JP4688608B2 - Film carrier - Google Patents

Description

  The present invention relates to a film carrier used when scanning and scanning a photographic film, and more specifically, to read a scanning point for scanning and scanning a photographic film, and to transport the photographic film on a transport lane including the reading point. A winding part for winding a photographic film and storing it in a storage space in the middle of the conveyance lane, and a photographic film that has passed through the winding part at the end of the conveyance lane Is provided with a discharge port for sending out the outside of the conveyance lane, and further provided with an opening means for opening a loop-shaped photographic film portion formed by a winding failure in the winding portion to the outside of the storage space. A first mode in which the photographic film conveyed by the film conveying mechanism is discharged from the discharge port; It relates selectively operably Configured film carrier in one of the second mode of winding by taking part.

  As this type of film carrier, there is Patent Document 1 shown below as prior art document information related to the present invention. Since the film carrier described in Patent Document 1 includes a winding part and a discharge port, high-resolution image reading is performed from the beginning while passing through the winding part and discharging the front end of the photographic film from the discharge port. Can be scanned in the one-pass mode (an example of the first mode), but as another option, a low-resolution image can be obtained as a pre-scan while winding the photographic film at the winding section located downstream of the reading point. The scanning scanning is performed in the two-pass mode (an example of the second mode) in which reading is performed and then the high-resolution image reading is performed as the main scanning while being pulled out from the winding unit. Since the winding means is provided with an opening means, even when a loop-shaped photographic film part is formed due to a winding failure, the loop-shaped part is opened to the outside without being confined in the storage space. The photographic film is not easily damaged.

JP 2004-37693 A (paragraph number 0008, FIG. 3)

  However, the opening means provided in the film carrier described in Patent Document 1 is based on a mechanism that opens the opening / closing cover that closes the upper part of the winding part by the pressing force generated from the looped photographic film part. In the second mode, it is difficult for the operator to notice the occurrence of winding failure until the opening / closing cover starts to open, and therefore, there is a problem that floating dust or the like tends to adhere to the part of the photographic film opened to the outside. there were.

  Accordingly, the object of the present invention is to allow the operator to quickly recognize the occurrence of a winding failure in the second mode in view of the above-mentioned drawbacks of the film carrier according to the prior art exemplified above, so that floating dust etc. It is in providing the film carrier to which it is hard to adhere.

A first characteristic configuration of the present invention includes a reading point for scanning and scanning a photographic film, and a film transport mechanism for transporting the photographic film on a transport lane including the reading point,
A winding unit for winding the photographic film and storing it in a storage space is disposed in the middle of the conveyance lane, and an end for discharging the photographic film that has passed through the winding unit to the outside of the conveyance lane. An exit is provided, and further there is provided an opening means for opening a loop-shaped photographic film portion formed by a winding failure at the winding portion to the outside of the storage space,
It is configured to be capable of scanning selectively in either a first mode in which scanning scanning is performed while discharging a photographic film from the discharge port, or a second mode in which scanning scanning is performed while winding the photographic film at the winding unit. A film carrier,
A film sensor capable of detecting a photographic film fed from the discharge port in the first mode is provided, and the film sensor detects the loop-shaped photographic film part opened from the opening means in the second mode. It is in the point where it is configured.

  In the film carrier according to the first characteristic configuration of the present invention, the film sensor for detecting the photographic film discharged in the first mode detects the winding failure immediately in the second mode, and the monitor or buzzer The operator can be alerted promptly to take-up failure, and the loop-shaped photographic film portion pushes that the loop-like photographic film portion has been formed due to the winding failure. Since there is no need to notify the operator by the movement of the opening / closing cover or the photographic film portion coming out of the opening / closing cover, problems such as adhesion of floating dust etc. to the photographic film portion opened to the outside hardly occur. Of course, in the first mode, the same film sensor can be used as a means for detecting the photographic film sent out from the discharge port, so that the timing at which the next photographic film can be inserted toward the reading point can be quickly known and processed. High efficiency can be secured. In addition, since the single sensor serves as both the film sensor in the first mode and the winding failure detection sensor in the second mode, the number of sensors mounted on the film carrier can be reduced. .

  According to a second feature of the present invention, a main body having the transport lane and a cover member capable of closing an upper surface portion of the main body are provided, and the film sensor is provided on the main body and the cover member. It is in the point which consists of a photosensor pair divided and arranged.

  If it is this structure, the structure which makes a single detection sensor serve as the film sensor in a 1st mode and the winding-up defect detection sensor in a 2nd mode can be implement | achieved rationally and easily. In addition, the light emitting unit and the light receiving unit constituting the optical sensor pair are separated from each other simply by opening the cover member to open the transport lane, and each part can be easily accessed. Easy to do.

  According to a third characteristic configuration of the present invention, a cover member capable of closing an upper surface portion of the main body provided with the transport lane is provided, and the film sensor is separated along the transport direction of the photographic film on the main body. It is in the point which consists of the arranged photosensor pair and the light reflecting means arranged on the cover member to reflect the light emitted from one of the photosensor pair to the other.

  With this configuration, similarly to the second feature configuration, it is possible to rationally realize a configuration in which a single detection sensor serves as both a film sensor in the first mode and a winding failure detection sensor in the second mode. . In addition, the cover member only needs to be provided with simple light reflecting means such as a mirror, and it is not necessary to provide wiring for electrically connecting the light emitting / receiving element to the cover member coupled to the main body by a hinge or the like. Also, with this configuration, the light beam passage position can be set more freely. For example, as shown in FIG. 17, the light beam from the light emitting element to the reflecting means or the light from the reflecting means to the light receiving element. Since the beam passing position can be arranged on the upstream side with respect to the film discharge direction, it is possible to make it possible to detect a winding failure in the second mode at an early stage.

The best mode for carrying out the present invention will be described below with reference to the drawings.
FIG. 1 and FIG. 2 show the appearance of a film carrier 9 as one embodiment of the present invention and the scanner device 1 capable of reading image data from a photographic film using the film carrier 9.

(Scanner device and its configuration)
The scanner device 1 photoelectrically converts an image formed on a developed photographic film F (negative film or positive film) by receiving light transmitted through each image frame of the photographic film with a light receiving element such as a CCD. To digital image data. The obtained digital image data is generally temporarily stored in a storage unit of a digital printing device (not shown) or a computer (not shown) connected to the scanner device 1 and can be output at an arbitrary timing. As an output method, output in the form of storage on various storage media such as a CD is possible in addition to output to a silver salt type photographic print by the digital printing device or the like.

  As shown in FIG. 1, the scanner device 1 includes a scanner main body 2 and a film carrier 9 that is detachably provided near the upper surface of the scanner main body 2. Here, the dual-purpose film carrier 9 corresponding to two types of films, that is, a 135 film F1 having an outer width of about 35 mm and a 240 film F2 having a width of 24 mm and also called an APS film will be described. Further, here, as the 135 film F1, a photographic film in the form of a short piece film having about 6 or less image frames is stored, and as the 240 film F2, it is accommodated in a dedicated cartridge FC so that it can be pulled out. It is assumed that 240 film F2 is processed.

(Configuration of the scanner body)
A light source 5 such as a halogen lamp is disposed inside the scanner body 2, and a light beam emitted from the light source 5 is transmitted through the photographic film F supported in the film carrier 9 on the upper surface of the scanner body 2. A light guide arm 6 is provided for converting into a downward light beam.
The scanner main body 2 further includes a linear CCD 8 for receiving the transmitted light transmitted through the image frame of the photographic film F and photoelectrically converting it into digital image data, and an arbitrary selected from several film width standards. The zoom lens 7 is arranged to adjust the width of the light beam delivered from the photographic film F having a width of 1 to the width of the CCD 8 and at the same time to focus the analog image formed by the transmitted light on the input surface of the CCD 8. Yes. The line-shaped CCD 8 extends in parallel with the arrow A in FIG. 1 that coincides with the main scanning direction of scanning.

(Structure of film carrier)
As shown in FIGS. 2 and 3, the film carrier 9 has a housing-like film carrier main body 10 formed mainly of a synthetic resin or the like. The film carrier main body 10 includes a lower main body 10L having an engagement groove (not shown) for receiving a positioning rail provided on the upper surface of the scanner main body 2 on the lower surface, and an upper main body 10U covering the upper surface of the lower main body 10L. Become. The right side of the film carrier body 10 is provided with an inlet 10a for receiving a 135 film F1 to be inserted by an operator, and the left side is provided with an outlet 10b for discharging the 135 film F1 to the left as required. It has been.

  As shown in FIG. 2, the upper main body 10U includes a first portion 10F far from the operator and a second portion 10G on the near side as viewed from the operator. The first part 10F is screwed to the lower main body 10L, but the second part 10G (an example of a cover member) has a closed posture (state shown in FIG. 2) in which the upper surface of the lower main body 10L is closed, and a lower side. The upper surface of the main body 10L is opened so as to be swingable around a horizontal axis between an open posture (not shown) accessible to a transfer lane or the like described later. A lock mechanism (not shown) that holds the second portion 10G in a closed posture is provided between the second portion 10G and the lower main body 10L. The film carrier 9 can be installed under the light guide arm 6 of the scanner body 2 in a closed posture.

  The upper body 10U is formed with an upper opening 11U that receives a scanning light beam extending downward from the distal end of the light guide arm 6. Similarly, the lower main body 10L is formed with a lower opening (not shown) that guides the transmitted light that has passed through the image frames of the photographic film F to the CCD 8 inside the scanner main body 2. The central axes extending in the optical axis direction of the upper opening 11U and the lower opening substantially coincide with the reading point SP by the CCD 8. The 135 film F1 received from the loading port 10a (as well as the 240 film F2) is along the linear transport axis Xm connecting the loading port 10a and the discharge port 10b, that is, in the sub-scanning direction orthogonal to the arrow A. It is scanned at the reading point SP while being conveyed.

  Further, as shown in FIGS. 3 and 6, a dual lane unit 30 having a first carrier lane FL1 for 135 film F1 and a second carrier lane FL2 for 240 film F2 in the film carrier body 10 at the same time. Is provided. A first slit for irradiating each photographic film with a light beam sent from the tip of the light guide arm 6 on each of the axial centers X1 and X2 in the respective transport directions of the first transport lane FL1 and the second transport lane FL2. SL1 and second slit SL2 are provided.

  As shown in FIGS. 6 (a) and 6 (b), the dual lane unit 30 slides along a main scanning direction on a pair of rails (not shown) formed on the floor surface of the lower main body 10L. The first slit SL1 for the 135 film F1 is movably supported and the first position where the first slit SL1 for the 135 film F1 coincides with the reading point SP (the state shown in FIG. 6A), and the second slit SL2 for the 240 film F2 is the reading point. It is possible to selectively lock at either one of the second positions (the state shown in FIG. 6B) coincident with SP. Switching of the position of the dual lane unit 30 and temporary fixing are performed manually by an operator via a first operation handle H1 protruding outside the film carrier 9.

(Film transport mechanism)
The film carrier 9 is equipped with a film transport mechanism 20 that transports the photographic film F in the sub-scanning direction. As shown in FIG. 5, the film transport mechanism 20 includes four pairs of transport rollers Rp1a, Rp1b, Rp1c, Rp1d arranged along the sub-scanning direction on the first transport lane FL1 of the dual lane unit 30, and 2 The three pairs of transport rollers Rp2a, Rp2b, Rp2c arranged along the sub-scanning direction on the transport lane FL2, the motor M1 fixed on the dual lane unit 30, and the rotational driving force of the motor M1. A timing gear and a timing belt which are rotatably arranged as appropriate for transmission to each of the conveying roller pairs. When the motor M1 is rotated forward, the photographic film F is conveyed leftward in FIG. 4 on the first conveyance lane FL1 or the second conveyance lane FL2, and when the motor M1 is reversed, the first conveyance lane FL1 or the second conveyance lane. It is conveyed rightward on FL2.

As shown in FIG. 3, the dual lane unit 30 is swingable on the lane unit main body 30a supported by the lower main body 10L of the film carrier 9 via the pair of rails and the upper surface of the lane unit main body 30a. The first and second swing plates 31a and 31b are supported.
The lower surface of the first and second transport lanes FL1, FL2 is formed on the lane unit body 30a, and the first and second swing plates 31a, 31b are formed on the first and second transport lanes FL1, FL2. An upper surface is formed. A lock mechanism (not shown) is provided that locks the first and second swing plates 31a and 31b with respect to the lane unit main body 30a in a closed state in which the upper and lower transport rollers are pressed against each other.

(About the winding unit of the film transport mechanism)
Further, as shown in FIG. 5, the film transport mechanism 20 is disposed between the fixed discharge roller pair Rp1e disposed immediately before the discharge port 10b and between the discharge roller pair Rp1e and the downstream end of the dual lane unit 30. The wound winding unit 40 (an example of a winding unit) is included.
When it is not desired to discharge the 135 film F1 from the discharge port 10b to the outside of the film carrier 9, the winding unit 40 winds up from the leading end and temporarily stores it in the film carrier 9. The 240 film F2 is not discharged from the discharge port 10b in principle, and is always scanned while being wound around the winding unit 40 from the front end side.

On the other hand, the fixed discharge roller pair R1e, R1e passes the take-up unit 40 without passing the 135 film F1 supplied from the dual lane unit 30 side to the right loading port 10a side, and passes through the left discharge port 10b. To the outside of the film carrier 9 or as an auxiliary mechanism for scanning while discharging.
Therefore, the winding unit 40 has a winding mode in which the photographic film F supplied from the dual lane unit 30 side is wound on the peripheral surface of the drum 41 of the winding unit 40 (state of FIG. 12 (A)). The photographic film F supplied is passed through as it is without being wound, and can be switched between a passing mode (state shown in FIG. 12B) that can be supplied toward the downstream discharge roller pair Rp1e. ing.

  Note that the winding unit 40 and the fixed discharge roller pair R1e, R1e are not fixed on the movable dual lane unit 30, but fixedly installed at a fixed position in the film carrier 9, but on the dual lane unit 30. It is driven by the rotational driving force from the motor M1 in the same way as each roller pair. That is, as shown in FIG. 5, an output gear DG for distributing the rotational driving force of the motor M <b> 1 to the outside of the dual lane unit 30 is provided on the lower surface on the near side of the downstream end of the dual lane unit 30. On the other hand, an input gear LG meshing with the output gear DG is rotatably supported by the lower main body 10L. The input gear LG has a shape with a long width in the main scanning direction so that the input gear LG can always keep meshing with the output gear DG regardless of the movement of the dual lane unit 30 between the first and second positions. .

(About two scanning operation methods)
The film carrier 9 can perform two types of scanning operations, a two-pass method and a one-pass method.
14A and 14B show an example of scanning operation of 135 film F1 by the two-pass method, and FIGS. 15A and 15B show an example of scanning operation of 240 film F2 by the two-pass method. In the two-pass method, first, as a first step, the photographic film F received from the loading port 10a is conveyed leftward at a high speed, and the portion of the photographic film F beyond the reading point SP is wound around the winding unit 40. Pre-scanning of the designated image frame is performed (steps of FIG. 14 (a) and FIG. 15 (a)). Next, as the second step, the main scan is performed while the photographic film F is conveyed rightward at a low speed while the portion of the photographic film F that has been wound is pulled out from the winding unit 40 (FIG. 14 ( B) and FIG. 15B).

  In the pre-scan in the two-pass method, auxiliary information such as information for specifying a reference position of an image frame that requires scanning (in other words, a position of a blank portion located between the image frames) is obtained. , Low-resolution image data necessary for performing pre-judgement such as color correction operation based on the image displayed on the monitor screen of the digital printing device or the like is transferred from the image frame to the storage unit by the CCD 8. Capture to a predetermined area.

  In the main scan in the two-pass method, based on the position information of the image frame obtained by the pre-scan, high-resolution image data necessary for print output by the digital printing device is transferred from the image frame to the storage unit by the CCD 8. Capture to another predetermined area. Next, print data reflecting color correction conditions obtained by the pre-judge is created in the high-resolution image data captured in the storage unit, for example, overwritten in the predetermined area of the storage unit, Output to print etc.

Next, an example in which the 135 film F1 is scanned by the one-pass method is shown in FIG. In the one-pass method, the photographic film F received from the loading port 10a is transported to the left at a low speed, and the designated image frame is scanned once as high-resolution scanning that combines pre-scanning and main scanning.
As shown in FIG. 14C, when the 135 film F1 is scanned by the one-pass method, the operation of winding the portion of the photographic film F supplied downstream from the dual lane unit 30 to the winding unit 40 is performed. If the take-up unit 40 is set to the pass mode, the 135 film F1 passes through the take-up drum 41 of the take-up unit 40 and is discharged by the conveying force of the downstream fixed discharge roller pair R1e and R1e. A scanning operation is performed while discharging the film carrier 9 from the outlet 10b. This eliminates the need to return the scanned 135 film F1 to the right, so that the operator can immediately load the next 135 film F1 from the loading port 10a, which greatly improves the scanning processing efficiency. As described above, the one-pass scanning is generally not performed on the 240 film F2.

(Configuration of discharge roller pair)
As shown in FIGS. 12 and 13, the fixed discharge roller pair R1e, R1e includes a lower conveyance roller R1e supported by the lane unit main body 30a and an upper conveyance roller R1e supported by the third swing plate 31c. It consists of. The lower transport roller R1e is a drive roller that is directly driven by a motor M1 via a timing gear and a timing belt, but the upper transport roller R1e is formed on the circumferential surface of the lower transport roller R1e. It is a driven roller driven driven based on the friction generated between the two. The relationship between the driving roller and the driven roller is the same for each of the transport roller pairs Rp1a, Rp1b, Rp1c, Rp1d, Rp2a, Rp2b, and Rp2c.

  As shown in FIG. 4, a one-way clutch mechanism 33 is interposed on the axis of the timing pulley that is directly connected to the lower conveying roller R1e. As a result of this configuration, when the motor M1 is driven forward, the lower transport roller R1e is the same as the lower transport rollers R1a, R1b, R1c, R1d, R2a, R2b, R2c on the lane unit body 30a. The 135 film F1 is driven to rotate at the peripheral speed and conveys the film F1 downstream (the state shown in FIG. 13A). When the motor M1 is driven in reverse, the one-way clutch 33 acts to drive the motor M1. The force is not substantially transmitted to the discharge roller pair R1e, R1e (the state shown in FIG. 13B), and the lower conveying roller R1e is held in a non-rotatable state by a slight load resistance.

  The configuration of the transport roller R1e using this one-way clutch 33 is such that if the 135 film F1 that has completed the scanning operation by the one-pass method is discharged out of the film carrier 9 from the discharge port 10b by the discharge roller pair R1e, R1e, two-pass. When the 135 film F1 that has completed the scanning operation by the method or the 240 film F2 that has completed the scanning operation by the two-pass method or the one-pass method is returned to the right by the reverse rotation of the motor M1, the previously discharged 135 film is discharged. This is to prevent a situation in which the film F1 is drawn into the film carrier 9 again by the discharge roller pair R1e and R1e and collides with another film to cause jamming in the winding unit 40 or the like.

(Detailed structure of winding unit)
As shown in FIGS. 5 and 10, the winding unit 40 mainly transmits the rotational force based on the forward rotation of the winding drum 41 and the motor M1 to the winding drum 41 to wind the winding drum 41 into a film. And an input unit 41B for rotationally driving in the direction. Further, as shown in FIGS. 9 and 11, the winding unit 40 includes a first guide arm 42 (upper guide of the upper guide) supported so as to be swingable around an axis X3 located on the upper upstream side of the winding drum 41. An example), a second guide arm 43 swingably supported around an axis X4 positioned downstream of the winding drum 41, and an axis X5 positioned downstream of the winding drum 41 upstream. The holding arm 44 is supported so as to be swingable. Further, as shown in FIG. 10, the winding unit 40 swings around the axis X3 common to the first guide arm 42 in order to swing the first guide arm 42 and the second guide arm 43. It includes an actuator mechanism 50 having an operation arm 51 that is supported and a solenoid 49 that swings the operation arm 51.

The winding speed of the photographic film F by the winding drum 41 increases as the photographic film F is wound on the winding drum 41 and the diameter of the outermost peripheral surface of the photographic film F increases. The rotation speed of the take-up drum 41 according to the normal rotation of the motor M1 is such that the photographic film F is wound up on the take-up drum 41 so that the photographic film F does not become slack at the start of winding. It is set on the basis of the state before being performed.
Then, as shown in FIG. 5, when the winding of the photographic film F progresses, the photographic films F are conversely pressed against each other by the strong force given by the rotational force of the winding drum 41 so as not to be damaged. A friction clutch 41c is interposed between the input unit 41B and the winding drum 41.

  In addition, when the photographic film F taken up on the take-up drum 41 is scanned with high resolution while being pulled out by the reverse operation of the motor M1, the action of the friction clutch 41c that tries to fix the take-up drum 41 is shown in the photograph. In order to prevent the film F from being damaged or having a subtle effect on the conveyance speed of the photographic film F, the photographic film F is pulled out between the winding drum 41 and the friction clutch 41c. A one-way clutch 41d for rotating the winding drum 41 is interposed.

(Operation arm structure)
The operation arm 51 of the actuator mechanism 50 is supported so as to be swingable around the axis X3 between a horizontal posture shown in FIG. 12 (a) and a lift posture shown in FIG. 12 (b). As shown in FIG. 8, the operation arm 51 includes an operated portion 51 a for inputting an upward operation force from the solenoid 49, a first operation portion 51 b that transmits the operation force to the first guide arm 42, and a second guide. A second operation portion 51c for transmitting an operation force to the arm 43;

(Structure of the first guide arm)
As shown in FIGS. 8, 9 and 12, a pair of idle rollers 42 a and 42 a are supported at the tip of the first guide arm 42 (upper guide). Further, a guide surface 42b extending from the vicinity of the axis X3 to the vicinity of the idle rollers 42a and 42a is formed on the lower surface of the first guide arm 42. The guide surface 42b has a downward concave concave cross-sectional shape and functions to smoothly guide the tip of the photographic film F. Further, the operated shaft 42c extends laterally from a position above the idle rollers 42a, 42a of the first guide arm 42.

  The first guide arm 42 has a first posture in which the idle rollers 42a and 42 are close to the peripheral surface of the take-up drum 41 and press the photographic film against the peripheral surface of the take-up drum 41 (the state shown in FIG. 12A). The idle rollers 42a, 42a are supported so as to be swingable around the axis X3 between the second posture (the state shown in FIG. 12B) separated from the circumferential surface of the winding drum 41. As shown in FIGS. 9 to 11, a coil spring 42 s for biasing the first guide arm 42 to the first posture is provided. The operated shaft 42c of the first guide arm 42 is always pressed downward toward the first operating portion 51b of the operating arm 51 by the urging force of the coil spring 42s.

  When power is supplied to the solenoid 49, the operating arm 51 is operated to the lift posture, and the first operating portion 51b of the operating arm 51 lifts the operated shaft 42c of the first guide arm 42 upward, whereby the first guide arm 42 is switched to the second posture against the urging force of the coil spring 42s. When the power supply to the solenoid 49 is released, the operation arm 51 is released and the state returns to the state shown in FIG. 12A. Therefore, the first guide arm 42 is in the first posture based on the urging force of the coil spring 42s. Return to.

(Second guide arm structure)
As shown in FIGS. 8, 9 and 12, the second guide arm 43 has a tip end portion 43a having an acute cross-sectional shape. On the inner surface of the second guide arm 43, a first guide surface 43b extending generally upward from the vicinity of the axis X4 to the tip end portion 43a is formed. The first guide surface 43b has a concave cross-sectional shape and functions to smoothly guide the front end of the photographic film F downward. A second guide surface 43c extending horizontally toward the downstream side extends from the distal end portion 43a. The second guide surface 43c has a planar cross-sectional shape and has a function of smoothly guiding the front end of the photographic film F toward the discharge port 10b. Further, the operated shaft 43d extends laterally from a position below the second guide surface 43c of the second guide arm 43.

  The second guide arm 43 has a first posture (state shown in FIG. 12A) in which the distal end portion 43a is retracted radially outward from the guide surface 42b of the first guide arm 42 in the second posture, and the distal end portion. Between the second posture 43a (a state shown in FIG. 12B) in which 43a enters the center side of the winding drum 41 with respect to the outer peripheral surface of the elastic belt 41a formed to protrude from the peripheral surface of the winding drum 41, It is supported so as to be swingable around the core X4. A coil spring 43s that biases the second guide arm 43 to the first posture is provided.

  When the second guide arm 43 is in the first posture, the leading edge of the photographic film F is guided downward along the first guide surface 43 b so as to be wound around the winding drum 41. On the other hand, when the second guide arm 43 is in the second position, the leading edge of the photographic film F is guided horizontally by the second guide surface 43c, passes over the take-up drum 41, and advances toward the discharge port 10b. . The operated shaft 43d of the second guide arm 43 is always pressed downward toward the second operating portion 51c of the operating arm 51 by the urging force of the coil spring 43s.

  When power is supplied to the solenoid 49, the operating arm 51 is operated in a lift posture, and the second operating portion 51c of the operating arm 51 swings the operated shaft 43d of the second guide arm 43 toward the loading port 10a. The second guide arm 43 is switched to the second posture against the urging force of the coil spring 43s. For the purpose of converting the upward movement indicated by the second operation portion 51c of the operation arm 51 in response to the power supply to the solenoid 49 into the movement closer to the horizontal of the second operation portion 51c of the operation arm 51, the operation arm 51 The second operation portion 51c of 51 is formed in a smooth surface that allows the second operation portion 51c to slide. When the power supply to the solenoid 49 is released, the operation arm 51 is released and returns to the state shown in FIG. 12 (a), so that the second guide arm 43 is in the first posture based on the urging force of the coil spring 43s. Return to.

(Holding arm structure)
As shown in FIGS. 8, 9, and 12, a pair of idle rollers 44 a and 44 a are supported at the tip of the holding arm 44. The holding arm 44 has a working posture in which the rolling rollers 44a and 44a press the leading end of the photographic film that has entered the circumferential surface of the winding drum 41, and the rolling rollers 44a and 44a are arranged in the radial direction from the winding drum 41. It is supported so as to be able to swing around the axis X5 between the non-acting postures spaced outward. A coil spring 44s that urges the holding arm 44 to the action posture is provided.

  About the holding arm 44, the outermost periphery of the photographic film F wound around the circumferential surface of the winding drum 41 or the circumferential surface of the winding drum 41 is always urged by the coil spring 44s regardless of the actuator mechanism. It is held pressed against the surface. As shown in FIG. 11, a guide surface 44b extending from the vicinity of the axis X5 to the vicinity of the idle rollers 44a and 44a is formed on the inner surface facing the downstream side of the holding arm 44. The guide surface 44b has a concave cross-sectional shape facing the downstream side, and the front end of the photographic film F is a boundary between the elastic belt 41a forming the peripheral surface of the winding drum 41 and the idle rollers 44a and 44a. Has the function of guiding smoothly to the department.

  As understood from the above description, when the operation arm 51 of the actuator mechanism 50 is switched to the passing mode of the winding unit 40, the operation of switching the first guide arm 42 from the first posture to the second posture; The operation of switching the second guide arm 43 from the first posture to the second posture is simultaneously performed. Similarly, when the operation unit 51 of the actuator mechanism 50 switches the winding unit 40 to the winding mode, the operation arm 51 returns the first guide arm 42 from the second position to the first position, and the second guide arm 43 is moved. An operation for switching from the second posture to the first posture is performed at the same time.

  By the way, in the pre-scan in the two-pass method, the winding drum 41 is driven in the winding direction based on the rotational force of the motor M1 regardless of the type of the photographic film F. Since 41 is rotated freely by the action of the one-way clutch 41d, the wound photographic film is pulled out without resistance, so that noise based on the change in scan speed is unlikely to occur in the high-resolution image data obtained in the main scan. It is configured.

  On the other hand, in the case of 135 photographic film F1, when the operator instructs the one-time scanning operation (main scanning) in the one-pass method, the winding unit 40 is automatically switched to the passing mode shown in FIG. After that, scanning of the 135 photographic film F1 is started. That is, in the passing mode, the first guide arm 42 and the second guide arm 43 are simultaneously switched to the second postures by the action of the operation arm 51 of the actuator mechanism 50. Therefore, the leading edge of the 135 photographic film F1 sent downstream as the scanning progresses is not pressed against the peripheral surface of the take-up drum 41, and the free-rolling rollers 42a and 42a of the first guide arm 42 are wound. Passing through a sufficiently large gap formed between the take-up drums 41 with almost no resistance, and being smoothly guided on the second guide surface 43c of the second guide arm 43, the main transport mechanism and It is sandwiched between a pair of auxiliary discharge rollers R1e and R1e that are rotationally driven at an equal conveying speed, and is sent out of the film carrier 9 from the discharge port 10b. Therefore, the main scan by the one-pass method is performed in a state where the frictional force of the friction clutch 41c interposed between the input unit 41B and the winding drum 41 does not affect the image data.

(Cartridge operation mechanism)
The film carrier 9 is provided with a cartridge operating mechanism 60 for scanning the 240 film F2 stored in the dedicated cartridge FC. As shown in FIGS. 3 and 4, the cartridge operating mechanism 60 includes a pocket-shaped cartridge holder 61 provided at the upstream end of the second transport lane FL2 of the dual lane unit 30 for locking the cartridge FC. A pair of spindles 62a, 62b projecting inwardly from a pair of opposing wall surfaces 61a, 61b of the cartridge holder 61 so as to engage with the end face of the spool shaft FC1 of the cartridge FC locked in the cartridge holder 61; The door operation shaft 63 projecting inwardly from the rear wall surface 61a so as to engage with the end surface of the scanning shaft of the light shielding door FC2 that opens and closes the opening of the cartridge FC, the front spindle 62b, and the door operation shaft 63 is fixed to the front end portion of the dual lane unit 30 in order to rotate it in a necessary direction at an appropriate timing. And a motor M2.

  The inner wall surface 61a of the cartridge holder 61 is formed in a block-like member 64 that can move along the axial direction of the cartridge FC. The block-shaped member 64 includes an open position where the distance between the pair of spindles 62a and 62b exceeds the length of the cartridge FC, and the pair of spindles 62a and 62b, as indicated by the bidirectional arrows in FIG. It is possible to switch between a locking position for engaging with the end surface of the spool shaft FC1 of the cartridge FC. Switching of the position of the block-like member 64 is performed by an operator's manual operation via the second operation handle H2 protruding outside the film carrier 9.

The dual lane unit 30 is switched to the first position, the cartridge FC of 240 film F2 is loaded into the cartridge holder 61 with the block member 64 in the open position, and the block member 64 is engaged by the second operation handle H2. When switching to the stop position, the door operation shaft 63 is automatically driven by the motor M2 to open the light shielding door FC2 of the cartridge FC, and then the spindle 62a is driven to 240 from the opening of the cartridge FC. The film F2 is configured to be supplied to the second transport lane FL2.
In the second transport lane FL2, a magnetic track reader 66 for reading the contents of the magnetic recording recorded on the magnetic track of the 240 film F2 is disposed. The contents of the magnetic recording relate to the shooting data recorded from the camera used for shooting, the exposure conditions recorded from the printing device that performed the previous printing process, etc. Can be reflected.

  In the case of pre-scanning in the two-pass method, for example, if the front end of the photographic film F is not locked between the peripheral surface of the winding drum 41 of the winding unit 40 and the holding arm 44, the winding is defective. Thus, the photographic film F is continuously wound into the storage space between the winding drum 41 and the first guide arm 42 by the upstream film transport mechanism 20 without the photographic film F being smoothly wound on the drum 41. As a result of being pushed in, a loop-shaped photographic film portion is formed, and this loop may gradually become longer. However, as described above, the first guide arm 42 is supported so as to be able to swing around the axis X3, so that the loop-shaped photographic film portion moves upward against the urging force of the coil spring 42s. Opening means that controls jamming of the photographic film is configured by opening the loop-shaped photographic film part to the outside of the storage space.

  As shown in FIG. 16B, a film sensor 70 capable of detecting the rear end of the photographic film discharged by the fixed discharge roller pair R1e and R1e in the one-pass mode is provided in the vicinity of the discharge port 10b. The film sensor 70 is installed downward on the lower surface of the second portion 10G (cover member) and the light emitting element 70a arranged upward on the portion of the film guide surface adjacent to the downstream side of the lower fixed discharge roller pair R1e. Light receiving element 70b. When the rear end of the photographic film is detected by the film sensor 70, that is, when the discharge of the photographic film is detected, "Negative discharge complete" is displayed on the monitor of the photographic processing apparatus (not shown), etc. It is a configuration that encourages the loading of photographic film.

  Further, as shown in FIG. 16 (a), the film sensor 70 is a loop-shaped photographic film portion opened to the outside from the opening means when a winding failure occurs in the winding unit 40 in the two-pass mode. It also serves as a winding failure detection sensor for detecting. Therefore, the light beam emitted from the light emitting element 70a toward the light receiving element 70b is configured to be greatly inclined with respect to the normal to the transport lane. That is, the lower light emitting element 70a is disposed downstream of the fixed discharge roller pair R1e and R1e, while the upper light receiving element 70b is fixed upstream of the fixed discharge roller pair R1e and R1e. It is disposed at a position between the discharge roller pair R1e, R1e and the winding unit 40. More specifically, in this embodiment, the light beam emitted from the lower light emitting element 70a toward the upper light receiving element 70b falls to the upstream side in the transport direction by about 30 ° with respect to the perpendicular to the transport lane. In this way, it is configured to cross the outermost peripheral surface of the upper fixed discharge roller pair R1e in a side view along the width direction of the transport lane.

  That is, as shown in FIG. 16 (a), the loop-shaped photographic film part opened to the outside from the opening means of the winding unit 40 in the two-pass mode is changed from the lower light emitting element 70a to the upper light receiving element 70b. The light beam emitted toward the light beam is blocked in the upper region of the light beam. As shown in FIG. 16B, the rear end of the photographic film discharged in the one-pass mode is blocked in the lower region of the light beam. Become. When a loop-shaped photographic film portion is detected by the film sensor 70, “winding failure” or the like is displayed on a monitor or the like of the photographic processing apparatus (not shown), and the operator is encouraged to take appropriate measures. . Of course, contrary to the above configuration, the light emitting element 70a may be disposed in the second portion 10G (cover member) and the light receiving element 70b may be disposed below.

As described above, the single film sensor 70 serves as both a discharge sensor that detects discharge of the photographic film in the first mode and a winding failure detection sensor that detects winding failure in the second mode. The detection algorithm is different for each mode.
That is, when the film sensor 70 is used as a discharge sensor in the first mode, the change pattern of the amount of light received by the light receiving element 70b, that is, the decrease in the amount of light seen when the leading edge of the photographic film blocks the light beam (transmits through the photographic film). By detecting the passage of the trailing edge of the photographic film by determining the change pattern characterized by the increase in the amount of light seen when the trailing edge of the photographic film exits the light beam. , “Negative discharge complete” is displayed on a monitor or the like.
On the other hand, when the film sensor 70 is used as a winding failure sensor in the second mode, the change in the amount of light received by the light receiving element 70b itself is reduced (the photographic film portion opened in a loop from the amount of light when the photographic film is absent). (Change in light quantity when the light beam starts to be interrupted) is immediately detected as jamming, and a message such as “winding failure” is displayed on a monitor or the like.

[Another embodiment]
As shown in FIG. 17, a light emitting element in which a film sensor 170 serving as both a film sensor in the first mode and a winding failure detection sensor in the second mode is spaced apart on the main body along the conveyance direction of the photographic film. 170a and light receiving element 170b, and reflecting means 171 such as a mirror disposed on the cover member to reflect light emitted from one of the pair of optical sensors to the other may be used. With this configuration, the light beam passing position can be freely set. For example, in the example shown in FIG. 17, the first beam passing position from the light emitting element 170a toward the reflecting means 171 is set to the transport of the discharged film. Since it can be arranged on the upstream side with respect to the direction, it is possible to detect the winding failure in the second mode even earlier compared to the configuration of FIG.

External perspective view of a scanner device used with the film carrier of the present invention External perspective view of film carrier as one embodiment of the present invention Perspective view showing the inside of the film carrier Plan view showing the inside of the film carrier Plan view mainly showing the rotation drive system of the film carrier Plan view mainly showing the movement of the dual lane unit of the film carrier Perspective view showing a film carrier winding unit An exploded perspective view showing a main part including an operation arm of the winding unit. Disassembled perspective view including coil spring of winding unit Plan view showing winding unit with solenoid Side view of the winding unit of FIG. Front view showing two modes of the winding unit together with photographic film Perspective view showing the vicinity of the auxiliary discharge roller pair of the film carrier Front view showing two scanning operation methods performed on 135 film Front view showing the scanning operation method performed on 240 films Schematic side view showing film sensor Schematic side view showing another embodiment of the film sensor

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Scanner apparatus 2 Scanner main body 9 Film carrier 10 Film carrier main body 10a Loading port 10b Outlet 10U Upper side main body 10F 1st site | part 10G 2nd site | part (cover member)
10L Lower body 30 Dual lane unit 40 Winding unit 42 First guide arm (opening means)
70 Film sensor 70a Light emitting element 70b Light receiving element F1 135 Film F2 240 Film FL1 First transport lane FL2 Second transport lane SP Reading points R1e, R1e Auxiliary discharge roller pair

Claims (3)

A scanning point for scanning the photographic film, and a film transport mechanism for transporting the photographic film on a transport lane including the scanning point,
A winding unit for winding the photographic film and storing it in a storage space is disposed in the middle of the conveyance lane, and an end for discharging the photographic film that has passed through the winding unit to the outside of the conveyance lane. An outlet is disposed, and further provided is an opening means for opening a loop-shaped photographic film portion formed by a winding failure at the winding portion to the outside of the storage space,
The photographic film conveyed by the film conveying mechanism is configured to be selectively operable in either a first mode for discharging the photographic film from the discharge port or a second mode for winding the photographic film at the winding unit. A film carrier,
A film sensor capable of detecting a photographic film fed from the discharge port in the first mode is provided, and the film sensor detects the loop-shaped photographic film part opened from the opening means in the second mode. A film carrier that can be configured.   The cover member which can close the upper surface part of a main part provided with the above-mentioned conveyance lane is provided, and the above-mentioned film sensor consists of a pair of photosensors divided and arranged in the above-mentioned main part and the above-mentioned cover member. Film carrier.   A cover member capable of closing an upper surface portion of the main body provided with the transport lane is provided, and the film sensor includes a pair of optical sensors spaced apart along the transport direction of the photographic film on the main body, and the light The film carrier according to claim 1, further comprising reflecting means disposed on the cover member so as to reflect light emitted from one of the sensor pair to the other.

Images