HU197703B - Device for inducting travel-command signals at lifts - Google Patents

Abstract

1. Device for registering car calls for a lift with floor call memories (16) and floor call buttons (DE), with cage call memories (10) and cage call buttons (DC), with a scanning device (13, 14, 17), which scans the cage call memories (10) and the floor call memories (16) for the purpose of ascertaining memorised calls, wherein a first and a second signal sequence (BC-Z, BE-Z) are generated, which contain the memorised calls, and with a control device (9), into which a cage call or a floor call is transferable only during the standstill of the lift cage (2) at a floor and which generates travel direction signals and stop signals for direct travel to chosen floors, characterised thereby, - that the scanning device (13, 14, 17) displays a counter (14), which generates addresses associated with the floors, - that address conductors (A0, A1, A2, A3) connected to the parallel outputs of the counter (14) and a conductor carrying the second signal sequence (BE-Z) are connected with the input of a first gate arrangement (18), - that a shift register (30) is provided for each address bit and the outputs of the first gage arrangement (18) are connected with the inputs of the shift registers (30), wherein the associated address is fed to the inputs of the shift register (30) on the appearance of a floor call in the second signal sequence (BE-Z), - that a second gate arrangement (20) is provided, the inputs of which are connected with the outputs of the shift registers (30) and with a releasing circuit (22), - that the outputs of the second gate arrangement (20) are connected to the control device (9), wherein an address present at the outputs of the shift registers (30) cannot be transferred into the control device (9) until the arrival of a clearance signal (~G~C), which signals the absence of a cage call, of the releasing circuit (22), - that the shift registers (30) are connected with an erasure switching circuit (31), wherein the last memories (30.15) of the shift registers (30) are reset and further addresses memorised in the shift registers (30) are shifted onwards after transfer of the address present at the outputs of the shift registers (30) into the control device (9) and - that the shift registers (30) are connected with an input switching circuit (32), wherein the address present at the inputs of the shift registers (30) is entered into the first memories (30.1) of the shift registers (30) if these first memories (30.1) are empty and the address concerned is not yet memorised in the shift registers (30).

Description

BACKGROUND OF THE INVENTION The present invention relates to apparatus for entering travel command signals for elevators comprising floor call store and floor call buttons, cabin call store and cabin call buttons, and a scanning device, wherein the call device identifies and stores calls stored in the cabin and floor call stores. creating a second sequence of stored calls. The apparatus further comprises a control device, which is capable of entering a cabin or floor call exclusively when the elevator car is at rest, and which generates direction and stop signals for direct travel to the selected floor.

HU 176,681. U.S. Pat. No. 4,102,115 discloses apparatus for transmitting control signals, wherein cab or floor calls can only be entered when the elevator car is at rest on a particular floor and transmitted to the control unit. In this solution, with the load cabin loaded, the power of the floor call buttons is interrupted by properly configured logic switching circuits so that they are ineffective.

Therefore, in order to enter and transfer a floor call, no one is in the elevator cab. The cabin and floor call buttons are connected to the power supply in series so that it is not possible to make multiple calls at the same time. This unit does not have storage units for storing both floor and cabin calls associated with each floor.

When a call is made, the call is encoded by a diode array and forwarded to a storage associated with the control unit. No more calls can be made while a call is stored.

The control device itself operates by comparing the call signal with the cab position signal transmitted in coded form on the fly and generating the travel direction and stop signals for direct travel to the desired floor. Because the floor call buttons are connected in series, only the call signal that is entered at the floor call button closest to the point can always be transmitted. Therefore, with this device, the call signals cannot be stored in the chronological order of administration, and thus, if desired, those wishing to travel on the elevator will have to wait a relatively long time on each floor.

HU 176,682. U.S. Pat. No. 4,123,115 discloses apparatus for sorting command signals for floor call signals, which also takes into account temporal conditions and partially eliminates the aforementioned disadvantage. In this apparatus, the entered floor calls are combined into successive call groups in time, which are then executed sequentially in chronological order. The floor calls are stored by the floor call store, which is scanned by a scanning device and generates a sequence of stored floor calls. The scanning device controls a blocking or enabling device by blocking floor call calls made during the running program and only allowing them to be executed after the running program is completed. The execution is then executed in the order of scanning. Thus, with this device, it is also not possible to achieve the elevator movement following the order of entering each floor call.

It is an object of the present invention to provide an apparatus as already mentioned in the introduction, wherein each floor call is transmitted to the control apparatus according to the chronological order of the input, and is executed in this chronological order.

In order to solve this problem, an apparatus is provided wherein the scanning device comprises a counter for generating address labels assigned to floors, to which parallel wires are connected to their outputs, which are connected to the inputs of the first gate wherein the number of cipher registers is equal to the number of address bits, the apparatus further comprising a second gate circuit whose inputs are connected to the outputs of the cipher registers and an enabling circuit for releasing the second gate circuit via a second AND gate in the absence of a cabin call signal; are connected to an end, the outputs of the sif register are further connected to a wipe circuit that deletes the last containers in the sif register, while the sif register The inputs of er are connected to a data entry circuit controlling the entry of a new address into the sif register.

Thus, in the apparatus according to the invention, the scanning device c comprises a counter which generates address labels assigned to each floor for scanning the floor call registers. If the second call sequence generated during the scan shows a floor call, the associated address signal is entered into the sif register, and the sif register registers enable the sif register to enter the signal only if the sif register is empty. After entering the addresses stored in the last stores of the cipher registers into the control apparatus, the erasure circuit deletes the last containers of the cipher registers and advances the additional address signals stored in the cipher registers.

-3197703

An advantage of the apparatus according to the invention is that at a sufficiently high scan frequency, up to one call signal is displayed in the second sequence generated by the scanning device, so that the floor call signals are transmitted to the control device via the sif registers according to the time call. the waiting time for those who want to use it can be minimized.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in more detail in the accompanying drawings, in which:

Figure 1 is a schematic diagram of an apparatus according to the invention for an elevator, a

Figure 2 illustrates an enabling circuit for the apparatus of the present invention;

Figure 3 illustrates the equipment sif register of the device shown in Figure 1 with the data input circuit and the wipe circuit,

Figure 4 shows a possible embodiment of the first and third gate circuits of the apparatus according to the invention, while

Figure 5 shows an embodiment of the second gate circuit.

Figure 1 shows an elevator shaft 1 in which an elevator car 2 is guided. The elevator car 2 is driven via a conveyor cable 5 with a conveyor device 4 controlled by a drive control device 3. The exemplary embodiment serves fifteen floors E1-E15, however, only the floors E9-E11 are indicated in the figure. Four bistable contactors 6.0, 6.1.6.2, 6.3 are associated with the elevator car 2, which are operatively connected to the switching magnets 7 attached to the elevator shaft 1. The contactors 6.0, 6.1, 6.2, 6.3 and the switching magnets 7 are described in EN 176 681. U.S. Patent No. 5,262,226, which is essentially a coding apparatus for generating codes corresponding to the position of the cabin by means of the GRAY code. The contactors 6.0, 6.1, 6.2, 6.3 are connected via a switching transistor 8 to a voltage source (not shown) and to a control device 9. The input of the switching transistor 8 is connected to the control device 9 via a first conductor of a SPDC control signal.

Each floor is associated with cabin call registers 10 which are operatively connected to the DC cabin call buttons. The DC cabinet call button is connected in series with each other and is connected via an additional switching transistor 11 to a voltage source not shown. The input of the switching transistor 11 is connected via a 12 gate NO to a conductor conducting the first SPDC control signal.

Cabin call logs 10 are coupled to data output 13 of first output multiplexer 13 whose address inputs are connected to parallel outputs of counter 14 via address lines A0, A1, A2, A3, while data output is connected to first input of first AND gate 15. The figure further illustrates floor call registers 16 operatively connected to floor call buttons DE which are connected in parallel to a positive output of a voltage source not shown. The outputs of the floor call storage 16 are connected to the data inputs of a second multiplexer 17, the address inputs of the multiplexer 17 being connected to the address lines A0, A1, A2, A3 and the data output connected to the input of the first gate circuit 18. The counter 14, and the first and second multiplexers 13, 17, use binary codes generated by the counter 11 to form a scanning device for retrieving the 4-bit cabin call store 10 and the store call store 16 assigned to the floors.

The first multiplexer data output 13 is connected to a first BC-Z signal line containing stored cabin calls, and the second multiplexer data output 17 is connected to a second BE-Z signal line containing stored floor calls. To control the scanning process, the counter 14 is connected to the input of the control device 9. The input of the first gate circuit 18 is connected to the address line A0, A1, A2, A3, while its output is connected to the input 19 of the siphon register arrangement described in more detail in FIG. When floor call signals appear in the second BE-Z signal sequence, the assigned address is led to the input of the cipher register arrangement 19.

The device is further provided with a second gate circuit 20 having its inputs connected to the outputs of the sif register 19 and a second AND gate 21, and outputs of which are connected to the input of the control device 9. The first input of the second AND gate 21 is connected to a control device 9 via a second conductor wire SPDE control signal. The second input of the second AND gate 21 is coupled to the output of the enable circuit 22 shown in more detail in FIG.

Figure 1 shows a third, a

Figure 4 illustrates in more detail the gate circuit 23 having input to the first AND gate 15. and are connected to the address lines A0, A1, A2, A3. The output of the third gate circuit 23 is coupled to the output of the second gate circuit 20 and the control arrangement 9. The second input of the first north gate 15 is connected to the control device 9 via a conductor conducting a second CE authorization signal. The third input of the first AND gate 15 is connected to the first SPDC control signal transmission line.

-4197703

The control apparatus 9 is configured with a digital computer comprising a central processing unit 9.1, a fixed value storage 9.2, a read-write storage 9.3, a 9.4 clock generator, a 9.5 interface circuit and a 9.6 bus. The control unit 9 also has a call register 9.7 and a location register 9.8, which may be, for example, the registers of the central unit 9.1. The call register 9.7 is adapted to receive the addresses of the cab or floor calls to be processed, while the position register 9.8 serves, for example, to store the cab position signals converted from the GRÁY code to the binary code via the central unit 9.1. The central unit 9.1 is provided with a comparator 9.9 comparing the call address signals with the cab position signals and thereby generating the travel direction and stop signals of the elevator car 2.

The control device 9 is associated with the door control device 3.

Figure 2 illustrates an exemplary embodiment of the enable circuit 22 comprising a first four-input AND gate 24, two stores 25, 26 consisting of one AND gate and an OR gate, and a second two input AND gate 27. The first AND gate input 24 is connected via an inverter to the address wires A0, A1, A2, A3, while its output is connected to one of the storage sockets 25 and one of the second AND gates 27. The Q output of the storage 25 is connected to the second input of the second AND gate 27, the output of which is connected to the S input of the second storage 26. The R-inputs of the storages 25 and 26 are fed to the BC-Z signal obtained by negating the first BC-Z signal sequence on the data output of the first multiplexer 13 containing the stored cabin calls. The data output of the first multiplexer 13 is thus connected via the NO gate to the R input of the storage 25, 26 (Figs. 1, 2). The Q output of the second container 26 is connected to the second input of the second AND gate 21, as shown in FIG.

The sif register register 19 shown in FIG. 3 includes four sif register registers associated with address bits, for example fifteen 30.1 to 30.15 storages, and also includes a wipe circuit and 32 data input circuits. The outputs of the containers 30.2 to 30.15 are connected via a 33 gates to an AND gate input 34, the output of the AND gate 34 being always connected to the clock input T of the corresponding containers 30.2 to 30.15 and to the R input of the preceding containers 30.1 to 30.14. Last

The R inputs of the containers 30.15 are connected to the output of a wipe circuit 31. The outputs of the first repositories 30.1 are connected via further non-gates 35 to the data input circuit 32 whose output is connected to the clock input T of the first repositories 30.1.

The wiper circuit 31 includes first and second comparators 36 and 37 including a four-input NO / OR gate 38, a four-input AND gate 39, a two-input needle 40 AND gate 41, and a gate 41. The inputs of the first and second comparators 36 and 37 are connected to the output of the last stores 30.15 in the sif register 30. The first comparator 36 is connected to an additional input A0, A1, A2, A3, while the second comparator 37 is connected to a parallel output of the call register 9.7 of the control device 9. The NO / OR gate input 38 is coupled to the address lines A0, A1, A2, A3, while its output is connected to the first input of the AND gate 39, the second input of which is connected to the output of the second comparator 37. The third input of the AND gate 39 is provided with an IKB information signal indicating the traveling (moving) state of the elevator car 2 and the fourth input is the inverted second SPDE control signal. The output of the AND gate 39 is connected via the OR gate 41 to the R input of the last storage 30.15. The inverted second BE-Z signal circuit is connected to the first input of the AND gate 40, and the second input is connected to the output of the first comparator 36. Output of AND gate 40

The OR gate is connected to the last 30.15 containers for input.

The 32 input circuits are seven inputs

AND gate, 15 three-input 43.1 -

It consists of 43.15 AND gates, fifteen 44.1 to 44.15 flip flops, one fifteen pass 45 OR gates, an additional 46 flip flops, 47 non-gates, where 43.1 to 43.15 AND gates and

44.1 to 44.15 flip flops are assigned to each floor. The input of the AND gate 42 is connected via the NO gates 35 to the outputs of the first containers 30.1 and the Q output of the flipflop 46. The AND gate 42 is provided with a second BE-Z sequence as well as an ON-A information signal indicating the call cancellation. Output of AND gate 42

43.1 to 43.15 are connected to one of the inputs of the AND gates, to which, for the second input, the respective flip flops 44.1 to 44.15 are fed with inverted GESR-1 to GESR-15 signals, and to the third input are the Al, ..., A-15 signals. . Signals A-1, ..., A-15, produced by a scanning device not described in more detail herein, each time have a logical value of "1" when the appropriate floor is scanned. A 43.1 -

43.15 Outputs of AND gates corresponding 44.1 -

44.15 are connected to the S-inputs of the flip flops and are connected to the inputs of the OR gates 45.15. The output of the OR gate 45 is connected to the R input 46 of the flipflop 46, the S input of which is connected to the clock generator 9.4 of the control device 9 and the Q output 47 is connected to the clock inputs T of the first storage 30.1.

Figure 4 shows a possible embodiment of the first and third gate circuits 18, 23, which are four dual-input AND gates 5.

It consists of -5197703 with one of its inputs connected to an address line A0, A1, A2, A3. The other input of the AND gates of the gate circuit 18 is coupled to the data output of the second multiplexer 17. The other input of the AND gates of the gate circuit 23 is connected to the output of the AND gate 15.

Figure 5 shows an embodiment of the second gate circuit 20 having an internal configuration corresponding to the gate circuit 18, 23. Here, one input of the AND gates is connected to the output of the AND gate 21, the other input is connected to the outputs of the sif register 19, and its output is coupled to the output of the gate circuit 23 and the control device 9. The apparatus according to the invention operates as follows:

By means of the control device 9, the first SPDC control signal and the second SPDE control signal are produced. The first SPDC control signal, respectively. to generate a second SPDE control signal from the drive control device 3 to the control device 9, carrying information carrying signals, e.g. they indicate the moving or standing position of the elevator car 2, with or without load.

When the elevator car 2 is in operation and going, the control device 9 sets the first SPDC control signal to zero, i.e. SPDC = 0, so that the contactors 6.0, 6.1, 6.2, 6.3 are connected to the positive terminal of the voltage source. In this position, the cab position information is entered into the control device 9. If the elevator car 2 goes and the first SPDC control signal is zero, i.e. SPDC = 0 and SPDC = 1, in this case, the DC cabin call buttons are grounded via switching transistor 11 and cabin calls cannot be made to the controller 9. If the elevator car 2 is standing, SPDC = 1, then the contactors 6.0, 6.1, 6.2, 6.3 are connected to the ground source of the voltage source, and the position information of the cabin is not transmitted to the control device 9. If the elevator car 2 is standing and SPDC = 1 and SPDC = 0, then the DC cabin call buttons are connected to the positive terminal of the voltage source, in which case cabin calls can be stored where, by serial switching of the DC cabin call buttons, prevent multiple calls.

Thus, by actuating the DC cabin call buttons, the calls are transferred to the cabin call storage 10, while the DE floor call buttons actuate each floor call to the floor call storage 16.

The scanning device provided with the counter 14 and the first and second multiplexers 13, 17 scans the cabin call store 10 and the store call store 16 using binary code generated in the counter 14 and assigned to each floor. As a result, a first BC-Z signal sequence containing the stored cabin call calls appears on the data output of the first multiplexer 13, while a second BE-Z signal sequence appears on the data output of the second multiplexer 17 containing the stored floor calls.

If there is a floor call in the second BE-Z signal sequence, in this case the assigned address is placed in the cipher register arrangement 19. The cipher register arrangement 19 is connected to the control device 9 via the second gate circuit 20.

The call register 9.7 of the control device 9 can be entered as follows for cabin calls or calls. addresses assigned to floor calls.

Suppose the elevator car 2 is on one floor and the first SPDC control signal equals 1, so SPDC = 1. If no address mark is stored in the call register 9.7 at the same time, the second enable signal is CE = 1. If a cabin call signal is received in the first BC-Z signal sequence, the output of the first AND gate 15 is also 1, so that the third gate circuit arrangement 23 passes the signal and the corresponding address is transmitted to the call register 9.7.

It is further assumed that the elevator car 2 is on one floor and that the base of the cabin is not loaded. Suppose further that in this case the second SPDE = 1. If, at the same time, there is no more cabin call signal in the first signal sequence BC-Z, then the first enable signal is GC = = 1. Then the output of the second AND gate 21 will also go to "1" and the second gate circuit 20 will open. the bell call address signals on the outputs of the sif register are transmitted to the call register 9.7. _

The first GC enable signal is generated by the enable circuit 22. The enable circuit 22 operates by applying to the first AND gate 24 an inverted starter address signal 1111 not assigned to any floor at the start of the scan cycle. Since at this time BC-Z = 1, the stores 25 and 26 are tilted, so that the first enable signal GC = 1 appears at the Q-output of the storage 26. If a cabin call signal occurs in the first BC-Z signal sequence during the scan cycle, BC-Z = 0. As a result, the containers 25 and 26 are tilted back and the first GC enable signal changes to zero for the remainder of the scan cycle.

The sif register 19 is provided with a sif register 30, a data input circuit 32, and a wipe circuit 31.

The wiper circuit 31 operates as follows:

If the address signal at the outputs of the last stores 30.15 matches the address signals stored in the call register 9.7 of Figure 1, then the second comparator 37 will be logically fired. For traveling 2 cabins, the IKB information signal and the inverted SPDE control signal are equal to 1, i.e. IK.B = 1, and SPDE = 1. After the current scan cycle has been completed, 6197703 will have the address code 0000, and the output of the NO gate 38, and the output of the AND gate 39, will be logical '1, so that the storages 30.15 will be cleared through the OR gate 41. In each case, there could be more than one storage of '30.15, or one of storage 30.1 to 30.15, since, as mentioned above, four siftrist registers 30 are contained in a siftr register arrangement 19. The last 30.15 repositories are deleted even if one of the floor call signs has been deleted and it is no longer found in the second BE-Z sequence. In this case, if the addresses to the first comparator 36 are matched, its output will be logical, 1. Since BE-Z = 1 at the same time, the output of AND gate 40 will also be logical "1, so

30.15 repositories will be deleted. The deletion is performed by first having the output signal of the AND gate 34 corresponding to the output of the last container 30.15 be logical "1, so that the address symbols at the inputs of the last containers 30.15 are stored, while the address symbols of the previous containers 30.14 are deleted. In this way, an incremental operation is initiated which, in the case of saturated cipher registers 30, terminates by deleting the address symbols in the first containers 30.1.

The operation of the 32 input circuits is as follows:

We assume that the siftr register 30 stores from the second to the fifteenth

30.2 to 30.15 are reserved and the second floor call is stored in the corresponding 16 storey call store. Scanning the second floor will be BE-Z = 1, so the corresponding address will be displayed at the inputs of the first 30.1 containers. Since the first containers 30.1 are empty, the input to the AND gate 42 connected to the outputs of the containers 30.1 will be at logical "1" level. As a result of the clock generated by the clock generator 9.4, the remaining storage 46 is occupied and generates an ESR = 1 information signal. Since the BE-Z and BE-A signals are also logical "1, the output of AND gate 42 will be provided with an information signal GESR-1 = 1, and since the input of AND gate 43.2 will be provided with A-2 = 1 and GESR -2 = = 1, flip flop 44.2 assigned to the second floor, and the GESR-2 signal returns to logical "O. As a result, a pulse signal is generated at the output of AND gate 43.2, by means of which the storage 46 can be reset. Then, ESR = 0, and the clock inputs T of the first stores 30.1 show ESR = 1 and store the address signal for the second floor. As a result, the GESR-E output information signal of AND gate 42 is reset to zero, whereby storage 46 cannot be restored and ESR = 1 signal can no longer be generated.

It is further assumed that the address label for the second floor is already stored in the cipher register 30. Since in this case the corresponding flip flop 44.2 is already occupied, the output of the corresponding second AND gate 43.2 is also logical "0" due to GESR-2 = 0, the flip flop 46 cannot return, the signal ESR = 1 is created, the second store of the second floor address mark was prevented.

The apparatus according to the invention thus ensures that the floor call signals are transmitted to and executed in the control apparatus 9 in the order corresponding to the time sequence of the calls.

Claims (5)

PATENT CLAIMS An apparatus for entering travel commands at elevators comprising apparatus for storing floor call registers and floor call buttons, cabin call registers and cabin call buttons, and scanning means for generating first and second series of signals for floor call stores and cabin call stores, and provided with a control device for generating and stopping direct cab movement, which control device is associated with the cabin call store and the floor call store, characterized in that the scanning device comprises a counter (14) for generating address signals assigned to floors, with parallel outputs A0, A1, A2, A3) are connected which are connected to the inputs of the first gate circuit (18) of the conductor conducting the second signal (BE-Z), the outputs of the first gate circuit (18) being segregated steers (30) are led to an input, wherein the number of cipher registers is the same as the number of address bits, the apparatus comprises a second gate circuit (20) having an input via the outputs of the sif registers (30) and a second AND gate (21) connected to an enabling circuit (22) for releasing the second gate circuit (20), wherein the outputs of the second gate circuit (20) are connected to the control device (9), the outputs of the sif register (30) and the last sockets (30.15) of the sif register (30) are connected to a wipe circuit (31), while the sif register (30) is connected to a data input circuit (32) controlling the input of a new address into the sif register (30). Apparatus according to claim 1, characterized in that the enabling circuit (22) is a four-input first AND gate (24), two one AND gate (OR) gate (25, 26) and a two-input second gate (25). It comprises an AND gate (27), and the input of the first AND gate (24) is connected via an inverter to the address lines (A0, A1, A2, A3), while its output is connected to the S input of one of the containers (25) and connected to one of the inputs of the gate (27), and the Q-output of one storage (25) is connected to the other input of the second AND-gate (27), the output of the second AND-gate (27) with the S-input of the other and the R inputs of the containers (25, 26) are connected via a non-gate to the output of the first signaling (BC-Z) of the scanning device. -7j The apparatus according to claim 1, characterized in that a container of AND (gate) (34) is assigned to the containers (30.2, 30.3, ... 30.15) of the sif registers (30), from the second to the last container, and the outputs of these storages (30.2 to 30.15) are connected via the NOT gate (33) to the inputs of the AND gate (34) assigned thereto and the outputs of the AND gate (34) to the clock inputs (T) of their respective store (30.2-30.15); connected to the R inputs of the preceding storage (30.1 to 30.14), the R inputs of the last storage (30.15) being coupled to the output of the wiping circuit (31) and the outputs of the first storage (30.1) via additional non-gates (35). are connected to an input circuit (32) whose output is connected to the clock inputs (T) of the first stores (30.1). The apparatus of claim 1, wherein the wiper circuit (31) comprises a first and second comparator (36, 37) with a four-input non-OR gate (38), a four-input first AND gate (39) and a two-input second AND gate. a gate (40) and an OR gate (41), the first and second comparator (36, 37) inputs being connected to the outputs of the last stores (30.15) of the siphon registers (30), and the first comparator (36) further inputting are connected to address lines (A0, A1, A2, A3), while the second comparator (37) is connected to the parallel outputs of the call register (9.7) of the control device (9) and the NO-gate (38) inputs the address lines (A0, A1, A2, A3) and its output connected to the first input of the first AND gate (39), the second input of the first AND gate (39) being connected to the output of the second comparator (37); AND gate (40) second in its thread is connected to the output of the first comparator (36), and the outputs of the first and second AND gates (39, 40) are connected to the inputs of the OR gate (41), the output of which is the output of the wiper circuit (31). 5. Apparatus according to any one of claims 1 to 5, characterized in that the data input circuit (32) has a seven-input first AND gate (42), a three-input second AND gate (43.1 to 43 15) assigned to the floors, and flipflops (44.1-44.15) assigned to the floors. ) and an OR gate (45) with a number of inputs corresponding to the number of elevators, an additional flip flop (46), and a NEM gate (47), with inputs of the first AND gate (42) with additional NEM gates (35). and connected to the Q output of the further flip flop (46), the output of the first AND gate (42) being connected to one of the inputs of the second AND gates (43.1-43.15) and the second AND gate (43.1) - 43.15) outputs the corresponding flip flops Connected to the S inputs of 20 (44.1 to 44.15) and the inputs of the OR gate (45), the output of the OR gate (45) is connected to the R input of a further flipflcp (46) which is ve25 control device (9) is connected to a clock generator (94) while its output (Q) is coupled to the input of the NEM gate (47), the output of the NEM gate (47) forming the output of the data input circuit (32). Apparatus according to claim 1, characterized in that it comprises a first multiplexer (13) for generating a first signal sequence (BC-Z), whose data inputs are connected to the outputs of the cabin call memory (10) and whose data output is in an AND gate. (15) connected to one of the inputs of a third gate circuit (23), the apparatus further provided with a second multiplexer (17) for generating a second signal sequence (BE-Z) whose data inputs are connected to the outputs of the floor call storage (16), and whose data output is connected to a conductor conducting a second signal sequence (BE-Z), while the address inputs of the multiplexers (13, 17) are connected to the address conductors (A0, A1, A2, 45 A3) are connected.