DE1946306A1 - Facility for balancing credit and debit amounts - Google Patents

Description

Device for balancing credit and debit

amounts

The invention relates to a device for balancing G-ut- and Lastsehrift amounts in vending machines with the one obtained by electrical means through coins or bills inserted into the vending machine Credit is determined and compared with the price of an item selected for purchase. Of course the applicability is The facility is not only limited to actual vending machines, but is useful for as well Gambling machines or record machines, where the price is the price, e.g. for playing a Record deals.

Known devices for adding up credit amounts and subtracting sales prices or direct debit amounts work in a mechanical or electromechanical way. These facilities in themselves serve their purpose, have but various disadvantages. For example, they work relatively slowly because the inertia of mechanically moving parts is overcome must be and since the working speed of mechanical con-

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constructions is limited by nature. The delay, the one with the credit for a properly inserted Coin or when subtracting the price of one for sale selected item from the accumulated credit occurs, gives the opportunity to fraud, multiple sales, Jamming of the machine and leaving customers dissatisfied.

They are already fully electronic ones Balancing devices have become known that have some advantages over the mechanical or electromechanical Have balancing facilities, but bring with them other, new difficulties or disadvantages. To this Disadvantages of electronically operating devices include that an electronic clock generator is required, which controls the operation of 3? lipflops and other circuits. The circuits themselves are in use built up discrete ^ components, and have the resulting stream parts of complex production, low reliability oM relatively large space requirements. Furthermore, the known electrical devices work faster than the mechanical or electromechanical, but still do not react instantly or practically without delay, as is actually necessary for vending machines were.

The invention is based on the object of a simply constructed, very compact and reliable device to create offsetting credit and debit amounts in vending machines that works very quickly and that necessary additions and subtractions practically without delay. The facility should be inexpensive be manufactured and have a long service life.

In short, this object is achieved according to the invention by means of an electronic accumulator which has several Full adders include, i.e. adders each having two or

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add more numbers arithmetically and generate an output corresponding to a digit and a transfer output to be added to the sum of the next digit. The digit output of each full adder arrives at a delay memory, the output of which is fed back to an input of the full adder. For selectively controlling the individual full adder logic gates preferably be used, wherein the data transmitted by the logic gates signals represent fixed value units in a certain way. The subtraction of units of value corresponding to the load tax amounts from accumulated, ie credited units of value, takes place by means of complementary addition.

With the help of the recently developed technology ": the integrated circuit, components and puncture members can be reduced in size considerably. This applies in particular to the so-called second generation of integrated circuits, the

so-called monolithic integrated circuits. These arrangements are completely out of the concept discrete components solved. Entire circuits are diffused into tiny chips made of semiconductor material. This technology has brought the solution of problems within reach, solving them with the help of discrete circuits seemed impossible. However, the integrated • circuits require new circuit concepts. As with many advanced ones The possibilities opened up by the integrated circuit have not been exploited since developments one has leaned too much on the traditional principles and solutions. The integrated circuit is available Time is the focus of interest and it becomes significant Research used on them, however, lags behind the practical application and commercial evaluation of the new technology to a certain extent still after.

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The balancing device according to the invention or the accumulator according to the invention was developed with special consideration of the requirements imposed by integrated circuit technology. It therefore has properties that make it particularly advantageous for implementation in the form of an integrated circuit. However, the device according to the invention can also be implemented with the aid of conventional circuit technology. The accumulator according to the invention is multi-stage, each stage having a binary full adder and a; Includes plip-flop which is in a feedback connection between the output of the full adder and one of its inputs. The flip-flop has a delay and a storage function. The various full adders are fed according to a specific selection pulses by inserting coins into the V _e rkaufsautomaten triggered by the inputting of money, for example, and associated with the individual coins, represent well-to-written value units which become added together in the accumulator . The impulses can be triggered or generated, for example, by coin switches that are activated when a coin is inserted. In order to be able to change the allocation between the amount of money and the number of value units as required, switches are provided with the aid of which the individual coin switches can be connected to predetermined groups of individual adders. Depending on the switch position, certain coin values can then be assigned to the individual coin switches and a certain number of value units can be assigned to the impulse generated or triggered by the corresponding coin switch when a coin is inserted. The device according to the invention can thus be adapted very flexibly to different applications, which is a great advantage and an essential feature of the invention.

In a further embodiment of the invention are for determination of the credit stored in the accumulator or the amount of credit, logical circuits are provided and

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- The further logic circuits that compare the accumulated * credit with the price of a selected item. If the credit amount is sufficient, the comparison logic causes the price of the item to be sold to be subtracted from the accumulated credit. Just like the allocation between the amount of money and the value units to be credited, the allocation between the individual articles and the units of value to be deducted assigned to them is completely freely adjustable, since the subtraction is effected by complementary addition and is therefore the same as the adding process in the workflow. In the device according to the invention, addition and subtraction take place practically instantaneously. The tooling and other production costs required to manufacture the device are relatively low. In addition, the effective device or circuit works without clock pulses and therefore avoids the difficulties of the known circuits caused by the use of a clock pulse generator. The device according to the invention is particularly suitable for implementation in the form of a monolithic integrated circuit, so that it can be constructed as an extremely small unit which, in addition to the stated advantages, has the advantage of low maintenance costs and very rare malfunctions.

The invention is explained in more detail below with further advantageous details on the basis of schematic drawings of exemplary embodiments. Show it:

Fig. 1 is a block diagram of an embodiment Invention,

2, 3 and 4 taken together show the block diagram of another embodiment of the invention,

Fig. 5 is a diagram from which the mutual arrangement of Figs. 2, 3 and 4 emerges,

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6 is a block diagram showing further advantageous features of the invention.

The explanation of the individual embodiments of a balancing device according to the invention is based on the assumption that that the customer with the accumulation of a credit, which should be equal to a certain purchase price, 'individual impulses, so-called Credit impulses, each of which triggers a certain amount of money to be credited, e.g. the amount of a ten-penny

Piece, a twenty-five-penny piece or a five-penny piece, represent. Each »amount of money should have a fixed one Number "correspond to value units, so ten pfennigs, for example, one value unit must be assigned.

Binary full adders are used to add up the value units according to the entered amounts of money with a delay memory located in a feedback loop, which is provided by a bistable element, e.g. by a flip-flop is formed, the delay in the Flip-flop would be built in. The delaying element in the feedback loop must also for the purpose of a subsequent Addition exercise a memory function.

In the first embodiment of the invention shown in FIG. 1, a multi-stage accumulator or counter is provided, the individual stages of which each have a binary full adder FA and a delay flip-flop FF. Each binary full adder FA can arithmetically add two binary digits and generate a count signal and a carry signal at two outputs. The first digits to be added up by a full adder are fed to an input A> as pulses which represent individual value units. The second digit required for an addition comes from the output of the full adder in the previous activation and is fed back as a corresponding signal to an input B ^{via the delay flip-flop I 1 F.} The * Such a coin is not in circulation in Germany, but would be

- 7 - which are given as an example. Classification by the one-, two- and five-mark piece for 3 g / q 1 0 9

Outputs of the individual full adders are labeled SO, S1, S2, S3, etc. Sn. 'The carry outputs are accordingly denoted by CO, 01, 02, C3 etc. Cn.

The count output S of each full adder is connected to a delay flip-flop FF. The corresponding output signal However, S is not immediately transmitted by the flip-flop FF to its output Q, but it is stored, until a pulse reaches an error input T of the flip-flop, which transfers the signal S to the output Q. The signal from output S can only be transferred to output Q. when a fixed time delay has expired, which ensures that a pulse at input A of the full adder has completely decayed before the signal from output Q reaches its input B. Without this time delay could "tear out" the circuit.

The pulses used to control the full adders PA come from coin switches 11 and 13. The coin switches 11 and are connected to a pulse generator V, which when actuated of switch 11 or 13 impulses on lines 15 resp. 17 gives up. There are only two coin switches shown, but more than two coin switches can also be provided. By which coins or coin types the switches 11 and 13 respectively can be operated can be freely selected by a corresponding setting. Serve to set the assignment Selector switch 19, 21, 23, 25, 27, 29, 31 and 33, with which the number of value units can also be set, which are used in Closing a coin switch 11 or 13 should be credited. If, for example, the coin switch 11 is set up so that it responds to ten pfennig pieces, and if each ten pfennig piece is to be assigned a unit of value, one would the switch 33 close so that each time a coin is inserted, the switch 11 closes

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Pulse to the full adder FAO gelarigtr3 * ^nd accordingly a unit of value is stored in the accumulator.

If, on the other hand, the coin switch 13 is set up to respond to fifty pfennig pieces, and if five value units are to be assigned to each fifty pfennig piece, the switches 19 and 29 would be closed. When the switch is closed by throwing in a fifty pfennig piece, a pulse is sent to the toll adders FAO and FA2. The pulse reaching the full adder I ¹ AO would of course increase the number of value units stored in the accumulator by 1. A ¹ I ¹ in the place of the full adder I ¹ AO means the amount 1 in binary terminology * An M 'in the place of the adder FA1 means counting state 2, while a ¹ I ¹ in place FA2 means counting state 4. So when impulses arrive at FAO and FA2, the accumulator registers the count status 5. If the coin switch 13 is still to respond to fifty pfennig pieces, but six value units are to be granted for each fifty pfennig piece, the switches and 31 would be closed, so that the accumulator the Counts 2 and 4 »total count 6, registered.

The pulses from the coin switches 11 and 13 reach at least one OR gate from a group of assigned OR gates GO, G1, G2, G3 _f etc. Gn via lines 15 and 17 and via the respectively closed selector switch. The OR- * gates G forward each pulse signal arriving at one of their inputs to the Vall adder FA assigned to the respective OR gate. In addition, the coin switch pulses arrive on lines 15 and to inputs 35 and 37 of a trigger gate GT. The gate GUT supplies signals to the trigger connections T of the flip-flops FF for transferring or transferring the full adder outputs S to the outputs Q of the flip-flops.

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In the idle or initial condition of the circuit are the inputs A and B and the outputs C and S in the binary state ¹ O. ¹ If a pulse then reaches the full adder FAO, the state Ί ¹ is set at the output SO. On the basis of a signal from the gate GT, the '1 · at SO is then transferred to the output Q of EFO. The delay inherent in the flip-flop FFO prevents the signal SO from being transferred to the output Q and thus to the input BO of the full adder FFO before the pulse AO has completely decayed.

If a further pulse AO then arrives at FFO, the M ¹ at AO and the Ί ¹ at BO are added, so that a ¹ O ¹ at SO, but a Ί ¹ at the carry output CO, which means that two value units are stored are.

The final indication that two value units are stored is done by the signal Ί 'at GO reaches the next full adder FA1 and there generates a • 1 * at S1. Further controls of the accumulator by inputting pulses from A into the full adders lead to a continuous addition of the pulses from A represented value units up to a limit set by the number of levels used.

When a customer selects an item, the price of that item must be deducted from the credit stored in the accumulator subtracted from. The subtraction for this purpose is carried out as a complementary addition. Because the counter or accumulator can only store units of value up to a limited maximum number, i.e. only up to a certain number Can count the maximum number, the addition «* of a number, which is the difference between the number to be subtracted and the maximum number that can be registered, to the same result, as if the number to be subtracted was subtracted itself. Assuming a four-stage accumulator, the maximum number that can be registered 15 »although normally one of them

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assumes a four-stage counter is sixteen units can save, weigh: only after sixteen counting steps in the Returned to the initial state. Let the assumption be made that ten denominations are accumulated; and that an item has been chosen that costs four denominations. The ten Units of value are represented by 1010 in the binary system. As a result, a remainder of six value units, represented by 0110, should remain in the accumulator. The complement of the price or the units of value to be deducted, namely 16-4 = 12, is represented by 1100. The binary addition the numbers 1010 and 1100 leads to the result 0110, the desired result. With the present establishment however, it is used to calculate the complement of the registrable Maximum number 15 assumed, since the direct debit logic generates a carry pulse with every subtraction operation.

To carry out the subtraction by means of complementary addition, additional OR gates GO ¹ , G1 ', G2', G3 ', etc. Gn ^{1 are} provided, via which the pulses reach the binary full adders FA. When a customer chooses an article, the corresponding price arrives as an impulse via one of two lines 39 or 41 to at least one of the OR gates GO ¹ to Gn ¹ . The last stage of the counter is fed back to the first stage so that the carry signal required for the complementary addition is given. As with the addition, the trigger signals come from the OR gate GT. For this purpose, the lines 39 and 41 are connected to the inputs 45 and the OR gate GT, so that the pulses corresponding to a price are also used to trigger the flip-flops.

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Look the Pig. 2 and 4- a further execution * Example of the invention described in connection with a control unit £ 8r vending machine. The control unit was specially developed with a view to training in the form of a compact monolithic integrated circuit.

The control unit comprises an accumulator and a Bonus granting system. The accumulator has a multi-stage structure, with each stage having a binary full adder and a flip-flop, namely binary full adders 103, 105, 107, 109 and 111 are each with a flip-flop 113, 115, 117 »119 bsw- 121 combined. The flip-flops are the same essential to the explanations in the previous exemplary embodiment Flip flops. The binary full adders perform arithmetic binary additions and form a carry, among other things to maintain the status loyalty. Every full adder is not combined with a flip-flop so that credit resp. Add or subtract debit pulses arithmetically *

Each toll adder 103, 105, 107, 109 and 111 has three input terminals, namely terminals A and B as main inputs and connection 0 as transmission input. The counter output of each full adder can be connected to a connection Z , decrease, while the information regarding the units of value to be transferred to the "next level" is sent to a Connection CO appears.

The connection Z of each full adder is connected via an inverter 123 to an inverse setting connection S "of the ordered flip-flop. Furthermore, each connection S is connected directly via a line 125 to an inverse reset connection Έ of the assigned flip-flop A delay element j27 and an inverter amplifier 129 are applied to terminal A of each binary

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Full adder pulses, each a certain number Represent units of value.

The impulses that represent units of value and reach the full adders are also fed to a NAND gate GMO. An output 131 of the NAND gate G1O is via an inverter amplifier 133 with the iDrigger connections CP of all flip-flops connected via which the tilting or triggering of the flip-flops is controlled. The output 131 is also connected via a delay element 137 connected to an input 135 of an AND gate G11. A Another input 139 of the AND gate G11 is connected to the connection CO of the full adder 111. The exit 141 of the AND gate G11 is connected to the direct set connections DS of the flip-flops 113, 115, 117, 119 and 121.

When the device is in operation, for example, a signal arrives at terminal A of full adder 103. When the circuit is in the initial or idle state, terminals B and D each have a ¹ O ¹ . The binary addition of Ί ¹ at connection A. to ¹ O ¹ at connection B and to ¹ O ¹ at connection C leads to a pulse '1 ^f at output connection Z. This Ί ¹ is then sent to connections S "and R of the flip-flop ^{113 forwarded. The corresponding 1} O ¹ occurring at the connection S "and the '1' occurring at the connection R ~ are then transferred to the connections Q and Q, if the flip-flop is triggered via the connection CP by the trailing edge of a pulse, which arrives via ", the NAND gate G10 and the inverter amplifier 133. If another Ί ^{1 is} fed to the same full adder, the Ί 'at A and the ^! ' 1 ^! / terminal B are added, resulting in a ¹ O ¹ at terminal Z. and a '1' results at the connection CO. The supply of further pulses representing value units leads to a continuous totaling of the value units in the accumulator or counter up to a maximum limit of 31 value units.

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Every amount of money entered by the customer, e.g. in Porm A ten pfennig piece, a twenty pfennig piece or a penny pfennig piece is determined in pulse form Supplied to full adders in such a way that the information required for summing is available via the respective number of value units results. This feature is described in more detail with reference to FIG. 6, in which the generation and forwarding of pulses to the full adders is shown. For the sake of clarity, Pig. 6 the delay elements 127 are omitted.

The device receives information about a credit to be made in each case from coin switches S1 to S4. And ihneja associated monostable circuits OS1 to OS4. The switch S1 to S4 can e.g. be thrown in a ten pfennig piece, a twenty pfennig piece, a fifty pfennig piece or of a medulla can be actuated. When a coin switch is closed, the associated monostable circuit results in a shaped one Pulse to a group of OR gates G12 to G16, which are connected to the terminals A of the full adders 103, 105, 107, 109 and 111, respectively. The connection between the monostable Circuits OS1 to 0S4 and the OR gates G12 to G16 depends on the number of value units that are passed through each of the full adder stages connected to the OR gates are represented. The individual ones, the full adder 103, 105, Levels comprising 107, 109 and 411 respectively represent one, two, four, eight and sixteen value units. So with that If the correct number of value units is added in the accumulator, for example the one triggered by a ten penny coin would be added Pulse from the circuit OSI to the gate G12 Forwarding to the full adder 103 is supplied. Correspondingly, a connection between OS2 and G13 would result in a twenty pfennig 'Assigned to two units of value. By connecting the gates G13 and G14 to the circuit 0S3 six units of value assigned to one penny coin

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on summed up, while by connecting the OR gates Gi3, GH and G15 to the circuit OS4 the assignment of fourteen value units to be added up to form a · © * «- Markstück would be realized.

It can happen that so many coins are inserted that the counting range of the accumulator of 51 V / er units is exceeded. In such a case the accumulator would simply start a new count starting from zero, so that the customer would lose a large part of the credit due to him. To eliminate this difficulty, an AND gate G11 is provided, see FIG. FIG. 4. When the counter reaches V erteinheiten its maximum of thirty-one /, is at terminal CO of the full adder 111, a ¹ I ^1. Since the NAND gate G10, as long as a signal occurs, generates a Ί ^1, including the AND gate the flip-flops 113, 115, 117 appears at the output 141 G11 a Ί · ^1, which via a corresponding connection to the direct set terminals DS, 119 and 121 is supplied and there suppresses the trigger pulse supplied to the connections CP, so that the state Ί ^{1 is} maintained at the output connections Q. The accumulator

is thus held in the highest counting position in this way, so that someone who inserts too many coins at least receives a credit of thirty-one V / ert units corresponding to the maximum count of the accumulator.

To decide whether a credit is high enough and therefore an ignition can receive an item ¹ offered at a certain price, the amount of credit stored in the accumulator must be determined. For this purpose, the signals at the connections Q d'er flip-flops are picked up via lines 122 and fed to a circuit, shown in FIG. 2, comprising gates G17 to G25 for determining the credit amount. The example explained here is intended to determine

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whether a credit of at least one, two, three, six, twelve or thirty units of value exist.

To determine whether at least one value unit has been accumulated, the connections Q of all flip-flops are connected to an OR gate G17. To determine whether there are at least two value units, the connections Q of all flip-flops with the exception of flip-flop 113 are connected to an OR gate G18. An AND gate G19 is used to determine the minimum number of three value units, the inputs of which are connected to the Q connections of the flip-flops 113 and 115 and the output of which goes to an OR gate G20, which, as further inputs, is the inputs to the Q connections of the flip-flops 117, 119 and 121 appearing impulses. To determine the minimum number of six value units, the Q terminals of the flip-flops 115 and 117 are connected to the inputs of an AND gate G21, the output of which is connected to an OR gate G22, the other inputs of which are connected to the Q terminals of the flip-flops 119 and 121 are connected. To determine the minimum number of twelve value units, the Q terminals of the flip-flops 117 and 119 are connected to the inputs of an AND gate G23 / the output of which is connected to an input of an OR gate G24, the other input of which is connected to the Q terminal of the flip-flop 121 . To determine the minimum number of thirty units of value are, after the terminals Q of the flipflops 115, 117, 121 119.und connected to the inputs of an AND-G _a tters G25.

Each of a certain minimum amount of credit or a certain minimum number of value units corresponding outputs of the circuit described above connected with AND gates, of which in Fig.6 as an example the and gates G26 and G27 are shown. The second entrances

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the AND gates are each connected to a monostable circuit OS5 or OS6, which in turn are triggered by a selector switch S5 or S6. The circuits OS5 and OS6 each emit a debit pulse corresponding to the price of a selected article or a selected service. It is assumed, for example, that a coin operated recorder can obtain a single game for two units of value "and that the single game is selected by operating the selector switch S5. When the switch S5 is closed, the aono * stable circuit OS5 sends a shaped pulse to the The other input of G-26 is connected in the selected example to the output of the OR gate GIS, which sends an impulse to gate. & 26 _- as soon as the accumulated credit reaches two or more value units, as soon as So a sufficient credit has been obtained by inserting coins.

The corresponding pulse from the output of the ünd gate arrives via an inverter amplifier 143 to some of the gates of the OR gates G12 to G16. The impulse has of course the task of bringing about the subtraction of the amount in the accumulator with which the customer according to the made Choice must be burdened.

The subtraction is done by complementary addition. In the case of the one given as an example, corresponding to two units of value Choice is the Koapleraent at thirty-one Units Twenty Nine Units <= normally would the complement on the basis of the whole number of the counter of thirty-two units calculated “But there a daytime signal is always supplied in the subtraction operation must be the computation of the complement of thirty-one Units run out. From Pig. 6 it can be seen that the pulse arriving via the inverter amplifier 145 reaches the OR gates G 12, GH, G15 and G16, which adds up to a total of twenty-nine value units in the

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Accumulator leads.

Another example, still referring to a record machine, is the choice of a long-playing record, for which six units of value are to be used. Correspondingly, the actuation of the selector switch Sö ^ fääß leads to the monostable Circuit OS6 outputs a pulse to the input of the gate G27, the other input of which is selected Example is connected to the output of the OR gate G22. When the balance is high, an impulse appears at the output of the gate G27 and passes via an inverter amplifier 145 to the OR gates G12, G15 and G16, which for adding twenty-five-fourth units in the accumulator and is equivalent to subtracting six units of value from the accumulated amount.

The outputs of the AND gates G26 and G27 do not have any effect only the subtraction of a number of units of value according to the choice made by the customer, but also arrive at Control of further functions to an OR gate G28, veggl. Pig. 2. A signal arrives at the output of the OR gate G28 Via a line 147 and a delay element 149 to the Terminal C of full adder 103 and serves there as the carry signal required during the subtraction operation. In addition, the signal from the output of the gate arrives at an inverter amplifier 151 and a delay element 153 Input 155 of gate G11. Via a line 157 and an inverter amplifier 159, the direct reset connections DR the I? Lip flops 113, 115, 117, 119 and 121 a reset signal fed.

The output of the OR gate G28 is also used as a reset signal for the circuit for bonus registration Output via an inverter amplifier 163 on a line 161. Finally, the signal from the OR gate G28 is used

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Triggering a monostable circuit 165, the pulses with a duration of 50 milliseconds. An output 167 of the circuit 165 is used to control a switch-on Sales rotor and the elements associated with it, while the other output Ί69 with an input 171 of a hand gate G29 is connected. Another input 173 of the gate G29 is connected to an input of the AND gate G26. Of the The output of the wall gate G29 is used to trigger a selection button that is held down for the 50 milliseconds for a customer to end their choice.

Pig. 3 shows the circuit for granting or registering bonuses. The circuit is not the subject of the invention, however, their mode of operation will be briefly explained. Representing the value units fed to the accumulator Pulses are sent to the bonus circuit at the same time. A number of logic gates and elipflops are used for summation of the total registered credit before a sale is initiated and emits signals when the credit amount is exceeded, which indicates the granting of an additional, the actual credit means bonus to be added. The circuit comprises a clock generator 187 which ensures that no bonus impulses are given before the impulses triggered by the coin switch have stopped. In order to it is achieved that the customer does not lose the benefit of an additional bonus.

6965 claims

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Claims (3)

"" -. ¹ ^ - f ^ yPBSTIIOFF 8 MUNICH OO 1946306 "" SCHTVEIUEH.STRASSE 2 ÜR.ETPKCHMAXX y, ₁ τκ ^ κγον- 2200Sl DR. ING. D. HKHKKXS PATENT LAWYERS piiotectwtext mCxciiux P 19 46 306.0 1A-36 827 December 3, 1969 Sponsorship claims 1 Device for balancing credit and debit amounts in vending machines by electrical means, characterized by several binary full adders (PAo-PAn; 103-111) connected in series, each with a pulse (Ao-An; A) and a feedback input (Bo -Bn; B) as well as a count (So-Sn; Z) and a carry output (Co-Cn; Co) connected to the next following full adder, with a delay memory (PPo-PPn; 113-121) between their count output and feedback input is switched, which, when activated with clock pulses, advances the counting output of a full adder to its feedback input, the pulse inputs of the full adders optionally being able to supply pulses - the coins or bills assigned to be credited vtnä. Representing sales items assigned to be deducted value units and the balance of the value units appearing in binary representation on the full adders. 2. Device according to claim 1, characterized in that the delay memory by delay flip-flops (PPo-PPn; 113-121) are formed. 3. Device according to claim 1 or 2, characterized in that the pulse inputs (Ao-An; A) the full adder (PAo-PAn; 103-111) is connected to at least one OR gate (Go-Gn; G12-G16). 009836/0109 _ΒΛ0 one »» · 4. Device according to claim 1, 2 or 3i g e k e η η - characterized by at least one coin switch (11, 13; 51-54)), which emits an impulse when a coin is inserted, which determines the value units assigned to the inserted coin represents. 5- device according to claim 4 »characterized in that. that the or »coin switches (11, 13» 51-54) each with one or more of the inputs of the OR gates (Go-Gn; G12-G16) via switches (19, 21, 23, 25, 27, 29, 31, 33) is or are connectable. 6. Device according to claim 4 or 5, characterized in that the coin switches (11, 13; 51-54) via an OR gate (GT) with the clock pulse inputs of the Delay flip-flops (PPo-PPn; 113-121) connected and these can be triggered by the pulse trailing edges. 7. Device according to one of Claims 1 to 6, characterized by one of the Yoll adders (PAo-PAn; 103-111) connected decoding circuit (G17-G25) for determining the sum of the credit units. 8. Device according to claim 7, characterized by several AND gates each connected to the outputs of the decoder circuit (G17-G25) with one input (G26, G27) whose other input is supplied with pulses representing value units to be deducted and whose ^, Outputs to inputs of one or more of the OR gates (Go-Gn; G12-G16) are connected. ⁶⁹⁶⁵ 0 09836/0109 ORIGINAL