JP3928568B2 - Image reading device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention integrally includes a light source unit for film irradiation, an optical system that is disposed opposite to the light source unit and forms an optical axis from the light source unit, and a light receiving unit that receives a light beam that has passed through the optical system. The present invention relates to an image reading apparatus that includes a housing and includes a light receiving unit configured to capture a film image of a photographic film conveyed between a light source unit and an optical system.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there has been known an image reading apparatus that receives a light image obtained by scanning a film image of a photographic film, converts the received light image into an electric signal, and outputs it to a photographic processing apparatus such as a printing apparatus. It has been. As the light receiving sensor, a so-called CCD line sensor in which a plurality of light receiving elements (CCD (charge coupled device)) are arranged in a row is generally used.
[0003]
In such an image reading apparatus, a film surface is irradiated from below on a photographic film conveyed by a conveying unit that receives a driving force from a motor and conveys the photographic film at a predetermined timing (generally at a constant speed). A light source unit for emitting the light is provided. Then, the light from the light source section that has passed through the photographic film enters the light receiving section through an optical system including a lens and the like, and is input to the light receiving sensor and converted into an electric signal. As the transport unit, one having transport paths arranged in parallel to transport a plurality of types of photographic films is known.
[0004]
In general, the light source unit, the optical system, and the light receiving unit are arranged in the vertical direction in this order, and a movable unit having a casing to which these units are integrally attached is formed. Such a movable unit is mounted on a linear rail laid on a plate-like base frame and is moved in the horizontal direction while being guided so that it can correspond to the photographic film on the selected conveyance path. By changing the position of the unit, a single image reader can handle a plurality of types of photographic films.
[0005]
[Problems to be solved by the invention]
However, in the conventional image reading apparatus as described above, the movable unit in which the light source unit, the optical system, and the light receiving unit are integrated has a considerable weight, and the heavy object is positioned below the light source unit. From the fact that it is supported by the linear rails laid on the foundation frame in the transport frame is mounted on a pair of support frames upright from the foundation frame and set at a predetermined height position Fine vibrations generated when the motor of the transport unit is driven are transmitted to the movable unit via the support frame, the base frame, and the linear rail. Therefore, the movable unit slightly moves left and right with the portion in contact with the linear rail at the lower end as a fulcrum. When the movable unit is slightly swung around the fulcrum, the optical path of the light emitted from the light source unit is deviated from the normal position of the photographic film, thereby considering the high density of the light receiving element of several hundred dpi. As a result, the film image cannot be read stably.
[0006]
The present invention has been made in view of the situation as described above, and is arranged in the vicinity of a guide member of a base that moves a casing that integrally supports a light source unit, an optical system, and a light receiving unit, as a photographic film transport unit. By adopting such a structure, it is possible to stably capture film images so that vibrations generated during conveyance of the photographic film can be substantially synchronized with each other by substantially synchronizing the vibrations of the conveyance unit and the housing. It is an object of the present invention to provide an image reading apparatus obtained.
[0007]
[Means for Solving the Problems]
The invention according to claim 1 is a light source unit for film irradiation, an optical system that is disposed opposite to the light source unit and forms an optical axis for the light source unit, and a light receiving unit that receives a light beam that has passed through the optical system. In an image reading apparatus that captures a film image of a photographic film transported between the light source unit and the optical system with the light receiving unit, and supporting the casing, A base provided with a guide member that guides the casing so as to be able to reciprocate in one direction on a horizontal plane, and is attached to the base, and conveys different types of photographic films in a direction perpendicular to the one direction. A first film transport path and a second film transport path for the transport section, and the optical axis provided on the base The The first film transport path Above and above On the second film transport path When In Selectively position Let A drive unit for moving the housing as much as possible. Become It is characterized by this.
[0008]
According to this invention, the casing is moved while the supported portion is guided by the guide member, and the casing is made to correspond to the selected one of the first and second film transport paths. . In this state, the film image is received by the light receiving unit by irradiating the photographic film with the light beam from the light source unit while transporting the photographic film along the selected transport path.
[0009]
The slight vibration generated by the conveyance of the photographic film by the conveyance unit is transmitted to the housing integrally provided with the light source unit, the optical system, and the light receiving unit. Is supported by a guide member of the base via a supported part located between the optical system and the optical system, so that the conveyance part and the housing are in a relatively close positional relationship. Compared to the case where a conventional guide member is provided at the bottom of the casing, the vibration of the conveying section is not transmitted to the casing in an amplified state, and the vibration of the conveying section and the casing The phases substantially coincide with each other, so that the relative offset is canceled and no phase occurs.
[0010]
Therefore, the case is transmitted with the vibration of the conveyance unit suppressed as much as possible, and the vibrations of the both are relatively canceled out, so that even if slight vibration occurs, the case is being conveyed to the optical system. Since there is no substantial shift in the relative positional relationship with a certain photographic film, the film image can be read stably.
[0011]
In the present invention, even if an optical system such as a lens or a diffusion plate exists in the light source unit, such an optical system is included in the light source unit.
[0012]
According to a second aspect of the present invention, in the first aspect of the present invention, the guide member is a pair of long guide rails arranged in parallel.
[0013]
According to this invention, since the guide member is formed by the pair of guide rails, the support state by the guide member via the supported portion of the housing becomes more stable.
[0014]
The invention according to claim 3 is the invention according to claim 1 or 2, The first film transport path and the second film transport path are disposed along a horizontal plane, The guide member is located below the first film transport path and the second film transport path.
[0015]
According to this invention, since the guide member is positioned below the first and second film transport paths, the transport unit is detachably attached to the base so that the transport unit covers the guide member from above. It becomes possible to mount, and the ease of mounting work of the transport unit is ensured.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is an exploded perspective view, partly cut away, showing an embodiment of an image reading apparatus according to the present invention, and FIG. 2 is an assembled perspective view thereof. 3 is a cross-sectional view of the image reading apparatus shown in FIG. 2 in a side view, and FIG. 4 is a cross-sectional view in the front view. 1 and 2, the XX direction is referred to as the sub-scanning direction or the front-rear direction, and in particular, the -X direction is referred to as the front and the + X direction is referred to as the rear. The Y-Y direction is referred to as the main scanning direction, the width direction, or the left-right direction. In particular, the -Y direction is referred to as the left, and the + Y direction is referred to as the right. These directions are defined based on the conveyance direction of the photographic film F.
[0017]
As shown in FIGS. 1 to 4, the image reading apparatus 10 includes a movable unit 20 for reading a film image of a photographic film F, which is movably mounted on a base 11 having a predetermined shape, for example, a box shape. A guide rail 60 as a guide member for guiding the movement of the movable unit 20, a moving mechanism 70 for moving the movable unit (housing) 20 guided by the guide rail 60 forward and backward, and a base 11. It has a basic configuration including a transport unit 80 for transporting the photographic film F.
[0018]
As shown in FIG. 1, the base 11 includes a rectangular bottom plate 12, a front plate 13 erected from the front edge of the bottom plate 12, and a rear plate erected from the rear edge. 14, a left plate 15 erected from the left edge, a right plate 16 erected from the right edge, the front plate 13, the rear plate 14, the left plate 15 and the right plate 16 and a top plate 17 supported by 16.
[0019]
A substantially right half of the top plate 17 is provided with a column body opening 171 for projecting a column body 22 (described later) of the movable unit 20 whose lower part is mounted in the base 11 upward. A light beam passage opening 172 that is long in the main scanning direction for allowing a light beam from a light source unit 30 to be described later to pass therethrough is provided at a left position of the column main body opening 171.
[0020]
A left-side stopper plate 18 formed by bending a part of the top plate 17 upward is provided at the left edge of the column body opening 171. A right stop plate 19 formed by extending a part of the upper edge of the right plate 16 upward is provided at the right position of the opening 171, whereby the column main body 22 The strut body opening 171 can be moved in the left-right direction (main scanning direction) between the stopper plates 18 and 19.
[0021]
The movable unit 20 receives a light source 30 that irradiates light toward the photographic film F being conveyed by the conveyance unit 80, and transmitted light that has passed through the photographic film F when irradiated with light from the light source 30. The optical system 40 and the light receiving portion 50 that receives the light beam that has passed through the optical system 40 and converts it into an electrical signal are formed by being mounted on a column member 21 that is movably attached to the base 11. Yes.
[0022]
The column member 21 includes a prism-shaped column main body 22 standing on the base 11 and a guided square member as a pair of supported parts extending in the front-rear direction from the bottom of the column main body 22 toward the left. 23. The guided square member 23 is guided by the guide rail 60, and the movable unit 20 moves forward and backward in the width direction with respect to the base 11 based on this guide.
[0023]
Moreover, the lower part of the said column main body 22 is formed in the forked shape divided | segmented in the front-back direction, and the pair of division body 24 is the state which faced front and back. A mounting space 25 in which the moving mechanism 70 is mounted is formed between the divided bodies 24.
[0024]
A shelf 26 protruding from the left surface of the column main body 22 is provided in the upper portion of the mounting space 25, and a positioning recess 261 that is recessed downward is provided on the upper surface of the shelf 26. In addition, an upward positioning projection 221 is provided on the top of the column main body 22. The positioning recess 261 and the positioning projection 221 are for positioning an optical system mounting container 41 (described later) mounted on the column main body 22. The pair of guided square members 23 are provided so as to protrude leftward from the bottom of each divided body 24.
[0025]
Further, in order to prevent disturbance light from entering the optical path from the light source unit 30 via the light beam passage opening 172 on the left surface side of the pair of divided bodies 24 and slightly above the top plate 17. A light shielding member 27 is provided. The light shielding member 27 includes a support bar 271 that protrudes leftward between the pair of divided bodies 24 in the main scanning direction, and a light shielding member that protrudes further leftward from the tip of the support bar 271. It consists of a main body 272. The light shielding member main body 272 has a trapezoidal shape in a cross-sectional view when cut in the front-rear direction, and is provided with a light beam passage opening 273 extending vertically in the center portion extending in the left-right direction.
[0026]
The light shielding member 27 is configured such that the light beam passage port 273 is located on the top side of the transport unit 80 in a state where the movable unit 20 is positioned at a first position corresponding to a first transport system 82 (described later) of the transport unit 80. While facing the first light flux passage hole 821 in the vertical direction, the light flux passage opening 273 is positioned at the second position corresponding to the second transport system 83, and the top side second light flux passage hole 831 of the transport unit 80. Are dimensioned so as to face each other vertically.
[0027]
The light source unit 30 is supported between the lower portions of the pair of divided bodies 24 of the column main body 22 and protrudes toward the left, and a light source lamp 32 supported by the light source support member 31. And. The light source support member 31 is positioned below the guided square member 23 and at least longer than the width of the photographic film F. The light source support member 31 is formed in a concave shape when viewed from the left, and a concave mirror is formed on the inner surface side thereof. The light source lamp 32 is arranged at the focal position of the concave mirror, so that the light from the light source lamp 32 is converted into a parallel light beam after being reflected by the concave mirror.
[0028]
In the present embodiment, the light source lamp 32 that emits a wavelength component light of a visible light component and an infrared light component is employed. Such a light source lamp 32 is used because, of the light transmitted through the photographic film F, visible light reacts not only to the image on the photographic film F but also to scratches on the photographic film F. In contrast, infrared light does not react to the image on the film, but reacts to scratches attached to the photographic film F. This is because, by splitting the transmitted light into a visible light component and an infrared light component and reading them, it is possible to repair a scratch based on a predetermined image processing technique during a subsequent baking process.
[0029]
The optical system 40 includes an optical system mounting container 41 that is mounted on the column main body 22 and an optical unit 45 that is detachably mounted on the optical system mounting container 41. The optical system mounting container 41 is formed by a bottomed cylindrical body having an open upper surface, and protrudes toward the left at the upper edge of the arcuate tip portion (left side in FIG. 1) of the peripheral wall 42 in plan view. The protruding piece 43 is provided, and a positioning screw 431 protruding upward is provided on the protruding piece 43. The positioning screw 431 is for positioning the optical unit 45.
[0030]
In addition, a positioning protrusion corresponding to the positioning recess 261 provided in the shelf 26 of the column main body 22 is provided at the lower edge of the base end portion (right side in FIG. 1) that is linear in plan view of the peripheral wall 42. 44, and the positioning projection 44 is fitted into the positioning recess 261 of the shelf 26 of the column main body 22, and the flat plate portion on the proximal end side of the peripheral wall 42 is screwed to the column main body 22. The optical system mounting container 41 is fixed to the column main body 22 of the column member 21 in a positioned state.
[0031]
The optical unit 45 includes a housing 46 having an external shape corresponding to the internal shape of the optical system mounting container 41, and a lens unit 47 housed in the housing 46. A positioning protrusion 461 protrudes leftward from the front edge of the top plate 463 of the housing 46, and the positioning screw 431 of the optical system mounting container 41 is located at the center of the positioning protrusion 461. A positioning hole 462 corresponding to is formed. Further, the base end side of the top plate 463 is extended outward, and an extended portion 464 is formed in this portion, and the central portion of the extended portion 464 corresponds to the positioning protrusion 221 of the column main body 22. A positioning hole 465 is formed.
[0032]
Then, a positioning screw is provided in which the positioning hole 462 of the positioning projection 461 protrudes from the protruding piece 43 of the optical system mounting container 41 while the positioning hole 465 of the extending portion 464 is externally fitted to the positioning protrusion 221 of the column main body 22. The optical unit 45 is mounted on the optical system mounting container 41 in a positioned state by being fastened with a nut after being externally fitted to 431.
[0033]
The lens unit 47 is for imaging the light beam from the light source lamp 32 reflected by the concave mirror mounted on the inner surface side of the light source support member 31 of the light source unit 30 at a predetermined position of the light receiving unit 50, A plurality of lenses are formed to overlap each other. In order to guide the light beam derived from the lens unit 47 to the light receiving unit 50, the top plate 463 is provided with a light transmission hole 466 extending in the main scanning direction.
[0034]
The light receiving unit 50 receives a light beam transmitted through the lens unit 47 and converts the light beam into an electrical signal proportional to the intensity of the light. The light receiving unit 15 is L-shaped when viewed from the main scanning direction. , A pair of CCD support plates 52 attached to the casing 51, a pair of CCD line sensors 53 respectively mounted on the CCD support plates 52, and a cold mirror 54 built in the housing 46. And is configured.
[0035]
The casing 51 includes a pair of L-shaped side plates in the width direction, a bent front plate erected between the edges of the L-shaped side plates that are perpendicular to each other when viewed from the front, and each L-shaped side plate. And a back plate erected between the rear edges, and an optical path of a light beam transmitted through the lens unit 47 is formed in a space surrounded by the L-shaped side plate, the bent front plate and the back plate. . The casing 51 is attached to the housing 46 by connecting a connecting plate 55 integral with the casing 51 to the top plate 463 of the housing 46 by bolting or the like.
[0036]
The cold mirror 54 reflects infrared light while reflecting visible light, and is inclined by 45 ° in the front-rear direction with respect to the optical path of the light beam from the lens unit 47. ing. Therefore, of the light flux from the light source unit 30 that has passed through the photographic film F, its visible light component is reflected by the cold mirror 54 and its optical path is converted to a right angle, while the infrared light component passes through the cold mirror 54. Go straight ahead.
[0037]
The visible light whose optical path is changed at right angles by the cold mirror 54 is input to the visible light line sensor 531 provided on the front side of the CCD line sensor 53, while the infrared light transmitted through the cold mirror 54 is transmitted. The light is input to an infrared light line sensor 532 provided immediately above the cold mirror 54. The light input to these line sensors 531 and 532 is converted into an electric signal and output to, for example, a photographic processing apparatus.
[0038]
The guide rail 60 guides the movement of the column member 21 mounted on the base 11 in the left-right direction, and the column is substantially left half of the position in the center of the base 11 in the front-rear direction. A pair is provided in the main scanning direction so as to correspond to the pair of guided square members 23 of the member 21. The guide rail 60 is formed of square bar, and a guide groove 61 extending in the left-right direction in which the guided square bar 23 is fitted in a sliding contact state is formed on the upper surface thereof.
[0039]
The guide rail 60 is integrally fixed at a position where both ends thereof are extremely close to the top plate 17 of the base 11 via a predetermined fixing bracket 62. Therefore, the vibration generated by driving the transport unit 80 is immediately transmitted to the guided square member 23 via the top plate 17, the fixing bracket 62 and the guide rail 60, so that the movable unit 20 integrated with the guided square member 23 is Then, it vibrates at the same phase as the transport unit 80.
[0040]
FIG. 5 is a partially cutaway perspective view showing an embodiment of the moving mechanism 70, (A) is an exploded perspective view, and (B) is an assembled perspective view. Hereinafter, based on FIG. 5, the moving mechanism 70 will be described in detail with reference to FIGS. The moving mechanism 70 drives and rotates the spiral rod 71 interposed between the split bodies 24 of the column main body 22, a buffer interposed body 72 externally fitted to the spiral rod 71, and the spiral rod 71 around its axis. And a gear group 77 that transmits the drive of the drive motor 76 to the spiral rod 71.
[0041]
The spiral rod 71 has a central shaft 711 that is concentrically provided from the right end portion thereof, and the central shaft 711 is passed through the right plate 16 of the base 11 through a bearing member, whereby the axial center is formed. It can rotate freely. A rod gear 712, which is one of the gear groups 77, is fitted on the central shaft 711 of the spiral rod 71 so as to be integrally rotatable, whereby the drive rotation of the drive motor 76 is driven by the gear group 77 and the rod gear. It is transmitted to the spiral rod 71 via 712.
[0042]
The buffer interposed body 72 includes a bottomed cylindrical body 73, a nut body 74 provided in the cylindrical body 73, and the nut body 74 sandwiched from the left and right with the nut body 74 provided in the cylindrical body 73. And a pair of coil springs 75.
[0043]
The cylindrical body 73 has an outer diameter dimension set slightly smaller than a gap dimension between the pair of divided bodies 24, and an inner diameter dimension set larger than the diameter dimension of the spiral rod 71, whereby the spiral rod 71 can be inserted. An insertion hole 731 through which the spiral rod 71 can be inserted in a sliding contact state is formed at the center position of the bottom portion (left side) of the cylindrical body 73, and the right edge portion is provided at the upper and lower positions of the peripheral surface. A pair of cut grooves 732 formed by cutting in the direction toward the cylinder center is provided. The cylindrical body 73 is closed by welding or the like with a closing plate 733 having an insertion hole 734 through which the spiral rod 71 is inserted in a state where the nut body 74 is housed.
[0044]
The nut body 74 has a columnar nut body main body 741 whose outer diameter is slightly smaller than the inner diameter of the cylindrical body 73, and a pair of protrusions that protrude upward and downward from the peripheral surface of the nut body 741. It consists of fins 742. The projecting fins 742 are fitted into the cut grooves 732 in a state in which the nut body main body 741 is housed in the cylindrical body 73. The projecting fins 742 are set in the radial direction so as to protrude outward from the cut groove 732 in a state of being fitted into the cut groove 732. This is used for detecting the position of the nut body 74 by a pair of left and right position sensors 79 provided on one side of the opposite surface.
[0045]
The length of the nut body 741 is set to approximately ¼ of the inner dimension of the cylindrical body 73 in the cylinder center direction, so that the nut body main body 741 can move forward and backward in the left-right direction within the cylindrical body 73. ing. Each end face of the nut body 741 is provided with an annular groove 743 for fitting the coil spring 75 mounted in the cylindrical body 73.
[0046]
In the moving mechanism 70, as indicated by an arrow in FIG. 5A, first, the spiral rod 71 is inserted into the insertion hole 734 of the closing plate 733, and then one coil spring 75 is attached to the distal end side of the spiral rod 71. While the nut body 74 and the other coil spring 75 are sequentially fitted into the spiral rod 71, the nut body 74 is adjusted to fit into the cut groove 732 while the nut body 74 and the other coil spring 75 are sequentially fitted to the spiral rod 71. Insert into.
[0047]
Next, in a state where the tip of the spiral rod 71 is inserted into the insertion hole 731 of the cylindrical body 73, the closing plate 733 is pressed in the direction of the cylindrical body 73 against the urging force of each coil spring 75. As shown in FIG. 5B, the assembly of the buffer interposing body 72 to the spiral rod 71 is completed by, for example, welding them together or screwing them in contact with the edge of the cylindrical body 73. .
[0048]
In the shock absorbing body 72 having the spiral rod 71 that has been assembled in this manner, the cylindrical body 73 is inserted from the right between the pair of divided bodies 24 of the column main body 22, and the closing plate 733 is a pair of divided bodies. In the state of being in contact with 24, the divided body 24 is fixed with screws or the like. Further, the central shaft 711 of the spiral rod 71 is passed through the right plate 16 of the base 11, and the rod gear 712 is mounted and fixed to the central shaft 711 in this state outside the right plate 16.
[0049]
On the other hand, the drive motor 76 is mounted outside the right side of the rear plate 14 of the base 11, and a gear group 77 is interposed between the drive shaft 761 penetrating the right plate 16 and the rod gear 712. As a result, the drive of the drive motor 76 is transmitted to the spiral rod 71 via the drive shaft 761, the gear group 77, and the rod gear 712.
[0050]
The left stopper plate 18 and the right stopper plate 19 of the base 11 are respectively provided with stopper pieces 181 and 191 made of an elastic material such as rubber at positions facing the column main body 22. The impact of the collision is buffered by 22 being stopped by these stopper pieces 181 and 191.
[0051]
The position sensor 79 is provided at a position corresponding to the left end and the right end of the movable range of the nut body 74 on one side of the opposing surfaces of the pair of divided bodies 24. Accordingly, whether the nut body 74 is located at the left end portion or the right end portion of the movable range is detected by these position sensors 79, and the drive of the cylindrical body 73 is stopped by this detection signal. Yes.
[0052]
According to the moving mechanism 70 configured as described above, the nut body 74 screwed into the spiral rod 71 is rotated by rotating the spiral rod 71 around the axis center via the gear group 77 driven by the drive motor 76. Will move in the axial direction. The movement of the nut body 74 is transmitted to the column main body 22 integral with the cylindrical body 73 via the coil spring 75 and the cylindrical body 73, whereby the column member 21 moves in the main scanning direction.
[0053]
If the rotation of the spiral rod 71 is continued in a state where the column main body 22 is in contact with any one of the stopper pieces 181 and 191, the nut body main body 741 resists the urging force of the coil spring 75 by this rotation. The inside of the cylindrical body 73 further advances while the coil spring 75 is compressed. As a result, the column main body 22 is elastically pressed and clamped between the coil spring 75 and the stopper pieces 181 and 191.
[0054]
Thereafter, when the nut body 74 reaches the end position of the movable range, the position sensor 79 detects this, and the drive motor 76 is stopped based on this detection signal, so the coil spring 75 and the stopper piece 181 of the column main body 22 are stopped. , 191 are maintained in an elastic pressing state, so that the column member 21 is reliably positioned at either end of the column main body opening 171 in the main scanning direction without play. Become.
[0055]
The transport unit 80 is for transporting the photographic film F to be read by the light receiving unit 50. In the present embodiment, the transport unit 80 is configured to support two types of photographic film F. As shown in FIGS. 1 to 4, the transport unit 80 includes two transport systems (a first transport system 82 and a first transport system 82 corresponding to the casing 81 and two types of photographic films F housed in the casing 81). 2 transport system 83).
[0056]
The casing 81 includes a bottom plate 811 having an area substantially the same as that of the left portion of the top plate 17 of the base plate 11 from the left stopper plate 18, and a pair of left and right erected from the left and right edges of the bottom plate 811. Side plates 812, a front plate 813 constructed between the front edges of each side plate 812, a back plate 814 constructed between the rear edges of each side plate 812, and these side plates 812, front plate 813 and back plate. 814, and a top plate 815 provided on each upper edge portion of 814.
[0057]
Each side plate 812 is shaped like a gate, and the side plate 812 is positioned so as to follow the shape protruding downward from each side plate 812 at a position forward from the front edge of the bottom plate 811 and a position rearward from the rear edge. The body is extended so that no gaps are formed in these parts. In particular, a winding space 816 for winding the photographic film F is formed in a portion protruding downward from the front portion of the transport unit 80.
[0058]
The top plate 815 has a pair of light beam passage holes that are long in the main scanning direction for passing the light beam at positions corresponding to the light beam emitted from the light source lamp 32 (the top corresponding to the first transport system 82). A top plate corresponding to the plate side first light beam passage hole 821 and the second transport system 83 is provided with a second light beam passage hole 831), and a front portion of the top plate 815 has a lid body 816 that can be opened and closed. Has been.
[0059]
The back plate 814 has a pair of film inlets 817 extending in the main scanning direction for drawing the photographic film F into the casing 81 in accordance with the first and second transport systems 82 and 83.
[0060]
Two film take-up motors 84 are provided at appropriate positions in the take-up space 816 corresponding to the first and second transport systems 82 and 83. Two film take-up reels 85 to be driven are provided, and the photographic film F drawn into the casing 81 through each film take-in port 817 is driven by the film take-up motor 84. The film is wound around the film take-up reel 85 by rotation around the axis.
[0061]
Further, a plurality of transport roller pairs 86 are provided in the film transport path from the film inlet 817 to the film take-up reel 85 so as to sandwich each edge of the photographic film F in the width direction. An unillustrated timing belt for transmitting the rotational drive of the film take-up motor 84 is stretched between each pair of conveying rollers 86, and the photographic film sandwiched between the pair of conveying rollers 86 by the rotation of the conveying roller pair 86 thereby. F constant speed conveyance is ensured.
[0062]
Further, the bottom plate 811 of the casing 81 is provided with a trapezoidal recessed portion 818 formed in a front view formed by recessing the position corresponding to the light shielding member 27 of the movable unit 20 upward. The recessed portion 818 covers the light shielding member 27 in a slidable contact state with the unit 80 mounted on the base 11.
[0063]
The top plate of the recessed portion 818 is opposed to the bottom plate side first light beam passage hole 822 and the top plate side second light beam passage hole 831 facing the top plate side first light beam passage hole 821 below. A bottom plate side second light flux passage hole 832 is formed.
[0064]
In the state where the transport unit 80 is mounted at a predetermined position on the front plate 13, the bottom plate 811 is integrally fixed by screwing or the like, so that the movable unit 20 is reliably positioned. ing.
[0065]
According to the image reading apparatus 10 configured as described above, the drive unit 76 drives the movable unit 20 via the spiral rod 71 to the first position corresponding to the first transport system 82 of the transport unit 80 and the second position. The position can be changed between the second position corresponding to the transport system 83.
[0066]
Then, when reading the type of photographic film F suitable for the first transport system 82, the movable unit 20 is set to the first position. In this state, the photographic film F is introduced into the casing 81 from the film inlet 817 on the first transport system 82 side and is mounted on the film take-up reel 85 on the first transport system 82 side. When light is emitted toward the photographic film F from the light source lamp 32 of the light source unit 30 while being wound around the film take-up reel 85 by driving the film take-up motor 84, this light flux passes through the bottom plate side first light flux passage hole 822. It passes through the photographic film F.
[0067]
This transmitted light passes through the top plate side first light flux passage hole 821, the light flux passage opening 273 of the light shielding member main body 272, the light flux passage hole 411 of the optical system mounting container 41, and the light flux passage hole 451 of the housing 46 of the optical unit 45. The light enters the lens unit 47. Then, the light beam is introduced into the casing 51 of the light receiving unit 50 through the light beam transmitting long hole 466 provided in the top plate 463 of the housing 46 of the optical unit 45, and the visible light component is reflected by the cold mirror 54. The infrared light component passes through the cold mirror 54 and is received by the infrared light line sensor 532 while being received by the visible light line sensor 531.
[0068]
Next, when reading the type of photographic film F suitable for the second transport system 83, the movable unit 20 is set to the second position by driving the drive motor 76, and in this state, the movable unit 20 is moved to the first transport system 82. By performing the same operation as in the case where the position is set, the reading of the photographic film F suitable for the second transport system 83 is executed.
[0069]
The image reading apparatus 10 according to the present invention includes a light source unit 30 for film irradiation provided in a lower part, and an optical system 40 as an optical system disposed on the upper part and forming an optical axis from the light source unit 30. The movable unit 20 is integrally provided with the light receiving unit 50 that receives the light beam that has passed through the optical system 40, and the film image of the photographic film F conveyed between the light source unit 30 and the optical system 40 is received by the light receiving unit. The base 11 is provided with a guide rail 60 that supports the movable unit 20 and guides the movable unit 20 so as to reciprocate in one direction on a horizontal plane, and is attached to the base 11. A transport unit 80 in which first and second transport systems 82 and 83 for transporting two types of photographic films F in a direction orthogonal to one direction are provided in parallel; Is the first And a moving mechanism 70 that moves the movable unit 20 so as to be positioned on the second transport systems 82 and 83. The movable unit 20 is provided between the light source unit 30 and the optical system on the guide rail 60 of the base 11. It is provided with a guided square member 23 supported by the above.
[0070]
Therefore, the movable unit 20 is moved while the guided square member 23 is guided to the guide rail 60 by driving the moving mechanism 70, and the movable unit 20 is selected from the first and second transport systems 82 and 83. The light beam is transmitted through the photographic film F by irradiating the photographic film F with the light beam from the light source unit 30 while transporting the photographic film F along the selected transport path in a state corresponding to the transport path of The transmitted light beam passes through the optical system 40 and is then received by the light receiving unit 50 to capture a film image.
[0071]
The vibration generated by the conveyance of the photographic film F by the conveyance unit 80 is transmitted to the movable unit 20 that is integrally provided with the light source unit 30, the optical system 40, and the light receiving unit 50, whereby the movable unit 20 also vibrates. The movable unit 20 is supported on the guide rail 60 of the base 11 via a guided square member 23 positioned between the light source unit 30 and the optical system 40, whereby the transport unit 80 and the movable unit 20 are relatively Since the positional relationship is very close, the fine vibration of the transport unit 80 is amplified compared to the case where the conventional guide rail 60 is provided at the bottom of the movable unit 20. In addition to being transmitted to the movable unit 20 in the state, the phase of the slight vibrations of the transport unit 80 and the movable unit 20 coincide. Made to the state.
[0072]
Therefore, the movable unit 20 is transmitted in a state in which the fine vibration of the transport unit 80 is suppressed as much as possible, and the phase of the two fine vibrations coincide with each other. Since the relative positional relationship between the photographic film F and the photographic film F being conveyed does not change, a film image is captured more stably than in the past.
[0073]
Further, since a pair of long linear rails arranged in parallel to each other are employed as the guide rail 60, the support state by the guide rail 60 via the guided square member 23 of the movable unit 20 is more stable. Can be.
[0074]
Further, since the guide rail 60 is positioned below the first and second transport systems 82 and 83 in the base 11, the transport unit 80 is configured to cover the transport unit 80 from above. Can be detachably mounted on the base 11, and the ease of mounting work on the base 11 of the transport unit 80 can be ensured.
[0075]
The present invention is not limited to the above embodiment, and includes the following contents.
[0076]
(1) In the light source unit 30 in the above embodiment, as shown in FIG. 6 (a), the light from the light source lamp 32 is guided through the optical fiber 33, and the lens unit is passed through the diffusion plate 35 from the exit port 34. 47 may be incident. In this case, the output width dimension d1 is set to about 8 mm, the distance d2 between the film surface of the photographic film F and the output port 34 is set to about 20 mm, and the light beam from the output port 34 is split on the film surface. After adjusting the emission as described above, the angle α formed between the optical axis and the light beam in the palm-arranged state is set to approximately 12 °.
[0077]
By doing so, the light from the light source lamp 32 can be efficiently used for scratching the photographic film F without waste. In addition, since an appropriate amount of light can be obtained without waste, heat generation of the light source lamp 32 can be suppressed, power consumption can be reduced, and the service life of the light source lamp 32 can be extended. .
[0078]
(2) Further, as shown in FIG. 6B, the exit 34 of the optical fiber 33 may be divided into a plurality of parts, or as shown in FIG. The light emitted from 34 is reflected, and the light distribution characteristics (output width dimension d1: approximately 8 mm, distance d2 between the film surface of the photographic film F and the exit port 34: approximately 20 mm, and the optical axis and the palm-arranged state. You may make it implement | achieve the angle (alpha) formed between light rays: about 12 degrees.
[0079]
(3) Furthermore, as shown in FIG. 6 (d), the light source lamp 32 may be configured to be rotatable so that the angle of the optical axis from the light source lamp 32 can be adjusted. By doing so, even if various components for the light source lamp 32 with inferior accuracy are employed, it is possible to supply appropriate light to the optical fiber 33 by the angle adjustment described above, which contributes to a reduction in component costs. be able to.
[0080]
【The invention's effect】
According to the present invention, the slight vibration generated by the conveyance of the photographic film by the conveyance unit is transmitted to the casing integrally provided with the light source unit, the optical system, and the light receiving unit. Since the body is supported by the guide member of the base via the supported part located between the light source part and the optical system, the transport part and the housing are in a relatively close positional relationship, The slight vibration of the transport unit is not transmitted to the housing in a state where the vibration of the transport unit is amplified as compared with the case where the conventional guide member is provided at the bottom of the housing. And the phase of the vibration of the housing substantially coincides and the shift is offset relatively, so that it does not occur. Therefore, the case is transmitted with the vibration of the conveyance unit suppressed as much as possible, and the vibrations of the both are relatively canceled out, so that even if slight vibration occurs, the case is being conveyed to the optical system. Since there is no substantial shift in the relative positional relationship with a certain photographic film, the film image can be read stably.
[Brief description of the drawings]
FIG. 1 is a partially cutaway exploded perspective view showing an embodiment of an image reading apparatus according to the present invention.
2 is an assembled perspective view of the image reading apparatus shown in FIG. 1. FIG.
3 is a cross-sectional view in side view of the image reading apparatus shown in FIG.
4 is a front sectional view of the image reading apparatus shown in FIG.
FIGS. 5A and 5B are partially cutaway perspective views showing an embodiment of a moving mechanism, in which FIG. 5A is an exploded perspective view and FIG. 5B is an assembled perspective view.
6A to 6D are explanatory views showing other embodiments of the light source unit.
[Explanation of symbols]
10 image reader 11 base
12 Bottom plate 13 Front plate
14 Back plate 15 Left plate
16 Right board 17 Top board
171 Opening for prop body 172 Opening for light beam passage
18 Left stop plate 181, 191 Stopper piece
19 Right stop plate 20 Movable unit
21 Prop member 22 Prop body
23 Guided square material 24 Divided body
221 Positioning projection 25 Mounting space
26 Shelf 261 Positioning recess
27 Shading member 271 Support rod
272 Light shielding member body 273 Light flux passage opening
30 Light Source 31 Light Source Support Member
32 Light source lamp 40 Camera unit
41 Camera mounting container 411 Luminous flux passage hole
42 Perimeter wall 43 Projection piece
431 Positioning screw 44 Positioning protrusion
45 Camera 451 Beam passage hole
46 Housing 461 Positioning protrusion
462 Positioning hole 463 Top plate
464 Extension part 465 Positioning hole
466 Long hole for luminous flux transmission 47 Lens unit
50 Light-receiving part 51 Casing
52 CCD support plate 53 CCD line sensor
531 Line Sensor for Visible Light
532 Infrared line sensor
54 Cold mirror 55 Connecting plate
60 Guide rail 61 Guide groove
62 Fixing bracket
70 Moving mechanism 71 Spiral rod
711 Center shaft 712 Rod gear
72 Buffering body 73 Cylindrical body
731 Insertion hole 732 Cut groove
733 Closing plate 734 Insertion hole
74 Nut body 741 Nut body
742 Protruding fin 743 Annular groove
75 Coil spring 76 Drive motor
761 Drive shaft 77 Gear group
79 Position sensor 80 Transport unit
81 Casing 811 Bottom plate
812 Side plate 813 Front plate
814 Back plate 815 Top plate
816 Lid 817 Film entrance
818 Recessed part 82 1st conveyance system
821 First light flux passage hole on top plate side
822 Bottom plate side first beam passage hole
83 Second transport system 831 Top plate side second light flux passage hole
832 Bottom plate side second beam passage hole
84 Film winding motor
85 film take-up reel
86 Transport roller pair

Claims (3)

A housing integrally provided with a light source unit for film irradiation, an optical system that is disposed opposite to the light source unit and forms an optical axis for the light source unit, and a light receiving unit that receives a light beam that has passed through the optical system An image reading device that captures a film image of a photographic film conveyed between the light source unit and the optical system with the light receiving unit, and supports the case and holds the case on a horizontal plane. A base having a guide member that reciprocally guides in the direction, and a first film transport path attached to the base for transporting different types of photographic films in a direction orthogonal to the one direction; and a conveying portion to which the second film transport path juxtaposed, provided on the base, Rubeku the housing selectively to position the optical axis and the second film transport path between the first film transport path on A drive unit that moves the body and Image reading apparatus characterized by comprising comprises.   The image reading apparatus according to claim 1, wherein the guide member is a pair of long guide rails arranged in parallel. The first film transport path and the second film transport path are disposed along a horizontal plane, and the guide member is located below the first film transport path and the second film transport path. The image reading apparatus according to claim 1 or 2.

Images