JP4810207B2 - Image reading apparatus and image forming apparatus - Google Patents

Description

  The present invention relates to an image reading apparatus such as an image scanner, and an image forming apparatus such as a copying machine or a facsimile equipped with the image reading apparatus.

An image reading apparatus that reads image data of a document represented on a sheet of paper, such as a copying machine or a scanner, and provides it to various processes, irradiates the document with light from a light source lamp, and reflects the reflected light to a photoelectric conversion device such as a CCD It is made to inject into the light-receiving part provided with. In a stationary document type image reading apparatus, light is irradiated to a document placed on a platen glass while moving a light source lamp. The light source lamp is mounted on a carriage so that the carriage moves.
Since the light source lamp has to irradiate the entire area of the original with the maximum size, the carriage moves from a position facing one end of the original table glass to a position facing the other end. That is, the carriage on which the light source lamp is mounted is a full rate carriage.

  A mirror is used to guide reflected light from the document to the light receiving unit, and the optical path length from the document to the light receiving unit needs to be kept constant even when the irradiation position on the document is changed. In order to keep the optical path length constant, a half-rate carriage is used that moves in the same direction in synchronization with the full-rate carriage at half the speed of the full-rate carriage. A second mirror and a third mirror are mounted on the half-rate carriage, and the reflected light from the original is reflected by the first mirror mounted on the full-rate carriage, and then sequentially reflected by the second mirror and the third mirror, and the apparatus main body Is guided to a light receiving portion fixed at a position on the other end side of the previous period from the moving range of the half-rate carriage in FIG.

The light source lamp included in the full rate carriage and the inverter circuit for driving the lamp fixed to the apparatus main body are connected by a flexible circuit board having flexibility so as not to impair the smooth movement of the full rate carriage. In this flexible circuit board, the bottom of the housing accommodating the two carriages is placed from the vicinity of the fixed position on the other end side of the first half of the movement range of the half-rate carriage, and the full-rate carriage is moved through the half-rate carriage. It has reached the light source lamp provided. Therefore, the flexible circuit board is appropriately curved by the guide member provided in the half-rate carriage from its fixed position and directed in the opposite direction, and passes through the air to reach the full-rate carriage.
The above-described full rate carriage and half rate carriage will be specifically described with reference to FIGS.

FIG. 8 is an explanatory view showing a state in which two carriages have started to move from one end side of the platen glass, and FIG. 9 is an explanatory view showing a state in which the full rate carriage has moved to the other end side of the platen glass. is there. The first carriage 110 is full rate carriage that includes a first lamp 12a and the second lamp 12b as a light source and a first mirror 13, as shown in FIG. 8 is the document while moving at a velocity V ₁ in the right direction in the drawing Irradiate light. The second carriage 120, which is a half-rate carriage including the second mirror 14 and the third mirror 15, synchronizes with the movement of the first carriage 110 and has a speed of ½ · V ₁ in the right direction in the figure. Move with. The reflected light of the light irradiated on the document is sequentially reflected in the order of the first mirror 13, the second mirror 14, and the third mirror 15, and is positioned on the other end side of the first end relative to the moving range of the second carriage 120 in the apparatus body. Then, the light is guided to the CCD 17 which is a light receiving portion through the imaging lens 16 fixed to the light receiving portion.
An optical path from the first mirror 13 to the second mirror 14 is a first optical path L ₁ , and an optical path from the third mirror 15 to the imaging lens 16 is a second optical path L ₂ . Then, when the second carriage 120 moves half as fast as the first carriage 110, it is possible to keep the length and length plus the length of the second optical path L ₂ of the first optical path L ₁ constant The optical path length from the original to the CCD 17 as the light receiving unit can be kept constant.

The flexible circuit board 140 that connects the first carriage 110 and the apparatus main body is bent appropriately by a guide 121 that is a guide member included in the second carriage 120, and is turned in the opposite direction by turning the bottom surface of the casing from the board fixing portion 141. Then, it passes through the air and reaches the first carriage 110. Incidentally, the flexible circuit board 140 so as not to interfere with the first optical path L _1, it is stretched in the air of the first upper optical path L _1.

In the flexible circuit board 140 having flexibility, the deflection due to its own weight increases as the length passing through the air increases. If a state in which the first carriage 110 and the second carriage 120 are close as shown in Figure 8, the amount of deflection of the upper of the flexible circuit board 140 of the first optical path L ₁ is very small. On the other hand, when the A3 size is read, for example, the deflection amount becomes maximum when the first carriage 110 and the second carriage 120 are farthest from each other as shown in FIG. Then, will be blocked some locations deflected the flexible circuit board 140 of the first optical path L ₁ as shown in FIG. 9, an image defect occurs due to the optical path vignetting.
In addition, by disposing the flexible circuit board 140 outside the width direction perpendicular to the moving direction of the two carriages in the image reading region, it is possible to prevent image defects due to the deflection of the flexible circuit board 140. . However, such a configuration requires a space for disposing the flexible circuit board 140 outside the width direction of the image reading area, leading to an increase in the size of the apparatus.

To solve the same problem as the problem in Patent Document 1, an elastic member that applies tension to the feeding cable is a flexible circuit board, it is described an image reading apparatus provided in the fixed portion of the feeder cable of the main body ing. In this image reading apparatus, one end of the plate-like elastic member is fixed to the fixing portion of the flexible circuit board, and the other end, which is a free end, is provided so as to contact the upper surface of the power feeding cable. When the first mirror base, which is a full rate carriage, and the second mirror base, which is a half rate carriage, are in the most distant state, the second mirror base comes close to the main body fixing connector, which is a fixing portion of the power supply cable. At this time, the power feeding cable in the vicinity of the fixed portion is curved and lifted, and the free end of the elastic member is lifted together with this. This will tension applied to the power supply cable by the elastic force of the elastic member, the occurrence of deflection of the power supply cable is prevented, the occurrence of image due to the deflection of the feed cable defects can be prevented.

JP 2000-78367 A

However, in the image reading apparatus described in Patent Document 1, until lifting the free end of the elastic member, the tension on the power supply cable is a flexible circuit board is granted Sarezu, can not prevent bending. That is, the maximum deflection in the state where the full-rate carriage and the half-rate carriage are the farthest can be erased, but it is possible to prevent the occurrence of deflection until the full-rate carriage approaches the fixed portion of the flexible circuit board. Can not. The deflection before the maximum causes vignetting of the optical path, resulting in an image defect.

  The present invention has been made in view of the above problems, and an object of the present invention is an image reading apparatus including a full-rate carriage and a half-rate carriage, and a flexible circuit board that connects the full-rate carriage and the apparatus main body. An object of the present invention is to provide an image reading apparatus that can reliably prevent the occurrence of deflection and always perform good image reading, and an image forming apparatus including the image reading apparatus.

In order to achieve the above object, the invention of claim 1 is equipped with a light source and a first mirror, a full rate carriage that moves from one end to the other end of the image reading area, and a second mirror and a third mirror. A half-rate carriage that moves half the distance of the full-rate carriage from the one end of the image reading area, and a half-width carriage that is looped back by a guide member provided in the half-rate carriage. A flexible circuit board for connecting the light source, irradiating the original with the light source while moving the full-rate carriage, and reflecting the reflected light in the order of the first mirror, the second mirror, and the third mirror, the image reading apparatus for reading an image on a document as image information, setting a resilient member for applying a tension to said flexible circuit board with the guide member, The elastic member in a position to guide the curved portion of the wrapping serial flexible circuit board, the elastic member is in contact with the flexible circuit board of the full rate carriage side of the turning points of the curved portion, and the full-rate carriage by applying a force in the opposite direction and is characterized in applying a tension to said flexible circuit board.
Further, the invention of claim 2, in the image reading apparatus according to claim 1, thin the elastic member one end fixed to the guide member, contacts the other end to the inside of the curved portion of the flexible circuit board plate It is a shape-like member.
According to a third aspect of the present invention, in the image reading apparatus according to the second aspect , the elastic member has a warp in a direction opposite to a bending direction of the flexible circuit board.
According to a fourth aspect of the present invention, in the image reading apparatus according to the second or third aspect , a relationship of 150 t ≦ R ≦ 160 t is established, where R is a bending radius of the flexible circuit board and t is a plate thickness t of the elastic member. It is characterized by this.
According to a fifth aspect of the present invention, in the image reading apparatus according to the second , third, or fourth aspect , the end portion of the elastic member that contacts the flexible circuit board is bent. .
The invention of claim 6, claim 1, 2, 3, was 4 or an image reading apparatus 5, is characterized in that said elastic member is a PET film.
The invention of claim 7, claim 1, 2, 3, 4, 5 or the image reading apparatus 6, the elastic member is characterized by pressing the entire width direction of the flexible circuit board Is.
According to an eighth aspect of the present invention, there is provided an image forming apparatus comprising: an image reading unit; and an image forming unit that forms an image on a recording material based on image information read by the image reading unit. , claim 1, 2, 3, 4, 6 or those, which comprises using the image reading apparatus 7.

In the image reading apparatus according to any one of claims 1 to 8 , the elastic member provided in the guide member provided in the half-rate carriage causes the elastic force of the elastic member to always act on the flexible circuit board, and the flexible circuit board is in tension. Is always granted .

According to the invention of claims 1 to 8, since the tension of the flexible circuit board is always applied, the occurrence of bending of the flexible circuit board reliably prevented, and excellent as always satisfactory image reading can be performed effectively There is.

Hereinafter, an embodiment in which the present invention is applied to a copying machine (hereinafter simply referred to as a copying machine 1) which is a digital image forming apparatus including an image reading device will be described.
FIG. 1 is a schematic configuration diagram showing the entire copying machine 1 of the present embodiment. FIG. 2 is an explanatory diagram showing a schematic configuration of a main part of the image reading apparatus 100 which is the image reading unit A of FIG. 2 is a view of the image reading unit A in FIG. 1 as viewed from the back side.
The copying machine 1 is roughly composed of an image reading unit (image reading device) A, an image processing unit B, an image storage unit C, an image writing unit D, an image recording unit E, a paper feeding unit F, and the like. . In the copying machine 1, the image writing unit D and the image recording unit E constitute an image forming unit. In the image reading unit A, a document d, which is an image reading object placed on a platen glass 11 (platen glass), is a light source provided on a first carriage 110 as a full-rate carriage that moves on a guide rail 18. Light is irradiated by the first lamp 12a and the second lamp 12b. In the copying machine 1, a light source combining two lamps is used to increase the amount of light applied to the document d. However, a single light source may be used, or a combination of three or more light sources may be used. . In addition, the 1st reflector 29a and the 2nd reflector 29b as a condensing member are each provided in the vicinity of the 1st lamp | ramp 12a and the 2nd lamp | ramp 12b over the elongate direction. The first reflector 29a and the second reflector 29b are for reflecting the light emitted from the first lamp 12a and the second lamp 12b to the side opposite to the original d and irradiating the original d side.

The first carriage 110 includes a first mirror 13 that reflects the reflected light from the document d, and the second carriage 120 that is a half-rate carriage includes a second mirror 14 that reflects the reflected light from the first mirror 13 and A third mirror 15 is provided.
Reflected light from the document d is reflected by the first mirror 13, the second mirror 14, and the third mirror 15, passes through the imaging lens 16, and is received by the CCD 17 as light receiving means. The CCD 17 sequentially photoelectrically converts the received line-shaped optical image and outputs an analog signal that is an electrical signal. As an example, the CCD 17 has a configuration of about 5000 pixels, the size of one pixel is 7 [μm], and the reading unit of one pixel on the document is 63.5 [μm].

  The analog signal photoelectrically converted by the CCD 17 is A / D converted after analog signal processing is performed in the image processing unit B. The digital signal is subjected to predetermined digital signal processing in the image processing unit B, and image data that is image information based on the digital signal after the processing is temporarily stored in the image storage unit C. Digital signal processing performed by the image processing unit B includes, for example, shading correction, luminance / density conversion, EE processing, character / halftone discrimination, filter / magnification processing, copy gamma correction, writing density correction, two beam control, Examples include error diffusion processing and data compression processing. The image data temporarily stored in the image storage unit C is output to the image writing unit D. The image writing unit D outputs writing light based on the image data from the semiconductor laser. The writing light from the semiconductor laser is rotationally scanned by a rotary polygon mirror 22 (polygon mirror) rotated by a drive motor 21. Then, the light passes through the fθ lens 23, passes through the first writing mirror 24, the second writing mirror 25, the cylindrical lens 26, and the third writing mirror 27, and is emitted from the cover glass 28 and provided in the image recording unit E. Irradiated onto the photosensitive drum 31 as the latent image carrier.

The image recording unit E includes a photosensitive drum 31, and a charger 32, a developing unit 33, a transfer unit 34, a separator 35, a cleaning device 36, and the like disposed around the photosensitive drum 31. Further, a transport unit 37, a fixing unit 38, and a paper discharge unit 39 are also arranged on the downstream side of the separator 35, and these also constitute an image recording unit E.
The paper feed unit F includes a paper feed cassette 41 that accommodates transfer paper P as a recording material, a paper feed mechanism 42 that separates and feeds the transfer paper p in the paper feed cassette 41, and the like.

The image reading apparatus 100 shown in FIG. 2 sets a document on the platen glass 11 and presses a start button of an operation unit (not shown) to move the first carriage 110 and the second carriage 120 by a drive motor (not shown). Let it run. At this time, the first carriage 110 moves at a predetermined speed V ₁ and the second carriage 120 moves at a speed V _1/2 . The first carriage 110 and the second carriage 120 slide on the surface of the guide rail 18 and reciprocate in the sub-scanning direction. The first carriage 110 starts moving from the initial position S1 when moving forward (when moving in the scanning direction), and performs image exposure, and when moving backward (when moving in the scanning back direction), image exposure ends. Later, a quick return is made to return to the initial position S1.
During image exposure, light is emitted from the first lamp 12a and the second lamp 12b to illuminate the reading position of the document d. The reflected light of the document d is reflected by the first mirror 13, the second mirror 14, and the third mirror 15 and is read by a reading sensor such as a CCD 17 as reading means through the imaging lens 16. Thereafter, the image forming operation is started in accordance with the mode setting in the operation unit. Although FIG. 1 shows the monochromatic copying machine 1 having only one developing device 33 as developing means, a color copying machine having a plurality of developing means may be used.

FIG. 3 is a perspective view of the first carriage 110 and the second carriage 120 at the initial position S1.
The first carriage 110 and the second carriage 120 shown in FIG. 3 are different from those described with reference to FIGS. 8 and 9 in that a PET film 122 as an elastic member is provided on a guide 121 provided in the second carriage 120. Different.
The first carriage 110 is equipped with a first lamp 12a and a second lamp 12b as two lamps. Electric power supply wires are provided from the respective lamps, and are wired on the first carriage 110 up to the attachment portion of the flexible circuit board 140 in the first carriage 110. The electric wires and the flexible circuit board 140 are coupled by connectors.
A guide 121 that is a guide member of the flexible circuit board 140 is attached to the second carriage 120, and the flexible circuit board 140 is rolled along the guide 121 with a predetermined bending radius. The other end of the flexible circuit board 140 turned downward is fixed by the board fixing portion 141 shown in FIGS. 8 and 9 attached to the scanner unit base.
The guide 121 is provided with a PET film 122 as an elastic member, which will be described in detail later.

FIG. 4 is an enlarged side view of the second carriage 120. The guide 121 is in contact with a flexible circuit board 140, which will be described in detail later, and an elastic member that applies tension to the flexible circuit board 140 by its elasticity is attached.
The elastic member is located on the first carriage 110 side, that is, on the inner peripheral surface of the flexible circuit board 140 above the guide vertex 121t in FIG. 4 with respect to the guide vertex 121t serving as the turning point of the curved portion of the flexible circuit board 140. Contact. Then, by its elastic force, and it applies tension to the flexible circuit board 140 by applying a force in a direction opposite to the first carriage 110 indicated by the arrow alpha.
When a force is applied to the flexible circuit board 140 below the guide vertex 121t, the tension is not directly applied to the flexible circuit board 140 between the second carriage 120 and the first carriage 110 where the tension is to be applied. Therefore, the efficiency of the magnitude of the tension with respect to the elastic force is deteriorated. The greater the elastic force applied to the flexible circuit board 140, the greater the tension of the flexible circuit board 140, and the more reliably the deflection can be prevented. However, the greater the elastic force, the more likely the scraping between the elastic member and the flexible circuit board 140 occurs. Therefore, it is desirable that the tension is efficiently generated with respect to the magnitude of the elastic force. Furthermore, if a force is applied to the flexible circuit board 140 below the guide vertex 121t, the deflection to the upper side becomes free, so that the flexible circuit board 140 above the guide 121 may move upward depending on how the force is applied. There is a possibility of bending. If the flexible circuit board 140 bends upward, the upper surface of the flexible circuit board 140 comes into contact with the lower surface of the document table glass 11, so that the document table glass 11 may be damaged and an image defect may occur.
In FIG. 4, by applying a force in the direction of arrow α, the efficiency of the magnitude of the tension with respect to the magnitude of the elastic force is improved, and the flexible circuit board 140 does not bend upward.

Next, the elastic member will be described.
5A and 5B are explanatory views of the PET film 122 and the guide 121 as thin plate-like elastic members. FIG. 5A is a perspective explanatory view of the PET film 122, and FIG. FIG. FIG. 6 is a cross-sectional explanatory view showing a state in which the PET film 122 is attached to the guide 121. The PET film 122 is fixed to the film adhesion surface 121b which is a curved portion of the guide 121 with a double-sided tape.

In FIG. 5 (a), PET film 122, and the double-sided tape area 122a that is affixed with double-sided tape to the guide 121, and the elastic region 122b that applies tension to the flexible circuit board 140 by its ends is in contact Can be divided into Since the PET film 122 is fixed to the film adhesion surface 121b which is a curved portion of the guide 121, it is desirable that the double-sided tape region 122a be as wide as possible.
That is, the PET film 122 is disposed so as to cover an edge portion that is a boundary between the width guide member 121a of the guide 121 and the beam member of the guide 121 having the film bonding surface 121b, which are in contact with both ends of the flexible circuit board 140 in the width direction. . By providing the PET film 122 so as to cover both ends of the beam member of the guide 121, the PET film 122 can press the entire width direction of the flexible circuit board 140. Thereby, the pressing force applied to the flexible circuit board 140 can be dispersed, and wear due to rubbing can be suppressed.
Further, as indicated by an arrow β in FIG. 5A, the PET film 122 is provided with a solice opposite to the bending direction of the flexible circuit board 140. By attaching the solitude, the flexible circuit board 140 can be surely given an elastic force.

  As shown in FIG. 5 and FIG. 6, the flexible circuit board is such that the PET film 122 is above the guide vertex 121 t by sticking the PET film 122 to the guide 121 so that the elastic region 122 b is above the guide vertex 121 t. 140 contacts the inner peripheral surface. Further, the elastic force acts in the direction opposite to that of the first carriage 110 due to the solitization of the PET film 122, that is, in the direction of the arrow α in FIG. Thereby, even when the two carriages are running, the flexible circuit board 140 can always maintain a stable posture with a constant curvature.

When the flexible circuit board 140 is hung on the guide 121 shown in FIG. 6, not only the end of the elastic region 122b but also the end of the double-sided tape region 122a can contact the flexible circuit board 140.
Therefore, in both ends of the PET film 122, the portion that contacts the flexible circuit board 140 is bent 122c as shown in FIG. If the edge of the end face of the PET film 122 directly hits the flexible circuit board 140, the flexible circuit board 140 and the PET film 122 are rubbed when the two carriages run, and the flexible circuit board 140 is damaged and repeatedly disconnected. There is a possibility. Therefore, the flexible circuit board 140 is received by the bending 122c at the end face of the PET film 122 that can be contacted.
State in this way, by providing the PET film 122 serving as an elastic member to the guide 121, always working status resilient force of the PET film 122 with respect to the flexible circuit board 140, the flexible circuit board 140 which is always tensioned It becomes. As a result, it is possible to reliably prevent the flexible circuit board 140 from being bent and always perform good image reading.

The plate thickness of the PET film 122 greatly contributes to the elastic force. Further, the bending radius of the flexible circuit board 140 greatly contributes to durability due to repeated bending.
Therefore, the film thickness t, which is the plate thickness of the PET film 122, and the bending radius R of the flexible circuit board 140 are examined.

[Experiment 1]
As Experiment 1, the thickness of the PET film 122 as an elastic member included in the image reading apparatus 100 was changed, and the pressing force by the PET film acting on the flexible circuit board 140 at that time was measured.
The measured values of Experiment 1 are shown in Table 1 and FIG.

  Next, the relationship between R / t and the durability of the flexible circuit board 140 was examined. Table 2 shows whether or not the flexible circuit board 140 is scraped (FPC scraped) and the durability is evaluated when R / t is changed.

Higher pressing force from the PET film 122 is large, tension imparted to the flexible circuit board 140 is large, is preferable in order to prevent bending, the flexible circuit board 140 is shaved by rubbing the pressing force is too large, There is a risk of disconnection. When the inventors changed the pressing force applied by the PET film 122 and conducted an experiment, when a load exceeding the pressing force of 0.196 [N] was applied, a problem that the amount of scraping with time increased occurred. Therefore, the pressing force by the PET film 122 is desirably 0.196 [N] or less. Therefore, a film having a film thickness of 0.188 [mm] is used as the PET film 122 applied to the image reading apparatus 100.
From Table 2, the relationship between the radius of curvature of the flexible circuit board 140 and the film thickness t of the PET film 122 is preferably R / t ≧ 150. Table 2 shows the results of evaluating the surface abrasion of the flexible circuit board 140 at the sliding portion and the bending durability of the flexible circuit board 140 in the actual use environment when the R / t is 130 to 160.
Further, if R is increased so that R / t exceeds 160, it is necessary to increase the curved portion of the guide 121. As a result, the height of the image reading apparatus 100 is required, and the large size of the apparatus is required. This is not preferable because it leads to conversion. If R / t exceeds 160 by reducing t, a desired tension cannot be obtained, and there is a possibility that the flexible circuit board 140 will not be sufficiently prevented from being bent. Therefore, a practical range is R / t ≦ 160.
The image reading apparatus 100 is laid out with R = 28.5 [mm] (R / t = 151.6), and can be used without problems in terms of durability and surface abrasion.

As described above, according to the present embodiment, the PET film 122 as the elastic member is provided on the guide 121 as the guide member provided in the second carriage 120 as the half-rate carriage, and the first carriage 110 as the full-rate carriage and the apparatus main body are provided. The elastic force of the PET film 122 always acts on the flexible circuit board 140 to be connected. Thus, the flexible circuit board 140 becomes a state of being always tension, deflection of the occurrence reliably preventing the flexible circuit board 140, can always be performed reading good image.
Further, by providing the PET film 122 at a position where the curved portion of the flexible circuit board 140 is guided, the end of the PET film 122 can be surely contacted, and an elastic force load can always be applied to the flexible circuit board 140. it can.
Further, the PET film 122 contacts the inner peripheral surface of the flexible circuit board 140 on the first carriage 110 side, that is, above the guide vertex 121t, with respect to the guide vertex 121t serving as the turning point of the curved portion of the flexible circuit board 140. , by its elastic force, and applies tension to the flexible circuit board 140 by applying a force in a direction opposite to the first carriage 110 indicated by the arrow alpha. Thus, it is possible to apply an effective tension to the magnitude of the elastic force, and, the flexible circuit board is deflected such upward during carriage travel, the platen glass 11, and there is no striking the frame or the like of the scanner It is possible to maintain a stable posture.
Further, by using a thin plate-like PET film 122 as an elastic member, a simple configuration, it is possible to apply tension to the flexible circuit board 140. Further, as in the embodiment, fixing by double-sided tape makes it possible to perform the removal work at the time of disposal very easily.
Moreover, the PET film 122 can be reliably brought into contact with the curved portion of the flexible circuit board 140 by being provided with a solitude opposite to the bending direction of the flexible circuit board 140.
Also, assuming that the radius of curvature of the flexible circuit board 140 is R and the film thickness of the PET film 122 is t, the relationship 150t ≦ R ≦ 160t holds, so that it can be used without any problem in durability and surface abrasion. And a practical image reading apparatus 100 can be obtained.
Further, a portion of the end face of the PET film 122 that contacts the flexible circuit board 140 is subjected to a bending process, and when the PET film 122 and the flexible circuit board 140 are slid by receiving the flexible circuit board 140 by the bending 122c. It is possible to prevent the flexible circuit board 140 from being scratched by the cosmetic.
Moreover, when the PET film 122 presses the whole width direction of the flexible circuit board 140, the pressing force applied to the flexible circuit board 140 can be dispersed, and wear due to rubbing can be suppressed.
Further, by using the image reading apparatus 100 as the image reading unit of the copying machine 1 as an image forming apparatus, it is possible to prevent image reading failure due to optical path vignetting and to perform good image formation.

1 is a schematic configuration diagram illustrating an entire copying machine according to an embodiment. FIG. 2 is a schematic explanatory diagram of an image reading apparatus of the copier. The perspective view of the 1st carriage and the 2nd carriage in the initial position. The enlarged side view of the 2nd carriage. Explanatory drawing of a PET film and a guide, (a) Perspective explanatory drawing of a PET film, (b) is a perspective explanatory view of a guide. Cross-sectional explanatory drawing of the state which affixed PET film on the guide. The graph which shows the measured value of the experiment 1. FIG. FIG. 3 is an explanatory diagram showing a state in which two carriages have started to move from one end side of an original table glass. FIG. 3 is an explanatory diagram illustrating a state in which a full rate carriage has moved to the other end of the platen glass.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Copy machine 12a 1st lamp | ramp 12b 2nd lamp | ramp 13 1st mirror 14 2nd mirror 15 3rd mirror 16 Imaging lens 17 CCD
31 Photosensitive drum 100 Image reading device 110 First carriage 120 Second carriage 121 Guide 121a Width guide member 121b Film adhesion surface 121t Guide vertex 122 PET film 122a Double-sided tape area 122b Elastic area 122c Bend 140 Flexible circuit board 141 Substrate fixing part

Claims (8)

A full-rate carriage having a light source and a first mirror and moving from one end to the other end of the image reading area;
A half-rate carriage mounted with a second mirror and a third mirror and moving half the distance of the full-rate carriage from the one end of the image reading area;
A flexible circuit board that is looped over by a guide member provided in the half-rate carriage and connects the full-rate carriage and the apparatus main body;
The original is irradiated with the light source while moving the full-rate carriage, and the reflected light is reflected in the order of the first mirror, the second mirror, and the third mirror to read the image on the original as image information. In the image reading device,
Setting an elastic member that applies tension to the flexible circuit board to the guide member,
Setting the elastic member in a position to guide the curved portion of the return of the flexible circuit board,
The elastic member is in contact with the full rate carriage side of the flexible circuit board relative to the turning point of the curved portion, that is with the full-rate carriage to apply tension to the flexible circuit board by applying force in the opposite direction A characteristic image reading apparatus. The image reading apparatus according to claim 1 .
The elastic member is a thin plate-like member having one end fixed to the guide member and the other end contacting the inside of the curved portion of the flexible circuit board. The image reading apparatus according to claim 2 .
The image reading apparatus according to claim 1, wherein the elastic member has a warp in a direction opposite to a bending direction of the flexible circuit board. The image reading apparatus according to claim 2 or 3 ,
When the radius of curvature of the flexible circuit board is R, and the thickness t of the elastic member is
150t ≦ R ≦ 160t
An image reading apparatus characterized by the following relationship: The image reading apparatus according to claim 2 , 3 or 4 ,
An image reading apparatus, wherein an end portion of the elastic member that contacts the flexible circuit board is bent. The image reading apparatus according to claim 1, 2, 3, 4 or 5,
An image reading apparatus, wherein the elastic member is a PET film. Claim 1, 2, 3, 4, 5 or in the image reading apparatus 6,
The image reading apparatus according to claim 1, wherein the elastic member presses the entire width direction of the flexible circuit board. An image reading unit;
In an image forming apparatus having an image forming unit that forms an image on a recording material based on image information read by the image reading unit,
As the image reading unit, according to claim 1, 2, 3, 4, 6 or the image forming apparatus, which comprises using the image reading apparatus 7.

Images