip sensor 196 detecting the blip mark 24A, as in the case described above.

After the film moving motor (C) is stopped, a predetermined time has elapsed, the solenoid 234 of the film pressing mechanism is excited at the position (IB) in FIG. 16, and the electrophotographic film 24 is pressed by the pressing plate 1.
It is pressed against the process head 54 at 98. At the same time, the seal pressure is supplied to the recess 92 and the solenoid valve 120 is opened.

When the solenoid valve 120 is opened, the developer 136 reaches the process head 54 through the conduit 122, and flows into the developing chamber 98 from the developer / squeeze air inlet 100 of the developing section 66. The toner particles dispersed in the developer 136 are charged with and are attached to the charged portion of the electrophotographic film 24 in the process of flowing down the developing chamber 98 to visualize the electrostatic latent image. . Development room
The developer 136 that has flowed down 98 flows from the developer / squeeze air outlet 102 to the developer bottle 13 through the return pipe 146.
Returned to 4.

The developer supplied from the developer tank 126 to the pipeline 124
The pipe diameter and the like of each pipe 136 are set so that a part of the pipe 136 is returned to the developer bottle 134 from the return pipe 138 and the other is directed to the solenoid valve 120.

Since the electrophotographic film 24 is pressed and abutted against the end surface of the mask 90 by the pressing plate 198, the developer 136 flowing down through the developing chamber 98 may penetrate into the gap between the end surface of the mask 90 and the electrophotographic film 24. Almost never. In particular, since the seal pressure is supplied to the concave portion 92, the developer that has tried to enter is pushed back into the developing chamber 98 by the seal pressure. For this reason, the developer does not stain the other frame portions and does not stick out from the upper and lower portions of the electrophotographic film 24. The recesses 92 may be provided only on both sides of the developing chamber 98, that is, between the developing chamber 98 and the adjacent frame as long as the other frames are not contaminated.

The developer pump 130 is a solenoid 2 of the film pressing mechanism.
The motor 128 is stopped and the operation is stopped after a lapse of a predetermined time after the excitation of 34, but the solenoid valve 120 is still open. Since the developer 136 is supplied from the developer tank 126 to the process head 54 by gravity, the supply of the developer 136 to the developing chamber 98 is continued even if the operation of the developer pumping pump 130 is stopped. .
In this way, since the supply of the developer 136 is continued even after the developer pumping pump 130 is stopped, it is possible to minimize the exposure blur due to the vibration of the developer pumping pump 130 during the exposure of the next frame. . In order to prevent unevenness of the image due to the developer moving in the developing chamber, the electromagnetic valve may be closed to provide a time period during which static development is performed.

When the solenoid valve 120 is opened and the specified time has elapsed, the solenoid valve 120
Is closed and the supply of the developer 136 to the developing chamber 98 is stopped. At the same time, the air pump 144 for pressure squeeze is operated, pressurized air is supplied from the developer / squeeze air inlet 100 to the developing chamber 98, and the developer 136 excessively attached to the electrophotographic film 24 is blown. It is dropped and drained. The developer 136 blown off is returned from the developer / squeeze air outlet 102 through the return pipe 146 to the developer bottle 134.

The supply of the pressurized air to the developing chamber 98, that is, the blowing of air, is made strong after a lapse of a predetermined time from the start of blowing, thereby improving the squeeze efficiency.

The blowing is controlled by the charging / exposure process of the next frame started by pressing the shooting button at the position (II) in FIG.
Solenoid 234 of film holding mechanism at position (II A) in the figure
Is demagnetized, the film moving motor (C) starts to be driven after a predetermined time has elapsed, and at the same time, the film moving motor (C) is stopped.
The squeeze process ends.

The presence of the developing electrode 96 during development makes it possible to obtain an image having no edge effect. Further, since the bias voltage is applied to the developing electrode 96, fogging of the image is prevented. Image reproducibility can be improved by applying a pulsed high voltage having the same polarity as the charging polarity of the toner particles during the development.

When the drive of the film moving motor (C) is stopped, the electrophotographic film 24 is moved one frame to the right in FIG. 6, and the frame located in the developing section 66 is located in the drying section 68. There is. After the film moving motor (C) is stopped, the solenoid 234 of the film pressing mechanism is excited at the position (II B) in FIG. 16 after a predetermined time has passed, and at the same time, pressurized air is heated and supplied through the pipe line 177. To be done. As a result, the warm air heated by the heater 179 is blown out from the warm air outlet 176 of the drying section 68 into the drying chamber 174, and the developer 136 is dried.

Here, in the present invention, the warm air once applied to the electrophotographic film 24 is reversed by the wind-back plate 183 and sent again in the direction of the electrophotographic film 24. As a result, the pressing plate 198 is heated and the drying effect of the electrophotographic film 24 is improved.

Since the temperature of the warm air supplied to the drying chamber 174 is detected by the temperature sensor 182 and is controlled to be constant, the amount of electric power of the heater 179 is increased by the amount corresponding to the improvement in the drying efficiency. Can be reduced. The operation of the air pump 181 is controlled by the charging / exposure process of the frame started by pressing the photographing button at the position (III) in FIG. 16, and the solenoid 234 of the film pressing mechanism at the position (III A) in FIG. Is demagnetized and stopped at the same time, and the drying process ends.

The drying chamber 174 shows the space between the electrophotographic film 24 and the wall 170 formed by the electrophotographic film 24 being pressed against the drying chamber frame 164 by the pressing plate 198, and is supplied to the drying chamber 174. The temperature of the warm air is detected by the temperature sensor 182, and the temperature is controlled to be constant.

In order for the temperature sensor 182 to detect the temperature of the hot air for drying with good response, it is effective to provide the wind return plate 183 on the downstream side of the temperature sensor 182. This is because the gap of the drying chamber 174 is as narrow as about 0.5 mm, so that it is about 1 mmφ when an inexpensive and small temperature sensor, for example, a thermistor is used, and is affected by outside air without the wind-back plate 183.

Since the temperature sensor 182 is provided on the side that exits the drying chamber 174, it does not disturb the flow of warm air, and the drying chamber 17
Since it is not buried in the wall of 4, it has good responsiveness to temperature. When the wind deflector 183 is provided, the wind flow is slightly disturbed, but it affects only the lower part of the electrophotographic film and does not affect the portion where the image is formed.

Here, the temperature sensor X for control (see the phantom line in FIG. 12)
A comparison between the case where the electrophotographic film 24 is provided upstream of the electrophotographic film 24 and the case where the electrophotographic film 24 is provided downstream as in the present invention will be described with reference to the graph of FIG. The volume of warm air is 6 / min and the width of the drying chamber is 12m.
m, the gap between the drying chambers was 0.5 mm. FIG. 17 shows that when the temperature control is performed based on the detected temperature of the sensor X provided on the upstream side or the sensor 182 provided on the downstream side when the environmental temperature is low or high, the temperature of the upstream side (the detected temperature of the sensor X is ), The dry point temperature (the temperature detected by the sensor Y), the downstream temperature (the sensor 182
Detection temperature) of the difference.

It should be noted that the sensor Y is provided for an experiment, and in an actual device, the sensor Y cannot be installed at the drying point to control the temperature.

In the characteristic curve of FIG. 17, that is, when the temperature is high, the temperature control is properly performed by the upstream sensor X and the downstream sensor 182.

Here, in the case of the characteristic curve of FIG. 17, if the same set temperature as that of the characteristic curve is set (see the intersection A in FIG. 17), a large difference occurs in the drying point temperature as compared with the case of high temperature control, and it is low. It becomes too much.

On the other hand, in the case of the characteristic curve in Fig. 17, if the same set temperature as the characteristic curve is set (see intersection B in Fig. 17), the drying point temperature is not much different from the high temperature control, and the temperature is suitable for drying. You can

As a result, by providing the sensor 182 on the downstream side of drying, it is not necessary to change the reference set temperature depending on the environmental temperature, and the control can be facilitated.

Since the drying chamber is formed to be larger than the developing chamber, the film wet with the developer can be dried uniformly and even around the image frame.

Further, in the above example, the solenoid 23 of the film pressing mechanism is
The air pump 181 for drying is operated only when the electrophotographic film 24 is pressed against the process head 54 in conjunction with the above-mentioned 4, but the air pump 181 may be continuously operated from the start.

After the solenoid 234 of the film pressing mechanism is demagnetized at the position (III A) in FIG. 16, the film moving motor (C) is driven and the frame located in the drying section 68 is moved to the fixing section 70. . After the drive of the film moving motor (C) is stopped, the solenoid 234 of the film pressing mechanism is excited at the position (III B) in FIG.
Cold air is supplied to. The cold air reaches the fixing chamber 188 from the space 190 through the upper part of the glass plate 186.

After a lapse of a predetermined time from the excitation of the solenoid 234 of the film pressing mechanism, the xenon lamp 192 emits light, the toner particles are fused and fixed on the surface of the electrophotographic film 24, and the fixing process is completed.

Solenoid 314D for vaporized substances and scattered substances generated during fixing
Since it is blown off by the cold air supplied by the operation of, it does not adhere to the surface of the glass plate 186.

By completing the above steps, the recording of the image on the electrophotographic film is completed.

In the apparatus of the present embodiment, the frame located in the charging / exposure unit 64 where the shooting button is pressed to start shooting is moved one frame to the developing unit 66, and then the solenoid 234 of the film pressing mechanism is excited. After a predetermined time has passed, it becomes possible to take a picture. From this time, the air pump 195 for pressure squeeze to the developing unit 66
If the shooting button is pressed to shoot the next frame in succession until the weak air blowing due to the operation of is completed and a predetermined time has elapsed, it is processed as continuous shooting, and this is continuous. , The process proceeds as shown in FIG.

If the shooting button is not pressed within the above period, or if the end of a series of shootings is input from the control keyboard 28, a strong wind is blown by the operation of the air pump 144 for pressure squeeze by the timer. It is stopped, and the subsequent drying and fixing are also processed by the timer.

The electrophotographic film 24 on which the image of the original is recorded as described above can be projected by selecting the reader mode. In the electrophotographic apparatus of this embodiment, the reader mode is automatically selected when the cassette is loaded by the same operation as described above (the third mirror 38 is located at a position other than the position shown in FIG. 2). By the same operation as described above, a predetermined frame is positioned and stopped at the charging / exposure unit 64, and at the same time, the light source of the projection light source unit 46 shown in FIG. 3 is turned on, and this light is emitted. The image of the electrophotographic film 24 is enlarged and projected on the screen 16 by the optical system shown in FIG. 3 through the through hole 200 of the holding plate 198 and the electrophotographic film 24.

At the same time as the light source is turned on, the solenoid 314A is activated to supply cold air to the charging / exposure chamber 72, and the electrophotographic film 24 is cooled by the heat from the projection light source unit 46 so as not to reach a high temperature. Focus shift due to deformation is prevented.

Further, in the reader mode, by operating the buttons of the control keyboard 28, the electrophotographic film 24 can be continuously frame-fed and the projected images can be continuously viewed in a short time. In this case, the shutter (A) is closed when the electrophotographic film 24 is moved, and flicker due to an afterimage phenomenon is prevented.

When the copy button of the control keyboard 28 is pressed while the projection is being made on the screen 16 as described above, the copy mode is selected and the copy mirror 52 is moved so that the optical system shown in FIG. The projected image is recorded on the copy paper 30.

(Effects of Embodiment) In this embodiment, since the developer in the developing section is sealed with a positive pressure instead of a negative pressure suction, it is possible to use the same with another air supply source such as a pressure squeeze. In addition, since the air from the supply source such as a single pump is selectively used in the branching device, it is possible to reduce the number of parts.

〔The invention's effect〕

As described above, the present invention is a process head for an electrophotographic apparatus for developing by supplying a developer to an electrophotographic film in a developing section, wherein the electrophotographic film which has been developed in the developing section is dried with warm air. The drying section is characterized by having a guide means for reversing the hot air applied to one surface of the electrophotographic film, so that the drying section is reached and the hot air applied to the electrophotographic film is reused. In addition, it has an excellent effect that the drying effect can be improved.

[Brief description of drawings]

FIG. 1 is an external perspective view showing an embodiment of an electrophotographic apparatus, and FIG.
FIG. 3 is a perspective perspective view showing a photographing optical system of an electrophotographic apparatus,
4 is a perspective conceptual view showing the projection optical system, FIG. 4 is a perspective conceptual view showing the copying optical system, and FIG. 5 is a process head according to the embodiment of the present invention arranged in the electrophotographic apparatus of FIG. FIG. 6 is an exploded perspective view of FIG.
VII-VII line view in the figure, FIG. 8 is a VIII-VIII line view in FIG. 6, FIG. 9 is a IX-IX line view in FIG. 6, and FIG. 10 is in FIG. FIG. 11 is an explanatory view showing the relationship between the process head developing unit and other devices, and FIG. 12 is a XI of FIG.
Fig. 13 is a schematic side view showing the positional relationship between the process head and the presser plate, and Fig. 15 is a process head. FIG. 15A is a perspective view showing the film holding mechanism provided, FIG. 15A is a perspective view of a part of FIG. 15 seen from the opposite side, and FIG. 16 is a chart showing the time chart in the camera mode of the electrophotographic apparatus. 17
The figure is a graph showing the temperature in the drying section. A ... Electrophotographic device, B ... Electrophotographic device optical system, C ... Charging / exposure unit, E ... Developing unit, F ... Drying unit, G ... Fixing unit, 72 ... Charging / exposure chamber , 89 …… turnout device, 119 …… conduit, 183 …… ventilation plate.

Claims (1)

[Claims] 1. A process head for an electrophotographic apparatus for developing by supplying a developer to an electrophotographic film in a developing section, comprising a wall surface facing a back surface of the electrophotographic film which has been developed in the developing section. In a drying unit for drying the electrophotographic film by passing warm air heated by a heating means through a gap between a wall surface and the electrophotographic film, the electrophotographic film disposed on the drying unit from one side of the drying unit. Guide means for inverting the warm air flowing into the gap and flowing out from the opposite side of the one side and guiding it to the surface of the photographic film; and a temperature provided in the vicinity of the guide means and flowing out from the gap. A temperature sensor for detecting the temperature of the wind, and a control means for controlling the heating means so that the detected temperature from the temperature sensor becomes a reference temperature set regardless of the environmental temperature, And a process head for an electrophotographic apparatus.