JPH08262357A - Optical scanner and image forming device provided therewith - Google Patents

Abstract

PURPOSE: To provide an image forming device from which a screw is not separated in course of detaching operation, and an optical scanner applied to the device. CONSTITUTION: This optical scanner 100 is equipped with a housing 101 which is provided with a cylindrical guide 151 and with which a mount hole 150b is integrally formed. A fixing member 200 equipped with an elastic member 201 is attached to the mount hole 150b and fixed at the mounting part 153 of the image forming device. The entire surface of the fixed optical scanner 100 is covered with a cover 160. A cover hole 161b is formed corresponding to the position of the mount hole 150b on the cover 160. The inside diameter of the cover hole 161b is smaller than the maximum outside diameter of the fixing member 200. Therefore, the fixing member 200 is prevented from falling out from the mount hole 150b at the time of detaching the optical scanner 100 because of maintenance care, and prevented from separated from the scanner.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical scanning device which can be used in an image forming apparatus for forming an image on a photoconductor by an electrostatographic process and which provides image information to the photoconductor.

[0002]

2. Description of the Related Art An image forming apparatus using an electrostatic copying process, for example, an electrophotographic copying apparatus, stores a document holding unit for holding a document to be copied, and image information of the document held by the document holding unit. It has an image reading unit for taking out as light and dark information of light, an image forming unit for forming a copy image based on the image information read by the image reading unit, and then outputting it to a recording material.

The document holder has a document table made of a transparent material such as a glass plate, and a document scale indicating a position where a document to be copied is to be placed.

The image reading section illuminates a document set on a document table, and a CCD reading device for photoelectrically converting the reflected light from the document illuminated by the illumination lamp into an electric signal corresponding to image information. And an image forming lens device for making reflected light from the original document enter the light receiving surface of the CCD reading device in a stable state. It should be noted that the reflected light from the document toward the CCD reading device is generally
Original plate and CCD for the purpose of reducing the installation area of the device
After being bent several times by a plurality of mirrors arranged between the reading device and the reading device, it is guided to the light receiving surface of the CCD reading device.

The image forming unit includes a photoconductor that holds an electrostatic latent image corresponding to the image of the original read by the CCD reading device, a charging device that charges the photoconductor to a predetermined voltage, and a photoconductor charged by the charging device. Optical scanning device for irradiating image information light for forming electrostatic latent image on body, developing device for developing by supplying developer to electrostatic latent image formed on photoconductor by optical scanning device, developing device The transfer device is configured to transfer the developer image formed on the photoconductor to the recording material as the image output material, and the recording material feeding mechanism that feeds the recording material toward the transfer device. The developer image transferred onto the recording material via the transfer device is melted by being heated by the fixing device, and is fixed on the recording material by the pressure supplied from the fixing device.

In such an electrophotographic copying apparatus, for example, a laser exposure apparatus is used as an optical scanning apparatus for exposing image information to be recorded on a photoconductor. The latent image formed on the photoconductor by the laser exposure device is developed by the toner supplied from the developing device and then output on the recording paper.

The laser exposure apparatus is a laser element for generating a laser beam, and an optical deflector for deflecting the laser beam generated by the laser element in a generally linear and continuous manner toward the photoconductor, that is, for deflecting the laser beam. Further, it is composed of an fθ lens or the like for forming an image of the laser beam deflected by the optical deflector at a predetermined position on the photoconductor.

The optical deflector has a rotary reflecting mirror including a rotatably formed reflector of at least one surface, a motor for rotating the rotary reflecting mirror at a predetermined speed, and the like.
By the way, the housing for accommodating the optical scanning device is fixed near the photoconductor of the image forming unit via a fixing member, for example, a screw, which is provided at a predetermined position of the housing. Also, this housing is, for example,
It is sealed by a cover that prevents dust and dirt from entering the inside of the housing.

[0009]

When fixing the housing to the image forming apparatus, a screw is inserted into the cover hole from the outside of the cover after the housing is covered with the cover, and the image is inserted through the mounting hole of the housing. It is fixed to the forming apparatus body.

By the way, after fixing the housing accommodating the optical scanning device to the image forming apparatus, if it becomes necessary to remove the optical scanning device for maintenance of the apparatus, the optical scanning device is removed by removing the screw. It may fall off inside. For this reason, a magnet driver in which the tip of the driver is magnetized is usually used. However, it is unavoidable that the screw falls due to improper magnetization of the driver. In addition, when an elastic member is interposed between the screw and the mounting hole to prevent distortion, the screw may jump out in an unexpected direction due to the restoring force of the elastic member.
Therefore, there is a problem that the screw is lost during the operation of removing the optical scanning device, or the screw is dropped inside the main body of the image forming apparatus, and it is necessary to disassemble the screw to an unnecessary portion for taking out the screw. Therefore, an object of the present invention is to provide an image forming apparatus in which a screw does not separate from the apparatus during a detaching operation and an optical scanning apparatus applied to this apparatus.

[0011]

SUMMARY OF THE INVENTION The present invention has been made based on the above-mentioned problems, and has a holding means having a hole portion for fixing to an external holding body, and is inserted into the hole portion of the holding means. Fixing means for fixing the holding means to a predetermined position of the external holding body and integrally formed around the hole of the holding means in parallel with an axis passing through the center of the hole of the holding means Guide means for preventing the fixing means inserted in the hole from undesirably tilting with respect to the axis and falling of the fixing means, and an opening having a diameter smaller than the maximum diameter of the fixing means. And a shielding means for preventing the fixing means from being moved to the outside of the guide means of the holding means.

Further, according to the present invention, a light source for generating light and a rotatably formed reflecting surface, and a deflecting means for deflecting the light from the light source in a predetermined direction, and the deflecting means. Image forming means for forming an image of the deflected light on a predetermined position of an object, holding means for integrally holding the light source, the deflecting means and the guiding means, and a supporting means for supporting the holding means. A fixing means for fixing the holding means to the supporting means via a hole formed at a predetermined position of the holding means, and a maximum diameter of the fixing means at a position corresponding to the hole of the holding means. A diameter slightly larger than that of the holding means and formed integrally with the holding means, and the fixing means located in the hole portion of the holding means is parallel to an axis passing through the center of the hole portion. Guiding means for guiding and holding When the maximum diameter of the fixing means which is parallel with the axis passing through the center of the hole of the stage is d,
When the fixing means inserted into the hole is removed from the holding means, the fixing means holds the holding portion having an opening having a diameter D defined so that d> D is satisfied. An optical scanning device is provided, which comprises a shielding means for preventing movement to the outside of the means and for making the inside of the holding means airtight.

Further, according to the present invention, a holding means having a hole for fixing to the external holding body, and the holding means inserted into the hole of the holding means, the holding means being a predetermined one of the external holding body. Fixing means for fixing in position and the fixing means formed around the hole of the holding means in parallel and integrally with an axis passing through the center of the hole of the holding means and inserted into the hole. Has an opening having a diameter smaller than the maximum diameter of the fixing means, and the fixing means of the holding means. Shielding means for preventing movement to the outside of the guiding means, the holding means is arranged at a predetermined position of the external holding body, and the shielding means is further positioned at a predetermined position of the holding means. The holding means The optical scanning device is characterized in that the holding means is fixed to the external holding body by inserting the fixing means into the guide means from the outside of the shielding means with the shielding means interposed. Provided.

Further, according to the present invention, holding means having a hole for fixing to the external holding body, and the holding means inserted into the hole of the holding means, the holding means being a predetermined part of the external holding body. Fixing means fixed to the position of the holding means, the fixing means formed around the hole of the holding means in parallel and integrally with an axis line passing through the center of the hole of the holding means, and inserted into the hole. The guide means for preventing the means from inclining undesirably with respect to the axis and the tilting of the fixing means, and the opening having a diameter smaller than the maximum diameter of the fixing means, and the fixing means has the guide means. And a shielding means for preventing the movement of the holding means to a predetermined position of the external holding body, and the shielding means is further positioned at a predetermined position of the holding means, The shielding means for the holding means The holding means can be fixed to the external holding body by inserting the fixing means from the outside of the shielding means into the guide means with the means interposed, and further, the fixing means holds the holding means. When the fixing between the means and the external holding body is released, the fixing means moves to the outside of the guiding means, or the fixing means falls inside the holding means, or the fixing means guides the guide. Provided is an optical scanning device characterized by preventing it from collapsing in the means.

Furthermore, according to the present invention, a light source for generating light, a rotatably formed reflecting surface, and a deflecting means for deflecting the light from the light source in a predetermined direction, and the deflecting means. An image forming means for forming an image of the light deflected by the object on a predetermined position of an object, a holding means for integrally holding the light source, the deflecting means and the guiding means, and a support for supporting the holding means. Means, fixing means for fixing the holding means to the supporting means through a hole formed at a predetermined position of the holding means, and a maximum of the fixing means at a position corresponding to the hole of the holding means. A diameter slightly larger than the diameter of the holding means is formed integrally with the holding means, and the fixing means located in the hole of the holding means is parallel to an axis passing through the center of the hole. Guide means to guide When the maximum diameter of the fixing means formed in parallel with the axis passing through the center of the hole of the holding means is d, an opening having a diameter D defined so that d> D is satisfied is provided. A shield for preventing the fixing means from moving to the outside of the holding means and for making the inside of the holding means airtight when the fixing means inserted in the hole is separated from the holding means. And an image carrier for holding an image corresponding to the light from the light source guided through the deflecting unit and the image forming unit of the optical scanning unit, and the image carrier. An image forming apparatus is provided that includes a developing unit that visualizes the image by supplying a developer to the image formed by the optical scanning unit.

[0016]

According to the present invention, in the optical scanning device, the fixing means is formed around the hole of the holding means in parallel and integrally with the axis passing through the center of the hole, and the fixing means is inserted into the hole. Has guiding means for preventing undesired tilting with respect to the axis and falling over in the fixing means. Further, according to the optical scanning device of the present invention, the guide means formed integrally with the holding means is hermetically sealed by the shielding member having a diameter smaller than the diameter of the fixing means inserted into the guide means.

Therefore, even when the fixing between the holding means and the external holding body by the fixing means is released, the fixing means is prevented from moving beyond the shielding means to the outside of the guide means. Also, the time required to fix the holding means by the fixing means is reduced. Further, the fixing means can be prevented from falling inside the optical scanning device.

On the other hand, the shielding means allows the fixing means to be positioned at a predetermined position of the holding means while keeping the holding means airtight, so that the fixing means is undesirably placed outside the holding means. It can be prevented from being scattered. This not only eliminates the possibility that the fixing means is mixed into the optical scanning means, but also shortens the assembly time of the optical scanning device.

[0019]

Embodiments of the present invention will be described in detail below with reference to the drawings. FIG. 1 is a plan view showing the outline of the optical scanning device of the present invention. FIG. 2 is a sectional view of the optical scanning device shown in FIG. 1 taken along the line AA. FIG. 3 is a sectional view schematically showing an image forming apparatus to which the optical scanning device shown in FIG. 1 is applied.

As shown in FIG. 3, the image forming apparatus, that is, the electrophotographic digital copying apparatus 2 has an image reading section 4 functioning as a reading means and an image forming section 6 functioning as an image forming means. In addition, an upper portion of the image reading unit 4 is formed so as to be openable and closable with respect to a document table of the image reading unit 4 which will be described later. An automatic document feeder (hereinafter, referred to as ADF) 8 that functions as a document retainer that holds the document D placed on the document table in close contact with the document table is set.

The image reading unit 4 is arranged on one side of the document table 11 and a document table 11 made of transparent glass on which the document D is set, facing the closed ADF 8 at the upper part thereof. 11 has a size plate 12 indicating a reference position when the document D is set. The document table 11
A control panel (not shown) is arranged in the vicinity of the document table 11 surrounding the.

Below the document table 11, the image reading unit 4 is provided with an exposure lamp 13 for illuminating the document D placed on the document table 11, and for converging light from the exposure lamp 13 on the document D. The auxiliary reflection plate 14 and the first mirror 15 that bends the reflected light from the document D to the left in the drawing are arranged. Exposure lamp 13, auxiliary reflector 14 and first
The mirror 15 is fixed to the first carriage 16,
The first carriage 16 is arranged so as to be movable in parallel with the document table 11 with the movement of the first carriage 16. The driving force of a pulse motor (not shown) is transmitted to the first carriage 16 via a toothed belt (not shown), and the first carriage 16 is moved in parallel along the document table 11.

The left side of the document table 11 and the direction in which the reflected light reflected by the first mirror 15 is guided are parallel to the document table 11 via a drive mechanism (not shown) such as a toothed belt and a DC motor. A second carriage 20 is arranged so as to be movable.

The first carriage 15 is attached to the second carriage 20.
The second mirror 21 that bends the reflected light from the document D guided by and downward and the third mirror 22 that bends the reflected light to the right in the drawing are arranged at right angles to each other. Second carriage 2
0 is driven by the first carriage 16 by a toothed belt (not shown) for driving the first carriage 16 and is moved in parallel along the document table 11 at a speed of ½ with respect to the first carriage 16. It

The reflected light from the second carriage 20 is imaged at a predetermined magnification in the plane below the first carriage 16 and including the optical axis of the light reflected by the second carriage 20. An image forming lens 23 and a CCD image sensor 24 that converts the reflected light, which is focused by the image forming lens 23, into an electric signal, that is, image data are arranged.

The image forming section 6 is a photosensitive drum 3 as an image bearing member rotatably positioned in the center of the copying apparatus 2.
Has 0. The photoconductor drum 30 is rotated at a predetermined rotation speed by a motor (not shown).

At a predetermined position around the photosensitive drum 30, a charger 31 for charging the surface of the drum to a predetermined electric charge, and by exposing the surface of the photosensitive drum 30 with a laser beam corresponding to image data, the photosensitive drum 30 is exposed. Body drum 30
An optical scanning device that forms an electrostatic latent image on the surface of the photosensitive drum 30, that is, a laser exposure device 32, supplies toner as a developer to the electrostatic latent image formed on the surface of the photosensitive drum 30 by exposure by the laser exposure device 32. And a developing device 33 having a developing roller 33a for developing with a desired image density, and a transfer material, that is, a copy sheet P fed from a sheet cassette described later.
The toner image formed on the photosensitive drum 30 is transferred onto the photosensitive drum 30 and the paper P on which the toner image is transferred is transferred onto the photosensitive drum 30.
From the surface of the photoconductor drum 30, a peeling claw 35 for peeling the copy sheet P from the surface of the photoconductor drum 30, a cleaning device 36 for cleaning the toner remaining on the surface of the photoconductor drum 30, and the photoconductor drum. A static eliminator 37 for eliminating static potentials remaining on the surface of 30 is arranged in order.

At the bottom of the copying machine 2 located below the photosensitive drum 30, a multi-stage paper feeding device as a paper feeding means is detachably mounted in a plurality of upper and lower stages from the front side of the copying machine 2.
40 (hereinafter referred to as PFP) is arranged integrally with the copying apparatus 2.

The PFP 40 includes an upper cassette 41, a middle cassette 42 and a lower cassette 43 for accommodating a plurality of types of copy sheets P of various sizes, and the respective cassettes 41, 42 and 43 are arranged in the longitudinal direction, for example. The A4 size copy sheet, the B4 size copy sheet and the A3 size copy sheet placed so as to be conveyed along are each formed to be able to store about 500 sheets.

Pickup rollers 44a, 44b and 44c are provided at predetermined positions of the upper cassette 41, the middle cassette 42 and the lower cassette 43 to take out the sheets P one by one from the respective cassettes 41, 42 and 43.

Each pickup roller 44a, 4
4b and 44c for each cassette 41, 42 and 4
A conveyance roller 45 for separating the sheets P one by one is provided at a position where the leading edge of the sheet P taken out from the sheet 3 is passed.
a, 45b and 45c, and separation rollers 46a, 46b and 46 that are integrally arranged with the respective conveying rollers.
c is arranged. The separation rollers 46a, 46b and 46c are arranged such that their axes are parallel to the mutually combined transport rollers and are in contact with each other at a predetermined pressure, and rotate in a direction opposite to the rotation direction of the transport rollers. By doing so, only the uppermost one sheet of the paper P taken out from each cassette is delivered to the transport path described later.

On the right side of the PFP 40 in the figure, there are three frequently used size paper sheets P, for example, A4 size paper sheets P.
A large-capacity feeder (hereinafter referred to as LCF) 47 that can store about 000 sheets is provided. LCF47
The paper P stored in the LCF 47 is placed at the predetermined position of
A pickup roller 48 is arranged to take out the sheets one by one. A separating mechanism 49 including a pair of upper and lower conveying rollers 49a and a separating roller 49b is arranged between the pickup roller 48 and the photosensitive drum 30. The separating mechanism 49 rotates the separating roller 49b in a direction opposite to the direction in which the conveying roller 49a is rotated, so that only the uppermost one sheet of the paper P taken out from the LCF 47 by the pickup roller 48 is conveyed as described later. Send to the road.

At the top of the LCF 47, each cassette 41,
Copy paper P independently of 42, 43 and LCF 47
A manual feed feeder 50 capable of feeding paper is formed. Between the manual feed feeder 50 and the photoconductor drum 30, a manual feed pickup roller 51 for taking in the paper P inserted in the manual feed feeder 50, a manual feed guide 52 for guiding the paper P taken in by the pickup roller 51,
Further, a conveyance roller 53 that conveys the sheet P guided toward the photosensitive drum 30 via the manual feed guide 52 is provided.

Respective cassettes 41, 42 and 43
In addition, between the LCF 47 and the photoconductor drum 30, the conveyance path 5 for guiding the paper P from the cassettes 41, 42 and 43 and the LCF 47 toward the photoconductor drum 30.
4 are formed. The transport path 54 further extends to the outside of the copying apparatus 2 via a transfer area defined between the photosensitive drum 30 and the transfer / separation charger 34. Further, in the transport path 54, the paper P fed from any of the cassettes, the LCF, or the manual feed guide is used.
A plurality of transport rollers 55 for transporting the sheet toward the photoconductor drum 30 are provided.

In the vicinity of the photosensitive drum 30 on the conveying path 54 and on the upstream side, the copy sheet P guided along the conveying path 54.
Of the toner image on the photoconductor drum 30 and the tip of the copy paper P are aligned, and the copy paper P is transferred to the transfer area at the same speed as the moving speed of the outer peripheral surface of the photoconductor drum 30. An aligning roller 56 for feeding paper is arranged. Further, in front of the aligning roller 56, that is, on the side of the transport roller 55, the aligning roller 56
An aligning sensor 56a is provided for detecting the arrival of the copy sheet P to the sheet.

A conveyor belt 57 that conveys the paper P is incorporated in the direction in which the paper P that has passed through the transfer area advances. At the position where the paper P is conveyed by the conveyor belt 57 and the heat is less likely to be applied to the photoconductor drum 30, a pair of heat rollers whose roller surfaces are in pressure contact with each other is included and the toner image is transferred to the paper. A fixing device 58 for fixing the toner image on the paper P by heating the toner image and melting the toner image to press the toner image and the paper P is provided.

On the side wall of the copying machine 2 facing the fixing device 58, the paper P on which the toner image is fixed by the fixing device 58.
A discharge tray 59 for discharging is disposed. A discharge switching unit 60 is disposed between the fixing device 58 and the discharge tray 59 to guide the copy paper P, on which the toner image is fixed by the fixing device 58, to either the paper reversing unit or the discharge tray 59 described later. There is.

The discharge switching unit 60 is arranged between the first and second discharge rollers 61 and 62 for propelling the sheet P that has passed through the fixing device 58, and between the first and second discharge rollers 61 and 62. A distribution gate 63 is provided for selectively distributing the copy paper P, which has passed through the fixing device 58, to either the discharge tray 59 or a paper reversing unit described later.

The reversing mechanism 64 includes a temporary stacking unit 65 for temporarily stacking the copy paper P that has already passed through the transfer area and the fixing device 58, and the copy paper P that has passed through the fixing device 58.
A reversing path 66 for reversing the front and back of the sheet to the temporary stacking section 65, a pickup roller 67 for taking out the copy sheets P stacked in the temporary stacking section one by one, and the aligning rollers for the sheets P stored in the temporary stacking section 65 again. It has a reversing conveyance path 68 that guides the sheet 56, and a paper feed roller 69 that feeds the sheet P guided by the reversal conveyance path 68 toward the aligning roller 56.

The ADF 8 has a cover 71, and the cover 7
The rear edge of the copying machine 1 is attached to the rear edge of the upper surface of the copying apparatus 2 via a hinge device (not shown).
By rotating and displacing the entire DF 8, as described above, it is formed so as to be openable and closable with respect to the document table 11 of the image reading section 4.

A document feeding table 72 for holding a plurality of documents D is provided on the upper surface of the cover 71 slightly to the left. The documents D set on the document feed table 72 are sequentially taken out one by one on the left side of the document feed table 72 in the figure, that is, one end side of the ADF 8, and the document table 11 of the image reading unit 4 is read from the left end side in the figure. A pickup roller 73 for supplying to one end side of is arranged. An empty sensor 7 as a document detection sensor for detecting whether or not the document D is set on the document feed table 72 at a predetermined position of the document feed table 72.
2a is provided. A document width detection sensor (not shown) that functions similarly to the document position detection sensor 17 that detects the position where the document D is set on the document table 11 may be arranged on the document feed table 72.

In the original pick-up direction of the pickup roller 73, there are a paper feed roller 74 for sending the original D taken out by the pickup roller 73 toward the original table 11, and a leading end of the original D fed by the paper feed roller 74. An aligning roller 75 for aligning is arranged. The document D is placed between the aligning roller 75 and the paper feeding roller 74.
An aligning sensor 75a for detecting the arrival of the aligning roller 75 on the aligning roller 75 is arranged.

Inside the cover 71, at a position facing the document table 11 of the image reading section 4 in a state where the ADF 8 is closed, a size that covers almost the entire document table 11 is provided, and a pickup roller is provided. A conveyance belt 76 is arranged to convey the document D conveyed from the document feed table 72 via the document feed roller 74 and the aligning roller 73 to a predetermined position on the document table 11. The conveyor belt 76 is stretched around belt rollers 77 arranged in a pair in the left and right in the figure, and is rotated by a belt drive mechanism (not shown) toward both the right side in the figure and the left side in the figure.

A conveyor belt 76 is provided on the right side of the ADF 8.
Thus, the reversing roller 78 that sends the document D moved from the left side to the right side in the drawing toward the outside of the cover 71, the pinch roller 79 that presses the document D against the reversing roller 78, and the reversing roller 78 and the pinch roller 79 convey the document D. Document D
Flapper 8 which switches between returning to the transport belt 76 again or discharging to a predetermined discharge position, that is, the cover 71.
0, when the flapper 80 is switched to the discharge side, a discharge roller 81 that discharges the document D conveyed by the reversing roller 78, and a jam sensor 82 that detects a jam of the document near the reversing roller 78. Are arranged.

1 and 2 show in detail the optical scanning device incorporated in the image forming apparatus shown in FIG.
As shown in FIGS. 1 and 2, the optical scanning device 100 includes
A housing 101 as a housing, a light emitting unit 120 as a light source for generating a laser beam, and a light emitting unit 12
0 from the laser beam at a predetermined position, for example, in FIG.
The optical deflector 130 that reflects or deflects linearly and continuously toward the photoconductor drum 30 of the image forming apparatus shown in FIG. The drum 30 is composed of an image forming optical unit 140 which forms an image under a predetermined image forming condition.

The light emitting unit 120, the light deflecting device 130 and the image forming optical section 140 are respectively provided in the housing 101.
Fixed in place. In the vicinity of the area of the housing 101 where the light deflector 130 is fixed, the light deflector 1
A partition wall 102 for housing 30 is formed.

At a predetermined position on a part of the partition 102, the laser beam from the light emitting unit 120 is deflected by the optical deflector 130.
Light source side dust-proof glass (or plastic) 103 for guiding it to a reflecting surface (polyhedral mirror) described later, and the laser beam reflected by the reflecting surface (polyhedral mirror) 103
An image-side dust-proof glass 104 for guiding to 0 is arranged. The light source side dust-proof glass 103 and the image plane side dust-proof glass 104 are formed of, for example, glass (trade name) Blue Pane glass in which blue plate glass, that is, optical plate glass is colored with a blue dye.

FIG. 4 is a schematic plan view of the light emitting unit 120 incorporated in the optical scanning device of the present invention. FIG. 5 schematically shows a front view of the light emitting unit 120 shown in FIG.

Referring to FIGS. 4 and 5, the light emitting unit 120 incorporated in the optical scanning device 100 of FIG. 1 focuses a semiconductor laser element 121 for generating a laser beam and a laser beam emitted from the laser element 121. First lens 122 for converting light or parallel light, first lens 122
Second lens 123 and first lens 122 for adjusting the beam cross-sectional shape of the laser beam passed through
And the second lens 123 and the laser element 12
It has a diaphragm 124 and the like for reducing fluctuations in the light intensity (light quantity) of the laser beam from the first laser. The first lens 12
2 and the second lens 123 are optical glass, respectively.
(Eg BK7).

The laser element 121 is, for example, aluminum die cast or plastic (PPS = polystyrene).
Lens barrel (or lens holder) manufactured by etc. 1
It is fixed directly to 25. In addition, the first lens 122, the second
The lens 123 and the diaphragm 124 are integrally held by the lens barrel 125 together with the laser element 121. In addition,
The lens barrel 125 has a positioning member (not shown) for fixing to the housing 101, and is fixed to a predetermined position of the housing 101 by, for example, screws or adhesion.

FIG. 6 shows the light emitting unit 1 shown in FIG.
A front view of 20 variants is schematically shown. Laser element 121, first lens 122 and second lens 123
Respectively, as shown in FIG.
The laser holder 226 and the lens holder 225 may be further fixed after being fixed to the lens holder 225.

Referring again to FIGS. 1 and 2, the optical deflecting device 130 is fixed to a rotor 131b which is arranged integrally with a rotary shaft 131a of a scanner motor 131 using a magnetic fluid bearing (not shown). It is composed of a polygon mirror 132a having a plurality of plane mirrors (that is, reflecting surfaces, in this example, eight surfaces) formed so as to be rotatable at a high speed. Each reflecting surface is formed so as to surround the polygonal mirror 132a and divide the polygonal mirror 132a into equal parts.

The scanner motor 131 has a rotor 131b.
Has a fixing portion 131c including a stator for rotating the rotor, and fixing means (screws in this embodiment) 133a and 13a.
It is fixed to a predetermined position of the housing 101 by a method such as screwing via a motor base 131d which is previously coupled to the fixing portion 131c by 3b. The motor base 131d may be integrally formed with the fixing portion 131c (as a part of the fixing portion 131c) by devising the shape of the fixing portion 131c.

A direction in which the laser beam continuously reflected between the optical deflector 130 and the photoconductor drum 30, that is, each reflecting surface of the polygon mirror 132a of the optical deflector 130 is emitted through the image side dustproof glass 104. The first fθ lens 132b, the folding mirror 132c, the second fθ lens 132d, the emission mirror 132e, and the dust-proof glass 1
05 are arranged in order.

The first fθ lens 132b makes the rotation angle of each reflecting surface proportional to the position at which the laser beam continuously reflected (deflected) with each rotation of each reflecting surface is imaged. The optical axis O ₂ defined between the reflection point of each reflecting surface and the center of the main scanning direction orthogonal to the axial direction of the photoconductor drum 30 and the laser beam reflected by each reflecting surface. In order to align the angle θ, the optical axis O ₂ and the position h on the photosensitive drum where the laser beam has reached, a focal length f that satisfies h = fθ is given in the main scanning direction. The first fθ lens 132b is the fixing member 10 integrally formed at a predetermined position of the housing 101.
It is fixed to the housing 101 by 6.

The folding mirror 132c is a plane mirror extending in the main scanning direction, and includes the first fθ lens 13
It is used to guide the laser beam passing through 2b toward the photoconductor drum 30 and to reduce the size of the optical scanning device 100. This folding mirror 132c
Is formed by fixing members 107a and 107b integrally formed at a predetermined position of the housing 101.
It is fixed to.

The second fθ lens 132d has a first fθ lens 132d.
In cooperation with the lens 132b, the position h of the laser beam guided by the photoconductor drum 30 is h = f with respect to the main scanning direction.
It is used for satisfying θ and for correcting the image forming characteristics such as the distortion aberration or the field curvature of the laser beam reflected by the folding mirror 132c on the photosensitive drum. The second fθ lens 132d is the fixing member 1 integrally formed at a predetermined position of the housing 101.
It is fixed to the housing 101 by 08.

The emission mirror 132e is a plane mirror extending in the main scanning direction, and has a second fθ lens 132d.
It contributes to further reduce the size of the optical scanning device 100 while folding back the laser beam passed through the photoconductor drum 30. The emission mirror 132e is fixed to the housing 101 by fixing members 109a and 109b integrally formed at a predetermined position of the housing 101.

At a predetermined position of the housing 101, at a position where the laser beam folded by the emitting mirror 132e is emitted to the outside of the housing 101,
Inside the optical scanning device 100, a dust-proof glass 105 for preventing the intrusion of toner or paper dust is arranged. This dustproof glass 105 is used for the housing 1
It is fixed to the housing 101 by a fixing member 110 integrally formed at a predetermined position 01.

The optical axis O ₂ defined between the reflection point of each reflecting surface of the polygon mirror 132a and the center of the main scanning direction orthogonal to the axial direction of the photosensitive drum 30 is the light emitting unit 12.
It is arranged on the same plane as the optical axis O ₁ defined between the emission point of the laser element 121 of 0 and the reflection point of each reflection surface of the polygon mirror 132a.

The optical scanning device 100 also includes a horizontal synchronization signal detecting section for detecting horizontal synchronization of the laser beam emitted from the light emitting unit 120 in the main scanning direction. The horizontal sync signal detector includes a horizontal sync detection mirror 141 and a sync signal detector 142.
The horizontal synchronization detection mirror 141 is arranged outside the area of the image to be printed when the beam passing through the second fθ lens 132d reaches the photoconductor drum 30 in the main scanning direction of the laser beam. Sync signal detector 14
2 is arranged at a position where the laser beam reflected from the horizontal synchronization detecting mirror 141 can be detected reliably.

In order to mount the optical scanning device 100 at a predetermined position of the image forming apparatus main body 2 shown in FIG. 3, the housing 101 has mounting holes 150a, 150b, and 150c.
Is provided. These mounting holes 150 to 150c
Is located inside the housing in order to suppress distortion of the housing itself caused by mounting the housing 101 and ensure rigidity. Also, this mounting hole 150
The periphery of a to 150c is surrounded by a cylindrical guide 151 formed integrally with the housing 101. The inner diameter of the guide 151 is larger than the maximum outer diameter of a fixing member 200 such as a screw described later in FIG. 7 for fixing the housing 101 to the image forming apparatus main body 2,
It is large enough to use a tool for inserting, and is large enough that the fixing member 200 does not fall more than 10 ° with respect to the axis of the fixing member inside the mounting hole. The guide 151 does not have to be formed integrally with the housing 101.

On the other hand, in order to seal the optical system housed inside the optical scanning device 100, the optical scanning device 100
Is covered with a metal cover 160. The cover 160, once attached, does not separate from the housing 101, except for the case where the internal optical system is repaired, in order to maintain the internal hermeticity. This cover 16
0 seals the optical system inside the housing from the outside air and separates the mounting holes 150a to 150c from the inside of the housing. In addition, the cover 160 includes the housing 1
No. 01 mounting holes 150a to 150c are provided with cover holes, respectively. As shown in FIG. 2, the cover hole 16 is provided at a position corresponding to the mounting hole 150b.
1b is provided.

Next, a method of attaching the optical scanning device 100 to the image forming apparatus main body 2 will be described. FIG.
FIG. 3 is a cross-sectional view schematically showing a portion where the optical scanning device is attached to the image forming apparatus. FIG. 8 is a partial cross-sectional view of FIG. 7 showing how the optical scanning device is attached or detached.

As shown in FIG. 7, the optical scanning device 100 is provided with a boss 152 having a part of the housing 101 protruding.
Is positioned at a predetermined mounting position 153 of the image forming apparatus main body. A fixing member, for example, the screw 200 is inserted into the mounting hole 150b. The screw 200 is provided with an elastic member 201 such as a spring in advance. When the screw 200 is mounted and the elastic member 201 is compressed, only the elastic force of the elastic member 201 is applied to the housing 101, and distortion of the housing 101 is suppressed. Meanwhile, a weight is applied to the boss portion 152. Such mounting work is similarly performed for the other mounting holes 150a and 150c shown in FIG. After the optical scanning device 32 is attached to the image forming apparatus 2 in this way, the optical scanning device 100 is covered with the cover 160. The cover 160 is fixed to the optical scanning device 32 with a screw or a method such as adhesion. The inner diameter D of the cover hole 161b located corresponding to the mounting hole 150b has a relationship of D <d, where d is the maximum outer diameter of the fixing member 200, that is, the outer diameter of the screw head in this embodiment. It is large enough to fill and insert a tool 202 such as a screwdriver as shown in FIG.

As described above, before the cover 160 is fixed to the housing 101 of the optical scanning device 100, the fixing member 200 such as a screw is inserted into the mounting holes 150a to 150c in advance, so that maintenance is possible. Therefore, when the optical scanning device 100 is detached from the image forming apparatus 2, there is no possibility that the fixing member 200 jumps out of the device 100 due to the restoring force of the elastic member 201. Therefore,
The fixing member 200 may be lost during the operation of removing the optical scanning device 100, or may drop inside the main body of the image forming apparatus,
This solves the problem that the fixing member 200 needs to be disassembled up to unnecessary portions in order to be taken out. In addition, the fixing member 200 is 1 in the mounting hole with respect to the axis of the fixing member.
Since the inclination is only about 0 °, the fixing member does not fall into the boss 152.

Next, a modified example of the cover that covers the optical scanning device 100 will be described. FIG. 9 is a sectional view schematically showing a portion where the optical scanning device is attached to the image forming apparatus. 10A is an enlarged plan view of the cover hole portion, and FIG. 10B is a partial cross-sectional view of FIG. 9 showing how the optical scanning device is attached or detached.

As shown in FIG. 9, a resin cover 170 is provided.
The cover hole portion 171 b at a position corresponding to the mounting hole 150 b of the optical scanning device 100 is closed by the cap portion 172. As shown in FIG. 10A, the cap portion 172
Is formed integrally with the cover 170 and is divided into six cap members 172a to 172f by making radial cuts in a part of the cover 170 so as to correspond to the cylindrical guide 151 of the mounting hole 150b. ing.
Similarly, the other mounting holes 150a and 150c shown in FIG.
The cover hole portion at a position corresponding to is also closed by the cap member 172.

After the optical scanning device 100 is attached to the predetermined position 153 of the image forming apparatus by the fixing member 200,
The cover 170 covers the entire surface of the device 100. The cover 170 is fixed to the optical scanning device 100 with a screw, or by a method such as adhesion. When the optical scanning device 100 fixed in this way is removed for maintenance or other reasons, as shown in FIG. 10, the driver 202 is pushed in from the vertical direction of the cap member 172, so that the cap member 172 of the driver 202 is removed. The driver 202 is pushed down along the pushed-in direction.
Is inserted into the mounting hole 150b. Therefore, the driver 20
Even if the fixing member 200 is removed in step 2,
The cap member 172 prevents the fixing member 200 from jumping out from the mounting hole 150b due to the restoring force of the elastic member 201. The axial direction of the fixing member 200 is
Since the guide 151 only allows an inclination of about 10 °, it stays at a predetermined position in the guide 151.

FIG. 11 is a sectional view schematically showing a portion where the optical scanning device is attached to the image forming apparatus. 12
1A is an enlarged plan view of the cover hole portion, and FIG.
2B is a partial cross-sectional view of FIG. 11 showing how the optical scanning device is attached or detached.

As shown in FIG. 11, the metal cover 18
0, a cover hole 181b is provided at a position corresponding to the mounting hole 150b of the optical scanning device 100. A resin cap member 182 is previously attached to the side of the cover hole 181b facing the attachment hole 150b. As shown in FIG. 12A, the cap member 182 has six cap members, for example, a radial cut is made in a part of the cap member so as to correspond to the cylindrical guide 151 of the mounting hole 150b. It is divided into 182a to 182f. Similarly, another mounting hole 150 shown in FIG.
Cover holes at positions corresponding to a and 150c are also closed by the cap member 182.

After the optical scanning device 100 is attached to the predetermined position 153 of the image forming apparatus by the fixing member 200,
The cover 180 covers the entire surface of the device 100. The cover 180 is fixed to the optical scanning device 100 with a screw, or by a method such as adhesion. When the optical scanning device 100 fixed in this manner is removed for maintenance or other reasons, the driver 202 is removed from the vertical direction of the cap member 182 as shown in FIG.
Is pressed, the cap member 182 is moved to the driver 2
The driver 202 is pushed down along the pushing direction of 02, and the driver 202 is inserted into the mounting hole 150b. Therefore, even if the fixing member 200 is removed by the driver 202, the fixing member 200 is still fixed by the restoring force of the elastic member 201.
Even if a force is applied to 00 from the mounting hole 150b to the outside, the cap member 182 prevents the force from protruding to the outside. Further, the axial direction of the fixing member 200 is only allowed to be tilted by an angle of about 10 ° by the guide 151, so that the fixed member 200 stays at a predetermined position in the guide 151.

The modified examples of the cover shown in FIGS. 9 to 12 are not limited to the relationship of D <d as described with reference to FIG. The present invention can also be applied to other image forming apparatuses such as a laser printer.

[0074]

As described above, in the optical scanning device and the image forming apparatus having the optical scanning device of the present invention, the fixing member inserted into the housing passes around the mounting hole of the housing and passes through the center of the mounting hole. The fixing member is formed in parallel with and integrally with the axis line and prevents the fixing member inserted in the mounting hole from undesirably tilting with respect to the axis line and falling down in the mounting hole. Further, according to the present invention, the guide integrally formed with the housing is hermetically sealed by the cover having a diameter smaller than the diameter of the fixing member inserted into the guide.

Therefore, even when the fixing between the housing and the image forming apparatus main body by the fixing member is released, the fixing member is prevented from moving beyond the cover to the outside of the guide. Also, the time required to fix the housing by the fixing member is reduced. Furthermore, the fixing member can be prevented from falling inside the optical scanning device.

On the other hand, the cover allows the fixing member to be positioned at a predetermined position of the housing while keeping the housing airtight, so that the fixing member is undesirably scattered to the outside of the housing. Can be prevented. This not only eliminates the possibility that the fixing means is mixed into the optical scanning means, but also shortens the assembly time of the optical scanning device.

[Brief description of drawings]

FIG. 1 is a plan view showing the outline of an optical scanning device according to an embodiment of the present invention.

FIG. 2 is a sectional view showing an outline of the optical scanning device shown in FIG.

FIG. 3 is a sectional view showing an outline of an image forming apparatus of the present invention.

FIG. 4 is a plan view schematically showing a light emitting unit of the optical scanning device shown in FIG.

5 is a front view schematically showing a light emitting unit of the optical scanning device shown in FIG.

FIG. 6 is a front view schematically showing a modification of the light emitting unit shown in FIG.

7 is a cross-sectional view schematically showing a portion to which the optical scanning device shown in FIG. 1 is attached.

FIG. 8 is a diagram showing how the optical scanning device shown in FIG. 7 is detached.

9 is a sectional view schematically showing a portion to which the optical scanning device shown in FIG. 1 is attached.

10A is a plan view showing a part of a cover of the optical scanning device, and FIG. 10B is a state in which the optical scanning device shown in FIG. 9 is removed. FIG.

FIG. 11 is a cross-sectional view schematically showing a portion to which the optical scanning device shown in FIG. 1 is attached.

12A is a plan view showing a part of a cover of the optical scanning device, and FIG. 12B is a state in which the optical scanning device shown in FIG. 11 is removed. FIG.

[Explanation of symbols]

2 ... Image forming device 4 ... Image reading unit 6 ... Image forming unit 8 ... ADF 11 ... Original platen 30 ... Photosensitive drum 33 ... Developing device 34 ... Transfer / peeling charger 40 ... Multi-stage paper feeding device 58 ... Fixing device 100 ... Optical Scanning device 101 ... Housing (holding means) 102 ... Partition 103 ... Light source side dustproof glass 104 ... Image plane side dustproof glass 120 ... Light emitting unit 121 ... Semiconductor laser element (light source) 122 ... First lens 123 ... Cylindrical lens 124 ... Aperture 125 ... Lens barrel 130 ... Optical deflection device 131 ... Scanner motor 131a ... Rotation shaft 131b ... Rotor 131c ... Fixed part 131d ... Motor base 132a ... Polygonal mirror 132b ... First f.theta. Lens 132c ... Folding mirror 132d ... Second f.theta. Lens 132e. ... Emitting mirror 132 ... Multi-faceted reflecting mirror 140 ... Imaging optical unit 50 ... Mounting hole 151 ... Guide 152 ... Boss 153 ... Mounting part 160 ... Cover 161 ... Cover hole 170 ... Cover 171 ... Cover hole part 172 ... Cap part 180 ... Cover 181 ... Cover hole part 182 ... Cap part 200 ... Screw (fixed) Member) 201 ... Spring (elastic member) 202 ... Driver (installation tool)

Claims (5)

[Claims] 1. A holding means having a hole for fixing to an external holding body, and a fixing means inserted into the hole of the holding means to fix the holding means at a predetermined position of the external holding body. And around the hole of the holding means, is formed integrally and parallel to the axis passing through the center of the hole of the holding means, the fixing means inserted into the hole with respect to the axis A guide means for preventing undesired tilting and the fall of the fixing means, and an opening having a diameter smaller than the maximum diameter of the fixing means,
An optical scanning device comprising: a shielding unit that prevents the fixing unit from being moved to the outside of the guiding unit of the holding unit. 2. A light source for generating light, a deflecting means for deflecting the light from the light source in a predetermined direction, which has a reflecting surface rotatably formed, and the light deflected by the deflecting means. An image forming means for forming an image on a predetermined position of the object; a holding means for integrally holding the light source, the deflecting means and the guiding means; a supporting means for supporting the holding means; Fixing means for fixing the holding means to the supporting means via a hole formed at a predetermined position, and a diameter slightly larger than the maximum diameter of the fixing means at a position corresponding to the hole of the holding means. And a guide means that is integrally formed with the holding means and that guides the fixing means located in the hole of the holding means so as to be parallel to an axis that passes through the center of the hole. Center of the hole of the holding means When the maximum diameter of the fixing means formed parallel to the axis passing through is d, the opening has an opening having a diameter D defined so that d> D is satisfied, and the fixing means is inserted into the hole. And a shielding means for preventing the fixing means from moving to the outside of the holding means and for making the inside of the holding means airtight when the fixing means is separated from the holding means. . 3. A holding means having a hole for fixing to an external holding body, and a fixing means inserted into the hole of the holding means to fix the holding means at a predetermined position of the external holding body. And around the hole of the holding means, parallel to and integrally with an axis passing through the center of the hole of the holding means, the fixing means inserted into the hole with respect to the axis The fixing means is provided outside the guiding means of the holding means, the guiding means preventing undesired tilting and the falling of the fixing means, and the opening having a diameter smaller than the maximum diameter of the fixing means. Shielding means for preventing movement, arranged the holding means at a predetermined position of the external holding body,
Inserting the fixing means into the guide means from outside the shielding means with the shielding means further positioned at a predetermined position of the holding means and the shielding means interposed between the holding means. The optical scanning device is characterized in that the holding means is fixed to the external holding body. 4. A holding means having a hole for fixing to an external holding body, and a fixing means inserted into the hole of the holding means to fix the holding means at a predetermined position of the external holding body. And around the hole of the holding means, parallel to and integrally with an axis passing through the center of the hole of the holding means, the fixing means inserted into the hole with respect to the axis Guide means for preventing undesired tilting and tilting of the fixing means, and an opening having a diameter smaller than the maximum diameter of the fixing means, and the fixing means being moved to the outside of the guide means And a shielding means for preventing the disposition of the holding means at a predetermined position of the external holding body,
Inserting the fixing means into the guide means from outside the shielding means with the shielding means further positioned at a predetermined position of the holding means and the shielding means interposed between the holding means. With the above, the holding means can be fixed to the external holding body, and further, when the fixing means releases the fixing between the holding means and the external holding body,
An optical scanning device, characterized in that the fixing means is prevented from moving to the outside of the guiding means, the fixing means from falling into the holding means, or the fixing means from falling down in the guiding means. 5. A light source for generating light, a deflecting means for deflecting the light from the light source in a predetermined direction, having a rotatably formed reflecting surface, and the light deflected by the deflecting means. An image forming means for forming an image on a predetermined position of an object, a holding means for integrally holding the light source, the deflecting means and the guiding means, a supporting means for supporting the holding means, and a holding means for the holding means. Fixing means for fixing the holding means to the supporting means through a hole formed at a predetermined position, and a diameter slightly larger than the maximum diameter of the fixing means at a position corresponding to the hole of the holding means. And a guide means that is integrally formed with the holding means and that guides the fixing means located in the hole of the holding means so as to be parallel to an axis that passes through the center of the hole. Pass through the center of the hole of the holding means. When the maximum diameter of the fixing means formed in parallel with the axis is d, the fixing means has an opening portion having a diameter D defined so that d> D is satisfied, and is inserted into the hole portion. An optical scanning unit including a shielding unit that prevents the fixing unit from moving to the outside of the holding unit when the fixing unit is separated from the holding unit, and that makes the inside of the holding unit airtight, An image carrier that holds an image corresponding to the light from the light source guided through the deflecting unit and the image forming unit of the optical scanning unit, and the image scanning unit formed on the image carrier by the optical scanning unit. And a developing unit that visualizes the image by supplying a developer to the image.