JP2007134907A - Image reader, and document conveying reader and copying machine using same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image reader capable of suppressing transmission of a radio wave to the outside while making positioning precision of a CCD higher than before. <P>SOLUTION: The image reader is equipped with a tubular lamp 162a which irradiates a document where an image is recorded with light and a scanner board unit 220 for an optical image obtained by light reflection on a document surface, and has a circuit board where photoelectric converting elements photoelectrically converting information of the optical image and other electronic components are mounted and an unillustrated bracket supporting it in the scanner board unit 220. A bracket made of a metal material is used as the bracket, and an unillustrated copper plate member as a body independent of the metallic bracket is arranged opposite lead terminals of the other electronic components across a gap and grounded. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an image reading apparatus such as a scanner for reading an optical image obtained by irradiating light on a document on which an image is recorded, and a document conveying / reading apparatus and a copying machine using the image reading apparatus.

  Conventionally, as this kind of image reading apparatus, the one described in Patent Document 1 is known. An optical image obtained by irradiating light from a light source toward a document is picked up by a CCD (Charge Coupled Device) comprising a plurality of photoelectric conversion elements mounted on a scanner board unit as an electronic circuit board.

  In the image reading apparatus having such a configuration, it is necessary to align the CCD with an imaging lens for forming an optical image by reflected light from the original on the CCD. Such alignment is performed by fixing the scanner board unit on which the CCD is mounted to the bracket and adjusting the mounting posture of the bracket with respect to the columns and beams in the apparatus main body. And about this bracket, it was common to use the thing made from resin from a viewpoint of weight reduction and cost reduction.

JP-A-7-162618

  However, the present inventors manufactured a testing machine equipped with a higher resolution CCD in order to meet the demand for higher performance in recent years, and are required for practical use due to the bending and distortion of the resin bracket. The alignment accuracy of the CCD could not be obtained.

  Therefore, the bracket was changed from a resin one to a metal with higher rigidity. Then, instead of obtaining the desired alignment accuracy, a new problem of generation of radio waves that did not occur when the resin bracket was employed occurred. A relatively high frequency radio wave was emitted from the inside of the image reading apparatus to the outside. This high-frequency radio wave may affect the electronic equipment disposed around the image reading apparatus.

  The present inventors have conducted extensive research on the cause of such radio waves, and have found the following. In other words, various electronic components such as IC chips and chip capacitors are mounted on the scanner board unit, which is an electronic circuit board, such as an IC chip and a chip capacitor. High radio waves are generated. The metal bracket functions as an antenna that receives and amplifies and transmits high-frequency radio waves emitted from a plurality of electronic components of the scanner board unit. This is a cause of transmitting high-frequency radio waves from the image reading apparatus.

  The present invention has been made in view of the above background, and an object of the present invention is to suppress the transmission of radio waves to the outside while increasing the alignment accuracy of a photoelectric conversion element such as a CCD as compared with the prior art. It is an object to provide an image reading apparatus capable of performing the above. Another object of the present invention is to provide a document conveying / reading apparatus and a copying machine using such an image reading apparatus.

In order to achieve the above object, the invention of claim 1 comprises a light irradiating means for irradiating a document on which an image is recorded, and a reading unit for reading an optical image obtained by light reflection on the document surface. And an electronic circuit board on which a photoelectric conversion element and other electronic components that photoelectrically convert information of the optical image are mounted, and a support that supports the electronic circuit board. A metal support made of a metal material is used, and the metal support is grounded.
According to a second aspect of the present invention, there is provided a light irradiating means for irradiating light on a document on which an image is recorded, and a reading means for reading an optical image obtained by light reflection on the document surface. In an image reading apparatus having, in the reading means, an electronic circuit board on which a photoelectric conversion element for photoelectrically converting information and other electronic components are mounted, and a support body that supports the electronic circuit board, a metal made of a metal material as the support body. In addition to using a support, a metal plate separate from the metal support is disposed opposite to the main body or lead terminal of the other electronic component via a gap and connected to the ground. It is what.
According to a third aspect of the invention, there is provided light irradiating means for irradiating light on a document on which an image is recorded, and reading means for reading an optical image obtained by light reflection on the document surface. In an image reading apparatus having, in the reading means, an electronic circuit board on which a photoelectric conversion element for photoelectrically converting information and other electronic components are mounted, and a support body that supports the electronic circuit board, a metal made of a metal material as the support body. A support is used, and a metal plate separate from the metal support is disposed opposite to the wiring pattern of the electronic circuit board via a gap and connected to ground. It is.
According to a fourth aspect of the present invention, in the image reading apparatus according to the second or third aspect, the metal plate is supported by the metal support, and the metal support is connected to the ground via the metal plate. It is characterized by this.
According to a fifth aspect of the present invention, in the image reading apparatus according to the fourth aspect, the metal plate having a smaller electric resistance than the metal support is used.
According to a sixth aspect of the present invention, in the image reading apparatus according to any one of the second to fifth aspects, a second metal support is provided for supporting the metal support in direct contact with the second metal support. The metal support is connected to ground.
According to a seventh aspect of the present invention, in the image reading device according to any one of the second to sixth aspects, the metal plate is soldered to a ground wiring pattern of the electronic circuit board.
According to an eighth aspect of the present invention, in the image reading device according to any one of the second to seventh aspects, the metal column, the metal side plate, wherein the end of the metal plate is disposed in the housing of the image reading device and connected to the ground. The metal base plate or the metal beam is brought into contact.
According to a ninth aspect of the present invention, in the image reading apparatus according to the eighth aspect, a plurality of terminals extending from the plate main body are provided on one end side of the metal plate, and the metal struts, metal side plates, metal are provided with the terminals as the end portions. It is made to contact | abut to a baseplate or a metal beam.
Further, the invention of claim 10 is the image reading apparatus of claim 9, wherein the plurality of terminals are each of a curved shape exhibiting flexibility, and the curved surfaces thereof are the metal struts, metal side plates, metal It is made to contact | abut to a baseplate or a metal beam.
According to an eleventh aspect of the present invention, in the image reading apparatus according to the ninth or tenth aspect, the plurality of terminals are arranged in the longitudinal direction of the electronic circuit board.
According to a twelfth aspect of the present invention, there is provided a document conveying / reading apparatus comprising: an image reading device that reads an image recorded on a document; and a document conveying unit that conveys the document to a document reading position by the image reading device. A reading device according to any one of claims 1 to 11 is used.
According to a thirteenth aspect of the present invention, there is provided an image forming means for forming an image on a recording material and an image reading device for reading an image recorded on a document, and the image read by the image reading means is used by the image forming means. In the copying machine for copying the original by being formed on the recording material, the image reading device according to any one of claims 1 to 11 is used.
According to a fourteenth aspect of the present invention, there is provided an image forming unit that forms an image on a recording material, and a document conveying / reading device that reads an image of the document while conveying the document. The image reading device of any one of claims 1 to 11 is used as an image reading device of the document conveying and reading device in a copying machine for copying the document by forming the read image on the recording material by the image forming means. It is characterized by the fact that

In these inventions, by supporting the electronic circuit board on which the photoelectric conversion element is mounted with a metal support, the alignment accuracy of the photoelectric conversion element is increased as compared with the conventional case where the photoelectric conversion element is supported with a resin support. be able to.
In addition, among these inventions, all of the invention specific matters of claim 1 are provided, and even if the radio wave from the electronic component of the electronic circuit board is received by the metal support, it is released to the ground. This suppresses the amplification and transmission of radio waves by the metal support. Thereby, it is possible to suppress transmission of radio waves toward the outside of the image reading apparatus.
Further, in the case of having all of the invention specific matters of claim 2, the electronic component mounted on the electronic circuit board and the radio wave emitted from the lead terminal are received by the electronic support before the metal support is received. Receive with the metal plate facing the lead terminal and escape to ground. Thereby, it is possible to suppress the transmission of radio waves to the outside of the image reading apparatus due to reception and transmission of radio waves by the metal support.
In addition, in the case of having all of the matters specifying the invention of claim 3, before the radio wave emitted from the wiring pattern of the electronic circuit board is received by the metal support, the metal plate facing the wiring pattern is used. Receive and escape to ground. Thereby, it is possible to suppress the transmission of radio waves to the outside of the image reading apparatus due to reception and transmission of radio waves by the metal support.

Hereinafter, an embodiment in which the present invention is applied to an electrophotographic copying machine (hereinafter simply referred to as a copying machine) will be described.
First, a basic configuration of the copying machine according to the present embodiment will be described. FIG. 1 is a schematic configuration diagram showing the copying machine. The copying machine includes an image forming apparatus 1 serving as an image forming unit, a blank paper supply device 40, and a document conveyance reading unit 50. The document conveyance reading unit 50 includes a scanner 150 that is an image reading device fixed on the image forming apparatus 1 and an ADF 51 that is a document conveyance device supported by the scanner 150.

  The blank paper supply device 40 has two paper feed cassettes 42 arranged in multiple stages in a paper bank 41, a feed roller 43 that feeds recording paper as a recording material from the paper feed cassette, and separates and feeds the fed recording paper. A separation roller 45 supplied to the path 44 is provided. The image forming apparatus 1 also includes a plurality of transport rollers 47 that transport the recording paper to the paper feed path 37. Then, the recording paper in the paper feeding cassette is fed into the paper feeding path 37 in the image forming apparatus 1.

  The image forming apparatus 1 includes an optical writing device 2, four process units 3K, Y, M, and C that form toner images of K, Y, M, and C, a transfer unit 24, a paper transport unit 28, and a registration roller. A pair 33, a fixing device 34, a switchback device 36, a paper feed path 37, and the like are provided. Then, a light source such as a laser diode or an LED (not shown) disposed in the optical writing device 2 is driven, and the laser is directed toward the photoconductors 4K, Y, M, and C of the process units 3K, Y, M, and C. Irradiate light L. By this irradiation, an electrostatic latent image is formed on the surface of the drum-shaped photoconductors 4K, Y, M, and C, and this latent image is developed into a toner image via a predetermined development process. Note that the subscripts K, Y, M, and C added after the reference numerals indicate specifications for black, yellow, magenta, and cyan.

  FIG. 2 is an enlarged partial configuration diagram illustrating a part of the internal configuration of the image forming apparatus. In the figure, process units 3K, 3Y, 3M, and 3C support a photosensitive member and various devices disposed around it as a single unit on a common support, and the image forming apparatus 1 It can be attached to and detached from the main body. Taking the process unit 3K for black as an example, this has a developing device 6K for developing the electrostatic latent image formed on the surface of the photosensitive member 4K into a black toner image in addition to the photoreceptor 4K. Further, it also includes a drum cleaning device 15 that cleans transfer residual toner adhering to the surface of the photoreceptor 4K after passing through a K primary transfer nip described later. This copying machine has a so-called tandem configuration in which four process units 3K, Y, M, and C are arranged so as to face each other along an endless movement direction with respect to an intermediate transfer belt 25 described later. .

  FIG. 3 is a partially enlarged view showing a part of a tandem part composed of four process units 3K, Y, M, and C. Since the four process units 3K, Y, M, and C have the same configuration except that the colors of the toners to be used are different, the subscripts K, Y, M, and C attached to the respective reference numerals in FIG. Omitted. As shown in the figure, the process unit 3 includes a charging device 23, a developing device 6, a drum cleaning device 15, a charge removal lamp 22, and the like around the photoreceptor 4.

  As the photoreceptor 4, a drum-shaped member is used in which a photosensitive layer is formed by applying a photosensitive organic photosensitive material to a base tube made of aluminum or the like. However, an endless belt may be used.

  The developing device 6 develops the latent image using a two-component developer containing a magnetic carrier and a nonmagnetic toner (not shown). Then, the agitation unit 7 that conveys the two-component developer contained therein and supplies the developer sleeve 12 with stirring, and the toner in the two-component developer carried on the development sleeve 12 is transferred to the photoreceptor 4. And a developing unit 11 for the purpose.

  The stirring unit 7 is provided at a position lower than the developing unit 11, and is provided on the bottom surface of the developing case 9, two conveying screws 8 arranged in parallel to each other, a partition plate provided between these screws. The toner density sensor 10 is included.

  The developing unit 11 includes a developing sleeve 12 that faces the photosensitive member 4 through the opening of the developing case 9, a magnet roller 13 that is non-rotatably provided inside the developing sleeve 12, a doctor blade 14 that approaches the developing sleeve 12, and the like. ing. The developing sleeve 12 has a non-magnetic rotatable cylindrical shape. The magnet roller 13 has a plurality of magnetic poles arranged along the rotation direction of the sleeve. Each of these magnetic poles applies a magnetic force to the two-component developer on the sleeve at a predetermined position in the rotation direction. As a result, the two-component developer sent from the stirring unit 7 is attracted and carried on the surface of the developing sleeve 12 and a magnetic brush is formed along the magnetic field lines on the sleeve surface.

  This magnetic brush is regulated to an appropriate layer thickness when passing through the position facing the doctor blade 14 as the developing sleeve 12 rotates, and then conveyed to the developing region facing the photoconductor 4. Then, the toner is transferred onto the electrostatic latent image by the potential difference between the developing bias applied to the developing sleeve 12 and the electrostatic latent image on the photosensitive member 4, thereby contributing to development. Further, as the developing sleeve 12 rotates, the developing sleeve 12 is returned to the developing portion 11 again, and after being separated from the sleeve surface by the influence of the repulsive magnetic field formed between the magnetic poles of the magnet roller 13, the developing sleeve 12 is returned to the stirring portion 7. An appropriate amount of toner is supplied to the two-component developer in the stirring unit 7 based on the detection result of the toner density sensor 10. The developing device 6 may employ a one-component developer that does not include a magnetic carrier, instead of one that uses a two-component developer.

  As the drum cleaning device 15, a system in which a polyurethane rubber cleaning blade 16 is pressed against the photosensitive member 4 is used, but another system may be used. For the purpose of enhancing the cleaning property, this example employs a system having a contact conductive fur brush 17 whose outer peripheral surface is in contact with the photoreceptor 4 so as to be rotatable in the direction of the arrow in the figure. The fur brush 17 also serves to apply the lubricant to the surface of the photosensitive member 4 while scraping the lubricant from a solid lubricant (not shown) into a fine powder. A metal electric field roller 18 for applying a bias to the fur brush 17 is rotatably provided in the direction of the arrow in the figure, and the tip of the scraper 19 is pressed against it. The toner attached to the fur brush 17 is transferred to the electric field roller 18 to which a bias is applied while rotating in contact with the fur brush 17 in the counter direction. Then, after being scraped from the electric field roller 18 by the scraper 19, it falls onto the recovery screw 20. The collection screw 20 conveys the collected toner toward the end of the drum cleaning device 15 in the direction orthogonal to the drawing sheet surface, and transfers it to the external recycling conveyance device 21. The recycle conveyance device 21 sends the delivered toner to the developing device 15 for recycling.

  The neutralization lamp 22 neutralizes the photoreceptor 4 by light irradiation. The surface of the photoreceptor 4 that has been neutralized is uniformly charged by the charging device 23 and then subjected to optical writing processing by the optical writing device 2. As the charging device 23, a charging device that rotates a charging roller to which a charging bias is applied while contacting the photosensitive member 4 is used. A scorotron charger or the like that performs a non-contact charging process on the photoreceptor 4 may be used.

  In FIG. 2 described above, K, Y, M, and C toner images are formed on the photoreceptors 4K, Y, M, and C of the four process units 3K, Y, M, and C by the processes described above. Is done.

  A transfer unit 24 is disposed below the four process units 3K, Y, M, and C. The transfer unit 24 moves the intermediate transfer belt 25 stretched by a plurality of rollers endlessly in the clockwise direction in the drawing while contacting the photoreceptors 4K, Y, M, and C. As a result, primary transfer nips for K, Y, M, and C in which the photoreceptors 4K, Y, M, and C contact the intermediate transfer belt 25 are formed. In the vicinity of the primary transfer nips for K, Y, M, and C, the intermediate transfer belt 25 is moved to the photoreceptors 4K, Y, M, and C by primary transfer rollers 26K, Y, M, and C disposed inside the belt loop. Pressing toward C. A primary transfer bias is applied to the primary transfer rollers 26K, Y, M, and C by a power source (not shown). As a result, a primary transfer electric field for electrostatically moving the toner images on the photoreceptors 4K, Y, M, and C toward the intermediate transfer belt 25 is formed in the primary transfer nips for K, Y, M, and C. Has been. In the drawing, a toner image is formed on each of the primary transfer nips on the front surface of the intermediate transfer belt 25 that sequentially passes through the primary transfer nips for K, Y, M, and C with endless movement in the clockwise direction. Are sequentially superimposed and primarily transferred. By this primary transfer of superposition, a four-color superposed toner image (hereinafter referred to as a four-color toner image) is formed on the front surface of the intermediate transfer belt 25.

  Below the transfer unit 24 in the figure, a paper transport unit 28 is provided between the drive roller 30 and the secondary transfer roller 31 to endlessly move the endless paper transport belt 29. The intermediate transfer belt 25 and the paper transport belt 29 are sandwiched between the secondary transfer roller 31 and the lower stretching roller 27 of the transfer unit 24. As a result, a secondary transfer nip is formed in which the front surface of the intermediate transfer belt 25 and the front surface of the paper transport belt 29 come into contact with each other. A secondary transfer bias is applied to the secondary transfer roller 31 by a power source (not shown). On the other hand, the lower stretching roller 27 of the transfer unit 24 is grounded. Thereby, a secondary transfer electric field is formed in the secondary transfer nip.

  A registration roller pair 33 is disposed on the right side of the secondary transfer nip in the drawing, and the secondary transfer nip 33 is arranged at a timing at which the recording paper sandwiched between the rollers can be synchronized with the four-color toner image on the intermediate transfer belt 25. Send to transfer nip. In the secondary transfer nip, the four-color toner images on the intermediate transfer belt 25 are secondarily transferred onto the recording paper under the influence of the secondary transfer electric field and nip pressure, and become a full-color image combined with the white color of the recording paper. The recording paper that has passed through the secondary transfer nip is separated from the intermediate transfer belt 25 and is conveyed to the fixing device 34 along with its endless movement while being held on the front surface of the paper conveying belt 29.

  On the surface of the intermediate transfer belt 25 that has passed through the secondary transfer nip, residual transfer toner that has not been transferred to the recording paper at the secondary transfer nip adheres. This transfer residual toner is scraped off and removed by a belt cleaning device in contact with the intermediate transfer belt 25.

  The recording paper conveyed to the fixing device 34 is fixed to a full color image by pressurization or heating in the fixing device 34, and then sent from the fixing device 34 to the paper discharge roller pair 35, and then to the outside of the apparatus. Discharged.

  In FIG. 1 described above, a switchback device 36 is disposed under the paper transport unit 22 and the fixing device 34. As a result, the recording paper that has undergone the image fixing process on one side is switched by the switching claw to the recording paper reversing device side, and is reversed there to enter the secondary transfer transfer nip again. Then, after the secondary transfer process and the fixing process of the image are performed on the other side, the sheet is discharged onto a discharge tray.

  The scanner 150 fixed on the image forming apparatus 1 includes a fixed reading unit 151 and a moving reading unit 152. A fixed reading unit 151 having a light source, a reflection mirror, a CCD, and the like is disposed immediately below a first contact glass (not shown) fixed to the upper wall of the casing of the scanner 150 so as to contact the document MS. Then, when a document MS conveyed by an ADF 51 (described later) passes through the first contact glass, the light emitted from the light source is sequentially reflected on the document surface and received by the CCD via a plurality of reflection mirrors. Thereby, the document MS is read without moving the optical system including the light source and the reflection mirror. Hereinafter, control for reading the image of the document MS by the fixed reading unit 151 while conveying the document by the ADF 51 is referred to as through-reading control.

  On the other hand, the moving reading unit 152 is disposed directly below the second contact glass (not shown) fixed to the upper wall of the casing of the scanner 150 so as to come into contact with the document MS, and is disposed on the right side of the fixed reading unit 151 in the drawing. The moving optical system including the light source and the reflecting mirror can be moved in the left-right direction in the figure. Then, in the process of moving the moving optical system from the left side to the right side in the figure, the light emitted from the light source is reflected by a document (not shown) placed on the second contact glass. The optical image obtained by this reflection passes through a plurality of reflecting mirrors and an imaging lens fixed to the scanner body, and is then read by the CCD. Thus, the moving reading unit 152 reads the image of the document MS that is stationary on the second contact glass while moving the moving optical system.

  An ADF 51 disposed on the scanner 150 includes a document placing table 53 for placing a document MS before reading on a main body cover 52, a transport unit 54 for transporting the document MS, and a document MS after reading. A document stack base 55 for stacking is held. As shown in FIG. 4, it is supported by a hinge 159 fixed to the scanner 150 so as to be swingable in the vertical direction. Then, by swinging, it moves like an open / close door, and the first contact glass 154 and the second contact glass 155 on the upper surface of the scanner 150 are exposed in the opened state. In the case of a single-sided original such as a book in which one corner of the original bundle is bound, the originals cannot be separated one by one and cannot be transported by ADF. Therefore, in the case of a single-sided original, the ADF 51 is opened as shown in FIG. 4, and then the single-sided original with the page to be read open is placed face down on the second contact glass 154, and then the ADF is close. Then, the image of the page is read by the moving reading unit 152 of the scanner 150 shown in FIG.

  On the other hand, in the case of an original bundle in which a plurality of independent originals MS are simply stacked, the original MS can be sequentially read by the fixed reading unit 151 of the scanner 150 while being automatically conveyed one by one by the ADF 51. . In this case, after setting the document bundle on the document placing table 53, a copy start button (not shown) is pressed. Then, the ADF 51 sends the originals MS of the original bundle placed on the original placement table 53 into the conveyance unit 54 in order from the top, and conveys the original MS toward the original stack table 55 while inverting it. In the course of this conveyance, immediately after the document MS is reversed, the original MS is passed directly above the fixed reading unit 151 of the scanner 150. At this time, the image of the document MS is read by the fixed reading unit 151 of the scanner 150.

  FIG. 5 is an enlarged configuration diagram showing the main configuration of the ADF 51 together with the upper portion of the scanner 150. In the figure, an ADF 51 has a document stacking table 55 for stacking documents MS after images are read. The document stacking table 55 is fixed to the lower part of the main body cover 52 of the ADF 51, and a document mounting table 53 on which the document MS before being read is mounted is fixed to the main body cover 52 just above the document stacking table 55. The document stacking table 55 and the document mounting table 53 are arranged so as to overlap each other in the vertical direction. On the left side of the table, a conveyance unit 54 as conveyance means for conveying the document MS is fixed to the main body cover 52, and a document conveyance path 56 for passing paper is formed inside. Yes. The document transport path 56 is curved in the shape of the letter “C” in the drawing, and after the document MS received from the document placing table 53 is transported from the right side to the left in the drawing, Invert at the bend. By this reversal, the reading surface of the document MS, which has the reading surface directed upward in the document mounting table 53, is directed downward in the vertical direction. Next, the document MS is conveyed from the left side to the right side in the drawing.

  Most of the document transport path 56 of the ADF 51 is formed between two guide plates that are curved in a complicated manner while facing each other with a predetermined gap therebetween, and the document MS is transported between these two guide plates. . However, in all the steps of the document conveyance path 56, the document conveyance path 56 is connected between the ADF 51 and the scanner 150 in the process of crossing directly above the document exposure position by a fixed reading unit (151 in FIG. 1) of the scanner 150. It is formed between. Specifically, it is formed between the fixed reading guide member 60 provided at the lower part of the document conveyance path 56 and the first contact glass 154 of the scanner 150.

  The original MS that is reversed from the leftmost curved portion in the drawing in the original conveying path 56 of the ADF 51 and then conveyed from the left to the right in the drawing is the first contact glass that is the exposure position of the fixed reading portion. Cross over 154. At this time, the image on the reading surface of the document MS is read by the fixed reading unit. After being read, the document MS is guided by the guide protrusion 156 disposed between the first contact glass 154 and the second contact glass 155 of the scanner 150 and again enters the transport unit 54 of the ADF 51. Then, it is sent onto the document stack table 55.

  FIG. 6 is a partial perspective view partially showing the scanner 150. In the figure, the moving reading unit (152 in FIG. 1) of the entire scanner 150 is shown obliquely from above, and the second contact glass is not shown for convenience. In the housing 160 of the scanner 150, two metal first rails 161 (only one is shown in the figure) extending in the longitudinal direction are fixed at a predetermined interval in the short direction. ing. Two metal second rails (not shown) extending in the longitudinal direction of the casing are fixed below the first rails 161 in the vertical direction with a predetermined interval in the lateral direction of the casing. ing. The first rail and the second rail 161 are grounded via a ground wire (not shown).

  A first moving body 162 is bridged between the two first rails 161 and can travel along the longitudinal direction on the first rail 161. Moreover, the 2nd mobile body 163 is spanned between the two 2nd rails which are not shown in figure, and it can drive | work along the longitudinal direction on a 2nd rail. Moreover, the edge part of the metal beam plates 164 is being fixed to the mutually opposing surface in the two 1st rails 161. As shown in FIG. As a result, the beam plate 164 is fixed in a posture spanned between the two first rails 161.

  The metal beam plate 164 supports a lens unit 200 fixed to the upper surface of the metal beam plate 164 and a scanner board unit 220 (hereinafter referred to as SBU 220) which is an electronic circuit board fixed to the lens unit 200.

  The first moving body 162 as a light irradiating means has a tubular lamp 162a as a light source, and irradiates the emitted light to a document (not shown) through a second contact lens (not shown).

  FIG. 7 is an enlarged configuration diagram showing the moving reading unit of the scanner 150 from the side. In the figure, a wire drive pulley 166 fixed to the rotary shaft member 165 is rotatably provided on the right side of the SBU 220 in the figure, and the drive wire 167 is wound around the pulley surface. The drive wire 167 has a single string shape without a loop structure. The wire drive pulley 166 crosses itself while being wound around the pulley surface and extends one end side from the wire drive pulley 166 in the right direction in the figure, and the other end side from the wire drive pulley 166 in the left direction in the figure. It is extended to. Hereinafter, the portion of the drive wire 167 extending from the wire drive pulley 166 in the left direction in the figure is referred to as one end side portion. Further, a portion extending from the wire drive pulley 166 in the right direction in the drawing is referred to as the other end portion.

  One end portion of the drive wire 167 extends from the wire drive pulley 166 (167d), and is then wound around a first relay pulley 171 that is rotatably supported by a bearing (not shown) so as to face left from a right-facing posture in the figure. (167e). Then, it is wound around an inner pulley portion (described later) of a carriage pulley 168 that is rotatably supported by a bearing (not shown) provided on the second moving body 163, and then turns back again from a leftward posture to a rightward posture in the drawing (167f). ). The end is fixed to the column of the main body via a tension spring 169.

  On the other hand, the other end portion of the drive wire 167 extends from the wire drive pulley 166 (167a), and is then wound around a second relay pulley 170 that is rotatably supported by a bearing (not shown). The posture is turned back from the posture to the right (167b). Then, it is looped around an outer pulley portion, which will be described later, of carriage carriage 168, and is turned back again from the rightward posture to the leftward posture in the drawing (167c). The end is fixed to the column of the main body.

  The first moving body 162 is connected to the extended portion between the first relay pulley 171 and the carriage pulley 168 at one end side portion of the drive wire 167. When the one end side portion of the drive wire 167 is sent out from the wire drive pulley 166 or wound around the wire drive pulley 166 as the wire drive pulley 166 rotates, the first moving body 162 is not shown in the drawing. Run on the rail in the horizontal direction in the figure. Accordingly, the second moving body 163 that holds the carriage pulley 168 is illustrated in which the other end side portion of the drive wire 167 is fed out of the wire drive pulley 166 or wound around the wire drive pulley. Run on the second rail in the horizontal direction in the figure.

  The first moving body 162 irradiates a document (not shown) with a tubular lamp 162a when traveling in the right direction in the drawing. Thus, the original is optically scanned in the sub-scanning direction that is the moving body moving direction. The reflected light beam (optical image) from the document is reflected on the first reflecting mirror 162 b held by the first moving body 162 and travels toward the second moving body 163. Then, the light is sequentially reflected on the second reflecting mirror 163a and the third reflecting mirror 163b of the second moving body 163, and is folded back from the direction toward the left side to the right side in the drawing. Thereafter, after passing through an imaging lens (not shown) of the lens unit 200, an image is formed on the element surface of the CCD 221 of the SBU 220. The CCD 221 has a plurality of photoelectric conversion elements (not shown) arranged in a direction orthogonal to the drawing surface, and receives light with each of them to perform optical scanning in the main scanning direction, which is a direction orthogonal to the scanning direction on the document surface. Do.

  The second moving body 163 has the same speed as that of the first moving body 162 at half the speed of the first moving body 162 so as to cancel the overlapping of the optical paths caused by the return of the light flux by the two reflecting mirrors (163a, b). Move in the direction. Due to such a moving speed relationship, even if the first moving body 162 moves relative to the document, the optical path length of the light beam from the document surface to the lens unit 200 does not change.

  Since the travel range of the second moving body 163 is half that of the first moving body 162, the region on the right half in the figure in the longitudinal direction on the second rail is not used for the travel of the second moving body 163. However, if this region is cut off, the parallelism of the second rail will be adversely affected. Therefore, it is extended to the right side in the figure without being cut off and fixed to the side plate of the casing. In this region, while the rotation shaft member 165 of the wire drive pulley 166 is rotatably received, the vertical position of the rotation shaft member 165 is positioned above the rail surface of the second rail in the vertical direction. By positioning the rotary shaft member 165 in this way, the wire drive pulley 166 can be brought closer to the document surface side, and the apparatus can be miniaturized.

  FIG. 8 is a schematic diagram illustrating a wire driving system in the moving reading unit of the scanner 150. The carriage pulley 168 moves on a second rail (not shown) together with the second moving body while being rotatably held by the second moving body (163). What is involved in the movement of the carriage pulley 168 and the second moving body is the first turn-back point 167b and the second turn-back point 167c at the other end side of the drive wire 167, which are the rails of the second rail, respectively. It must be parallel to the surface. This is because the second moving body and the carriage pulley 168 cannot be moved at a constant speed if they are not parallel. The carriage pulley 168 is a double groove pulley that rotates an inner pulley portion 168a for winding the one end side portion of the drive wire 167 and an outer pulley portion 168b for winding the other end side portion on the same axis. It is.

  Each of the first relay pulley 171 and the second relay pulley 170 has its rotation axis inclined so that the top of the first relay pulley 171 and the second relay pulley 170 are further away from the central extension line in the thickness direction of the wire drive pulley 166 than the bottom top in the vertical direction. (Hereinafter, such an inclination is referred to as an inner inclination). Further, the carriage pulley 168 has its rotation shaft inclined in the direction opposite to these relay pulleys (hereinafter, such inclination is referred to as an outer inclination). The rotating shaft member of the wire drive pulley 166 is horizontal. The reason why each axis is in such a relationship is as follows. In other words, the portion 167a before folding at the other end of the drive wire 167 slightly moves the winding start position in the axial direction as the wire drive pulley 1664 rotates. Then, when the carriage pulley 168 comes closest to the second relay pulley 170, there is a possibility that the portion 167a before folding and the carriage pulley 168 come into contact with each other. In order to avoid this contact, the second relay pulley 170 is inclined to keep the front part 167a and the carriage pulley 168 away from each other in the vertical direction.

  FIG. 9 is an enlarged configuration diagram showing the wire driving motor 172 of the moving reading unit and the surrounding configuration from the direction of extending the driving wire. In the figure, the wire drive motor 172 is fixed in such a posture that its motor shaft 172a extends in a direction parallel to the rotating shaft member 165 of the wire drive pulley 166 described above. A belt drive pulley 173 is fixed to the tip of the motor shaft 172a. A drive receiving pulley 175 is fixed to the end of the rotating shaft member 165 of the wire drive pulley. A driving belt 174 is wound around the belt driving pulley 173 and the driving receiving pulley 175, and the rotational driving force of the motor shaft 172 a is wire driven via the driving belt 174, the driving receiving pulley 175 and the rotating shaft member 165. It is transmitted to the pulley 166.

  The center in the lateral direction of the scanner is on the right side of the area shown in FIG. The rotational drive shaft 165 of the wire drive pulley 166 is in a horizontal posture, but the second relay pulley 170 has its top apex directed to the center in the short direction of the apparatus as indicated by an arrow A in the figure. Inclined. The first relay pulley has a similar posture. On the other hand, the carriage pulley 168 is inclined so that its upper long portion is directed outwardly opposite to the center in the short direction of the apparatus, as indicated by an arrow B in the drawing. The center position of each pulley in the horizontal direction is in the order of the wire drive pulley 166, the second relay pulley 170, and the carriage pulley 168 from the outside of the apparatus toward the center.

  The upper top portion of the wire drive pulley 166 is positioned above the bottom top portion of the second relay pulley 170 in the vertical direction. Thereby, the height in the vertical direction of the entire apparatus can be reduced. However, the upper top portion of the wire drive pulley 1664 is positioned lower than the upper top portion of the second relay pulley 170 in the vertical direction. Thereby, interference with the drive wire 167 and the wire drive pulley 166 is avoided. This relationship is the same for the first relay pulley (171).

  In the other end portion of the drive wire 167, the extended portion between the wire drive pulley 166 and the second relay pulley 170 is located on the same line as the tangent to the wire drive pulley 166. Strictly speaking, the winding start position of the drive wire 167 with respect to the wire drive pulley 166 (corresponding to a contact when the wire is regarded as a tangent) moves slightly in the axial direction, but on the average is located on the same line. It can be said.

  In addition, the extended portion between the second relay pulley 170 and the carriage pulley 168 at the other end of the drive wire 167 is located on the same line as the tangent to both pulleys. Therefore, the winding start position for both pulleys overlaps the same point in FIG. The first relay pulley (171) is the same.

  By adopting such a configuration, it is possible to reduce the overlap of the drive wires 167 in the vertical direction and facilitate the wire winding work around each pulley.

Next, a characteristic configuration of the copying machine will be described.
FIG. 10 is a perspective view showing the beam plate 164, the lens unit 200, and the SBU 220 in the moving reading unit of the scanner. The Z axis in the figure is the moving body moving direction (sub-scanning direction) axis of the reflected light beam (optical image) sent from the first moving body 162 through the second moving body 163 shown in FIG. Yes, it is the same as the incident direction axis with respect to the lens unit 200. The X axis is the main scanning direction axis of the document and is orthogonal to the Z axis. The Y axis is an axis orthogonal to the Z axis and the X axis, and corresponds to the vertical direction axis in this copying machine. Further, an arrow α in the figure indicates a rotation direction around the X axis (hereinafter, this rotation direction is referred to as an α rotation direction). Further, in the figure, an arrow β indicates a rotation direction about the Y axis (hereinafter, this rotation direction is referred to as a β rotation direction). In the figure, an arrow γ indicates a rotation direction around the Z axis (hereinafter, this rotation direction is referred to as a γ rotation direction). The reflected light beam is incident on the lens unit 200 with a certain angle range in a plane parallel to the X axis, and the center of the angle range is the incident angle of the reflected light beam.

  In FIG. 10, the beam plate 164 is fixed between two first rails (not shown) as described above. The lens unit 200 includes a box portion 201 formed into a box shape by bending a sheet metal and press-fitting and connecting the bent portions, and an imaging lens 202 fixed inside the box portion 201. The box part 201 has a bottom plate part and a standing wall raised by a bending process of a peripheral part thereof and a press-fitting connection process of the bent part. However, no standing wall is formed by bending at the end of the rear side of the bottom plate (the incident side of the reflected light beam is the front side). That is, the box portion 201 includes a front wall that is a standing wall rising on the front side in the Z-axis direction, and two side walls that are opposed to each other at a predetermined distance in the X-axis direction while orthogonal to the front wall. have. A reflected light beam (not shown) is received in the box part 201 from the opening provided in the front wall, and then passed through the imaging lens 202 in the box part 201. The reflected light beam that has passed through the imaging lens 202 forms an image on the photoelectric conversion element surface of the CCD of the SBU 220.

  Two screw holes are formed in each of the two side walls described above in the box part 201. The third bracket 203 has an L-shaped shape that is bent when viewed from the X-axis direction. The third bracket 203 has two positions from the rear side with respect to the box portion 201 in a posture in which the L-shape is rotated by 180 [°]. Inserted between the side walls. There are two contact walls that individually contact the two side walls of the box part 201, and screw holes are formed in each of them. Bolts are inserted so as to pass through the screw holes of the third bracket 203 and the screw holes of the box part 201, and the third bracket 203 is fixed to the box part 201 with screws.

The third bracket 203 is screwed from the rear side with a metal second bracket 204 formed into a “U” -shaped cross-sectional shape by bending the sheet metal and press-fitting and connecting the bent portions. ing. Specifically, screw holes are respectively formed at both end portions in the X-axis direction on the falling wall that falls at the rear end portion of the third bracket 203. Further, the second bracket 204 has a contact wall that contacts the falling wall, and two screw holes respectively corresponding to the two screw holes of the third bracket 203 are formed on the contact wall. ing. Bolts are inserted so as to pass through the screw holes of the third bracket 203 and the screw holes of the second bracket 204, and the second bracket 204 is screwed and fixed to the rear end side of the third bracket 203.

  Screw holes are formed in both ends of the top plate of the second bracket 204 in the X-axis direction. On the other hand, the first bracket 205 has an L-shape when viewed from the X-axis direction, and takes a posture in which the L-shape is rotated by 180 [°]. One side portion of the L-shape of the first bracket 205 is a contact portion with the top plate of the second bracket 204, and this contact portion has two contact holes respectively corresponding to the two screw holes of the second bracket 204. Screw holes are formed. Bolts are inserted so as to pass through the screw holes of the first bracket 205 and the screw holes of the second bracket 204, and the first bracket 205 is screwed and fixed to the rear end side of the second bracket 204.

  The SBU 220 is in a vertical position in the scanner housing, and this is realized by screwing and fixing to the vertical surface of the first bracket 205 as shown in FIG. A CCD 221 having a plurality of photoelectric conversion elements (not shown) is mounted on the SBU unit 220. The CCD 221 is fixed on the substrate by soldering the first bracket 205 to the wiring substrate through an opening provided in the first bracket 205 after the first bracket 205 is fixed to the wiring substrate of the SBU unit 220 with screws. For this reason, the SBU 220 positions the wiring board on the rear side of the falling plate portion of the first bracket 205, while positioning the CCD 221 on the front side of the falling plate portion. In the CCD 221, the red (R) photoelectric conversion element, the grain (G) photoelectric conversion element, and the blue (B) photoelectric conversion element are sequentially arranged from the upper side to the lower side in the Y-axis direction in FIG. A plurality of arranged RGB element rows are arranged in the X-axis direction.

  In this way, as shown in FIG. 10, the SBU 220 includes the first metal bracket 205, the second metal bracket 204, the third metal bracket 203, and the metal box portion 201. Is supported by a metal beam plate 164.

  By adjusting the mounting posture of the third bracket 203 with respect to the box portion 201 of the lens unit 200 in the α rotation direction at the time of fixing with screws, the CCD unit can be aligned with the imaging lens 202 of the lens unit 200 in the α rotation direction. it can. Further, by adjusting the mounting position of the second bracket 204 with respect to the third bracket 203 in the X-axis direction and the Y-axis direction when fixing with screws, the CCD is aligned with the imaging lens 202 in the X-axis direction and Y-axis direction. It can be carried out. Further, by adjusting the mounting posture of the second bracket 204 in the γ rotation direction with respect to the third bracket 203 at the time of fixing with screws, it is possible to align the CCD in the γ rotation direction with respect to the imaging lens 202. Further, by adjusting the mounting position of the first bracket 205 in the X-axis direction and the X-axis direction with respect to the second bracket 204 when fixing with screws, the alignment of the CCD in the X-axis direction and Y-axis direction with respect to the imaging lens 202 is adjusted. It can be carried out. Further, by adjusting the mounting orientation of the first bracket 205 in the β rotation direction with respect to the second bracket 204 at the time of fixing with screws, the CCD lens can be aligned with the imaging lens 202 in the β rotation direction.

  As shown in FIG. 12, the first bracket 205 has a screw hole provided in the board and a screw hole provided in the board while the inverted L-shaped falling part is brought into close contact with the board surface of the SBU 220. Bolts are inserted so as to penetrate. Then, the SBU 220 is fixed to the falling portion of the first bracket 205. In the copying machine according to the present embodiment, the first bracket 205, which is a support for supporting the SBU 220, is made of metal, so that unlike the conventional case of using resin, the high resolution The alignment accuracy required for the CCD could be satisfied.

  In addition to the CCD, various electronic components such as an IC chip and a chip capacitor (not shown) are mounted on the wiring board of the SBU 220. The mounting surface of these electronic components is opposite to the first bracket fixing surface, and this surface faces the front side in the figure. A plurality of electronic components (not shown) mounted on the surface are fixed to the wiring board by soldering lead terminals penetrating through through holes (not shown) of the wiring board on the first bracket fixing surface of the wiring board. Yes. High-frequency radio waves are generated from the packages of the plurality of electronic components and are received by the first metal bracket 205 that functions as an antenna. Thereafter, the first bracket 205 amplifies and transmits the radio wave, thereby transmitting a relatively strong high-frequency radio wave toward the outside of the scanner.

  Unlike the plurality of electronic components described above, the CCD 221 is mounted on the first bracket fixing surface of the wiring board of the SBU 220 as shown in FIG. A plurality of electronic component packages do not exist on the first bracket fixing surface, but lead terminals of the electronic components penetrate from the opposite surface side and are fixed by soldering. High-frequency radio waves are also generated from the plurality of lead terminal solder fixing portions, and are received, amplified, and transmitted by the first metal bracket 205.

  On the other hand, in FIG. 10 shown above, the metal first bracket 205 includes a metal second bracket 204, a metal first bracket 203, a metal box 201, and a metal beam plate. It is connected to ground via 164 and a metal first rail (not shown). In such a configuration, by letting the radio wave received by the first bracket 205 escape to the ground, it is possible to suppress a situation where the radio wave is received, amplified, and transmitted by the first bracket 205.

  In the copying machine according to the present embodiment, as shown in FIG. 13, a copper plate member 230 as a metal plate separate from the metal support is fixed to the first bracket 205 with screws. Then, the ground connection was made while facing the lead terminal fixing pattern, which is a wiring pattern on the first bracket fixing surface of the wiring board of the SBU 220, through a gap. In such a configuration, the radio wave received by the first bracket 205 is released to the ground via the second bracket (204) and also to the ground via the copper plate member 230, thereby Reception, amplification and transmission can be further suppressed. Further, most of the high frequency radio waves emitted from the lead terminal fixing pattern on the first bracket fixing surface are received by the copper plate member 230 and released to the ground before being received by the metal first bracket 205. Thereby, reception, amplification and transmission of radio waves by the first bracket can be further suppressed.

  As the metal plate opposed to the above-described lead terminal fixing pattern, one made of various metals can be used in place of the copper plate member 230 made of copper. However, it is desirable to use one whose overall electrical resistance is smaller than the overall electrical resistance of the first bracket 205. This is because such a configuration can suppress a situation in which radio waves received by the metal plate are leaked to the first bracket 205. Also in the present embodiment, the copper plate member 230 is thinner than the first bracket 205 and inferior in strength but has a much smaller electrical resistance.

  FIG. 14 is a cross-sectional view showing the SBU 220 and the surrounding configuration. The CCD 221 of the SBU 220 is located on the front side (light incident side) of the first bracket 205 in the Z-axis direction as shown in the figure, but is not in contact with the metal first bracket 205. The lead terminal 221a is soldered to the wiring board through the opening of the first bracket 205, so that the lead terminal 221a is fixed on the wiring board while maintaining a non-contact state with the first bracket 205.

  As described above, a plurality of electronic component packages (not shown) are present on the surface of the wiring board of the SBU 220 opposite to the first bracket fixing surface, and high-frequency radio waves are also generated from these packages. On the other hand, on the rear side in the Z-axis direction from the first bracket 205, a second copper plate member 231 is erected on the beam plate 164 of the scanner main body by screwing and fixing, and is opposite to the opposite surface of the wiring board and a predetermined amount. It is opposed through a gap. The second copper plate member 231 has an inverted L-shape, and is opposed to the beam plate 164 in addition to the opposite surface of the wiring board. Then, before the high-frequency radio waves emitted from the packages of the plurality of electronic components existing on the opposite surface of the wiring board are received by the first metal bracket 205, they are received and escaped to the ground. As a result, it is possible to suppress a situation in which radio waves generated from the package (the main body of the electronic component) are received, amplified, and transmitted by the first bracket 205.

  As shown in FIGS. 12, 13, and 14, the peripheral edge of the copper plate member 230 provided on the first bracket fixing surface side of the wiring board is provided with a peripheral edge that is bent toward the wiring board. . Thereby, the radio wave emitted from the lead terminal fixing pattern on the first bracket fixing surface can be more reliably caught by the copper plate member 230.

  Also, the copper plate member 230 is provided with a fine bent protrusion 230b, which is passed through a through hole (not shown) of the wiring board and soldered to a ground wiring pattern (not shown) of the wiring board. In such a configuration, the ground wiring pattern of the wiring board can be connected to the ground via the copper plate member 230. Also, the copper plate member 230 can be fixed on the wiring board by solder bonding.

  In addition, a plurality of strip-shaped terminals 230a are provided at the lower end of the copper plate member 230 in the vertical direction, and these terminals abut against the beam plate 164 which is a metal beam disposed in the scanner housing and connected to the ground. By making the contact, the copper plate member 230 is connected to the ground. In such a configuration, by connecting the copper plate member 230 to the ground by contact with the beam plate 164, a soldering operation and a ground wire bolt fixing operation for connecting the copper plate member 230 to the ground can be omitted.

  The plurality of terminals 230a provided on the copper plate member 230 exhibit appropriate flexibility due to their thinness, and have a curved shape as illustrated. The curved surface is in contact with the beam plate 164. Even if the copper plate member 230 or the SBU 220 has some dimensional error or assembly error, the terminal 230a having such a configuration contacts the beam plate 164 while flexing flexibly according to the dimensional error or the assembly error. Thereby, poor contact with the beam plate 164 due to dimensional error or assembly error can be avoided.

  The plurality of terminals 230a are arranged in the longitudinal direction of the wiring board of the SBU 220. With such a configuration, more terminals 230a can be provided on the copper plate member 230 than in the case where they are provided side by side in the short direction of the wiring board.

  Heretofore, an example has been described in which radio waves received by the first bracket 205 are released to the ground through two systems, the copper plate member 230 and the second bracket 204. You may adopt only. Alternatively, the ground wire may be directly fixed to the first bracket 205 so that the radio wave can escape to the ground wire. Further, the example in which the present invention is applied to the movable reading unit 152 of the scanner 150 has been described, but the present invention can also be applied to the fixed reading unit 151. Moreover, although the example which employ | adopted what forms an image by the electrophotographic process as the image forming apparatus 1 was demonstrated, you may employ | adopt what forms an image by another system.

  As described above, in the copying machine according to the present embodiment, the copper plate member 230 that is a metal plate is supported by the first bracket 205 that is a metal support, and the first bracket 205 is connected to the ground via the copper plate member 230. . In such a configuration, even if a radio wave is received by the first bracket 205, it can be released to the ground from the copper plate member 230, and reception, amplification and transmission of the radio wave by the first bracket 205 can be suppressed.

  In addition, since the copper plate member 230 having a lower electrical resistance than the first bracket 205 is used, it is possible to suppress a situation in which radio waves received by the copper plate member 230 are leaked to the first bracket 205.

  Further, a second bracket 204 as a second metal support that supports the first bracket 205 while directly contacting the first bracket 205 is provided and connected to the ground. In such a configuration, even if radio waves are received by the first bracket 205, they are released to the ground via the second bracket 204 in addition to being released to the ground via the copper plate member 230. Thereby, reception, amplification, and transmission of radio waves by the first bracket 205 can be further suppressed.

  Further, since the fine bent protrusion 230b of the copper plate member 230 is soldered to the ground wiring pattern of the wiring board of the SBU 220 which is an electronic circuit board, the ground wiring pattern of the wiring board is connected to the ground via the copper plate member 230. Can do. Further, the copper plate member 230 can be fixed on the wiring board by solder bonding.

  In addition, a plurality of terminals 230a, which are the ends of the copper plate member 230, are brought into contact with a beam plate 164 which is a metal beam disposed in the scanner casing and connected to the ground, so that the copper plate member is interposed via the beam plate 164. Soldering work and ground wire bolt fixing work for connecting the copper plate member 230 to the ground can be omitted while the 230 is connected to the ground.

  Also, a plurality of terminals 230 a extending from the plate body are provided on one end side of the copper plate member 230, and these terminals 230 a are brought into contact with the beam plate 164 as end portions of the copper plate member 230, whereby the terminals 230 a and the beam plate 164 are connected. The copper plate member 230 can be connected to the ground by contact.

  In addition, since a plurality of terminals 230a having curved shapes exhibiting flexibility are used and the curved surfaces are brought into contact with the beam plate 164, some dimensional errors or attachments are made to the copper plate member 230 or the SBU 220. Even if there is an error, it is possible to avoid contact failure with the beam plate 164 due to a dimensional error or an assembly error by causing the beam plate 164 to be flexibly bent according to the error.

  In addition, since the plurality of terminals 230a are arranged side by side in the longitudinal direction of the SBU 220, more terminals 230a can be provided on the copper plate member 230 than when arranged in the short direction.

1 is a schematic configuration diagram showing a copier according to an embodiment. FIG. 2 is a partially enlarged configuration diagram illustrating an enlarged part of an internal configuration of an image forming apparatus in the copier. FIG. 3 is a partially enlarged view showing a part of a tandem portion of the image forming apparatus. FIG. 2 is a perspective view showing an ADF and a scanner of the copier. The expanded block diagram which shows the principal part structure of the same ADF with the upper part of a scanner. The fragmentary perspective view which shows the scanner partially. The block diagram which shows the movement reading part of the scanner from the side. The schematic diagram which shows the wire drive system in the movement reading part. FIG. 3 is an enlarged configuration diagram illustrating a wire drive motor of the movement reading unit and a surrounding configuration from a drive wire extending direction. The perspective view which shows the beam board, lens unit, and SBU in the movement reading part. The perspective view which shows the same SBU and a 1st bracket. The perspective view which shows the SBU, a copper plate member, and a 1st bracket from the opposite side to the 1st bracket fixing surface side. The perspective view which shows the SBU, a copper plate member, and a 1st bracket from the 1st bracket fixing surface side. The cross-sectional view which shows the SBU220 and its surrounding structure.

Explanation of symbols

1: Image forming apparatus (image forming means)
50: Document transport reading unit (document transport reading device)
51: ADF (original conveying means)
150: Scanner (image reading device)
162: 1st moving body (light irradiation means)
164: Beam plate (metal beam)
204: Second bracket (second metal support)
205: 1st bracket (metal support)
220: SBU (part of reading means, electronic circuit board)
230: Copper plate member (metal plate)
230a: Terminal 2311: Second copper plate member (metal plate)

Claims (14)

A photoelectric conversion element that includes a light irradiating unit that irradiates light on a document on which an image is recorded, and a reading unit that reads an optical image obtained by light reflection on a document surface; and a photoelectric conversion element that photoelectrically converts information of the optical image; In an image reading apparatus having an electronic circuit board on which other electronic components are mounted and a support body supporting the electronic circuit board in the reading unit,
An image reading apparatus, wherein a metal support made of a metal material is used as the support, and the metal support is grounded. A photoelectric conversion element that includes a light irradiating unit that irradiates light on a document on which an image is recorded, and a reading unit that reads an optical image obtained by light reflection on a document surface; and a photoelectric conversion element that photoelectrically converts information of the optical image; In an image reading apparatus having an electronic circuit board on which other electronic components are mounted and a support body supporting the electronic circuit board in the reading unit,
A metal support made of a metal material is used as the support, and a metal plate separate from the metal support is arranged opposite to the main body or lead terminal of the other electronic component via a gap. An image reading apparatus characterized by being installed and connected to ground. A photoelectric conversion element that includes a light irradiating unit that irradiates light on a document on which an image is recorded, and a reading unit that reads an optical image obtained by light reflection on a document surface; and a photoelectric conversion element that photoelectrically converts information of the optical image; In an image reading apparatus having an electronic circuit board on which other electronic components are mounted and a support body supporting the electronic circuit board in the reading unit,
A metal support made of a metal material is used as the support, and a metal plate that is separate from the metal support is disposed to face the wiring pattern of the electronic circuit board via a gap. An image reading apparatus connected to ground. The image reading apparatus according to claim 2 or 3,
An image reading apparatus, wherein the metal plate is supported by the metal support, and the metal support is connected to the ground via the metal plate. The image reading apparatus according to claim 4.
An image reading apparatus using the metal plate having a smaller electric resistance than the metal support. The image reading apparatus according to any one of claims 2 to 5,
An image reading apparatus comprising: a second metal support that supports the metal support in direct contact with the second metal support, and the second metal support is connected to ground. The image reading apparatus according to any one of claims 2 to 6,
An image reading apparatus, wherein the metal plate is soldered to a ground wiring pattern of the electronic circuit board. The image reading apparatus according to any one of claims 2 to 7,
An image reading apparatus characterized in that an end portion of the metal plate is brought into contact with a metal column, a metal side plate, a metal bottom plate, or a metal beam, which is disposed in a housing of the image reading device and is grounded. The image reading apparatus according to claim 8.
An image reading apparatus comprising: a plurality of terminals extending from a plate main body on one end side of the metal plate; and the terminals being in contact with the metal column, metal side plate, metal bottom plate, or metal beam as the end portions. The image reading apparatus according to claim 9.
An image reading apparatus characterized in that a plurality of curved terminals exhibiting flexibility are used as the plurality of terminals, and the curved surfaces are brought into contact with the metal columns, metal side plates, metal bottom plates, or metal beams. The image reading device according to claim 9 or 10,
An image reading apparatus comprising a plurality of the terminals arranged in the longitudinal direction of the electronic circuit board. In a document conveying / reading apparatus comprising: an image reading device that reads an image recorded on a document; and a document conveying unit that conveys the document to a document reading position by the image reading device.
12. A document conveying / reading apparatus using the image reading apparatus according to any one of claims 1 to 11. An image forming unit that forms an image on a recording material and an image reading device that reads an image recorded on a document, and an image read by the image reading unit is formed on the recording material by the image forming unit, In a copying machine for copying the manuscript,
A copying machine using the image reading apparatus according to any one of claims 1 to 11. An image forming unit that forms an image on a recording material, and a document conveyance reading device that reads an image of the document while conveying the document, and an image read by the image reading device of the document conveyance reading device is provided by the image forming unit. In a copying machine for copying the original by forming it on the recording material,
A copying machine using the image reading apparatus of the document conveying / reading apparatus according to any one of claims 1 to 11.

Images