DE3620615C2 - - Google Patents

Description

The invention relates to a ticket vending machine for operation in a vehicle according to the preamble of the claim 1.

There are known cash cassettes on the top arranged access openings for banknotes and coins through one below these openings in the cash box arranged plate can be closed by one at the front the handle arranged on the cash box twisted becomes. An unauthorized operation of the handle can also can be prevented by a safety device. At the Inserting such a cash cassette into a housing further security measures against unauthorized removal of the Cash box required. So it is with an automatic Fernbankschalter (DE 31 38 732 A1) known that the banknotes containment container only in a certain, in the predetermined sequence of steps can be inserted in the switch and only if followed this sequence of steps using a mechanical Locking device on the security container arranged door can be opened for the access opening.

The invention has for its object the cash cassette to be arranged in a ticket machine such that a maximum security against theft is given.

According to the invention, the stated object is based on the features of claim 1 solved. Advantageous further training result from the subclaims.

Access to the cash box is thus blocked according to the invention, if the bill placed over the cash cassette  and coin mechanism should be removed. Further the cash cassette itself can only be removed from the ticket machine be removed if from the outside via a data transmission device an unlock signal is effective. Next to the one that closes the openings in the cash box mechanical closure device and the housing side Mechanical openings closing openings above the cash box The locking device is still the electronic locking device intended for the cash box. So that is given high security against theft.

An embodiment of the invention is shown below the drawing explained in more detail. It shows

Fig. 1 is a perspective view of a facing to the front of a passenger ticket vending machines,

Fig. 2 is a perspective view of a facing with the back of the driver's ticket vending machines,

Fig. 3 is a side sectional view of the ticket vending machines with a banknote device via a cashbox,

Fig. 3A shows a detail of Fig. 3 showing the locking device,

Fig. 4 is a side section with a coin system to the cashbox,

Fig. 5 is a perspective view of the cash cassette,

Fig. 6 is a block diagram of the functional blocks of the ticket vending machines,

Fig. 7 is a block diagram of the fare processor,

Fig. 8 is a flowchart for the operation of the fare processor,

Fig. 9 shows the terminal of the fare machines to a data conditioning,

Fig. 10 is a front view of the coin system,

Fig. 11 is a plan view of a security plate over the cash box with a mechanical locking device and

Fig. 12 is a plan view of the cash box.

In Fig. 1, a ticket vending machine 10 is shown from the perspective of a bus driver. The machine 10 is thus arranged directly next to the bus driver at the passengers' entry into the bus. In addition to operating the bus, the driver checks and monitors the machine 10 .

The fare can be paid by several means of payment. In the preferred embodiment, the means of payment accepted by the machine 10 for issuing a ticket include banknotes, stripe cards, each stripe corresponding to a prepaid fare, coins, tokens and tickets or tickets which include magnetically encoded signals on a strip of magnetic Wear material. Other forms of payment that the machine accepts are prepaid tickets or prepaid transfer cards.

A ticket is initiated when a passenger a means of payment for the machine when boarding the bus offers.  

When a payment process is carried out, the machine 10 can respond to banknotes, tickets, coins, tokens or tickets from passengers and register the payment. The possibility that the machine registers a payment also includes the possibility of determining the amount of the offer from the offered means of payment and deciding whether the offered amount is equal to or exceeds a certain fare. If the amount offered is sufficient to pay the fare, the machine responds and accepts the payment.

Reference is made to Figure 2. 1 and FIG.. FIG. 2 shows the ticket machine 10 from the perspective of a passenger boarding a bus. The machine housing 12 has an upper housing part 13 with an inclined opening for accepting money and tickets. The banknotes and tickets entered by a passenger into the opening 14 are individually guided from the opening 14 to a viewing window 17 visible to the driver through a banknote device 16 . From the viewing window 17 , the bill device 16 guides the bills on a path 18 , on which the bills and tickets get further into the interior of the housing 12 .

A coin opening 19 is arranged in the upper housing part 13 , through which coins and tokens are inserted into a coin device 21 by a passenger. Coins and tokens pass through the coin device 21 to a coin viewing window 23 which is visible to the bus driver. From the viewing window 23 , coins and tokens are guided further into the interior of the machine 10 via a channel 25 .

A magnetic ticket reader 27 is attached to the upper portion of the housing 13 and has a reading slot 29 through which a passenger slides a ticket with magnetically encoded travel data by hand while maintaining physical control of the ticket as it travels through the slot.

An alphanumeric value display 33 for the passenger is arranged on the magnetic ticket reader 27 , where it is visible to the passenger. An alphanumeric value display 35 for the driver / user is arranged on the driver's side of the machine, where it is only visible to the driver. An alphanumeric input keypad 36 is also arranged on the driver's side of the machine 10 next to the coin viewing window 23 and the price display 35 for the driver. A fare status indicator 38 for the driver / operator is arranged on the side of the magnetic ticket reader 27 , which can only be seen by the driver.

Other control elements for the driver, which are arranged on the side of the machine 10 , are a manually operated coin cash register lever 39 and a bypass lever 41 . Finally, a loudspeaker 42 is arranged on one side of the machine, where it emits sounds and certain speech messages that are audible to both the driver and the passenger.

A cash cassette 46 is securely arranged in a chamber 47 in the lower part of the machine 10 . In the machine and above the cash box 46 there is a security plate 50 which separates the upper part of the machine with the bill and coin device 16 , 21 from the lower chamber 47 which contains the cash box 46 . An electronic locking device 60 is securely mounted on the inside of the housing over the security plate 50 immediately above the top of the cash cassette 46 . A rotatable handle 64 is arranged on the front of the cash cassette 46 . On the wall of the machine 10 facing the passenger is a socket 66 which is used when the bus is driven to an end station for removing the cash cassette 46 .

The structure of the bill device 16 is explained in more detail in FIGS. 2 and 3. In operation, bill opening 14 is illuminated by means not shown and accepts any US banknote in circulation. In addition, passengers can buy tickets such as pre-printed cardboard tickets (stripe cards) that are produced in appropriate lengths, the length of the stripe card corresponding to the fare paid in advance by the passenger holding the ticket. The lengths of the stripe cards differ from the length of a US currency bill. In the fare processing described below, it is assumed that the detected bills are one dollar bills regardless of the real value of the bill. Thus, a one hundred dollar bill is recognized and a value of one dollar is assigned to it.

A ticket is entered through ticket opening 14 in the direction of the arrow shown. When he enters the housing through the opening 14 , its front edge is scanned by two optical sensors 70 a and 70 b. When the edge of the ticket passes between the two sensors, they generate a BILL PRESENT signal for a fare processor described below, which in turn generates a START MOTOR signal. The START MOTOR signal causes a motor 71 to rotate. A drive pulley 72 connected to the output shaft of the motor 71 transmits the force via a drive belt to two toothed pulleys 73 a and 73 b. The toothed pulley 73 a is rotated by the belt, which is in engagement with the motor pulley 72 , whereby it causes the toothed pulley 73 b to rotate.

The toothed pulleys 73 a and 73 b drive the pulleys 74 and 75 , which are rotatably mounted on shafts in the interior of the ticket module 16 . Rotation of the drive pulleys 74 and 75 causes rotation of two endless conveyor belts 76 and 77 , so that the front edge of a bill inserted through the opening 14 is pinched and conveyed inside to the viewing window 17 . The viewing window 17 is made of a clear, transparent material and is formed in one piece with the bill module 16 . When the trailing edge of the bill through the endless conveyor belts 76 and 77 optical to a location between two sensors 78 a and transported b 78, this will produce a signal MEASURE BILL (bill measure), which is fed to the fare processor described below, in turn, a signal generated to stop the motor 71 for a certain period of time. Immediately after the motor 71 stops, a second pair of sensors 79 a and 79 b are scanned to determine whether the leading edge of the bill is blocking the pair of sensors or not. If the rear edge of the bill does not block the pair of sensors, it is of a certain length which corresponds to a prepaid ticket of a certain number. If the pair of sensors 79 a and 79 b are blocked, then the bill is considered a one dollar bill in US currency. Since the bill is stopped immediately below the viewing window 17 , the value can be visually confirmed by the operator of the machine.

After a certain period of time, after the back edge of the bill has passed through the two optical sensors 78 a and 78 b or when the operator presses the DUMP key on the keypad 36 , the motor 71 starts again and causes the belts 76 and 77 rotate again in a direction in which the bill in the bill module is conveyed down to the drive rollers 74 and 75 . When the bill runs between the rollers 74 and 75 , it is led out through the plate 81 on the bottom of the bill device 16 . After another certain period of time, when no other BILL PRESENT signal is present, the fare processor clears the signal that is applied to the motor 71 . If a different ticket or bank note is scanned by the sensor pair 70 a and 70 b, the motor 71 continues to run and the sequence described above is repeated.

A printed circuit board 83 represents a conventional interface for receiving, formatting and forwarding the signals from the optical sensor pairs 70 a and 70 b, 78 a and 78 b, and 79 a and 79 b. The printed circuit 83 also carries the conventional circuit for forwarding sensor signals from the coin module to the fare processor described below.

The coin device 21 is explained in more detail below with reference to FIGS . 2, 4 and 10. The coin opening 19 is also illuminated by means not shown, so that the passenger can find it more easily. It inserts coins or tokens of certain values into the coin opening, where they fall into the coin device 21 . From the opening 19 , the coins fall past a group of optical sensor pairs, a pair 95 a and 95 b being shown, and onto an inclined ramp surface 96 , whereupon they cover a short distance until their direction is changed by a ramp-shaped guide flange, which forms a conventional trough or slide 97 . The chute 97 directs the movement of the coins moving on the surface 96 to a conventional coin separating device 99 .

The sensors 95 a and 95 b indicate the presence of coins by means of a signal COIN PRESENT, which is fed to the fare processor. Depending on this, the fare processor transmits a signal RUN SINGULATOR (START SINGULATOR), whereby the coin separating device 99 is switched on. Then when the coins reach the device 99 , it works and is ready to separate the coins from one another.

The trough 97 has an electrostatic sensor, not shown, which senses the presence of a coin in the separating device 99 and reports it to the fare processor. As long as the electrostatic sensor senses the presence of a coin in the device 99 answers the fare processor described below, by maintaining the signal for the separating means 99, whereby it can continue to operate.

The trough 97 and the separating device 99 convey coins one by one in a conventional manner through a coin determining device 100 .

Coin determining devices are known.

The coin determining device 100 recognizes the value of each coin in the order specified by the separating device 99 and generates signals for the fare processor, first the presence of a coin (COIN PRESENT) and then the value of the coin (penny, dime,. ., Brand or brands) is displayed.

The coins pass through the determination device 100 and fall onto a plate 101 mounted in a hinge 102 . In the normal position of the hinge plate, its ends touch a coin collecting plate 103 , which stops the movement of the coins through the coin module 21 under the viewing window 23 . If the coins accumulate under the viewing window 23 , their value can be optically confirmed by the driver.

The end of the hinge plate 101 is pulled away from the coin collecting plate 103 by a hinge 104 . The swivel for retracting the plate is rotated either by a solenoid valve 105 or by a hand-operated rocker arm 106 which is connected to and operated by the hand-operated coin rocker arm 39 . Coins can thus be dropped under the viewing window either by the driver operating the rocker arm 39 or automatically by the solenoid valve 105 . The solenoid valve is acted upon as a function of a signal which is applied by the fare processor described below. In normal operation, the solenoid valve 105 drops coins after a period of 10 seconds, which begins when the electrostatic sensor in the separating device 99 does not scan any coins. Another sensor, not shown, on the plate 101 recognizes when enough coins have accumulated in the plate 101 before the end of the time period to detect a specific position of the plate 101 . This sensor then generates a signal HOPPER FULL for the fare processor, whereupon the latter applies magnetic valve 105 to carry the coins.

If coins are tipped over either manually or automatically, they fall out through a chute 114 and an opening in the bottom of the coin device 21 .

The automatic operation of the separating device 99 and the coin determining devices 100 can be transferred either automatically or by hand. Manual dubbing is carried out by pressure from the driver on the bypass lever 41 . Pressing the bypass lever 41 causes a bypass shaft 107 to rotate on a pivot point 108 in the direction of the arrow in FIG. 4A. The shaft 107 moves a joint 110 , the movement of which lifts the channel 107 from the inclined surface 96 . When the sloping guide plate is lifted from the surface 96 , the coins drop directly through the opening 19 over the sloping surface 96 onto the hinge plate 101 . After depressing the bypass lever, the coin device 21 does not work automatically until the ticket machine is reset by a controller.

The articulation 110 can also be actuated by a solenoid valve 111 , which in turn is acted upon by the fare processor described below when it recognizes that the separating device 99 is blocked.

A printed circuit board 112 is attached to the lower back portion of the coin device. It has several conventional circuits for receiving the signals from the optical sensor of the separating device 99 and the signals for the presence and the value of a coin of the coin determining device 100 . The conventional circuit on the board also formats these signals and feeds them via conventional cables, not shown, to the fare processor described below, which is arranged on another circuit board 113, which is mounted on the inner rear wall of the upper section of the machine 10 .

Referring to Figs. 2-5, 11 and 12, a secure mounting and storage of coins and bills will now be illustrated in the vending machine. As shown in FIGS. 2, 3, 3A and 4, the interior of the machine housing 12 is divided into two parts by a safety plate 50 which is fixedly attached to the interior of the housing. The security plate 50 has a banknote opening 118 ( FIGS. 3 and 11) which is connected to the bottom of the banknote device 16 and through which the banknotes and tickets fall. A coin opening 119 (FIGS . 4 and 11) is provided in the security plate below the coin device, where it is flush with the bottom of the coin slide 114 . In addition to the security plate 50 , a coin groove 116 is attached to the housing 12, centered above the coin opening 119 , which forms a continuous path for the coins which are tipped over by the coin device 21 , this path descending from the groove 114 through the groove 116 of the safety plate extends over the opening 119 in the security plate. The groove 116 of the security plate has a conventional access-proof funnel construction with two oppositely directed ramp surfaces 117 a and 117 b in order to prevent anyone from passing through the coin opening 119 when the coin device 21 is removed from the machine 10 .

When the bill and coin device 16, 21 is removed from the machine, the bill and coin openings 118 and 119 in the security plate are closed by a mechanical locking device. A bezel 120 is slidably attached to the top of the security plate 50 and slides back and forth between a first position in which the openings 118 and 119 ( FIG. 4) are uncovered and a second position in which both openings are closed ( FIG . 3 and 11).

The cover 120 is pushed back and forth between the two positions by a joint which has a rod 121 and is rotatably attached to the bill device 16 , as well as a locking linkage 122 and an articulated arm 124 . When the rod 121 rotates into one position, it rotates the articulated arm 124 . As can be seen from FIG. 11, a slot 124 a in the articulated arm 124 displaces the panel 120 with the aid of a pivot 125 attached to the panel 120, which projects through the slot. Rotation of the rod 121 in the other direction causes the lock to move to the other position.

The rod 121 can only be separated from the articulated arm 124 if the end 121 A of the rod 121 is rotated into a position in which the diaphragm 120 closes. Therefore, removing the ticket module requires rotation of the bar to close the bezel 120 and prevent unauthorized access to the cash register 46 .

The insertion, operation and removal of the cash cassette 46 will now be explained in more detail with reference to FIGS. 2-5 and 12. The cash cassette is partially inserted into the machine 10 in FIG. 3, fully inserted in FIGS. 2, 3A and 4 and removed from the machine in FIG. 5. Secure cash cassettes such as cash cassette 46 are known.

As shown in FIGS. 5 and 12 show, the cashbox 46 to two openings 126 and 127 through which notes and coins fall where they are collected in separate compartments, not shown, in the interior of the cashbox 46. One compartment is used to collect money and tickets; the other is the collection of coins and tokens. The cash cassette 46 has an upper cover which is formed from two parallel plates, between which a locking device, not shown, is provided which connects the rotatable handle 64 to a slide lock 129 . The inner closure device is actuated by the rotatable handle 64 . When this is rotated into a closed position, the inner closure device pushes the slide closure 129 into a position in which it closes the openings 126 and 127 . Rotation of handle 64 to an unlocked position causes the closure means to slide slide 129 away from openings 126 and 127 so that bills and coins can fall into their respective compartments in the interior of cash cassette 46 . In FIGS. 3 and 5, the slide lock 129 is in the closed position in which the cash box is used either partly or completely into the machine from this away. It is apparent that the slide lock must close the banknote and coin openings of the cashbox 46 before the cashbox can be fully inserted into the machine 10 to prevent unauthorized access to the cashbox collection chambers.

If the cash cassette 46 is not inserted in the machine as in Fig. 3, then the handle 64 is normally locked against rotation and is released when the cash cassette 46 is placed in the chamber 47 by an automatic key pin 131 ( Figs. 3 and 12) that protrudes from the lower housing into the interior of the chamber 47 . When the cash cassette is inserted into the chamber ( FIG. 12), the magnetic key pin 131 fits into a slot 133 . The key slot 133 allows the magnetic key pin 131 to enter the inside of the cash cassette 46 , where it releases the locking device, whereby the handle 64 can be rotated in a direction in which the locking device pushes the slide lock 129 into the open position and thus the openings 126 and 127 releases.

As can be seen from FIGS. 5 and 12, the locking device of the cash cassette 46 also rotates a magnetic key carrier 135 which carries a magnetic key 137 and a locking pin 139 . If the handle 64 is turned to the open position, a rotation of the magnetic key 137 on the key carrier 135 brings the magnetic key 137 next to a position sensor 141 which is mounted on the rear wall of the lower part of the housing 12 . When the magnetic key 137 is rotated in the opposite direction to the position sensor 141 , this transmits a signal CASHBOX SEATED to the fare processor described below. The rotation of the locking pin 139 out of the side wall of the cash cassette 46 brings it behind the projection 143 in the lower chamber 47 of the ticket machine. As a result, the cassette 46 is held in the lower chamber 47 until the handle 64 is rotated into the open position. It is clear that when the handle 64 is rotated to the closed position for removing the cassette, access to the cassette is blocked by the lock 129 since it is displaced so that it closes the openings 126 and 127 .

When the cash cassette 46 is fully inserted into the lower chamber 47 and the handle 64 is rotated to the open position, the CASHBOX SEATED signal causes the fare processor described below to transmit a LOCK signal to the electronic locking device 60 to lock a pin 145 insert into a slot 147 on the top of the cash cassette 46 . The locking pin 145 prevents the cash cassette from being removed from the lower chamber of the ticket machine, even when the handle 64 is turned to the open position.

FIG. 6 gives an overall overview of the functions performed by the units of the ticket machine 10 described above. The central unit for the operation of the machine is a fare processor 152 , which is connected to the value display 33 for the passenger, the value display 35 for the driver, the status display 38 for the driver, the alphanumeric keypad 36 for the driver and the loudspeaker 42 . Audible and visible messages, which indicate the result of the payment process, are communicated to a passenger via the value display 33 and the loudspeaker 42 . In the preferred exemplary embodiment, the passenger value display 33 has a conventional alphanumeric multi-segment display which operates in dependence on digital signals which are generated by the fare processor 152 . The driver value display 35 essentially corresponds to the passenger value display 33 .

The driver status display 38 has a conventional multi-element display ASCII, which operates as a function of ASCII code signals from the fare processor 152 . The driver's alphanumeric keypad 36 is a normal hand-operated keypad. The keypad 36 generates digitally coded signals in a conventional manner depending on the depression of the key on the keypad. The buttons are pressed by the driver in a specific order in order to generate assigned codes which are fed into the fare processor 152 so that it assumes the corresponding operating states.

Signals corresponding to the magnetically encoded signals on a ticket are obtained by the magnetic ticket reader 27 by a magnetic ticket processor 154 . Processor 154 performs a magnetic ticket payment process in response to magnetically encoded tickets that are slid by reader 27 described below and forwards the results to fare processor 152 .

The bill device 16 and the coin device 21 are electrically connected so that they can exchange the sensor, control and data signals described above with the fare processor 152 .

The insertion and closing of the cash cassette 46 in and in the machine 10 using the mechanical locking device described above is reported to the fare processor by the position sensor 141 . If it is determined from the CASHBOX SEATED signal generated by the position sensor 141 that the cash cassette 46 has been properly inserted and locked in the machine 10 , the fare processor 152 transmits a signal to the electronic locking device 60 which locks the cash cassette 46 in the housing. A socket 66 for data transmission provides a two-way connection between a data transmission device, not shown, and the fare processor 152 . In order to be able to remove the cash cassette 46 after turning the handle 64 into the closed position, the data transmission device transmits a specific command, described in more detail below, to the fare processor 152 , which contains a secure unlocking code, via the socket 66 . Depending on this unlocking code, the fare processor 152 transmits a signal to the electronic locking device which unscrews the locking pin 145 from the slot 147 in the cash cassette, as a result of which the cash cassette 46 can be removed from the machine 10 .

Fig. 7 shows the structure of the fare processor 152 in detail, wherein a conventional microprocessor 172 is acted upon by data and address signals supplied by a conventional address / data bus (A / D) 174 and a conventional address bus (A) 178 . An address decoder 176 is conventionally connected to busbar A / D 174 and receives data signals therefrom during a data cycle. Typically, address decoder 176 converts the data on busbar A / D 174 into address signals that augment a complement of address signals generated by an address cycle on busbar A 178 by microprocessor 172 . Conventional battery-loaded random access memory RAM 180 is conventionally operated by microprocessor 172 to enable the immediate storage and retrieval of data signals at locations indicated by the addresses on address bus 178 . A read-only memory ROM 182 also permanently stores program data which are supplied by the microprocessor 172 via the busbar A / D 174 as a function of address signals on the busbar A 178 . A clock 184 operates in a conventional manner to generate updated clock data on the busbar A / D 174 depending on the address signals.

The interface between the microprocessor 172 on the one hand and the processor 154 for magnetic tickets and the socket 66 takes place via a double input / output module for serial data transmission (DUART = dual universal asynchronous receive-transmit module) 186 . Two first oppositely directed half-duplex input outputs T _XA and R _XA effect an asynchronous duplex operation between the microprocessor 172 and the ticket processor 154 . Two other oppositely directed half-duplex I / O outputs provide another asynchronous full-duplex transmission path between the microprocessor 172 and the socket 66 . A first group of conventional issuing points P _O enables the microprocessor to generate a control signal START MOTOR (STARTING THE ENGINE) for the motor 71 of the bill module, the control signal RUN SINGULATOR for the separating device 100 and control signals for the solenoid valves 105 and 111 . A signal tone for driving a loudspeaker 42 is also generated. A group of parallel input points P _I in the DUART 186 enable the signals BILL PRESENT and MEASURE BILL (MONEY EXIST, MONEY EXAMPLE) from the bill module, the signals COIN PRESENT (COIN EXIST) and the sensor of the separating device and interruption signals from the keypad for connection to the processor 172 .

The DUART 186 causes the input signals from the bill device 16 , the coin device 21 and the keypad 36 to be classified as interrupt signals which conventionally interrupt a running program that is executed by the microprocessor 172 . The DUART 186 uses the signals from the pair of sensors 78 a and 78 b from the bill device to report to the processor 172 when a bill has reached the measurement position behind the viewing window. At the input P _{I there} is also a signal from the sensor and the separating device 99 , which indicates the presence of a coin.

The DUART 186 outputs signals from the microprocessor 172 which control the rotation of the motor 71 of the bill device in order to switch the separating device 99 and the magnet coils 105 and 111 of the coin device on and off.

A conventional input-output expansion circuit 188 is connected to the analog / digital bus 174 and the analog bus 178 , which is conventionally controlled by the microprocessor 172 and feeds data from the keypad 36 into the microprocessor 172 . A conventional group of outputs P _C provides the connection between the microprocessor 172 and the status display 38 .

Another input / output expansion circuit 190 connects the coin determiner 100 to the microprocessor 152 via the printed circuit 112 . The coin determination device generates signals which indicate that it is working and determines the value of a coin and also reports the coin value. The input / output expansion circuit 190 also has sensors or scanning signals from the bill device 16 which indicate the length of a bill or ticket (and therefore also the denomination or the prepaid value). Finally, the position sensor 141 for the position of the cash cassette generates the signal CASHBOX SEATED via the input / output expansion circuit 190 , while the microprocessor 172 emits an electronic closing signal in two switching states, the first state LOCK causing the electronic one Locking device 60 inserts locking pin 145 into slot 147 of the cash box; the other state UNLOCK causes the electronic locking device 60 to retract the locking pin 145 and thus release the cash cassette for removal from the ticket machine 10 .

Fig. 8 shows the overall operation of the ticket machine 10. First of all, a driver takes over the control of a bus and a ticket vending machine and initiates the program in FIG. 8 by pressing the keys corresponding to B 3 on the keypad 36 . The program of FIG. 8 responds by performing a series of diagnostic tests to check the reliable operation of the ticket machine. Thereafter, the driver enters the code B 2 via the keypad 36, after which causes the fare processor that a number of request or the guide mark in the status display 38 appears. Depending on each request character, the driver then enters a combination of digits that generate data that enables the fare processor to set up a test block table in RAM 180 . Each test block is clearly identified by an identification of the route that the bus must follow, the identification of the driver and the current journey on the short route.

After entering the identification or identification data, the driver selects buttons B and 1 , whereupon the fare processor generates a request character on the display 38 . The request character causes the driver to enter a code according to the choice of the fare table from the ROM 182 . This fare table is called up during the entire subsequent payment process until another fare table is selected. The selected fare table is also transmitted by the fare processor to the magnetic ticket processor.

The ticket processor then checks the condition of the cash cassette sensor 141 to see if the cash cassette has been safely inserted into the lower portion of the ticket machine. If this is not the case, the fare processor stops all the transportation payment operations until a valid CASHBOX SEATED signal is present. Assuming that the signal is present, the fare processor executes a payment process until either a new test block is generated, the cassette removed or a group of control / test functions is called. The CASHBOX SEATED signal is monitored continuously throughout the payment process, which is described below. If the cash box is moved during these processes, the payment processes are interrupted until it is firmly in place again.

The control / checking function can be carried out during a payment process with a jump back to it, when the process is finished. On the other hand, you can Control / test functions shortly before the end of the Payment process carried out by removing the cash box will. Finally, a payment process without calling up control / test functions by removing the cash box.  

The functions of the automated teller machine are ended when the bus carrying it is driven to a transit station in which a data system 239 is available. Fig. 9 provides an explanation performed by the money ticket machines 10 process in a station. The data exchange with the data system takes place via the socket 66 for the station data exchange, which is mounted on the machine and a half-duplex data transmission between itself and a conventional optocoupler 240 , which is connected to the connections T _XA and R _{XA of} the DUART 186 of FIG. 7 is. In the station, the data transmission device calls up the ticket machine via PIN 241 , which is plugged into socket 66 . The PIN is inserted into the socket 66 by hand and is electrically isolated by another optocoupler 242 , which essentially corresponds to the optocoupler 240 .

After the PIN 241 is in the socket 66 , the data transmission between the station device 239 and the ticket machine 10 takes place in an asynchronous half-duplex standard method using a multi-word protocol with a message structure according to reference number 245 in FIG. 9. In this, STX means the beginning of the text for the multi-word transmission. The end of the message is indicated by the field ETX. The message is structured in a conventional manner between the fields STX and ETX and offers command and computing data. A field allows the identification of a command.

In the preferred embodiment, an AUDIT (CHECK) command, which is displayed in the command field of a data transmitted from the plant 239 to the ticket machine 10 message causes the state machine 10 transmits all of its Prüfblockregister to the data conditioning the content. In the process of test data transmission from the ticket vending machines to the data system of the ticket vending machine 10 erases all running Streckenprüfregister in the RAM 180 according to a below-described cycle for the cash cassette.

The second command of interest consists of an UNLOCK command, which is transmitted from the station data system to the bank note machine 10 and which has a code in the computing data and command fields of the message, which is recognized by the ticket processor 152 of the machine and acts on it, to actuate the electronic locking device 60 so that the locking pin 145 is moved out of the slot 147 on the top of the cash cassette 46 . As a result, the cash cassette can be removed by rotating the handle 64 into its closed position, the openings on the top of the cash cassette 46 being closed and the locking pin 139 moving back into the cash cassette. A cash cassette cycle is complete when the cash cassette is reinserted into the lower chamber and locked there, as described above. When the processor of the automated teller machine senses the fixing of the cash cassette, it deletes the running check registers.

A third important command consists of the communication FARE TABLE UPDATE (FARE TABLE updating) that is transmitted from the station data means for ticket machine 10, requesting the fare processor 152 auszustauschen the fare table rides in the RAM 180 to the updated fare table data in the data field of the message.

Finally, a fourth important message includes a TIME / CLOCK UPDATE command that is accompanied by current time / date data and prompts fare processor 152 to clear time / data clock 184 .

Claims (8)

1. Ticket machine for operation in a vehicle with a bill and coin device for accepting, checking and conveying coins and bank notes, a device for accepting and checking tickets and magnetically coded tickets, with a memory for the fares belonging to several user categories, with a fare processor for registering the payment made in accordance with the determined fare, with a portable and detachably held cash cassette for receiving coins and banknotes that enter the cash cassette through openings, and with a locking device for the cash cassette, characterized in that the bank note and coin device ( 16, 21 ) is detachably arranged above the cash cassette ( 46 ), that between the bill and coin device ( 16, 21 ) and the cash cassette ( 46 ) a mechanical locking device ( 120 to 125 ) is arranged, which when removing the Bank note and coin device ( 16, 21 ) closes openings ( 118, 119 ) on the housing above the cash cassette ( 46 ), and that the locking device ( 60, 145, 147 ) of the cash cassette ( 46 ) can be released when an unlocking signal occurs, which is triggered by a stationary, data transmission device that can be connected to the automatic ticket machines is generated and can be transmitted to the locking device ( 60, 145, 17 ) via the fare processor ( 152 ). 2. Ticket machine according to claim 1, characterized in that the unlocking signal is generated by the vehicle processor ( 152 ) upon receipt of an unlocking code from the data transmission device. 3. Ticket machine according to claim 1 or 2, characterized in that the data transmission device to the fare processor ( 152 ) via a socket ( 66 ) can be connected. 4. Ticket machine according to one of claims 1 to 3, characterized in that a position sensor ( 141 ) connected to the vehicle processor ( 152 ) is provided for scanning the inserted cash cassette ( 46 ) and is conveyed by the fare processor ( 152 ) when the cash cassette is not inserted and Checking tickets, banknotes and coins is interrupted. 5. Ticket machine according to claim 4, characterized in that the locking device ( 60, 145, 147 ) from the fare processor ( 152 ) for mechanically locking the cash cassette ( 46 ) in the housing can be activated when the position sensor ( 141 ) the seat of the inserted cash cassette ( 46 ) scans. 6. Ticket machine according to claim 4 or 5, characterized in that the position sensor (141) is operated by a magnetic key (137), which is arranged on the cashbox (46) and adjustable from a handle (64) to the currency cassette (46) Openings ( 126, 127 ) in the cash cassette ( 46 ) which are aligned with the openings ( 118, 119 ) on the housing can be closed. 7. Ticket machine according to claim 6, characterized in that with the handle ( 64 ) a locking pin ( 139 ) for securing the cash cassette ( 46 ) can be actuated in the housing. 8. Ticket machine according to claim 6 or 7, characterized in that the actuation of the handle ( 64 ) can be released by a key pin ( 131 ) actuated by the cash cassette.