JP6293526B2 - Ticket gate and control method of ticket gate - Google Patents

Description

  Embodiments described herein relate generally to a ticket gate and a method for controlling the ticket gate.

  Station equipment that performs various types of station services is installed at railway stations. The station service device is, for example, a ticket gate, a ticket machine, a payment machine, or a window terminal. These station service devices perform various processes on commuter passes, boarding tickets, and the like. The ticket checker performs ticket check processing based on information stored in the commuter pass and the boarding ticket, and determines whether the passport and the user who holds the boarding pass are permitted or not permitted. The ticket gate restricts the passage of users who are judged to be unauthorized. Further, the ticket gate collects the ticket that has been subjected to the ticket gate processing in a ticket collection box.

  In addition, a ticket gate having a function of issuing a ticket (ticketing function) is realized. Such a ticket gate can issue a ticket by communicating with an IC card possessed by the user and printing on a roll-shaped ticket medium.

JP-A-7-282303

  A ticket gate having a ticket issuing function prints on a roll-shaped ticket medium, cuts the ticket medium, and issues the cut ticket medium as a ticket. Note that the ticket medium has a pre-print area in which information is printed in advance. For this reason, when the ticket medium is cut as a boarding ticket, the position to be cut is determined in advance. That is, an operator of the ticket gate needs to set the ticket medium so that the ticket medium is correctly cut, and there is a problem that it is troublesome to load the ticket medium.

  It is an object of the present invention to provide a convenient ticket gate and a method for controlling the ticket gate.

A ticket gate according to an embodiment includes a storage unit, a transport mechanism, a cutter, a bill collection unit, a detection unit, and a control unit. The storage unit is loaded with a roll-shaped ticket medium in which cutting areas are set at regular intervals. The transport mechanism transports the ticket medium stored in the storage unit along a transport path. The cutter cuts the ticket medium transported by the transport mechanism. The bill collection unit collects the ticket medium cut by the cutter and conveyed by the conveyance mechanism. A detection part detects the front-end | tip of the said ticket medium, and the position on the said conveyance path of the said cutting | disconnection area | region of the said ticket medium. The control unit calculates a surplus length from the cutting area to the tip of the ticket medium based on the detection result of the detection unit, and cuts the ticket medium as a waste ticket based on the calculated surplus length. And controlling the transport mechanism and the cutter. Further, the control unit determines whether the remainder length is equal to or greater than a preset minimum length and is equal to or less than a preset maximum length, and the remainder length is equal to or greater than a preset minimum length and When not exceeding the preset maximum length, the waste ticket is cut from the ticket medium by the maximum length by an integer of a numerical value obtained by dividing the remainder length by the difference between the maximum length and the interval between the cutting areas. The value obtained by multiplying the difference between the maximum length and the interval between the cut areas by the number of discarded tickets cut from the ticket medium is subtracted from the excess length, and the length obtained by adding the interval between the cut areas is added. The transport mechanism and the cutter are controlled so as to cut a waste ticket from the ticket medium.

FIG. 1 is an explanatory diagram for explaining a ticket gate system according to an embodiment. Drawing 2 is an explanatory view for explaining the appearance of the ticket gate concerning one embodiment. Drawing 3 is an explanatory view for explaining the structure of the ticket gate concerning one embodiment. FIG. 4 is an explanatory diagram for explaining a control system of the ticket gate machine according to the embodiment. FIG. 5 is an explanatory diagram for explaining a partial structure of the ticket gate according to the embodiment. FIG. 6 is an explanatory diagram for explaining a partial structure of the ticket gate according to the embodiment. FIG. 7 is an explanatory diagram for explaining a partial structure of the ticket gate machine according to the embodiment. FIG. 8 is an explanatory diagram for explaining the ticket medium loaded in the ticket gate according to the embodiment. FIG. 9 is an explanatory diagram for explaining the operation of the ticket gate according to the embodiment. FIG. 10 is an explanatory diagram for explaining the operation of the ticket gate according to the embodiment. FIG. 11 is an explanatory diagram for explaining the operation of the ticket gate according to the embodiment. FIG. 12 is an explanatory diagram for explaining the operation of the ticket gate according to the embodiment.

Hereinafter, a ticket gate and a method for controlling the ticket gate will be described in detail with reference to the drawings.
FIG. 1 shows an entire ticket gate system including a ticket gate according to the present embodiment. As shown in FIG. 1, the ticket gate system includes a host computer 10 that functions as a ticket gate control device. The host computer 10 is connected to a plurality of ticket gates 100-1, 100-2,... Installed at a boarding gate of a station or airport, for example, via the communication line 20, and monitors these ticket gates 100.

  The host computer 10 controls the entire apparatus and various devices connected at a lower level, and has a CPU 11 that controls a plurality of ticket gates 100 in an integrated manner. A memory unit 12, a display unit 13, an input unit 14, a communication control unit 15 and the like are connected to the CPU 11.

  The memory unit 12 stores various data including control data for controlling lower-level devices such as the host computer 10 itself and the ticket gate 100. The display unit 13 displays the operation state of the host computer 10 itself, the operation state of lower-level devices, and the like. The input unit 14 includes a keyboard for inputting various information such as the operation mode of each ticket gate 100, a touch panel for outputting corresponding information based on detection of contact. The communication control unit 15 transmits / receives various information to / from a lower level device via the communication line 20.

  Next, the structure of the ticket gate 100 applicable to the ticket gate system will be described. FIG. 2 shows the appearance of the ticket gate 100. The ticket gate shown in FIG. 2 is usually installed as a set of two, and a ticket gate passage through which a user can pass is formed between the two. Ticket media that can be used in ticket gates that perform ticket processing, such as entrance processing and exit processing, include wireless first ticket media with a communication unit, non-contact second ticket media with barcodes, and ticket surfaces. It is intended for magnetic ticket media with ticket information printed on the back and magnetic information recorded on the back side, and more specifically, such as ordinary tickets, commuter passes, limited express tickets, coupon tickets, boarding passes, prepaid cards, etc. It is intended for magnetic ticket media and non-contact and wireless ticket media (wireless IC cards).

  As shown in FIG. 2, the ticket gate 100 includes, for example, a device body 1 that is elongated and flat and has a rectangular wall shape. The apparatus main body 1 includes an insertion port 2, a discharge port 3, an indicator lamp 4, a display unit 5, an openable / closable door 16, a reading device (reader) 6 provided in a reading area 6a over which a ticket medium is placed, a speaker 7, and a ticket gate. An operation panel 8 for changing the setting of the machine, a plurality of passage detectors 9 for detecting passage of people, and the like are provided.

  The slot 2 is provided on the upstream side of the ticket gate passage in the device body 1 and can receive the ticket medium inserted when entering the facility or entering the facility. A shutter 17 (see FIG. 3) for preventing the ticket medium from being inserted is provided in the vicinity of the slot 2. The discharge port 3 is provided on the downstream side of the ticket gate passage in the device main body 1, and discharges the ticket medium received from the insertion port 2 as necessary.

  The reading unit 6 is arranged on the upstream side of the ticket gate passage in the device main body 1 and reads information from a ticket medium placed over the reading area 6a. The reading unit 6 has a wireless antenna, wirelessly communicates with a wireless ticket medium, reads ticket gate information from the ticket medium, and writes a desired information on the ticket medium. A bar code reader or the like that reads a two-dimensional bar code from the attached ticket medium in a non-contact manner is provided.

  The display unit 5 is arranged in front of the discharge port 3 in the device main body 1 with respect to the user's direction of travel, and displays various guidance information, such as a guidance screen corresponding to the result of the ticket gate process, to the user and staff. Display in a predetermined display pattern. The door 16 is arrange | positioned at the both ends of the side surface by the side of the ticket gate path in the apparatus main body 1, and is comprised so that opening and closing is possible in order to control a user's passage. The door 16 opens the ticket gate when the user can pass, and closes the ticket gate when the user is blocked.

  The plurality of passage detectors 9 are arranged on a side surface portion of the device main body 1 on the ticket gate passage side, and output an output signal for detecting the passage of the user. The indicator lamp 4 notifies the operation state of the apparatus such as insertion of a child ticket, an invalid ticket or an abnormal ticket, or an abnormality of a device.

  FIG. 3 shows the internal structure of the ticket gate 100. As shown in FIG. 3, the ticket checker 100 includes a plurality of transport rollers and a transport belt, and transports a ticket medium input from the input port 2 to the discharge port 3 or a bill collection box to be described later along the transport path. And a plurality of mechanism portions provided along the transport path. That is, the ticket checker 100 includes a separation unit 30 that separates a plurality of bill media that have been batch-inserted from the slot 2, and an alignment unit that is provided at a stage subsequent to the slot 2 and that aligns the bill media that has been inserted into a predetermined posture. 32 and a plurality of read heads 45a, 45b, 45c and a write head 46, and a magnetic processing unit 33 for reading and writing magnetic data of the magnetic ticket medium. The ticket checker 100 includes a front / back determination unit that performs front / back determination of the inserted ticket medium, a reversing pocket 29, a reversing unit 34 that reverses the ticket medium when the inserted ticket medium is inserted in the reverse direction, and a transport. A barcode reading unit having a scanner (not shown) that reads the two-dimensional barcode printed on the ticket medium.

  Further, the ticket checker 100 has a holding unit 35 for temporarily holding the ticket medium, a punch 28, a punch unit 36 for punching a hole in the ticket medium as necessary, and a plurality of thermal heads 27. In response to this, the printing unit 37 that prints on the ticket surface of the ticket medium, the bill collection unit 40 that collects the collected ticket medium in the collection box 38, and the plurality of ticket media are stacked and discharged to the discharge port 3 in a lump. And an integrated discharge part 42.

  Further, the ticket checker 100 waits until a ticket issuing command is issued for the ticket unit 41 that issues a ticket medium by cutting a ticket medium of a predetermined size from the roll paper, and issues a print after the command is issued. A print holding unit 44. The ticket issuing unit 41 includes a storage unit 43 in which a roll-shaped ticket medium 47 is set, a reflection sensor 48, a transmission sensor 49, a cutter 51, and a motor 50 that drives the cutter 51. The reflection sensor 48 and the transmission sensor 49 detect the tip of the ticket medium 47 and the position of the cutting area on the ticket medium 47 on the conveyance path. The ticket issuing print holding unit 44 has a thermal head 52 that prints desired information on the ticket surface of the ticket medium to be issued. The configuration of the ticket issuing unit 41 will be described later.

  Further, a number of ticket gates 100 are provided along the conveyance path, a plurality of passage sensors 54 for detecting the passage of the ticket medium, and a plurality of sorting gates respectively provided at branch portions of the conveyance path to switch the conveyance direction of the ticket medium. 53, 55, 56, 57, 58, 59, a plurality of motors 70, 71, 72, 73, 74, 75, 76 for driving the transport mechanism in each mechanism section, temporarily hold the ticket medium in the transport path A plurality of stoppers 60, 61, 62, 63, 64 and the like are provided.

  FIG. 4 shows a control system of the ticket gate 100. As shown in FIG. 4, the ticket checker 100 includes a CPU 200 that controls the entire apparatus. The CPU 200 controls operations such as ticket gate processing based on ticket gate information read from the ticket medium, reading processing by the reading unit 6 including a wireless reader / writer and a barcode reader, ticket issuing processing of the ticket medium 47 by the ticket issuing unit 41, and the like. It functions as a part.

  The CPU 200 includes a ROM 201 that stores a control program, a RAM 202 that records information read from the ticket medium and records information as a buffer for the control program, a fare memory 203 that records fare information, and the like. A read circuit 204 that controls the heads 45a, 45b, and 45c and a write circuit 205 that controls the write head 46 are connected. The CPU performs a ticket gate process based on information read by the reading heads 45a and 45b, and determines whether or not the user can be permitted to pass through the ticket gate.

  Further, the CPU 200 has a reader control circuit 227 for controlling the reading unit 6 having a barcode reader and a wireless reader / writer for reading a two-dimensional barcode of a ticket medium held over the reading area 6a, and a wireless of the wireless reader / writer. A wireless communication circuit 226 that modulates data transmitted via the antenna 68 and demodulates data received via the antenna 68 is connected. The CPU 200 performs a ticket gate process based on the information read by the reading unit 6 and the scanner, and determines whether or not the user can be permitted to pass the ticket gate.

  Further, the CPU 200 includes a distribution control circuit 206 that controls the distribution gates 53, 55 to 59, a print control circuit 207 that controls the thermal heads 27 and 52, an inversion pocket control circuit 209 that drives the inversion pocket 29, a punch 28, a punch control circuit 210 for controlling 28, a stopper control circuit 211 for controlling stoppers 60 to 64 for holding the ticket medium, a cutter control circuit 212 for controlling the motor 50 for driving the cutter 51 of the ticket issuing unit 41, Is connected.

  In addition, the CPU 200 includes a detection circuit 213 that detects the conveyance status of the ticket medium based on signals from a large number of passage sensors 54, a conveyance control circuit 214 that controls the motors 70 to 76 that drive the conveyance mechanism, and a slot. 2 is connected to a shutter drive circuit 215 that drives a shutter 17 that prevents the ticket medium from being inserted into the shutter 2.

  Further, the CPU 200 has a display circuit 220 for controlling the display unit 5 to display an image corresponding to the result of the operation guidance and the ticket gate processing, a display control circuit 221 for controlling the indicator lamp 4, and a speaker for performing voice guidance. 7, a sound detection circuit 222 for controlling the user from the output signals of the plurality of passage detectors 9, a door control circuit 224 for controlling the opening and closing of the door 16, and various settings of the device Is connected to an operation panel control circuit 225 for controlling the operation panel 8 for changing. In addition, the communication control unit 15 is connected to the CPU 200. The communication control unit 15 performs information communication with a device higher than the ticket gate 100, for example, the host computer 10 based on the control of the CPU 200.

  The ticket checker 100 includes a ticket collecting and conveying mechanism that conveys and inputs the ticket medium to the ticket collecting unit 40 that collects ticket media such as a ticket. FIG. 5 shows an example of the bill collection and conveyance mechanism. FIG. 6 shows a configuration in the vicinity of the bill collection unit 40. FIG. 7 shows the configuration of the bill collection unit 40.

  The ticket collecting and conveying mechanism distributes the ticket medium whose ticket gate information is read by the magnetic processing unit 33 to the discharge port 3 or the ticket collecting unit 40. The first sorting gate 57, the first and second bill collection paths 80a and 80b that branch into two toward the bill collection section 40, and the branch sections of these collection paths are provided, and the ticket medium is the first one. Alternatively, a second sorting gate 59 for sorting to the second bill collection path is provided. Furthermore, the transport mechanism temporarily discharges the ticket medium that has been discharged to the discharge port 3 and forgotten to the third stacking path 81 that leads to a separate stacking box for the forgotten ticket medium to be described later, and the first and second ticket media. A third distribution gate 53 for distributing to the second collection path 80a, 80b side or the third collection path 81;

  As shown in FIG. 7, the bill collection unit 40 is provided in parallel, for example, a first temporary storage box 82a and a second temporary storage box 82b provided in a horizontal direction, First and second guide chutes 84a and 84b for guiding the ticket medium conveyed to the second bill collection paths 80a and 80b to the first temporary storage box 82a and the second temporary storage box 82b, respectively, and the first and second temporary storage A bill collection box 38 disposed below the box and a bottom lid opening / closing mechanism 88 for opening the bottoms of the first and second holding boxes 82a and 82b are provided.

  When the user accidentally receives a ticket check process, the ticket checker 100 collects the predetermined number of tickets collected last in the first temporary holding box 82a or the second temporary holding box 82b. When the number of tickets collected in the first temporary holding box 82a or the second temporary holding box 82b reaches a predetermined number, the ticket gate 100 is collected in the first temporary holding box 82a or the second temporary holding box 82b. Move the ticket to the collection box 38.

  The bill collection unit 40 includes a full detection sensor 110a that detects that the first holding box 82a is full and a full detection sensor 110b that detects that the second holding box 82b is full. The CPU 200 of the ticket gate 100 is connected to a full detection sensor 110a and a full detection sensor 110b that detects the fullness of the second temporary holding box 82b via detection circuits 116, respectively. The full detection sensor 110a and the full detection sensor 110b send detection signals to the CPU 200 via the detection circuit 116, respectively. Thereby, the CPU 200 can recognize that the first temporary holding box 82a and the second temporary holding box 82b are full. When the first temporary holding box 82a or the second temporary holding box 82b is detected to be full, the CPU 200 releases the bottom cover of the holding box once the full is detected, thereby temporarily collecting the ticket media collected. To the collection box 38.

  In addition, as shown in FIG. 6, a separate accumulation box 85 is provided alongside the second temporary holding box 82b. In this separate collection box 85, the forgotten ticket medium sent through the third collection path 81 is collected.

  Furthermore, the CPU 200 of the ticket gate 100 is connected to the reflection sensor 48 and the transmission sensor 49 of the ticket issuing unit 41 via the detection circuit 117, respectively. Each of the reflection sensor 48 and the transmission sensor 49 sends a detection signal to the CPU 200 via the detection circuit 117. Thereby, the CPU 200 can recognize the detection results of the reflection sensor 48 and the transmission sensor 49.

  FIG. 8 shows an example of the ticket medium 47 set in the ticket issuing unit 41. The ticket medium 47 has a printable area 47a, a preprinted area 47b, an area (cutting area) 47c assumed to be cut by the cutter 51, and a predetermined pattern printed as a mark. A region 47d. Furthermore, the ticket medium 47 includes a magnetic layer (not shown) that can record magnetic information and the like. The ticket medium 47 has a roll shape, for example, and is provided with a region 47a, a region 47b, a region 47c, and a region 47d at predetermined intervals. The region 47d is provided for each distance T that is a fixed interval in the direction of the region 47c and the arrow a.

  FIG. 9 shows an example of the operation of the ticket issuing unit 41. The CPU 200 detects the tip of the ticket medium 47 and the position of the cutting area 47c of the ticket medium 47 on the conveyance path by the detection unit such as the reflection sensor 48 and the transmission sensor 49. The CPU 200 calculates a surplus length from the cutting area 47c to the tip of the ticket medium 47 based on the detection result of the detection unit, and transports the ticket medium 47 as a waste ticket based on the calculated surplus length. And the cutter 51 are controlled.

  The storage unit 43 of the ticket issuing unit 41 stores the roll-shaped ticket medium 47 in which the cutting areas 47c are set at regular intervals. In the ticket issuing unit 41, the motor 76 is operated based on the control of the CPU 200 to convey the roll-shaped ticket medium 47 in the direction of the arrow a. Further, a cutting position by the cutter 51 exists on the conveyance path of the ticket medium 47. The CPU 200 can cause the cutter 51 to cut the ticket medium 47 at the cutting position in FIG. 9 by sending a command to the cutter control circuit 212. Further, the CPU 200 controls the position on the ticket medium 47 to be cut by the cutter 51 by causing the cutter 51 to cut the ticket medium 47 while controlling the transport position of the ticket medium 47.

  The motor 76 is a motor such as a stepping motor. The stepping motor is a motor driven by, for example, pulse power, and rotates by one step per pulse of the electric signal. Further, the motor 76 transports the ticket medium 47 in the direction of the arrow a by a predetermined distance in one step. That is, the motor 76 is a transport mechanism that transports the ticket medium 47 stored in the storage unit 43 along the transport path.

  The CPU 200 can control the operation of the motor 76 by sending a pulse signal to the motor 76 by the transport control circuit 214 that controls the motor 76. Further, the CPU 200 can recognize how much the ticket medium 47 has been conveyed according to the number of steps in which the motor 76 has operated. That is, the CPU 200 can sequentially recognize how much the ticket medium 47 has moved since the ticket medium 47 was set. For example, the CPU 200 measures the operating time of the motor 76 using an OS timer or a hard timer of the ticket gate 100. The CPU 200 can calculate the transport amount of the ticket medium 47 based on the measured time and the operating speed of the motor 76.

  The CPU 200 can recognize the position of the region 47 d on which the mark on the ticket medium 47 is printed based on the detection result of the reflection sensor 48. The reflection sensor 48 includes a light emitting unit and a light receiving unit. The light emitting unit outputs, for example, visible light or infrared light to the conveyance path on which the ticket medium 47 is conveyed. The light receiving unit is provided on the same side as the light emitting unit with respect to the conveyance path. The light receiving unit receives light output from the light emitting unit and reflected by the ticket medium 47, converts the received light into an electrical signal, and outputs the electrical signal to the CPU 200 as a detection signal via the detection circuit 117.

  For example, the mark printed in the area 47 d is printed with a design that has a significantly different luminance than the other parts of the roll-shaped ticket medium 47. For example, when the area 47d of the ticket medium 47 enters the detection position of the reflection sensor 48, the number of detection signals output from the reflection sensor 48 changes. The CPU 200 determines whether or not the area 47d of the ticket medium 47 exists in the light receiving range (detection position of the reflection sensor 48) of the light receiving unit of the reflection sensor 48 according to the number of detection signals from the reflection sensor 48. The CPU 200 continuously monitors the detection signal from the reflection sensor 48. Thereby, the CPU 200 can sequentially recognize the position of the area 47d of the ticket medium 47 on the conveyance path.

  As described above, the region 47d is provided at a certain distance from the region 47c. That is, the CPU 200 can also recognize the position of the region 47c on the conveyance path by recognizing the position of the region 47d.

  The CPU 200 can recognize the position of the tip of the ticket medium 47 based on the detection result of the transmission sensor 49. The transmission sensor 49 includes a light emitting unit and a light receiving unit. The light emitting unit outputs, for example, visible light or infrared light to the conveyance path on which the ticket medium 47 is conveyed. The light receiving unit is provided to face the light emitting unit across the conveyance path. The light receiving unit converts the received light into an electrical signal and outputs the electrical signal to the CPU 200 as a detection signal via the detection circuit 117.

  For example, when the ticket medium 47 exists between the light receiving unit and the light emitting unit (detection position of the transmission sensor 49), the transmission sensor 49 does not output a detection signal. When the CPU 200 does not receive the detection signal from the transmission sensor 49, the CPU 200 determines that the ticket medium 47 exists at the detection position of the transmission sensor 49. For example, when the ticket medium 47 is present at the detection position of the transmission sensor 49, the transmission sensor 49 outputs a detection signal. When receiving the detection signal from the transmission sensor 49, the CPU 200 determines that the ticket medium 47 does not exist at the detection position of the transmission sensor 49.

  The CPU 200 continuously monitors the presence / absence of a detection signal from the transmission sensor 49. For example, when the ticket medium 47 enters the detection position of the transmission sensor 49, the transmission sensor 49 switches from a state in which a detection signal is output to a state in which the detection signal is not output. The CPU 200 determines that the ticket medium 47 has entered the detection position of the transmission sensor 49 when the detection signal of the transmission sensor 49 is switched to the non-output state. That is, the CPU 200 determines that the tip of the ticket medium 47 exists at the detection position of the transmission sensor 49 when the detection signal of the transmission sensor 49 is switched to the non-output state. Further, the CPU 200 sequentially recognizes the distance from the cutting position of the cutter 51 to the tip of the ticket medium 47 according to the transport distance of the ticket medium 47 after the tip of the ticket medium 47 is detected at the detection position of the transmission sensor 49. can do.

  Furthermore, the CPU 200 can recognize the distance from the region 47 d of the ticket medium 47 to the tip of the ticket medium 47 based on the detection signal of the reflection sensor 48 and the detection signal of the transmission sensor 49. Further, the CPU 200 can also recognize the distance from the area 47 c of the ticket medium 47 to the tip of the ticket medium 47.

  The ticket issuing unit 41 cuts the ticket medium 47 by the cutter 51 in the region 47c. That is, the CPU 200 causes the motor 76 to transport the ticket medium 47 so that the cutting position of the cutter 51 and the area 47 c of the ticket medium 47 overlap, and causes the cutter 51 to cut the ticket medium 47.

  The CPU 200 controls the transport mechanism so that the ticket medium 47 cut by the cutter 51 is transported to a position where printing can be performed by the thermal head 52. For example, the CPU 200 moves the ticket medium 47 cut by the cutter 51 by operating the motors 72 and 76 and the like.

  The CPU 200 controls the print control circuit 207 to operate the thermal head 52, thereby printing predetermined information on the area 47a of the ticket medium 47. For example, the CPU 200 controls the thermal head 52 to print boarding ticket information or the like on the area 47 a of the ticket medium 47.

  Further, the CPU 200 controls the magnetic processing unit 33 to record predetermined information on the magnetic layer of the ticket medium 47. For example, the CPU 200 controls the magnetic processing unit 33 to record the ticket information, the entrance record, and the like on the magnetic layer of the ticket medium 47. Further, the CPU 200 controls the transport mechanism so that the ticket medium 47 on which printing and device recording have been performed is discharged from the discharge port 3. Thereby, the ticket gate 100 can issue the ticket medium 47 which can be used as a boarding ticket.

  The ticket medium 47 issued by the ticket gate 100 is printed with ticket surface information such as ticket type, ticket number, valid section, expiration date, and train information.

  Note that the total length of the ticket medium 47 that can be transported has a lower limit due to the structure of the transport mechanism inside the ticket gate 100. For this reason, the lower limit Xmin of the length X of the ticket medium 47 cut by the cutter 51 corresponds to the lower limit of the length that can be transported by the transport mechanism inside the ticket gate 100. In addition, when the ticket medium 47 is cut in the area 47c of the ticket medium 47, the length X = T of the cut ticket medium 47 is obtained. That is, the distance T between the regions 47c (cutting region interval) T corresponds to the length of the ticket when the ticket medium 47 is normally issued. Hereinafter, the distance T is referred to as a reference length T.

  Furthermore, as described above, the ticket medium 47 is accumulated in the first temporary holding box 82a and the second temporary holding box 82b. For this reason, the upper limit Xmax of the total length X of the ticket medium 47 cut by the cutter 51 corresponds to the upper limit of the size that can be accommodated in the first temporary holding box 82a and the second temporary holding box 82b.

  That is, the total length X of the ticket medium 47 is not less than the length that can be transported by the transport mechanism inside the ticket gate 100, and is a size that can be accommodated in the first temporary storage box 82a and the second temporary storage box 82b. When the ticket medium 47 is cut in the region 47c, the region 47c is provided so as to satisfy Xmin <X <Xmax.

  However, there is a possibility that the tip of the roll-shaped ticket medium 47 is cut at another position other than the region 47 c and loaded into the ticket issuing unit 41. In such a case, the ticket checker 100 cuts the end portion of the ticket medium 47 (the amount less than one ticket medium 47 plus one) as a waste ticket. The ticket checker 100 collects the ticket medium 47 cut as a waste ticket in the ticket collecting unit 40. That is, the ticket checker 100 can adjust the ticket medium region 47c to overlap the cutting position of the cutter 51 by cutting the ticket medium 47 one or more times by the ticket issuing unit 41.

  As described above, the CPU 200 can recognize the distance from the area 47 c of the ticket medium 47 to the tip of the ticket medium 47. For example, when the length (remaining length) from the area 47c of the ticket medium 47 to the tip of the ticket medium 47 is R, the CPU 200 cuts the area 47c of the ticket medium and the cutter 51 if Xmin ≦ R ≦ Xmax. It can be recognized that the position overlaps. In this case, the ticket gate 100 can issue the ticket medium 47 by the ticket issuing unit 41 by the above processing.

  Further, when Xmin ≦ R ≦ Xmax is not satisfied, the CPU 200 can recognize that the area 47c of the ticket medium 47 and the cutting position of the cutter 51 do not overlap. In this case, the ticket gate 100 adjusts the area 47 c of the ticket medium 47 so as to overlap the cutting position of the cutter 51 by cutting the waste ticket from the roll-shaped ticket medium 47 by the ticket issuing unit 41.

  FIG. 10 shows an example of the operation of the ticket gate 100 when the ticket gate 100 is activated or when the ticket medium 47 is set in the ticket issuing unit 41.

  The CPU 200 of the ticket gate 100 conveys the ticket medium 47 loaded in the ticket issuing unit 41 by controlling the motor 76. The CPU 200 conveys the ticket medium 47 to the detection positions of the reflection sensor 48 and the transmission sensor 49. Thereby, CPU200 recognizes the position of the edge part of ticket medium 47 (Step S11). Furthermore, the CPU 200 recognizes the positions of the area 47c and the area 47d on the ticket medium 47 (step S12). Further, the CPU 200 recognizes the length R from the area 47c on the ticket medium 47 to the end of the ticket medium 47 (step S13).

  CPU 200 determines whether or not length R satisfies Xmin ≦ R ≦ Xmax (step S14). That is, when the ticket medium 47 is cut in the area 47d on the ticket medium 47, the CPU 200 can transport the length X of the ticket medium 47 by the transport mechanism inside the ticket gate 100, and the first temporary holding box 82a. And it is judged whether it is the size which can fit in the 2nd temporary storage box 82b.

  When determining that Xmin ≦ R ≦ Xmax is not satisfied, the CPU 200 calculates the number of cuts and the cut length necessary for arranging the region 47c at the end of the ticket medium 47 (step S15). As described above, even when the ticket medium 47 is cut as a waste ticket, it is necessary to cut with a cut length between Xmin and Xmax. Therefore, the CPU 200 calculates the number of cuts and the cut length based on R, which is the remaining length of the ticket medium 47, the reference length T, and the maximum cuttable length Xmax.

  The difference between the reference length T and the maximum length Xmax that can be cut corresponds to the length that can be shortened from the remainder when one piece of waste ticket is cut. That is, the CPU 200 can calculate the necessary number of cuts by dividing the remaining length R by the difference between the reference length T and the maximum cuttable length Xmax. The CPU 200 determines that the waste ticket is cut from the ticket medium 47 with the maximum length Xmax by an integer of a numerical value obtained by dividing the remaining length R by the difference between the reference length T and the maximum length Xmax that can be cut. That is, the CPU 200 determines to cut the waste ticket from the ticket medium 47 with the maximum length Xmax by an integer of R / (Xmax−T). Further, the CPU 200 determines whether or not there is a remaining length R. When there is a surplus length R, it is determined that the waste ticket is cut from the ticket medium 47 by a length obtained by adding the surplus length R to the reference length T.

  The CPU 200 controls the motor 76 and the cutter 51 so as to cut the waste ticket from the ticket medium 47 with the calculated number of cuts and cut length. Further, the CPU 200 controls the transport mechanism so that the cut waste ticket is collected on the collection unit 40. Thereby, CPU200 cuts a waste ticket one by one. Further, the CPU 200 determines whether or not the waste ticket has been cut from the ticket medium 47 by the number of cuts calculated in advance every time the waste ticket is cut from the ticket medium 47 (step S16). When it is determined that the waste ticket has been cut from the ticket medium 47 by the number of cuts calculated in advance, the CPU 200 ends the process. As a result, the CPU 200 can install the region 47 c at the end of the ticket medium 47.

  If it is determined in step S14 that Xmin ≦ R ≦ Xmax is satisfied, the CPU 200 controls the motor 76 and the cutter 51 so as to cut the waste ticket from the ticket medium 47 with the length R (step S17). . Further, the CPU 200 controls the transport mechanism so that the cut waste ticket is collected in the collection unit 40, and ends the process. As a result, the CPU 200 can install the region 47 c at the end of the ticket medium 47.

  According to the above-described configuration, the ticket checker 100 is not less than a preset minimum length even when the ticket medium 47 is loaded in the ticket issuing unit 41 without being cut at the predetermined area 47c. One or a plurality of waste tickets are cut with a length that is equal to or less than a preset maximum length.

  The ticket gate 100 cuts the ticket from the ticket medium 47 on the basis of the remaining length, one of the minimum length and the maximum length, and the interval of the cutting area when the remaining length is not the minimum length or the maximum length. And the length of each scrap ticket are calculated, and the ticket medium 47 is cut based on the calculation result.

  Furthermore, the ticket checker 100 can convey the cut waste ticket to the bill collection unit 40. Furthermore, the ticket checker 100 can collect the waste ticket inside the ticket checker 100 even if the ticket collection box for collecting the waste ticket is small.

  Thus, the CPU 200 can control each part of the ticket gate 100 so that the area 47 c is installed at the end of the ticket medium 47. As a result, it is possible to provide a convenient ticket gate and a method for controlling the ticket gate.

  In the above-described embodiment, the CPU 200 of the ticket gate 100 has been described as having a configuration in which the number of cuts and the cut length are determined based on the remaining length R, the reference length T, and the maximum length Xmax. It is not limited to the configuration. The CPU 200 may be configured to determine the number of cuts and the cut length based on the remaining length R, the reference length T, and the minimum length Xmin.

  In this case, the CPU 200 corresponds to the length that can be extended from the remainder when the difference between the reference length T and the minimum cuttable length Xmin cuts one waste ticket. That is, the CPU 200 can calculate the necessary number of cuts by dividing the extra length R by the difference between the reference length T and the minimum cuttable length Xmin. The CPU 200 determines that the waste ticket is cut from the ticket medium 47 by the minimum length Xmin by the integer number of the remainder length R divided by the difference between the reference length T and the minimum length Xmin that can be cut. That is, the CPU 200 determines that the waste ticket is cut from the ticket medium 47 with the minimum length Xmin by an integer of (TR) / (T-Xmin). Further, the CPU 200 determines whether or not there is a remaining length R. If there is a surplus length R, it is determined that the waste ticket is cut from the ticket medium 47 with the surplus length R.

  Further, the CPU 200 may be configured to switch the processing method based on the extra length R and the reference length T. For example, the method of determining the number of cuts and the cut length based on the remaining length R, the reference length T, and the maximum length Xmax as described above is the first method, and the remaining length R and the reference length T are determined. A method of determining the number of cuts and the cut length based on the minimum length Xmin is a second method. The first method is a method in which the extra length R is shortened each time a waste ticket is cut. The second method is a method in which the extra length R is increased every time a waste ticket is cut. Therefore, for example, when the surplus length R is less than half of the reference length T, the CPU 200 determines the number of cuts and the cut length of the waste ticket by the first method, and the surplus length R is the reference length. When it is more than half of T, the number of cuts and the cut length of the waste ticket are determined by the second method described above. Thereby, the ticket gate 100 can complete the cutting of the waste ticket in a shorter time.

  In the above embodiment, the CPU 200 recognizes the end of the ticket medium 47 based on the detection signal from the transmission sensor 49, and the position of each region on the ticket medium 47 based on the detection signal from the reflection sensor 48. However, the present invention is not limited to this configuration. The CPU 200 may be configured to recognize the end portion of the ticket medium 47 based on the detection signal from the reflection sensor 48. In this case, the transmission sensor 49 may be omitted.

  Further, in the above-described embodiment, the ticket checker 100 is described as having a configuration for collecting the waste tickets in the ticket collection unit 40, but is not limited to this configuration. The ticket gate 100 may be configured to discharge the waste ticket from the discharge port 3.

  FIG. 11 shows another example of the operation of the ticket checker 100 when the ticket checker 100 is activated or when the ticket medium 47 is set in the ticket issuing unit 41.

  The CPU 200 of the ticket gate 100 conveys the ticket medium 47 loaded in the ticket issuing unit 41 by controlling the motor 76. The CPU 200 conveys the ticket medium 47 to the detection positions of the reflection sensor 48 and the transmission sensor 49. Thereby, CPU200 recognizes the position of the edge part of ticket medium 47 (Step S21). Furthermore, the CPU 200 recognizes the positions of the area 47c and the area 47d on the ticket medium 47 (step S22). Further, the CPU 200 recognizes the length R from the area 47c on the ticket medium 47 to the end of the ticket medium 47 (step S23).

  CPU 200 determines whether or not length R satisfies Xmin ≦ R ≦ Xmax (step S24).

  When determining that Xmin ≦ R ≦ Xmax is not satisfied, the CPU 200 controls the motor 76 and the cutter 51 so as to cut the waste ticket from the ticket medium 47 in the region 47c (step S25). Further, the CPU 200 controls the transport mechanism so that the cut waste ticket is discharged from the discharge port 3 (step S26). In this case, the CPU 200 controls the motor 76 and the cutter 51 so as to cut the waste ticket from the ticket medium 47 in the second and subsequent areas 47c from the tip of the ticket medium 47. When the waste ticket is discharged from the discharge port 3, the CPU 200 ends the process.

  If it is determined in step S24 that Xmin ≦ R ≦ Xmax is satisfied, the CPU 200 controls the motor 76 and the cutter 51 so as to cut the waste ticket having the length R from the ticket medium 47 (step S27). . Further, the CPU 200 controls the transport mechanism so that the cut waste ticket is collected in the collection unit 40, and ends the process.

  Even with such a configuration, the ticket gate 100 can install the area 47 c at the end of the ticket medium 47. As a result, it is possible to provide a convenient ticket gate and a method for controlling the ticket gate.

  In the example of FIG. 11, when the length R does not satisfy Xmin ≦ R ≦ Xmax, the ticket gate 100 discharges the waste ticket from the discharge port 3 and the length R satisfies Xmin ≦ R ≦ Xmax. However, the present invention is not limited to this configuration. The ticket gate 100 may be configured to discharge the waste ticket from the discharge port 3 regardless of whether the length R does not satisfy Xmin ≦ R ≦ Xmax.

  FIG. 12 shows still another example of the operation of the ticket checker 100 when the ticket checker 100 is activated or when the ticket medium 47 is set in the ticket issuing unit 41.

  The CPU 200 of the ticket gate 100 conveys the ticket medium 47 loaded in the ticket issuing unit 41 by controlling the motor 76. The CPU 200 conveys the ticket medium 47 to the detection positions of the reflection sensor 48 and the transmission sensor 49. Thereby, CPU200 recognizes the position of the edge part of ticket medium 47 (Step S31). Furthermore, the CPU 200 recognizes the positions of the area 47c and the area 47d on the ticket medium 47 (step S32). Further, the CPU 200 recognizes the length R from the area 47c on the ticket medium 47 to the end of the ticket medium 47 (step S33).

  CPU 200 determines whether or not length R satisfies Xmin ≦ R ≦ Xmax (step S34).

  When determining that Xmin ≦ R ≦ Xmax is not satisfied, the CPU 200 controls the motor 76 and the cutter 51 so as to cut the waste ticket from the ticket medium 47 in the region 47c (step S35). Further, the CPU 200 controls the transport mechanism so that the cut waste ticket is discharged from the discharge port 3 (step S36). In this case, the CPU 200 controls the motor 76 and the cutter 51 so as to cut the waste ticket from the ticket medium 47 in the second and subsequent areas 47c from the tip of the ticket medium 47. When the waste ticket is discharged from the discharge port 3, the CPU 200 ends the process.

  If it is determined in step S34 that Xmin ≦ R ≦ Xmax is satisfied, the CPU 200 controls the motor 76 and the cutter 51 so as to cut the waste ticket of length R from the ticket medium 47 (step S37). The process proceeds to step S36. That is, the CPU 200 controls the transport mechanism so that the waste ticket cut by the length R is discharged from the discharge port 3, and ends the process.

  Even with such a configuration, the ticket gate 100 can install the area 47 c at the end of the ticket medium 47. Further, since the ticket checker 100 discharges the waste ticket from the discharge port 3 regardless of whether the length R satisfies Xmin ≦ R ≦ Xmax, the operation by the operator can be simplified. As a result, it is possible to provide a ticket gate with higher convenience and a ticket gate control method.

  In the above embodiment, an example of processing in station equipment installed on a railway has been described. However, the ticket gate 100 can be similarly applied to, for example, an airplane entrance and an airplane boarding pass. .

  It should be noted that the functions described in the above embodiments are not limited to being configured using hardware, but can be realized by causing a computer to read a program describing each function using software. Each function may be configured by appropriately selecting either software or hardware.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Further, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, you may combine suitably the component covering different embodiment.

  DESCRIPTION OF SYMBOLS 1 ... Apparatus main body, 2 ... Input port, 3 ... Release port, 33 ... Magnetic processing part, 38 ... Collection box, 40 ... Collection box, 41 ... Ticketing part, 43 ... Storage part, 47 ... Ticket medium, 48 ... Reflection sensor, 49 ... transmission sensor, 50 ... motor, 51 ... cutter, 52 ... thermal head, 76 ... motor, 80a ... collecting path, 80b ... collecting path, 82a ... temporary holding box, 82b ... temporary holding box, 100 ... ticket gate, 117 ... detection circuit, 200 ... CPU, 201 ... ROM, 202 ... RAM.

Claims (2)

A storage section in which a roll-shaped ticket medium having a cutting area set at a constant interval is loaded;
A transport mechanism for transporting the ticket medium stored in the storage section along a transport path;
A cutter for cutting the ticket medium transported by the transport mechanism;
A bill collection section for collecting the ticket medium cut by the cutter and conveyed by the conveyance mechanism;
A detection unit that detects the tip of the ticket medium and the position of the cutting area of the ticket medium on the conveyance path;
The transport mechanism calculates a surplus length from the cutting area to the tip of the ticket medium based on the detection result of the detection unit, and cuts the ticket medium as a waste ticket based on the calculated surplus length. And a control unit for controlling the cutter,
Equipped with,
The controller is
Determining whether the remainder length is greater than or equal to a preset minimum length and less than or equal to a preset maximum length;
If the remainder length is not less than the preset minimum length and not more than the preset maximum length, the remainder length is divided by an integer that is a value obtained by dividing the remainder length by the difference between the maximum length and the interval between the cut areas. Cutting the scrap ticket from the ticket medium with the maximum length,
A value obtained by multiplying the difference between the maximum length and the interval of the cutting area by the number of discarded tickets cut from the ticket medium is subtracted from the remainder length, and the waste ticket is obtained by adding the interval of the cutting areas. A ticket gate for controlling the transport mechanism and the cutter so as to cut the sheet from the ticket medium . A storage unit loaded with a roll-shaped ticket medium having a cutting area set at regular intervals, a transport mechanism for transporting the ticket medium stored in the storage unit along a transport path, and transported by the transport mechanism A cutter for cutting the ticket medium, a bill collection section for collecting the ticket medium cut by the cutter and transported by the transport mechanism, a tip of the ticket medium, and the cutting area of the ticket medium. A control unit for a ticket gate having a detection unit that detects a position on the conveyance path,
Based on the detection result of the detection unit, calculate the extra length from the cutting area to the tip of the ticket medium,
Determining whether the remainder length is greater than or equal to a preset minimum length and less than or equal to a preset maximum length;
When the surplus length is not less than a preset minimum length and not more than a preset maximum length, the ticket medium is cut as a waste ticket with the calculated surplus length ,
If the remainder length is not less than the preset minimum length and not more than the preset maximum length, the remainder length is divided by an integer that is a value obtained by dividing the remainder length by the difference between the maximum length and the interval between the cut areas. Cutting the scrap ticket from the ticket medium with the maximum length,
A value obtained by multiplying the difference between the maximum length and the interval of the cutting area by the number of discarded tickets cut from the ticket medium is subtracted from the remainder length, and the waste ticket is obtained by adding the interval of the cutting areas. Controlling the transport mechanism and the cutter so as to cut from the ticket medium ,
How to control the ticket gate.