JP2000267033A - Multi-color image forming device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the occurrence of a color slippage caused by the thermal expansion of a multi-color image forming device without lowering the rigidity of a frame and without reducing the reliability of a correcting action with a structure low in cost and easy to assemble. SOLUTION: When the inside temperature of the device rises, the distance to an image writing device 26-n from an image writing device 26-1 and a distance to an (n)th image carrier 28-n from a 1st image carrier 28-1 are also extended as much as ΔLn in the same direction by the elongation ΔLn of the iron-made main body device frame 12. However, the (n)th image carrier 28-n is inclined with a rotary shaft 36 as an inclination supporting point by the elongation of an expansion correcting member 44 made of DeIrin (R) and the position thereof irradiated with a light beam is deviated as much as ΔLn toward a downstream side in a feeding direction. Thus, a toner image B3' formed by the image writing device 26-n can be aligned and superposed with/on a toner image A' formed by the image writing device 26-1.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electrophotographic multicolor image forming apparatus provided with a plurality of image writing apparatuses and image forming apparatuses, and can prevent color misregistration due to temperature rise with a simple structure. The present invention relates to a multicolor image forming apparatus.

[0002]

2. Description of the Related Art In an electrophotographic multicolor image forming apparatus,
After the power is turned on, the temperature inside the machine gradually increases due to the heat generated inside the machine, and the main frame constituting the mechanical device thermally expands in response to the temperature increase until the temperature is stabilized.

The positions of the exposure means and the image carrier attached to the main frame change for each color.

[0004] As a result, there is a problem that a color shift occurs between the respective colors due to a temperature rise after the image is transferred to the recording medium.

In order to solve this problem, conventionally, a color shift on a recording medium is grasped by using a detecting means, a correction amount is calculated by an operating means, and this value is corrected by, for example, a writing timing. Automatic control for preventing color misregistration (a so-called registration control, hereinafter referred to as a registration control).
I went.

[0006] On the other hand, as a conventional technique which does not use a registration control, there is a technique disclosed in JP-A-1-169466 and a technique disclosed in JP-A-8-62920.

In the former, the linear expansion coefficient (α) of the main frame in the portion where the exposure means is mounted is doubled (α = 2β) with respect to the linear expansion coefficient (β) of the main frame in the portion where the image carrier is mounted. This technology is characterized in that both main frames are supported so that they are parallel to each other, but the difference in expansion is absorbed by the fact that the main frame is integrally formed of two materials having different linear expansion coefficients. There is a problem that it is difficult to achieve the required rigidity as a main frame with a structure at a low cost.

In the latter case, the former is a combination of the exposure means and the image carrier.
The problem of relative misregistration due to thermal expansion occurring between users is considered as a factor of color misregistration, but in addition to these, the linear expansion coefficient (γ) of the material constituting the recording medium itself, In addition to the change in the transport speed due to the change in the radius of the rotating body as a factor of the color shift, each of the linear expansion coefficients (α, β,
This is a technique characterized by being formed of a material having γ).

Both are basically the same technology. Because both implicitly assume that the angular velocity (ω) of the rotating body is constant (ω = constant) regardless of the temperature change, and the former ignores γ, The latter only specifies γ.

The radius of the recording medium rotating body (photosensitive drum) is usually 1/1/3 of the pitch between the recording media or the pitch between the exposure means.
The size is in the range of 4 to 1/5, and the influence on the color shift is correspondingly small. The former is considered to be judged to be a level that can be ignored for color misregistration, and the latter can be said to be a technology that dares to add it.

On the other hand, as another conventional technique which does not use a registration control and exceeds the above two conventional techniques, there is a color shift prevention proposed in Japanese Patent Application No. 10-37579 filed by the present inventors.

According to this technique, there are provided a main body frame, a plurality of image writing devices which are arranged at intervals in one direction with respect to the main body frame and emit a light beam; A plurality of image carriers on which an image is formed by the light beam are disposed at positions different from the image writing device so as to face the image writing device, and provided for each of the image carriers. A plurality of developing means for developing the latent image into a toner image, and a conveying means for conveying the recording medium on which the toner image is transferred in the direction, and a recording medium conveyed in the one direction. In a multi-color image forming apparatus for forming a multi-color image on the recording medium by superimposing and transferring the toner images, the multi-color image forming apparatus is arranged such that the first image writing apparatus positioned most upstream in the recording medium transport direction is below the recording medium. When the distance Ln to the n-th image writing position located on the side changes by ΔLn due to thermal expansion of the main body frame, the n-th image writing device is moved in the one direction by an amount equal to ΔLn. The present invention is applied to a multi-color image writing apparatus by a technique characterized by providing a correcting means for moving the toner image along the direction away from the first image writing apparatus to match the toner image.

The moving means is an expansion compensating member which expands and contracts due to a change in temperature. The mounting length of this member is such that the linear expansion coefficient of the main unit frame is α1, the line of the expansion compensating means is linear. The expansion coefficient is α2, and the expansion correction member measured along the one direction from the connection between the expansion correction means and the nth image writing device to the connection between the movement correction means and the main body frame. When the effective length dimension is X, X = α1 / (α2−α1) ·
Ln is satisfied.

[0014]

The market demand for improving the image quality naturally extends not only to high-priced machines but also to low-priced machines.

As a conventional technique for solving this problem, there is a resisticon, but this technique is expensive and difficult to apply as a technique used for a low-priced small and low-speed machine.

As a low-cost and reliable color misregistration correction technique that satisfies this demand for improvement in image quality, a registration-less technique is required.

As a conventional registrationless technology, Japanese Patent Laid-Open No.
169466 and JP-A-8-62920,
In both cases, the material of the frame on which the main components (image writing device and image carrier) related to the color shift due to thermal expansion are mounted is selected by a combination of materials having a linear expansion coefficient that offsets the color shift. However, when the main frame of the M / C is constructed integrally with a material having a different linear expansion coefficient, it causes a new color shift caused by a bending deformation due to a difference in thermal expansion of the main frame itself. .

In order to avoid this, the structure of the main frame needs to be devised to absorb the difference in thermal expansion of the frame itself.

For example, when aluminum and iron are selected as materials having a linear expansion coefficient doubled, a structure in which the aluminum frame penetrates the iron frame is adopted.
That is, it is necessary to separate the fastening from the iron frame structure by an amount corresponding to the extension of the aluminum to the iron, and to provide an assembling structure for freely expanding the frame structure, which may cause a reduction in frame rigidity.

In addition, this has a practically difficult problem that it is necessary to achieve at a low cost an extensible frame assembly structure due to a difference in thermal expansion without reducing the frame rigidity.

It is important for a multicolor image forming apparatus to eliminate color misregistration for improving the image quality. Among the color misregistration elements, the main scanning direction misalignment, the main scanning magnification misalignment, and the main scanning skew misalignment. Regarding color misregistration such as (Skew) and main scanning direction curvature misregistration (Bow), color accuracy can be improved by improving the accuracy of parts, improving the device configuration, and assembling accuracy without using expensive registration control technology for low-cost small machines. Although it is expected that the misregistration can be eliminated, among the misregistration elements, the color misregistration in the sub-scanning direction (paper transport direction) is directly affected by the thermal expansion for each color of the image. It has been a difficult problem to achieve this at low cost without using a resin con.

However, as another technique for solving this problem without using a register, there is color shift prevention proposed in Japanese Patent Application No. 10-37579 described above. This means that the image writing device attached to the main unit frame is pushed and pulled in the sub-scanning direction on the main unit frame by the linear expansion force of the expansion correction member, which is a movement compensating unit for the position of the image writing unit. By moving the image, the color misregistration of the multicolor image is corrected.

However, this technique has the following operational concerns.

This is because a case where the frictional force of the sliding portion exceeds the linear expansion force of the expansion compensating member can be considered in terms of design quality, assembly quality, or when the friction coefficient of the sliding portion changes over time.

Of these, the following three color shift occurrence cases are conceivable except for the case of design quality.

In the first case, dust is liable to change the friction coefficient of the sliding surface over time due to dust and rust, and to increase the sliding load resistance due to the adsorption phenomenon between the sliding surfaces. When the frictional force exceeds the linear expansion force of the expansion correction member, the image writing device cannot move to a predetermined correction position, and color shift occurs.

In the second case, there is a problem of proper control of the fastening force of a mounting screw for slidably mounting the image writing device to the main body frame. In this case, the vertical stress on the sliding portion friction surface becomes too large, and the frictional force of the sliding portion exceeds the linear expansion force of the expansion correcting member. Color shift occurs due to the inability to move to the position.

In the third case, the image writing device can be moved in the respective transient cases of the first case and the second case, but the movement lacks smoothness and the breathing phenomenon occurs. When the breathing occurs, the image writing device cannot move to the predetermined correction position, and a color shift occurs.

In consideration of the above facts, the present invention prevents color misregistration caused by thermal expansion of the multicolor image forming apparatus without lowering the frame rigidity, and has no concern about the reliability of the correction operation at low cost. Moreover, it is intended to achieve the structure with an easily assembled structure.

[0030]

First, the process leading to the present invention will be described.

FIG. 1 shows a multicolor image forming apparatus 10 according to the present invention for obtaining a multicolor image by a plurality of image writing apparatuses.
Is described.

The main unit frame 12 has a linear expansion coefficient α.
It is composed of the material designated as ₁ .

Reference numeral 26-1 denotes a first image writing device which is arranged at the most upstream side in the paper transport direction and writes an image first, and 2-n writes an image n-th. This is the n-th image writing device.

It should be noted that the image writing device in the intermediate portion between the first and the n-th is not shown.

The upper stage 18 of the main unit frame 12 extends in the sheet transport direction (the direction of arrow A).
8, a first image writing device 26-1 to an n-th image writing device 26-n are arranged.

In the middle stage 20 of the main body frame 12, an arrow CW is provided immediately below the first image writing device 26-1.
Image carrier 28 which is a photosensitive drum rotating in
1, and an n-th image carrier 28-n is disposed immediately below the n-th image writing device 26-n.

Here, first, the first image writing device 26
-1 from the first image carrier 28
-1 is formed on the latent image A, and the latent image A is transported by the transport belt 30A after development by the developing device 27 (not shown).
Is transferred to a toner image A ′.

Similarly, the n-th image writing device 26-n
Image carrier 28-n by the light beam emitted from
Latent image B ₁ is formed in a sheet having the latent image B ₁ is carried by the conveyor belt 30A after development by the developing device 27 (not shown)
To a toner image B ₁ ′ (a color different from the toner image A ′).

[0039] In the multi-color image forming apparatus 10, paper (not shown) toner image B ₁ after the distance Ln moving at a velocity V _o '
Is set so that the image is transferred so as to be superimposed on the toner image A ′, and a multicolor image without color shift is formed.

However, there is a problem that the relationship without the color shift causes a change in the initial setting due to a temperature change due to heat generation or heat radiation inside the device, and a color shift occurs.

Normally, if the power-on state is continued, the temperature of many of the mechanical devices rises, so the following description will be made in the case of rising, but the invention of the present technology includes the case of falling. Needless to say.

Now, the temperature rise T (° from the initial setting state)
Due to C), the distance Ln between the image writing devices and between the image carriers increases by ΔLn (= Ln · α ₁ · T).

The latent image B ₂ which is formed at the n-th image writing apparatus 26-n that moved by the sheet conveyance direction ΔLn than before the temperature rise, the image carrier of the n drawn with two-dot chain lines in FIG. 1 28-n, and is transferred to the leading end side (downstream in the sheet conveyance direction) of the sheet (not shown) at a timing earlier by the distance ΔLn than the toner image A ′ as shown in the toner image B ₂ ′. , A color shift corresponding to the distance ΔLn between the toner image A ′ and the toner image A ′.

Here, the conventional technology (Japanese Patent Application No. 10-3775) is disclosed.
No. 9), the n-th image writing device 26-n is slid to the downstream side in the sheet conveyance direction due to thermal expansion of the member, and
The method of eliminating the color shift by shifting the transfer timing of the toner image by the image writing device 26-n described above is used. However, because of the above-described problem, the inventor has made various studies and found that It has been found that the irradiation position of the light beam is shifted by inclining the n image writing device, whereby the transfer timing of the toner image can be shifted to eliminate the color shift.

In FIG. 1, reference numeral 44 denotes the n-th image writing device 26.
-N is an expansion correction member that inclines the position of the light beam emitted from the n-th image writing device 26-n using thermal expansion.

Here, the first image writing device 26-1
Is fixed so as to be relatively immovable with respect to the upper stage 18 of the main frame 1.

On the other hand, the other image writing device, the n-th image writing device 26-n in FIG. 1, has the upstream side in the sheet conveyance direction supported by the rotating shaft 36 and the downstream side in the sheet conveyance direction supported by the expansion correcting member 44. Due to the thermal expansion of the expansion correcting member 44, the n-th image writing device 26-n can rotate (swing) with the rotation shaft 36 stopped.

Here, the reference image writing device 26
The distance from -1 to the n-th image writing device 26-n is Ln, the coefficient of linear expansion of the main unit frame 12 is α1,
The length of the expansion correction member 44 provided in the n-th image writing device 26-n is D, and the expansion coefficient of the expansion correction member 44 is α.
2. The distance from the rotation shaft 36 to the expansion correction member 44 is W,
H is the distance from the rotation axis 36 to the irradiation position of the light beam on the image carrier 28-n, and it is necessary to form a latent image on the image carrier 28 at a distance ΔLn in the paper conveyance direction. Assuming that the inclination angle of the n-th image writing device 26-n is θ, the following relational expression (1) holds between them.

For example, here, the temperature rise t is 20 ° C.,
The main body frame 12 is iron, and the pitch of the image carrier 28 is 1
In the case of 00 mm, ΔLn = Ln · α1 · t = 100 · 1.17 × 10 ⁻⁵ · 20 = 23 μm When H = 100 mm, the inclination angle θ of the image writing device is θ = tan ⁻¹ ( ΔLn / H) = tan ⁻¹ 2.3 × 10 ⁻⁴ = 0.013 ° = π × 0.013 / 180 rad = 2.27 × 10 ⁻⁴ rad≪1 Therefore, θ is sufficiently smaller than 1. And the following equation holds.

Θ = tan ⁻¹ (ΔLn / H) ≒ ΔLn / H≪1 Further, since θ = tan ⁻¹ (ΔD / W) ≒ ΔD / W≪1, ΔD / W = ΔLn / H. ΔD = ΔLn · W / H D · α2 · t = Ln · α1 · t · W / HD D = Ln · (α1 / α2) · (W / H) (1)

Therefore, assuming that the main body frame 12 is iron (α1 = 1.17 × 10 ⁻⁵ ), the expansion correcting member 44 is delrin (α2 = 8.1 × 10 ⁻⁵ ), and W = H, D ≒ (1/8) Ln.

That is, the required length D of the expansion correction member 44 is
The length can be configured to be about 1/8 of the distance Ln from the reference image writing device 26-1 to the n-th image writing device 26-n. This length is sufficiently small so that there is no problem in designing it as a component of the multicolor image forming apparatus.

Further, since the load of the image writing device 26-n is received at two places, the expansion correction member 44 and the rotating shaft 36, half of the load of the image writing device 26-n is applied to the expansion correction member 44. The expansion correction member 4
The load applied to the thermal expansion of No. 4 is reduced, and the load is smaller than in the prior art, and the operation is stable.

The present invention has been made in view of the above facts.

According to the first aspect of the present invention, there is provided a main body device frame, a plurality of image writing devices which are arranged at an interval from the main body device frame in one direction and emit a light beam, A plurality of image carriers on which a latent image is formed by the light beam are arranged at a position different from the image writing device of the device frame so as to face the image writing device, and for each of the image carriers. A plurality of developing units provided to develop the latent image into a toner image; and a conveying unit that conveys the recording medium on which the toner image is transferred along the one direction, and is conveyed along the one direction. A multi-color image forming apparatus for forming a multi-color image on the recording medium by superimposing and transferring each toner image onto the recording medium, wherein the multi-color image forming apparatus is configured to transfer a recording medium from a reference image writing apparatus. When the distance Ln to the n-th image writing device located downstream side or upstream side, that ΔLn changed by thermal expansion of the main device frame,
The n-th frame is formed by extending an adjustment mechanism provided on the other mounting portion of the main body device frame in a direction of coming into contact with and separating from a reference portion of the main body device frame, with one mounting portion of the main body device frame as an inclined fulcrum. The n-th image writing device is tilted, and the irradiation position of the light beam emitted from the n-th image writing device on the n-th image carrier is shifted along the recording medium transport direction by a size equal to the ΔLn. And an inclination correcting means for moving the toner image in a direction away from the reference image writing apparatus so as to match the respective toner images, to the n-th image writing apparatus.

Next, the operation of the multicolor image forming apparatus according to the first aspect will be described.

In the multicolor image forming apparatus according to the first aspect,
The light beam emitted from the image writing device is irradiated on the image carrier, and a latent image is formed on the image carrier. This latent image is developed by a developing unit to become a toner image.

This toner image is transferred to a recording medium conveyed by the conveying means.

The recording medium is conveyed in one direction, and a plurality of toner images are sequentially superimposed to form a multicolor image.

Here, as in the prior art, in the initial setting of the assembly, the toner image formed by the n-th (two or more) image writing device is replaced by the toner image formed by the first image writing device formed on the conveyed recording medium. The interval between the image writing devices or the interval between the image carriers is mechanically fine-tuned or the writing timing of the image writing device is finely electrically adjusted so that the image writing device overlaps with the position of the image. In addition,
After the adjustment, the write timing is not changed.

By the way, if all the image writing devices are fixed to the frame of the main device, if the temperature change T (° C.) occurs due to the subsequent heat generation in the device, the linear expansion coefficient is α ₁ . For example, the distance Ln between the first image writing device and the nth image writing device, the image carrier facing the first image writing device, and the nth image writing device attached to the main frame. Is equal to ΔLn
(= Ln · α ₁ · T).

Therefore, when the temperature rises by T (° C.), the n-th image writing device moves away from the first image writing device by ΔLn, and similarly, the n-th image writing device moves. Is moved farther by ΔLn from the image carrier facing the first image writing device.

The toner image formed by the n-th image writing device and the image carrier facing the n-th image writing device located farther from the first image writing device by ΔLn, if the conveying means does not expand or contract due to a temperature change. .DELTA. On the downstream side in the conveyance direction from the toner image by the first image writing device.
The image is transferred to the recording medium with a shift of Ln, resulting in a color shift.

On the other hand, according to the present invention, when the temperature rises by T (° C.), the movement correction means moves the n-th image writing device by a size equal to ΔLn to the main unit frame. Move in the same direction of expansion and contraction.

Therefore, the n-th image writing device has moved farther from the first image writing device by 2ΔLn, and the image carrier corresponding to the n-th image writing device has a recording medium. Is located at a position shifted by ΔLn to the downstream side in the transport direction.

For this reason, the toner image obtained by developing the latent image formed on the image carrier by the n-th image writing device is ΔLn (the position of the n-th image writing device and the n-th image writing device). Transfer timing time (ΔL) corresponding to the difference from the position of the image carrier corresponding to the image writing device)
n is transferred to the recording medium with a delay of n times. When the recording medium advances by a distance ΔLn from the position of the distance Ln from the first image writing device,
The toner image by the n-th image writing device is coincident with and overlaps the position of the toner image by the first image writing device, and color shift can be eliminated.

According to a second aspect of the present invention, in the multicolor image forming apparatus according to the first aspect, the extension of the adjustment mechanism is caused by thermal expansion.

Next, the operation of the multicolor image forming apparatus according to the second aspect will be described.

In the multicolor image forming apparatus according to the second aspect,
As the temperature of the main unit frame rises, the adjustment mechanism also extends due to the rise in temperature, and the extension causes the n-th image writing device to tilt. Then, the irradiation position of the light beam on the image carrier corresponding to the n-th image writing device moves by an amount equal to the extension of the frame of the main unit, and the image writing device based on the toner image by the n-th image writing device is used as a reference. , And overlap with the position of the toner image, thereby eliminating color shift.

According to a third aspect of the present invention, in the multicolor image forming apparatus according to the second aspect, a linear expansion coefficient of the adjusting mechanism is larger than a linear expansion coefficient of the main body frame. And

Next, the operation of the multicolor image forming apparatus according to the third aspect will be described.

In the multicolor image forming apparatus according to the third aspect,
Since the linear expansion coefficient of the adjusting mechanism is larger than the linear expansion coefficient of the main body frame, the amount of expansion of the adjusting mechanism when the temperature rises can be increased. For this reason, it is possible to reduce the size of the adjustment mechanism and, consequently, the size of the multicolor image forming apparatus.

If the adjusting mechanism is lengthened, the amount of extension of the adjusting mechanism when the temperature rises can be increased, but the size of the apparatus increases.

According to a fourth aspect of the present invention, in the multicolor image forming apparatus according to the second or third aspect, the distance from the reference image writing apparatus to the n-th image writing apparatus is Ln, The linear expansion coefficient of the main body frame is α1, the length of the adjusting mechanism provided in the n-th image writing device in the extending direction is D, the linear expansion coefficient of the adjusting mechanism is α2, When the distance to the adjustment mechanism is W and the distance from the tilt fulcrum to the irradiation position of the light beam on the image carrier is H, D =
Ln · (α1 / α2) · (W / H).

Next, the operation of the multicolor image forming apparatus according to the fourth aspect will be described.

In the multicolor image forming apparatus according to the fourth aspect,
The distance from the reference image writing device to the n-th image writing device is Ln, the linear expansion coefficient of the main unit frame is α1, the extension direction of the adjusting mechanism provided in the n-th image writing device. , The linear expansion coefficient of the adjustment mechanism is α2, the distance from the tilt fulcrum to the adjustment mechanism is WO, and the distance from the tilt fulcrum to the light beam irradiation position on the image carrier is H. Since D = Lnｎ (α1 / α2) ・ (W / H) is satisfied, the toner image by the reference image writing device and the toner image by the n-th image writing device can be reliably determined. Can be overlapped with each other, and color shift can be eliminated.

According to a fifth aspect of the present invention, in the multi-color image forming apparatus according to any one of the first to fourth aspects, the adjusting mechanism is configured to control the recording medium transport direction of the image writing device to be different from the recording medium transport direction. The inclined fulcrum is provided at two places on both sides in a direction intersecting with the recording medium transport direction of the image writing device, and the image writing device is provided with: It is characterized in that it is supported at three points with respect to the main unit frame, namely, one adjusting mechanism and two inclined fulcrums.

The operation of the multicolor image forming apparatus according to claim 5 will be described.

In the multicolor image forming apparatus according to the fifth aspect,
Since the image writing device is supported at three points with respect to the main unit frame, the image writing device can be attached to the main unit frame with a minimum number of members.

Further, in the frame of the main body device, the number of receiving portions of the image writing device is required and sufficient enough at three places, and the flatness (position accuracy) of these mounting portions is determined by the image writing device after the image writing device is mounted. (Generally, since the main body frame serving as the basic skeleton has high rigidity, the image writing device side is more easily deformed than the main body frame).

According to a sixth aspect of the present invention, in the multicolor image forming apparatus according to any one of the first to fifth aspects, the adjusting mechanism intersects a recording medium conveying direction of the image writing device. The tilt fulcrum is provided at two places on both sides in a direction intersecting with the recording medium conveying direction of the image writing device, and the image writing device is provided with the main unit. It is characterized in that the frame is supported at four points: two adjusting mechanisms and two inclined fulcrums.

Next, the operation of the multicolor image forming apparatus according to claim 6 will be described.

In the case where the image writing apparatus is supported by a total of three support portions including one adjusting mechanism and two inclined fulcrums as in the multicolor image forming apparatus according to the fifth aspect, If the center of gravity of the image writing device is located outside the triangle connecting the three support portions, the stability of supporting the frame of the main body device is deteriorated, and the stability against vibration is reduced.

On the other hand, the adjusting mechanism is provided at two places on both sides in the direction intersecting the recording medium transport direction of the image writing apparatus, and the tilt fulcrum is provided at two places on both sides in the direction intersecting the recording medium transport direction of the image writing apparatus. When the image writing device is supported at four points with respect to the main body frame near the four corners, the bending distortion of the image writing device after the image writing device is attached due to the flatness (position accuracy) of the mounting portion of the main body frame. Is less than three-point support,
The center of gravity of the image writing device can be arranged inside a quadrangle formed by four points of the mounting portion, and the stability of the image writing device against vibration can be improved.

According to a seventh aspect of the present invention, in the multicolor image forming apparatus according to any one of the first to sixth aspects, in the image writing apparatus provided with the tilt fulcrum and the adjusting mechanism, The tilt fulcrum is located closer to the reference image writing device than the adjustment mechanism.

Next, the operation of the multicolor image forming apparatus according to the present invention will be described.

When the tilt fulcrum is arranged closer to the reference image writing apparatus than the adjustment mechanism, an adjustment mechanism for tilting the image writing apparatus when the main body frame thermally expands is provided between the main body frame and the image writing apparatus. The image writing device can be tilted by increasing the distance between the main unit frame and the image writing device by expanding the adjustment mechanism.

Therefore, in the case of a configuration in which the image writing device is arranged on the main body frame, the image writing device is adjusted upward as the temperature rises. This is a configuration in which the assemblability is improved for a multicolor image forming apparatus having a mechanical structure in which the image writing device is mounted on the main body frame from above.

[0089]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [First Embodiment] A first embodiment of a multicolor image forming apparatus according to the present invention will be described with reference to FIGS.

FIG. 1 shows a multicolor image forming apparatus 1 according to this embodiment.
It is a front view which shows the schematic structure of No. 0. The multicolor image forming apparatus 10 includes a main body frame 12.

The main unit frame 12 includes a pair of side plates 1.
4, 16 and a plate-shaped upper stage 18, a middle stage 20 and a lower stage 22 for connecting the side plates 14 and 16 to each other. The upper stage 18, the middle stage 20, and the lower stage 22 are arranged horizontally.

In the upper part 18, a plurality of image writing devices 26-1 to 26-n are sequentially arranged in the direction of arrow A.
Is installed. Note that the illustration of the image writing device in the intermediate portion between the image writing device 26-1 and the image writing device 26-n is omitted.

The image writing device 26-1 is arranged at the most upstream side in the sheet transport direction (the direction of arrow A), and in the first embodiment, an image serving as a reference for writing an image first. It is a writing device.

Each of the image writing devices 26-1 to 26-n includes an image carrier 28-1 described below.
To perform main scanning of the light beam toward the image carrier 28-n (the main scanning direction is the axial direction).

The image carriers 28-1 to 28-n are
They are arranged in the direction of arrow A in the middle stage 20 and are located immediately below the image writing devices 26-1 to 26-n.

Each of the image carriers (so-called photosensitive drums) 28-1 to 28-n has a cylindrical shape with a radius r, and has a constant angular velocity (ω) in the direction of arrow CW by independent motors (not shown). ).

The image bearing members 28-1 to 28-
A developing device 27 that develops the latent image formed on the outer peripheral surface to form a toner image is opposed to each of n.

[0098] Between the middle stage 20 and the lower stage 22, a conveying means 30 having an endless paper conveying belt 30A is arranged. The upper surface of the paper transport belt 30A is horizontal,
It is a transport surface for paper (not shown).

The reference image writing device 26-1 is:
As shown in FIG. 2, the upper stage 18 is fixed with bolts 34.

On the other hand, the reference image writing device 26-
1, the image writing devices 26-n (the others are not shown) in FIG. 1 are attached to the upper stage 18 as follows.

That is, both ends of the image writing device 26-n in the direction (main scanning direction of the light beam; the paper conveying direction is the sub-scanning direction) orthogonal to the paper conveying direction on the upstream side in the paper conveying direction. The rotating shaft 36 is fixed to the.

The rotary shaft 36 is inserted into a bearing 38 provided on the upper stage 18. Therefore, the image writing device 26-n can rotate (swing) about the rotation shaft 36.

In the image writing device 26-n, a projection 40 is provided at a central portion in a direction orthogonal to the sheet conveyance direction on the downstream side in the sheet conveyance direction. It is in contact with the upper surface of a cylindrical expansion correction member 44 mounted on the surface 42.

The center of the rotary shaft 36 is located on a horizontal extension of the reference plane 42.

Here, the screw portion (not shown) of the bolt 46 penetrating the projection 40 and the expansion correcting member 44 is
And is fixed to the head 46 of the bolt 46.
A compression coil spring 48 is interposed between A and the projection 40.

This compression coil spring 48
0 is firmly pressed against the expansion correction member 44 so as not to rattle.

With this configuration, when the expansion compensating member 44 expands in size due to thermal expansion, the compression coil spring 48 contracts, and the image writing device 26-n rotates (swings) a little about the rotation shaft 36, that is, tilts. Will do.

In the case where the pitch P between the image writing devices is 200 mm, for example,
When four image writing devices are provided (n = 4), the center-to-center distance L2 (Px) from the image writing device 26-1 to the second image writing device 26-2 (not shown) on the downstream side in the sheet transport direction. 1) 200 mm, image writing device 26
-1 to a third image writing device 26-3 (not shown) on the downstream side in the sheet transport direction L3 (P ×
2) is 400 mm, and the center distance L4 (P × 3) from the image writing device 26-1 to the fourth image writing device 26-3 (not shown) on the downstream side in the sheet conveyance direction is 600 mm.

The main body frame 12 is made of iron.
The material of the expansion correction member 44 is delrin resin (polyacetal).

In each of the image writing devices 26-2 to 26-4, the dimension W from the rotation shaft 36 measured along the sheet transport direction (horizontal direction) to the expansion correction member is 126.
mm.

The reference plane 4 passing through the center of the rotating shaft 36 from each light beam irradiation position of the image carriers 28-1 to 28-n.
The distance H to the horizontal extension line 2 is 126 mm.

FIG. 3 shows the temperature rise T of the apparatus, the distance Ln between the centers of the image writing apparatuses, the expansion of delrin, aluminum, and the expansion of the delrin, and the expansion correction members (dellin and aluminum) for preventing image displacement. The required length relationship is shown.

From this, as described above, Ln is 200 mm,
In the case of 400 mm and 600 mm, the length D-2 of the expansion correction member 44 of the second image writing device 26-2 (not shown) is 29 mm, and the third image writing device 26-3.
The length D-3 of the expansion correction member 44 (not shown) is 58 m.
m, it can be seen that the length D-4 of the expansion correction member 44 of the fourth image writing device 26-4 (not shown) should be 87 mm.

Next, the operation of the present embodiment will be described.

First, the transport means 30 is driven, and the paper (not shown) mounted on the upper surface of the paper transport belt 30 is transported in the direction of arrow A at a constant speed V ₀ (= rω).
The image writing devices 26-1 to 26-n are rotated at a constant angular velocity (ω) in the direction of the arrow CW (see FIG. 1).

On the other hand, the light beams emitted from the image writing devices 26-1 to 26-n form latent images on the image carriers 28-1 to 28-n. The toner image is developed at 27 and is transferred to a sheet (not shown) conveyed by the sheet conveying belt 30A.

For example, as shown in FIG.
A latent image A is formed at -1. The latent image A is developed by the developing device 27 to become a toner image A ', which is transferred to a sheet (not shown) conveyed by the sheet conveying belt 30A.

Similarly, a latent image B is formed on the n-th image carrier 28-n, which is developed to form a latent image B.
To form a toner image B ′.

When a sheet (not shown) is conveyed in the direction of arrow A, a toner image B 'is superimposed on a toner image A' on the sheet (not shown).

[0120] That is, in the multi-color image forming apparatus 10, paper (not shown) is a second toner image after the distance P (= 200 mm) moving at a velocity V _o is transferred superposed right above the toner A ' Similarly, the initial setting is such that the third toner image is assembled so as to be transferred directly over the toner image A ′ and the second toner image after being moved by the distance P (= 200 mm). No multicolor image is formed.

Next, the internal temperature of the multi-color image forming apparatus 10 rises, and the iron main body frame 12 is uniformly T (°).
C) For example, it is assumed that the temperature rises by 10 ° C.

Thus, the image writing devices 26-1 to 26-1
The distance (P) of the second image writing device 26-2 (not shown) extends by 23 μm, and
The distance (2P) of the second image writing device 26-3 (not shown) extends 47 μm,
The distance (3P) of the fourth image writing device 26-4 (not shown) increases by 70 μm.

Similarly, the center-to-center distance between the image carriers 28-1 and 28-2 (not shown) is also extended by 23 μm, and the image carriers 28-1 to 28-3 are the same. 3 (not shown) also extends 47 μm, and the image carrier 28-
The center-to-center distance between the first to fourth image carriers 28-4 (not shown) also increases by 70 μm, and the corresponding image writing devices 26
It moves in the same direction as the first to fourth image writing devices 26-4.

On the other hand, the size of the expansion correcting member 48 made of Delrin resin also increases due to the temperature rise (10 ° C.), and the size D is 3 μm in the second image writing device 26-2 (not shown).
3rd image writing device 26-3 (not shown)
, The dimension D is increased by 6 μm, and the fourth image writing device 2
6-6 (not shown), the dimension D is elongated by 9 μm, whereby the image writing devices 26-1 to 26-4 are tilted by the tilt angle θ corresponding to the expansion of the respective expansion correction members 48, and thereby the light beam Irradiation position on the image carrier is 2
In the second image carrier 28-2, the downstream side in the sheet transport direction is 23
.mu.m, the third image carrier 28-3 moves by 47 .mu.m downstream in the sheet conveyance direction, and the fourth image carrier 28-4 moves by 70 .mu.m downstream in the sheet conveyance direction.

Here, in FIG. 1, the image carrier 28-n indicated by a solid line indicates the position before the temperature rise, and the image carrier 28-n indicated by the two-dot chain line indicates the position shifted after the temperature rise. Is shown.

Further, in FIG. 1, the line CL is
Indicates the exit position of the ₁Before the temperature rise
The emission position is shown.

Further, CL ₂ indicates the emission position when only the upper stage 18 expands, and CL ₃ indicates the expansion correcting member 44.
Also shows the emission position when expanded.

Assuming that there is no thermal expansion of the transporting means 30, and if each part of the apparatus (the main unit frame 12, the expansion correction member 44, etc.) thermally expands due to temperature rise, for example, the light beam of the n-th image writing device 26-n is It is emitted at the position of the CL ₃ of Figure 1, the image bearing member 28 the light beam is indicated by a two-dot chain line
Irradiated (scanning exposure) in -n, the latent image B ₃ is formed.

For example, the second image writing device 26-
In the case of 2, the latent image B ₃ is formed on the side opposite to the rotation direction by a dimension corresponding to the elongation of 23 μm as compared to before the temperature rise.

Therefore, the toner image B ₃ ′, in which the latent image B ₃ has been developed, is delayed by the transfer timing time corresponding to the elongation of 23 μm (the time to move 23 μm) (compared to before the temperature rise) on the paper ( (Not shown).

For this reason, the paper (not shown) is located at a position 200 mm away from the image writing device 26-1 in the direction of arrow A (the position of the image writing device 26-2 before the temperature rise).
Is advanced by a distance of 23 μm, the toner image B ₃ ′ coincides with and overlaps the position of the toner image A ′, and color shift can be eliminated.

On the basis of the same principle, the toner images on the other image carriers 28 also coincide with each other, and a multicolor toner image without color shift can be obtained.

Further, in this embodiment, since the image writing device 26-n is supported at three points with respect to the main body frame 12, the image writing device 26-n can be mounted on the main body frame 12 with a minimum number of members. Can be attached.

Further, in the main frame 12, the number of the receiving portions of the image writing device 26-n is required and sufficient at three, and the flatness (position accuracy) of these mounting portions is sufficient.
However, it can be avoided that this causes bending distortion of the image writing device 26-n after the image writing device 26-n is attached.

In this embodiment, one of the image writing devices 26-n is rotatably supported by the rotation shaft 36, and the other is moved by the expansion correcting member 44, thereby tilting the image writing device 26-n. For this reason, only half of the load of the image writing device 26-n is applied to the expansion correction member 44, the resistance when the expansion correction member 44 expands is extremely small, and the image writing device 26-n is reliably moved with the temperature rise. Can be tilted. [Second Embodiment] Next, a multicolor image forming apparatus according to a second embodiment of the present invention will be described with reference to FIGS.
The same components as those of the first embodiment are denoted by the same reference numerals,
The description is omitted.

In the first embodiment, the image writing device 26-1 which is the most upstream in the paper transport direction is fixed to the main body frame 12 with reference to the other image writing devices 26 downstream in the paper transport direction when the temperature rises. −n is the expansion correction member 4
4, the present invention is not limited to this. As shown in FIGS. 4 and 5, the temperature is fixed to the main unit frame 12 based on the image writing device 26-m in the middle of the sheet conveyance direction. Sometimes, the image writing device 26-n on the downstream side in the paper transport direction and the other image writing device 26-n on the upstream side
mk can also be tilt-corrected by the expansion correction member 44.

In the case of such a configuration, the other image writing devices 26-n downstream of the reference intermediate image writing device 26-m in the sheet conveyance direction have the same configuration as that of the first embodiment. However, the configuration of the other image writing devices 26-mk upstream of the reference intermediate image writing device 26-m in the paper transport direction is reversed.

The configuration of another image writing device 26-mk upstream of the reference intermediate image writing device 26-m in the sheet conveyance direction will be described below.

The reference intermediate image writing device 26-
other image writing device 2 on the upstream side in the paper transport direction from
In 6-mk, as shown in FIG.
6 is disposed on the downstream side in the sheet conveying direction, and the expansion correcting member 44
Is disposed on the upstream side in the sheet transport direction.

With this configuration, when the temperature rises, the image writing device 26-n on the downstream side in the paper transport direction performs the same correction operation as in the first case, while the image writing device 26-n on the upstream side in the paper transport direction is performed. mk is inclined in the direction opposite to the image writing device 26-n on the downstream side in the paper transport direction, and the irradiation position of the light beam on the image carrier 28-mk is ΔLm-k toward the upstream side in the paper transport direction. (correction amount) deviation, corrects so that the image writing device 26-m in the resulting toner image a 'and an image writing device 26-m-k toner images C ₃ obtained' match. Third Embodiment Next, a third embodiment of the multicolor image forming apparatus of the present invention will be described with reference to FIGS.
The same components as those of the above-described embodiment are denoted by the same reference numerals, and description thereof will be omitted.

In the first and second embodiments, the lower surface of the projection 40 of the image writing device 26-n is brought into contact with the upper surface of the expansion correction member 44 attached to the upper part of the upper stage 18, and the expansion correction member When the thermal expansion of the protrusion 44 is performed, the protrusion 40 is moved upward, thereby tilting the image writing device 26-n. However, the present invention is not limited to this, and as shown in FIGS. The positions of the rotation shaft 36, the expansion correction member 44, and the protrusion 40 are reversed with respect to the form.
The lower part of the expansion compensating member 44 is brought into contact with the upper surface of the expansion compensating member 44, and the upper portion of the expansion compensating member 44 is brought into contact with the lower surface of the supporting member 50 provided on the upper stage 18 and supported by bolts 46.
When the is thermally expanded, the projection 40 is moved downward, whereby the image writing device 26-n can be inclined in the same manner as in the first embodiment. [Fourth Embodiment] Next, a fourth embodiment of the multicolor image forming apparatus of the present invention will be described with reference to FIG. The same components as those of the above-described embodiment are denoted by the same reference numerals, and description thereof will be omitted.

In the above-described embodiment, the image writing device 26 is supported by the upper stage 18 at three points: two rotating shafts 36 and one expansion correction member 44.
The expansion correction member 44 is provided at two places on both sides, and is supported on the upper stage 18 at four points.

For this reason, the image writing device 26 depends on the flatness (position accuracy) of the mounting portion of the main frame 12.
After the attachment of -n, the bending strain of the image writing device 26-n is less than three-point support. This makes it possible to dispose the image writing device 26-n, thereby improving the stability of the image writing device 26-n against vibration. (Other Embodiments) In the above embodiment, an example was described in which iron was used for the main body frame 12 and delrin was used for the expansion correction member 44. Of course, it may be used. For example, aluminum can be used for the expansion correction member 44. Dimension D for expansion compensation member 44 using aluminum
Is as shown in FIG.

In order to shorten the dimension D, it is preferable to use a material having a larger coefficient of linear expansion than that of the main body frame 12 for the expansion correcting member 44. This is because D = Ln · (α1 / α2) · (W / H)
It is clear from the relationship.

In the above embodiment, the image writing device 26-n is tilted with the rotation shaft 36 as a tilt fulcrum.
Even if the temperature rises by about 20 ° C., the actual angle of inclination of the image writing device 26-n is, for example, 0.0 °.
This is an extremely small angle of about 013 °.

Therefore, such an extremely small angle does not need to be a mounting structure having a complete rotating shaft mechanism as shown in the embodiment, and for example, even if it is a normal screwing structure, it is easily inclined. Any supporting structure (e.g., knife edge, piped, etc.) may be used as long as it has sufficient rigidity to achieve the purpose of correcting color misregistration with good reproducibility.

[0147]

As described above, according to the present invention,
Prevention of color misregistration due to thermal expansion of the multicolor image forming apparatus can be achieved without lowering the frame rigidity, and with a low-cost and easy-to-assemble structure without concern about the reliability of the correction operation. It has an excellent effect.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of a multicolor image forming apparatus according to a first embodiment of the present invention.

FIG. 2 is a plan view of the multicolor image forming apparatus shown in FIG.

FIG. 3 is a table showing a relationship among a temperature rise, a distance, an elongation, and a required length of a correction member.

FIG. 4 is a schematic configuration diagram of a multicolor image forming apparatus according to a second embodiment of the present invention.

FIG. 5 is a plan view of the multicolor image forming apparatus shown in FIG.

FIG. 6 is a schematic configuration diagram of a multicolor image forming apparatus according to a third embodiment of the present invention.

FIG. 7 is a plan view of the multicolor image forming apparatus shown in FIG.

FIG. 8 is a schematic configuration diagram of a multicolor image forming apparatus according to a fourth embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Multicolor image forming apparatus 12 Main body apparatus frame 26 Image writing apparatus 27 Developing device (developing means) 28 Image carrier 30 Conveying means 36 Rotation axis (inclined fulcrum) 42 Reference plane (reference section) 44 Expansion correction member (adjustment mechanism)

Claims (7)

[Claims] 1. A main body frame, a plurality of image writing devices arranged at one interval from the main body frame and emitting a light beam, and the image writing device of the main body frame A plurality of image carriers on which a latent image is formed by the light beam, which is disposed at a position different from the image writing device, and which is provided for each of the image carriers and develops the latent image. A plurality of developing means for converting the toner image into a toner image, and a conveying means for conveying the recording medium on which the toner image is transferred in the one direction. A multi-color image forming apparatus for forming a multi-color image on the recording medium by superimposing and transferring images, wherein the multi-color image forming apparatus is downstream or upward in a recording medium transport direction from a reference image writing apparatus When the distance Ln to the n-th image writing device located on the side changes by ΔLn due to the thermal expansion of the main body device frame, one of the mounting portions of the main body device frame is used as an inclined fulcrum, and the other of the main body device frame The n-th image writing device is tilted by extending an adjusting mechanism provided on the attachment portion in a direction to come into contact with and separate from the reference portion of the main body device frame, and is emitted from the n-th image writing device. The irradiation position of the light beam on the n-th image carrier is moved in the direction away from the reference image writing device along the recording medium transport direction by a size equal to the ΔLn, and the respective toner images are moved. A multicolor image forming apparatus, characterized in that a tilt correcting means for matching is connected to the n-th image writing device. 2. The multicolor image forming apparatus according to claim 1, wherein the extension of the adjustment mechanism is caused by thermal expansion. 3. The multicolor image forming apparatus according to claim 2, wherein a linear expansion coefficient of the adjustment mechanism is larger than a linear expansion coefficient of the main body device frame. 4. The distance from the reference image writing device to the n-th image writing device is Ln, the linear expansion coefficient of the main unit frame is α1, the adjustment provided in the n-th image writing device. The length of the mechanism in the extension direction is D, the linear expansion coefficient of the adjustment mechanism is α2, the distance from the tilt fulcrum to the adjustment mechanism is W, the irradiation position of the light beam on the image carrier from the tilt fulcrum. The multicolor image forming apparatus according to claim 2, wherein, when the distance to H is H, D = Ln · (α1 / α2) · (W / H) is satisfied. 5. The image forming apparatus according to claim 1, wherein the adjusting mechanism is provided at a central portion of the image writing device in a direction intersecting with the recording medium conveying direction, and the tilt fulcrum is provided in the recording medium conveying direction of the image writing device. The image writing device is supported at three points, one adjusting mechanism and two inclined fulcrums, with respect to the main body device frame. The multicolor image forming apparatus according to any one of claims 1 to 4, wherein 6. The adjusting mechanism is provided at two positions on both sides in a direction intersecting the recording medium transport direction of the image writing device, and the inclined fulcrum intersects the recording medium transport direction of the image writing device. The image writing device is supported at four points with respect to the main body device frame: two adjustment mechanisms and two tilt fulcrums. The multicolor image forming apparatus according to claim 1. 7. An image writing apparatus including the tilt fulcrum and the adjustment mechanism, wherein the tilt fulcrum is disposed closer to the reference image writing apparatus than the adjustment mechanism. Claims 1 to 6
5. The multicolor image forming apparatus according to claim 1.