JPH0758909A - Image-forming device for image reader - Google Patents

Abstract

PURPOSE:To prevent the divergence of focus due to the thermal expansion of an image reader from occurring. CONSTITUTION:The position of an image sensor 2 is regulated at the lens side terminal part of a high thermal expansion member 12 connected tightly to a frame 3 on the counter lens side of the image sensor 2, or, the position of a lens 4 is regulated at the image sensor terminal part of the high thermal expansion member 12 connected tightly with the frame 3 on the counter image sensor side of the lens 4. Or, the position of the image sensor 2 is regulated at the image sensor side terminal part of a low thermal expansion member connected tightly to the frame 3 on the counter image sensor side of the lens 4, or the position of the lens 4 is regulated at the lens side terminal part of the low thermal expansion member connected tightly to the frame 3 on the counter lens side of the image sensor 2. Or, a reverse thermal expansion member of bimetal plate is provided between the lens 4 and the image sensor 2. The image sensor 2 is loaded on the center part of a substrate 1 connected tightly to the frame 3 at both terminal sides, and the center part of a packaged substrate 1 is bent facing with a lens 4 side by thermal expansion difference between the high thermal expansion member and the low thermal expansion member.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image reading apparatus for converting character and graphic information on the surface of an original into electric signals as image information, and in particular, the above-mentioned apparatus for preventing out-of-focus due to thermal expansion of members. The present invention relates to an image device.

[0002]

2. Description of the Related Art Image reading devices are used as image information input devices for electronic computers and as facsimile terminals. These devices have a light source lamp for illuminating a document and also have electronic circuits mounted in high density. These light source lamps and electronic circuits generate heat when energized and raise the device temperature when continuously used.

In order to read the image of the original clearly, it is necessary to accurately focus the lens, and it is necessary to accurately set the distance between the lens and the image sensor.
However, the lens has chromatic aberration, the focal length changes when the color (wavelength) of the light source lamp changes, and the distance between the set lens and image sensor changes due to the heat expansion of the device due to the heat generation of the device and the change of the outside air temperature. Change. These changes cause the lens to be out of focus and reduce the sharpness of the read image.

Since a certain degree of tolerance is recognized in the accuracy of focusing of the lens, conventionally, the thermal expansion of the device during use is expected, and even if the device thermally expands, the focus is located within the allowable range. By setting the position of the image sensor, it is possible to prevent deterioration of the clarity of the read image due to thermal expansion of the device.

[0005]

Recently, in an image reading device as an input device to an electronic computer, there is a demand for reading a manuscript in a state in which a red or blue book written on the manuscript is erased. To meet this requirement, there is a method of reading an original with, for example, infrared light in addition to normal white light.

However, when such a means is adopted,
Since the wavelengths of white light and infrared light are different, the focal length of the lens is also different. The difference in focal length due to the difference in wavelength can be kept within the allowable range of the focal length described above, but this causes a problem that there is no margin for the temperature rise of the device. That is, when both the image forming position of white light and the image forming position of infrared light are kept within the permissible width of focus, when the distance between the lens and the image sensor changes due to the temperature rise of the device,
The image sensor deviates from the permissible width of focus, and it becomes impossible to maintain the sharpness of the read image.

The present invention has been made in order to solve the above problems, and provides a technical means for preventing the variation of the distance between the lens and the image sensor due to the temperature change of the apparatus, whereby the light source for illuminating the original document is provided. Therefore, even when a plurality of light sources having different wavelengths are used, it is an object to obtain an image reading device which can always read clear image information without being affected by the temperature rise of the device.

[0008]

In the image forming apparatus of the image reading apparatus according to the present invention, at the lens side end of the high thermal expansion member 12 fastened to the frame 3 on the side opposite to the lens from the mounting position of the image sensor 2, The position of the image sensor 2 is restricted in the optical axis direction.

In the image forming apparatus of the image reading apparatus according to the present invention, the end of the high thermal expansion member 12 fastened to the frame 3 on the side opposite to the image sensor side with respect to the mounting position of the lens 4 is an end portion of the high thermal expansion member 12 on the image sensor side. The feature is that the position is regulated in the axial direction.

In the image forming apparatus of the image reading apparatus according to the present invention, the image sensor 2 is attached at the end portion of the low thermal expansion member 19 fastened to the frame 3 on the side opposite to the image sensor side with respect to the mounting position of the lens 4. It is characterized in that the position is regulated in the optical axis direction.

In the image forming apparatus of the image reading apparatus according to the present invention, the lens 4 is attached at the lens side end of the low thermal expansion member 19 fastened to the frame 3 on the side opposite the lens from the mounting position of the image sensor 2. It is characterized in that the position is regulated.

In the image forming apparatus of the image reading apparatus according to the present invention, the lens 4 is provided on the lens frame 3 so as to be movable in the optical axis direction, and the spring 18 for biasing the lens 4 toward the image sensor is provided. The lens 4 is pressed by the urging force of the spring 18 to the lens-side end portion of the extremely low thermal expansion member 20 fastened to the lens frame 3 at the mounting position.

In the image forming apparatus of the image reading apparatus according to the present invention, the image sensor side end portion of the inverse thermal expansion member 22 fastened to the frame 3 at a position between the lens 4 and the image sensor 2 is provided with the image sensor. 2 is positionally regulated in the optical axis direction, and the inverse thermal expansion member 22 is a bimetal plate bent so that the low thermal expansion plate 24 and the high thermal expansion plate 25 are bonded together so that the low thermal expansion plate 24 side is convex. It is characterized by.

In the image forming apparatus of the image reading apparatus according to the present invention, the lens 4 has an end portion on the lens side of the inverse thermal expansion member 22 fastened to the frame 3 at a position between the lens 4 and the image sensor 2. The position is regulated in the optical axis direction, and the reverse thermal expansion member 22 is a bimetal plate which is formed by bonding the low thermal expansion plate 24 and the high thermal expansion plate 25 together and bending so that the low thermal expansion plate 24 side is convex. It is a feature.

In the image forming apparatus of the image reading apparatus according to the present invention, the image sensor 2 is mounted on the central portion of the mounting substrate 1 which is fastened to the frame 3 on both sides, and the high thermal expansion member 25 and the low thermal expansion member are mounted. It is characterized in that the mounting substrate 1 is curved so that the central portion thereof is convex toward the lens 4 side due to the difference in thermal expansion from 24. Specifically, the mounting substrate 1a of the image sensor is mounted on the low thermal expansion plate 24.
And a high thermal expansion plate 25 are bonded together to form a bimetal structure, and the high thermal expansion plate 25 side is fastened to the frame 3 with the lens 4 facing. As another specific structure having the above characteristics,
For example, a structure in which the mounting substrate 1 is fastened in a state where both sides of the mounting substrate 1 are in surface contact with the fastening surface 30 of the frame 3 so that the thermal expansion coefficient of the mounting substrate 1 is lower than the thermal expansion coefficient of the frame 3; A main frame 7 having a small thermal expansion coefficient and a lens frame 3 having a large thermal expansion coefficient, and the lens frame 3 is fixed to the main frame 7 at positions on both sides of the image sensor 2 opposite to the lens 4 in the direction perpendicular to the optical axis. With the same structure as described above, a structure in which the lens frame 3 is fixed to the main frame 7 at a position separated in the optical axis direction of the central portion thereof can be adopted.

The low thermal expansion member and the high thermal expansion member referred to here are relative members, and do not necessarily have to have low or high absolute values of thermal expansion coefficient. That is, aluminum is a high thermal expansion member based on iron, and iron is a low thermal expansion member based on aluminum. Examples of the low thermal expansion member include carbon steel, cast iron, glass epoxy, and the like, and examples of the high thermal expansion member include aluminum, polyethylene, epoxy, and the like. The extremely low thermal expansion member referred to in the present invention means a member whose coefficient of thermal expansion is extremely small in absolute value, and is, for example, amber (iron-nickel alloy).

[0017]

The invention according to claims 1 to 4 in which the positions of the lens 4 and the image sensor 2 in the optical axis direction are restricted by the high thermal expansion member 12 and the low thermal expansion member 19, the frame 3 and the high thermal expansion member 12 or the low thermal expansion member 19 are defined. By having a certain correlation between the difference in the distance from the fastening position of the lens 4 or the image sensor 2 to the difference in the thermal expansion of the low or high thermal expansion members 19 and 12 with respect to the frame 3, it is possible to increase the temperature. The variation in the distance between the lens 4 and the image sensor 2 is canceled so that the distance between the lens 4 and the image sensor 2 is always constant.

According to the invention of claim 5 using the extremely low thermal expansion member 20, the distance between the lens 4 and the image sensor 2 is regulated by the extremely low thermal expansion member 20, so that the lens 4 and the image sensor 2 due to temperature change. Minimize the fluctuation of the interval between
This prevents deviation of the focal position from the allowable width due to temperature changes.

According to the sixth and seventh aspects of the present invention which uses the inverse thermal expansion member 22, by using a special member having a bimetal structure, the inverse thermal expansion member intervening as a spacer when the temperature rises is arranged in the optical axis direction of the lens. Utilizing the contracting action,
By canceling the extension of the frame 3 and the contraction of the inverse thermal expansion member 22 due to the temperature rise, the variation of the distance between the lens 4 and the image sensor 2 due to the temperature change is prevented.

According to the invention of claims 8 to 12, the image sensor mounting substrate 1 whose both ends are supported by the frame 3 is bent toward the lens 4 side when the temperature rises, so that the extension of the frame 3 is extended. Offset by flexure,
The distance between the lens 4 and the image sensor 2 is kept constant.

[0021]

Embodiments FIGS. 15 and 16 show an example of the structure of an image sensor mounting portion of an image reading apparatus. The structure shown in FIG. 15 has an image sensor 2 fixed to a mounting substrate 1.
Is screwed to the rear end of the lens frame 3 on both sides of the mounting substrate 1. The lens frame 3 has a cylindrical through hole on the front side (back side in the drawing), and the lens 4 is fitted into this through hole and its position in the optical axis direction is fixed by the set screw 5. The lens frame 3 is screwed to the main frame 7 with screws 6.

FIG. 16 shows the main frame 7
The mounting substrate 1 having the image sensor 2 directly mounted thereon is screwed. The lens 4 is fixed to the front of the image sensor 2 on the same main frame (back side in the figure), and the light source lamp 8 for reflecting the original and the reflection mirror 9 are also mounted on the main frame. . The main frame 7 in the figure serves as a carrier of an image reading apparatus of a type in which a reading unit is run along a transparent top plate which serves as a document placing table. In this specification, when simply referred to as a frame, it means that either the lens frame 3 or the main frame 7 may be used.

FIG. 1 shows a first embodiment of the present invention. FIG. 1 shows an example of using the lens frame 3,
The lens 4 is fitted in the cylindrical hole 11 of the lens frame 3 and fixed by the set screw 5, and the image sensor 2 is mounted via the mounting substrate 1 fixed to the rear end of the lens frame 3. The high thermal expansion member 12 is interposed as a spacer between the image sensor 2 and the mounting substrate 1.
The lens frame 3 is fixed to the main frame 7 with the above-mentioned screws or the like. The lens frame 3 is made of, for example, carbon steel (coefficient of linear expansion of 10.7 × 10 ⁻⁶ ) and the high thermal expansion member 12 is made of polyethylene (coefficient of linear expansion of 100 to 200 × 10 ⁻⁶ ). And lens 4
A and B, where A is the length from the center to the mounting position of the mounting substrate 1 and B is the thickness of the high thermal expansion member 12 in the optical axis direction.
Is determined so that Aα ₁ = Bα ₂ is satisfied. Here, α ₁ is a linear expansion coefficient of the lens frame 3, and α ₂ is a linear expansion coefficient of the high thermal expansion member. When carbon steel and polyethylene are used, the thickness B of the high thermal expansion member 12 is about 1/10 to 20 of the distance A between the lens 4 and the mounting substrate.
It will be one-third.

In the first embodiment described above, the high thermal expansion member 12 is interposed between the image sensor 2 and the mounting substrate 1 thereof. As shown in FIG. 2, the high thermal expansion member 12 is fixed to the frame 3. It may be interposed between the member (screw) 16 and the sensor mounting board 1. In the example of FIG. 2, a screw 16 is attached to the rear end of the lens frame 3 on which the lens 4 is mounted,
A thick washer-shaped high thermal expansion member 12 is fitted between the screw head and the sensor mounting substrate 1, and the mounting substrate 1 axially movably mounted on the screw 16 is inserted through the screw 16 to form a spring 17.
The structure is pressed against the high thermal expansion member 12. The image sensor 2 in this case is directly fixed to the mounting substrate 1.

In the structure of the embodiment shown in FIGS. 1 and 2, the thermal expansion of the high thermal expansion member 12 corresponds to the amount by which the frame 3 thermally expands due to the temperature rise of the apparatus and the distance between the lens 4 and the image sensor 2 is increased. The image sensor 2 is pushed back toward the lens 4 to cancel each other, thereby preventing a change in the distance between the lens 4 and the image sensor 2 due to a temperature change.

FIG. 3 shows a third embodiment of the present invention, which corresponds to the structure of claim 2. In FIG. 3, the mounting substrate 1 having the image sensor 2 directly fixed to the rear end of the lens frame 3 is fixed, and the lens 4 is movable in the optical axis direction to the lens frame and attached to the image sensor 2 side by the spring 18. It is set up with power. The position of the rear end of the lens 4 is regulated by the stopper of the high thermal expansion member 12 whose base end is fixed at a position opposite to the image sensor from the lens 4. That is, the lens 4 has a structure in which the rear end thereof is always locked by the tip of the stopper and positioned by the biasing force of the spring 18. Lens frame 3 in this case
As a material of, for example, cast iron (coefficient of linear expansion 10.5 × 1
0 ⁻⁶ ) and aluminum (coefficient of linear expansion 23.6 × 10 ⁻⁶ ) is used as the high thermal expansion member 12. Then, the distance from the fastening position of the high thermal expansion member 12 to the image sensor is A, the distance to the locking position of the lens is B, the thermal expansion coefficient of the frame is α ₁ , and the linear expansion coefficient of the high thermal expansion member is α ₂ , The ratio of the distances between A and B is determined so that Aα ₁ = Bα ₂ . By doing so, the extension of the frame 3 caused by the temperature rise of the apparatus is compensated by the extension of the high thermal expansion member 12 to move the lens 4 relatively to the image sensor 2 side, and the lens 4 and the image sensor. That is, the distance from 2 is kept constant.

FIG. 4 shows a fourth embodiment of the present invention and corresponds to the structure of claim 4. The structure of FIG. 4 is similar to the structure of FIG. 3 in that the lens 4 is biased toward the image sensor 2 side by the spring 18 and the position of the rear end of the lens 4 is regulated by the stopper. The expansion member 19 is used, and its fastening position to the frame 3 is set on the side opposite to the lens of the image sensor 2.
The image sensor 2 is directly fixed to the mounting substrate 1 fixed to the rear end of the frame 3. In the case of FIG. 4, for example, the frame 3 is made of aluminum, the low thermal expansion member 19 is made of iron, the distance from the fastening position of the low thermal expansion member 19 to the rear end of the lens is A, and the mounting position of the mounting substrate 1 is A. To B, the linear expansion coefficient of the frame is α ₁ , the linear expansion coefficient of the low thermal expansion member is α ₂ , and the distances A and B are determined so as to satisfy Bα ₁ = Aα _2. Due to the difference in thermal expansion between the low thermal expansion member 4 and the frame 3, the lens 4 is moved toward the image sensor 2 by the biasing force of the spring 18 when the frame 3 is thermally expanded. The distance between and is kept constant.

In the embodiment shown in FIG. 5, the image sensor 2 side is relatively moved by the low thermal expansion member 19 so that the distance between the lens 4 and the image sensor 2 is kept constant by the same operation as that of the embodiment shown in FIG. Then, it corresponds to the configuration of claim 3. That is, the position of the lens 4 in the optical axis direction is regulated by the lens frame 3 by the set screw 5, and the mounting substrate 1 of the image sensor 2 is attached to the frame 3 at a position opposite to the image sensor side of the lens 4 and has a low thermal expansion. Member 19
It is fixed at the tip of. Letting A be the distance from the fastening position of the low thermal expansion member 19 to the mounting position of the mounting substrate and B be the distance to the fixing position of the lens 4, the distances A and B are set so as to satisfy the condition of Bα ₁ = Aα _2. By deciding,
The difference in thermal expansion between the frame 3 and the low thermal expansion member 19 cancels the fluctuations between the lens 4 and the image sensor 2 due to temperature changes. Note that α ₁ and α ₂ in the above equation are shown in FIG.
Similar to the embodiment described above, the linear expansion coefficient of the frame 3 and the linear expansion coefficient of the low thermal expansion member may be such that aluminum is used for the frame 3 and iron is used for the low thermal expansion member 19.

FIG. 6 shows a sixth embodiment of the present invention, which is a structure corresponding to claim 5. The structure of FIG. 6 is shown in FIG.
Similar to the structure of FIG.
It is biased to the side and the rear end thereof is locked by a stopper 20, which is fastened to the frame 3 at the same position as the position of the image sensor 2 in the optical axis direction.
It is manufactured with 0. As the ultra-low thermal expansion member 20, for example, amber (coefficient of linear expansion 1.2 × 10 ⁻⁶ ) which is an alloy of iron 64% and nickel 36% is used. The structure of FIG. 6 can be said to be a modification of the structure of FIG. 4, and since the ratio of the linear expansion coefficients of the frame 3 and the extremely low thermal expansion member 20 is very large, the dimension B shown in FIG. It is a structure that can be set to 0.

FIG. 7 shows an example of a structure using the extremely low thermal expansion member 20 similar to that shown in FIG. 6, in which the dimension B of FIG. 4 can be accurately set. The extremely low thermal expansion member 20 is shown in FIG.
Is colored and is fitted in the lens frame 3 so as to be movable in the optical axis direction. The position of the lens 4 is regulated by the lens side end thereof, and the image sensor side end thereof is adjusted by the adjusting screw 21.
The position in the optical axis direction can be adjusted with. That is, according to this structure, the frame 3 and the extremely low thermal expansion member 20
It is possible to accurately set the distance B to the image sensor 2 and the tightening position of the extremely low thermal expansion member 20 corresponding to the ratio of the thermal expansion coefficients of

FIG. 8 shows an eighth embodiment of the present invention, which corresponds to the structure of claim 6. The lens 4 having this structure is fixed at a fixed position of the lens frame 3, and the mounting substrate 1 of the image sensor is mounted on the rear end of the lens frame 3 via a bimetal washer 22 having a disc spring shape. That is, the screw 1 is attached to the rear end of the lens frame 3.
6, the bimetal washer 22, the sensor mounting substrate 1, the compression coil spring 17, and the spring receiving washer 23 are inserted into the screw 16 from the lens frame side, and the mounting substrate 1 is urged by the spring 17 to urge the bimetal washer 22. It is attached while being pressed against. The bimetal washer 22 is a low thermal expansion plate 2 located on the mounting substrate 1 side.
4 and the high thermal expansion plate 25 located on the lens frame 3 side are bonded together, and the low thermal expansion plate 24 side is bent so as to be convex. When the temperature rises, the bimetal washer 22 deforms in a flattened direction due to the expansion of the high thermal expansion plate 25 located on the concave side, and acts as a reverse thermal expansion member. Therefore, the distance C between the end surface of the lens frame 3 and the sensor mounting substrate 1 becomes smaller as the device temperature increases. Therefore, by setting the rate of change of the distance C so as to cancel the rate of change of the distance D from the lens fixing position of the lens frame 3 to the rear end due to thermal expansion, the lens 4 and the mounting substrate when the device temperature changes. It is possible to maintain a constant distance from the image sensor attached to No. 1.

FIG. 9 shows a structure corresponding to claim 7, which is a structure in which a bimetal washer 22 similar to that shown in FIG. 8 is attached to the frame 3 so as to relatively move the lens 4 side.
That is, the structure is such that the lens 4 and the spring 8 that are fitted to the frame 3 so as to be movable in the optical axis direction are urged toward the bimetal washer 22. Bimetal washer 2 with this structure
2 also has a low thermal expansion plate 24 on the convex side and a high thermal expansion plate 25 on the concave side similarly to the bimetal washer in FIG. 8, and by the same operation as the structure in FIG.
It is possible to prevent a change in the distance between the image sensor 2 and the image sensor 2.

10 and 11 show the structure of a tenth embodiment of the present invention, which corresponds to the structure of claim 8. In this embodiment, the lens 4 is fixed at a fixed position on the lens frame 3, and the image sensor 2 is mounted on the mounting substrate 1a having a bimetal structure. The mounting substrate 1a includes a low thermal expansion plate 24 and a high thermal expansion plate 25, and the high thermal expansion plate 25 is a lens 4
The structure is such that the two side members are bonded to each other, and both side portions thereof are sandwiched between the two edge members 28, 28 and are locally swingable, and are fixedly mounted on the lens frame 3. In the structure of this embodiment, the mounting board 1 is affected by the temperature rise of the device.
a is bent toward the lens 4 side, and the extension of the lens frame 3 is offset by the mounting substrate 1 a being bent and the image sensor 2 being moved toward the lens 4 side.
The image sensor 2 is kept at a constant distance.

In the embodiment shown in FIG. 12, the sensor mounting substrate 1 is bent toward the lens 4 side due to the difference in linear expansion coefficient between the lens frame 3 and the mounting substrate 1, and aluminum is used as the lens frame 3. As the mounting substrate 1, ceramics (coefficient of linear expansion of about 3.5 × 10 ⁻⁶ ) or glass epoxy (coefficient of linear expansion of about 10 × 10 ⁻⁶ ) is used.
The mounting board 1 is fastened in a state where both sides thereof are in surface contact with a fastening surface 30 that is pasted toward the rear outer side of the lens frame 3. In this structure, when the lens frame 3 and the mounting substrate 1 expand due to thermal expansion of the device,
Due to the difference in thermal expansion in the direction perpendicular to the optical axis, the mounting substrate 1 pulls the fastening surface 30 projecting to the rear of the lens frame 3 toward the inside, and the tilt generated on the fastening surface 30 causes the mounting substrate 29 to move toward the lens 4 side. By bending the image sensor 2 toward the lens 4 side,
The thermal expansion of the lens frame 3 in the optical axis direction is offset.

A structure for bending the sensor mounting substrate 1 toward the lens 4 side is shown in FIG. 13 or FIG. 14, which utilizes the difference in thermal expansion between the lens frame 3 and the main frame 7 for fixing the lens frame in addition to the above structure. A structure can also be adopted. In the structure shown in FIG. 13, the lens frame 3 made of aluminum is attached to the iron main frame at two positions 3 apart from the image sensor 2 in the direction perpendicular to the optical axis.
The structure of fixing with 1 and 31 is adopted. According to this structure, when the temperature rises, the expansion of the lens frame 3 in the direction perpendicular to the optical axis causes the main frame 7 to move at the positions of the screws 32, 32.
The fastening surface 30 to which the mounting board 1 is fixed is deformed so as to fall inward. This deformation is transmitted to the mounting substrate 1, and the mounting substrate 1 is bent in a convex shape to move the image sensor 2 to the lens frame 3 side, and the thermal expansion of the lens frame 3 in the optical axis direction is offset.

Similarly, in the structure shown in FIG. 14, the lens frame 3 made of aluminum is fixed to the iron main frame at two positions separated from each other in the optical axis direction by screws 32, 32, and the device temperature rises. The thermal expansion of the lens frame 3 in the optical axis direction at this time is restricted by the main frame at the fixing parts by the screws 32, 32, and therefore, the difference is caused by the difference in the extension between both side parts freely extending and the central part whose extension is restricted. The fastening surface 30 to which the substrate is fixed is deformed so as to be tilted inward, and the mounting substrate 1 is bent toward the lens 4 side by this tilt, and the image sensor 2 is moved to the lens 4
By moving the lens frame 3 toward the side, the extension of the lens frame 3 due to the temperature rise is offset.

[0037]

According to each structure of the present invention described above,
The change in the distance between the lens and the image sensor due to the thermal expansion of the frame due to the temperature rise of the device is offset by the bending of the low thermal expansion member, the high thermal expansion member, the extremely low thermal expansion member, the reverse thermal expansion member, or the mounting substrate, The distance between the lens and the image sensor can be kept constant irrespective of the temperature change, and even in an image reading device using white light and infrared light, the sharpness of the read image is maintained regardless of the temperature change of the device. There is an effect that can be done.

[Brief description of drawings]

FIG. 1 is a sectional side view of a first embodiment.

FIG. 2 is a sectional plan view of a second embodiment.

FIG. 3 is a sectional side view of the third embodiment.

FIG. 4 is a sectional side view of the fourth embodiment.

FIG. 5 is a sectional side view of the fifth embodiment.

FIG. 6 is a sectional side view of the sixth embodiment.

FIG. 7 is a sectional side view of the seventh embodiment.

FIG. 8 is a side view of the eighth embodiment.

FIG. 9 is a sectional side view of the ninth embodiment.

FIG. 10 is a sectional plan view of a tenth embodiment.

FIG. 11 is a perspective view of a mounting board mounting portion according to a tenth embodiment.

FIG. 12 is a sectional plan view of the eleventh embodiment.

FIG. 13 is a sectional plan view of the twelfth embodiment.

FIG. 14 is a sectional plan view of the thirteenth embodiment.

FIG. 15 is a perspective view showing a first example of a frame structure of an image forming portion.

FIG. 16 is a perspective view showing a second example of the frame structure of the image forming portion.

[Explanation of symbols]

 2 Image sensor 3 Lens frame 4 Lens 7 Main frame 12 High thermal expansion member 19 Low thermal expansion member 22 Bimetal washer 24 Low thermal expansion plate 25 High thermal expansion plate 30 Fastening surface 30

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Makoto Kano Uno-nu, Uno-cho, Hebei-gun, Ishikawa Prefecture 2 No. 98, PFU Co., Ltd. (72) Inventor Yasuhiro Matsuda 98 Uno-nu, Unoki-cho, Kawakita-gun, Ishikawa Prefecture No. 2 of the house, PFU Co., Ltd. (72) Nobuhisa Yamazaki, inventor, Nouki-nu, Unoki-cho, Hebei-gun, Ishikawa Prefecture 98 No. 2 House of P-FU Co., Ltd. (72) Tomohiro Sunazaki, Unoki-nu, Unoku-cho, Ishikawa Prefecture, No. 98 Address No. 2 PF Corporation

Claims (12)

[Claims] 1. The image sensor (2) is arranged in the optical axis direction at the lens side end of a high thermal expansion member (12) fastened to a frame (3) on the side opposite to the lens from the mounting position of the image sensor (2). An image forming apparatus for an image reading apparatus, characterized in that its position is restricted. 2. The lens (4) is arranged in the optical axis direction at the end of the high thermal expansion member (12) fastened to the frame (3) on the side opposite the image sensor from the mounting position of the lens (4). An image forming apparatus for an image reading apparatus, characterized in that its position is restricted. 3. An image sensor side end of a low thermal expansion member (19) fastened to the frame (3) on the side opposite to the image sensor side of the mounting position of the lens (4), and the image sensor (2) is moved in the optical axis direction. An image forming apparatus for an image reading apparatus, characterized in that its position is regulated. 4. The position of the lens (4) is regulated in the optical axis direction at the lens side end of the low thermal expansion member (19) fastened to the frame (3) on the side opposite to the lens mounting position of the image sensor (2). An image forming apparatus of an image reading apparatus, characterized in that. 5. The lens (4) is provided on the lens frame (3) so as to be movable in the optical axis direction, and a spring (18) for urging the lens (4) is provided on the lens frame (3) to attach the image sensor (2) to the mounting position. Image reading, characterized in that the lens (4) is pressed against the lens side end of the ultra-low thermal expansion member (20) fastened to the lens frame (3) by the biasing force of the spring (18). Device imaging device. 6. The image sensor side end of the inverse thermal expansion member (22) fastened to the frame (3) at a position between the lens (4) and the image sensor (2), the image sensor (2) Is regulated in the optical axis direction, and the inverse thermal expansion member (22) is formed by bonding the low thermal expansion plate (24) and the high thermal expansion plate (25) together so that the low thermal expansion plate (24) side becomes convex. An image forming device of an image reading device, which is a bent bimetal plate. 7. The lens side end of the inverse thermal expansion member (22) fastened to the frame (3) at a position between the lens (4) and the image sensor (2), the lens (4) The position is regulated in the axial direction, and the inverse thermal expansion member (22) is bent so that the low thermal expansion plate (24) and the high thermal expansion plate (25) are bonded together and the low thermal expansion plate (24) side is convex. Image forming device of an image reading device, which is a bimetal plate. 8. A high thermal expansion member (25) and a low thermal expansion member (24), wherein the image sensor (2) is mounted on the central portion of the mounting substrate (1) fastened to the frame (3) on both sides. Due to the difference in thermal expansion between the mounting board (1) and the lens (4)
An image forming apparatus of an image reading apparatus, characterized in that the image forming apparatus is curved so as to be convex toward the side. 9. The mounting board (1a) has a bimetal structure in which a low thermal expansion plate (24) and a high thermal expansion plate (25) are bonded together, and the high thermal expansion plate (25) side faces the lens (4) to form a frame. 9. The image forming apparatus according to claim 8, wherein the image forming apparatus is fastened to (3). 10. The mounting board (1) is fastened with its both side portions in surface contact with the fastening surface (30) of the frame (3), and the thermal expansion coefficient of the mounting board (1) is equal to that of the frame (3). 9. The image forming apparatus according to claim 8, wherein the coefficient of thermal expansion is lower than the coefficient of thermal expansion. 11. A frame is formed of a main frame (7) and a lens frame (3), and a lens (4) and an image sensor (2) are attached to the main frame (7) via the lens frame (3). The lens frame (3) is located on both sides of the image sensor (2) opposite to the lens (4) side in the direction perpendicular to the optical axis, and the main frame (7) shows the relative movement in the direction perpendicular to the optical axis at each position. It is fixed in the blocked state, and the coefficient of thermal expansion of the lens frame (3) is the main frame.
The coefficient of thermal expansion is higher than that of (7), and the mounting substrate (1) is fastened in both side portions in surface contact with the fastening surface (30) of the lens frame (3). The imaging device according to claim 8. 12. A frame is formed of a main frame (7) and a lens frame (3), and a lens (4) and an image sensor (2) are attached to the main frame (7) via the lens frame (3). The lens frame (3) is located in the center of the lens frame (3) at positions separated from each other in the optical axis direction, and the relative movement in the optical axis direction at each position is blocked.
It is fixed to (7), the coefficient of thermal expansion of the lens frame (3) is higher than that of the main frame (7), and the mounting board (1) is fastened to the lens frame (3) at both sides. 9. An imaging device according to claim 8, characterized in that it is fastened in surface contact with the surface (30).