JPH0622096A - Image reader - Google Patents

Abstract

PURPOSE:To easily perform the adjustment of the fitting position of a second mirror stand (inclination adjustment) from the outside of the device by providing an adjustment part for adjusting the fitting state of the mirror of a scanning optical system through the armour of the device. CONSTITUTION:In the case of reading an original, a second mirror (folding mirror) stand U2 moves on rails for movement by a wire 8 and a pulley 10. A round pressing terminal 11 at the terminal part of the wire 8 is held by the notch, etc., of the device. The wire 8 is supported by a terminal part 25 in the main body of the device. The head of a screw 12 for adjustment enters the recessed part of the caulking part of the terminal 11. A driver 15 is inserted from an opening 14 for adjustment at a device armour 13 and the screw 12 is vertically moved so as to vary the effective length of the wire 8 with distance difference between A and B and between A and B' by vertically moving the terminal 11. Thus, the angle of the second mirror stand U2 in the lengthwise direction can be adjusted to be vertical to an optical axis.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention
The present invention relates to an image reading device that reads by using an image sensor such as an element.

[0002]

2. Description of the Related Art As shown in FIG. 3, an image reading section such as a copying machine or an image scanner irradiates a document placed on a document table glass 5 with a light source 4 of a first mirror stand U ₁ and reflects the reflected light. Is folded by the mirror 1, the mirror 2 and the mirror 3 mounted on the second mirror base U ₂ , and an image is formed on the image sensor (CCD element) 7 using the imaging lens 6. Then, by scanning the first mirror table U ₁ and the second mirror table U ₂ in parallel with the platen glass 5 at a speed ratio of 1: 1/2, the document on the platen glass is read, so-called 1: 1.
A / 2 optical system is often used.

The scanning means of the above-mentioned 1: 1/2 optical system is shown in FIG.
Will be described in detail. The scanning means includes a wire-driven first mirror base U ₁ (moving body) and a second mirror base U ₂
(Moving body). In addition, 6 is an imaging lens. The first mirror base U ₁ includes a light source 4 for irradiating a document and a first mirror 1 for reflecting the image reflected light of the document P irradiated by the light source 4 toward the second mirror base U ₂ . On the other hand, the second mirror base U ₂ is provided with second and third mirrors 2 and 3 for returning the image light reflected by the first mirror 1 toward the image sensor 7. The first mirror base U ₁ and the second mirror base U ₂ are arranged so that the rail 23 can scan parallel to the optical axis of the lens 6 while maintaining a right angle to the optical axis of the lens 6.
It is supported by a and 23b. 22 is the first mirror stand U ₁
The rotation of the second mirror stand U ₂ is transmitted to the starting pulley 21 through a gear group. Two wires 8a connected to the drive pulley 21 at one place on the way,
8b is wrapped around. One end of each wire is the first
It is fixed to the mirror base U ₁ and half-circulates over the pulleys 10 a and 10 b at both ends of the second mirror base U ₂ and fixed to the main body.

The other ends of the wires are pulleys 10a, 10
The tension spring 24 is connected halfway around b. As a result, the second mirror base U ₂ travels at half the speed of the first mirror base U ₁ on the principle of a moving pulley, so that the optical path length is always kept constant over the entire travel area.

The read image accuracy is equipped with an image sensor, an imaging lens and a folding mirror. It depends on the mounting position of the second mirror base.

The relationship between the mounting position of the second mirror base and the image accuracy will be described with reference to FIG.

FIG. 5 is a developed view of the optical path of the 1: 1/2 optical system. The reflected light from the document P includes a first mirror (mounted on the first mirror base U ₁ ), a second mirror 2 and a third mirror 3.
An image is formed on the image sensor 7 by the image forming lens 6 through (mounted on the second mirror base U ₂ ). As shown in FIG.
If the longitudinal direction of the second mirror base U ₂ on which the second mirror 2 and the third mirror 3 are mounted is perpendicular to the optical axis of the imaging lens 6, the point c at the reading start position
Is in the same position even when the second mirror base U ₂ is moved and the reading is completed, and the straight line parallel to the optical axis of the image to be read becomes a straight line even after being read by the image sensor 7.

However, as shown in FIG. 6, if the longitudinal direction of the second mirror base U ₂ is not perpendicular to the optical axis of the imaging lens 6, the point d at the reading start position is
At the reading end position, the second mirror base U ₂ moves to shift to the point d '. That is, the straight line parallel to the optical axis of the read image becomes a diagonal line in the read image due to the influence of the folding mirror (see FIG. 7).

Adjustment of the mounting position of the second mirror base (hereinafter referred to as skew adjustment) will be described with reference to FIG.

FIG. 8 is a diagram schematically showing one end of the second mirror base U ₂ in FIG. 4, and the driving means is as described above. When reading a document, the second mirror base moves on the moving rail via the pulley 10 by the action of handing the wire 8'in the direction of arrow a. Also, the second mirror base U ₂
When returning to the reading start position, the second mirror base U ₂ is moved in the direction opposite to the reading direction by the action of handing the wire 8 in the direction of the arrow b.

On the other hand, a screw portion 19 is provided at the end of the wire 8 so that the length of the wire between the main body fixed end 20 and the second mirror base U ₂ can be adjusted. For skew adjustment, for example, a straight line parallel to the optical axis is read, and the positional relationship of the straight lines in the read image near the reading start position and near the reading end position is compared before and after, that is, a reading sensor (CCD).
The position of the bit in the element) is adjusted so that the read start position and the read end position have the same bit.

That is, the screw portion 18 is moved in the direction of arrow C,
The distance between the second mirror base U ₂ and the fixed end 20 is shortened, and the action is used to move the second mirror base U ₂ in the direction of arrow d (the other end of the second mirror base U ₂ (not shown)). Then, since the wire length is not adjusted, the second mirror base U ₂ moves in an arc shape as shown by the arrow d).

In this way, the angle of the second mirror base U _{2 in} the longitudinal direction is adjusted to be perpendicular to the optical axis. Finally, fix the screw portion 18 with the nut 19,
Finish the skew adjustment.

[0014]

In the skew feeding adjustment described above, since the adjustment end (screw portion 18) of the wire is moved in the wire tension direction to adjust the angle in the longitudinal direction of the second mirror base, the apparatus is Due to the configuration, adjustment cannot be performed from the outside of the apparatus, and therefore, there is a problem that a large-scale jig and tool is required and repair and adjustment cannot be performed in the market.

It is an object of the present invention to make the skew adjustment possible from the outside of the apparatus, and to perform the adjustment easily without using a large-scale skew adjusting jig.

[0016]

According to the present invention to achieve the above object, an adjustment is made in the image reading apparatus for adjusting an attachment state such as an attaching position and a tilt of a mirror of a scanning optical system via an exterior of the apparatus. It is characterized by having a section.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The following is a description based on the illustrated embodiments of the present invention.

FIG. 1 shows a schematic construction of the skew feeding adjusting method of the present invention (a diagram schematically showing one end of the second mirror base U ₂ in FIG. 4).

In the figure, the second mirror base U ₂ is arranged on a moving rail (not shown) parallel to the optical axis and the platen glass. Then, when reading the original P, the second mirror base U ₂ is operated by the wire 8 in the direction of the arrow a.
It moves on the moving rail via the pulley 10. Also,
When returning the second mirror stand U ₂ to the reading start position, the second mirror stand U ₂ is moved by the action of handing the wire 8 ′ in the direction of the arrow b.
Move ₂ in the direction opposite to the reading direction.

The end of the wire 8 has a round crimp terminal 1
1 and its terminals utilize wire tension,
Hold it in the notch of the device. In addition, the round crimp terminal 11
The protruding end of the adjusting screw 12 is inserted into the concave portion of the caulking portion, and the adjusting screw 12 is arranged so as to be pushed from the lower side of the device.
Here, the round crimp terminal 11 is moved in the vertical direction by inserting the driver 15 from the adjustment opening 14 in the device exterior 13 and moving the adjustment screw 12 up and down in the direction of arrow C.

The wire 8 is supported by the end 25 in the main body of the apparatus. On the other hand, since the end of the wire opposite to the fixed end 20 is held through a tension spring (not shown), the extension of the tension spring does not change the length of the wire, but the effective wire length of the device is variable. can do. As a result, the length of the wire can be shortened or shortened due to the difference in the path between AB and AB ′, and the angle in the longitudinal direction of the second mirror base U ₂ can be adjusted to be perpendicular to the optical axis. it can. Further, although the skew feed adjusting mechanism is provided on both sides of the second mirror base U ₂ , the skew feed adjustment may be performed on only one side.

Further, as shown in FIG.
In the non-image area near the reading start position and in the non-image area near the reading end position, marks 16 and 17 as skew adjustment charts are arranged on the optical axis.

With such an apparatus configuration, the driver 15 is inserted from the outside of the apparatus through the adjustment opening 14 with reference to the positional difference between the marks 16 and 17 on the platen glass 5 in the read image. , The adjustment screw 12 is moved up and down in the direction of arrow C, and the mark 1 is displayed on the image sensor (CCD element).
By confirming the bit positions of 6 and 17, skew adjustment can be performed so that the error between the read start position and the read end position is within the standard value.

The same effect can be expected when the skew feed adjustment chart is provided not on the platen glass but on the exterior of the device on the same surface of the platen glass.

Further, even if the chart is not built in, the adjustment chart may be set on the platen glass every time the adjustment is performed.

In the above embodiment, the alignment of the end portions of the mirror base is shown, but the tilt of the mirror base and the adjustment of the base alone without adjusting the base are also developed from the configuration of FIG. It goes without saying that it can be implemented as.

[0027]

According to the present invention having the above-described structure and operation, the skew feeding can be performed from the outside of the apparatus, and the skew feeding adjusting chart is also provided in a part of the apparatus, so that the skew feeding can be adjusted. By correcting the position and tilt of the mirror without using jigs and tools, skew adjustment can be easily performed, cost can be reduced, and further adjustment can be easily performed at a service base in the market.

[Brief description of drawings]

FIG. 1 is a partial side view showing an embodiment of the present invention.

FIG. 2 is a conceptual explanatory view showing an embodiment of a document table glass according to the present invention.

FIG. 3 is a side view showing a schematic configuration diagram of a general image reading apparatus.

FIG. 4 is a plan view showing a drive system of a general image reading apparatus and a side view of an optical system.

FIG. 5 is an explanatory diagram illustrating skew feeding adjustment.

FIG. 6 is an explanatory diagram illustrating skew feeding adjustment.

FIG. 7 is an explanatory diagram illustrating skew feeding adjustment.

FIG. 8 is a partial side view showing a conventional adjustment example.

[Explanation of symbols]

1 Mirror 2 2nd Mirror 3 3rd Mirror 4 Light Source 5 Original Plate Glass 6 Imaging Lens 7 Image Sensor 8.9 Wire 10 Pulley 11 Round Crimping Terminal 12 Adjustment Screw 13 Device Exterior 14 Adjustment Aperture 15 Driver 16 ・17 Adjustment Mark 18 Adjustment Screw (Wire End) 19 Nut 20 Terminal Fixed End 21 Drive Pulley 22 Drive Motor 23 Guide Rail 24 Tension Spring 25 Wire Support End U ₁ First Mirror Stand U ₂ Second Mirror Stand

Claims (7)

[Claims] 1. An image reading apparatus for reading an image by forming reflected light obtained by irradiating an original on an image sensor by using an image forming means, and reading the image from the outside of the apparatus via the exterior of the apparatus. An image reading apparatus comprising an adjusting unit that enables adjustment of an attached state. 2. The image reading device according to claim 1, wherein an opening for adjusting a mounting position of the folding mirror is provided on the exterior of the device. 3. The image reading device according to claim 1, further comprising a chart for adjusting a mounting position of a folding mirror in a part of the device. 4. The image reading device according to claim 3, wherein the original placing table glass of the device has a chart for adjusting a mounting position of a folding mirror. 5. The image reading device according to claim 3, which has a chart for adjusting a mounting position of a folding mirror in a non-image area of the original placing table glass on an optical axis of an imaging lens and in a straight line direction parallel to the optical axis. . 6. The image reading device according to claim 3, wherein the device exterior has a folding mirror mounting position adjusting chart. 7. The image reading device according to claim 6, wherein a non-image area of the device exterior has a chart for adjusting the mounting position of the folding mirror in the optical axis of the imaging lens and in a straight line direction parallel to the optical axis.