EP0445419A1 - Arrangement to select an elevator car for a handicapped person in elevator systems with direct allocation of calls - Google Patents

Abstract

Using this device, a cabin particularly suitable for physically handicapped passengers can be selected in an elevator group controlled by means of group control system. For this purpose, call registration devices arranged at the stories exhibit a key by means of which a circuit (20) can be activated. In this arrangement, the circuit (20) is connected at the input to a memory (RAM1.2) storing the calls for the destination stories and a load memory (13), a first and second condition for the selection of a cabin being met with the non-presence of an exit call and with a load which is less than a particular load limit value. The circuit (20) is also connected at the input to the output of a comparator (17) which compares the travelling time of the cabin to the call input story with the time needed by a handicapped person for travelling between the call registration device operated and the liftwell door of the relevant elevator, a third condition for the selection being met if the travelling time is greater. When all conditions are met, the cabin selected in this manner can participate in the call allocation process. <IMAGE>

Description

The invention relates to a device for selecting an elevator car for the physically handicapped in elevators with immediate assignment of destination calls, with call registration and display devices arranged on the floors, which have a keyboard for entering calls for desired destination floors, with each elevator assigned to a lift group, the call memories are connected to the call registration and display devices, a call characterizing the input floor and a call characterizing the destination floor being stored in the call memories when a call is input on a floor, with load memories in which the number of people present in the respective elevator car per floor Persons is stored, and with the elevators assigned to the group travel time memories, according to the preamble of claim 1.

EP-A 0 356 731 discloses a group control similar to the device according to the preamble, which uses the shortest waiting time of all passengers as a criterion for the assignment of the cabins to the entered calls. With this control, the travel destinations can already be entered on the floors, for example by means of call registration and display devices proposed with EP-A-0320 583. Immediately after the registration and transmission of a call into a call memory structured according to the input and destination floors, a computer in the form of a microprocessor determines an amount called operating costs for each car from elevator-specific data, which corresponds to the waiting time which corresponds to the waiting time for the passengers when the call is served would arise. The operating costs are transferred to a cost register immediately after the calculation and then immediately using a Comparison device compared with the operating costs of the other elevators. In this case, an allocation instruction that has the lowest operating costs is stored in an allocation memory of the elevator. Immediately after the cabin / call assignment has been made in this way, the elevator and its position in question are displayed in a display field of the activated call registration and display device, so that the passenger can go to the assigned landing door in good time.

With the group control described above, optimal results can be achieved with regard to the smallest waiting times of the passengers. However, this control is not suitable for certain users of the elevators, such as physically handicapped persons, since other criteria must be taken into account when selecting an elevator car.

The invention is therefore based on the object of modifying the device mentioned in the prior art in such a way that physically handicapped persons have sufficient time to reach the landing door of the selected elevator before the arrival of the cabin, that they can get in unhindered and that wheelchair users in particular have enough space in find the cabin.

This object is achieved by the invention characterized in claim 1. For each elevator, a circuit is provided for each floor, which is connected on the input side to a memory part of the call memory which stores the calls for the destination floors and the load memory, one in the absence of an exit call and a load which is less than a certain load limit first and a second condition for the selection of a cabin is met. The circuit is still connected on the input side to a comparator that measures the travel time of the cabin to Compares the call input storey with the time required by a physically disabled person to travel between the actuated call registration and display device and the shaft door of the elevator in question, with a third condition for the selection of a car being fulfilled in the case of a longer travel time. On the output side, the circuit is connected to the comparison device in such a way that when the first, second and third conditions are met, the elevator in question can take part in the call allocation process. The keyboards of the call registration and display devices have a further key provided with a wheelchair symbol, by means of which the circuits of a floor are activated and the normal operating mode is switched off.

The advantages achieved by the invention are, in particular, that the use of the elevators for physically handicapped people becomes easier and easier since a cabin is selected from which nobody gets out and which has enough space that a wheelchair can be comfortably accommodated. There is no abnormally long waiting time for the passengers in the cabin when stopping, because when selecting the cabin, the path covered by the physically handicapped between the activated keyboard and the lift displayed is taken into account in such a way that the disabled passenger is already in front of the landing door in question when the cabin is on the floor arrives.

Fig. 1

eine schematische Darstellung einer Gruppensteuerung für zwei Aufzüge einer Aufzugsgruppe,

Fig. 2

eine schematische Darstellung eines einem Aufzug zugeordneten Teiles der Gruppensteuerung gemäss Fig. 1 mit einem Schaltkreis der erfindungsgemässen Einrichtung,

Fig. 3

auf einem Stockwerk angeordnete Rufregistrier- und Anzeigeeinrichtungen bei drei Aufzügen einer Aufzugsgruppe,

Fig. 4

eine Ansicht einer Rufregistrier- und Anzeigeeinrichtung in gegenüber der Fig. 3 vergrössertem Massstab, mit einer Taste zur Einleitung einer Körperbehindertenfahrt,

Fig. 5

auf einem Stockwerk angeordnete Rufregistrier- und Anzeigeeinrichtungen für eine aus vier Aufzügen bestehende Aufzugsgruppe,

Fig. 6

eine schematische Darstellung von den Aufzügen zugeordneten Speichern für die Zeiten, die ein körperbehinderter Fahrgast für die Wege zwischen den Rufregistrier- und Anzeigeeinrichtungen und den Schachttüren benötigt, und

Fig. 7

eine Schaltungsanordnung für die Feststellung einer auf einem Stockwerk betätigten Rufregistrier- und Anzeigeeinrichtung.

The invention is explained in more detail below with reference to an exemplary embodiment shown in the drawing. Show it:

Fig. 1

1 shows a schematic representation of a group control for two elevators of an elevator group,

Fig. 2

1 shows a schematic representation of a part of the group control according to FIG. 1 assigned to an elevator, with a circuit of the device according to the invention,

Fig. 3

Call registration and display devices arranged on one floor for three elevators of an elevator group,

Fig. 4

3 shows a view of a call registration and display device on an enlarged scale compared to FIG. 3, with a button for initiating a journey for the physically disabled,

Fig. 5

Call registration and display devices arranged on one floor for an elevator group consisting of four elevators,

Fig. 6

is a schematic representation of the memories associated with the elevators for the times that a physically disabled passenger needs for the routes between the call registration and display devices and the landing doors, and

Fig. 7

a circuit arrangement for the determination of a call registration and display device operated on a floor.

In Fig. 1, two elevators of an elevator group are designated by C and D, with each elevator a car 2 guided in an elevator shaft 1 is driven by a conveyor 3 via a conveyor cable 4 and fifteen floors EO to E14 are served. The carrier 3 is controlled by a drive control known from EP-B-0 026 406, the setpoint generation, the control functions and the start of the stop being implemented by means of a microcomputer system 5 which is connected to measuring and actuating elements 6 of the drive control. The microcomputer system 5 also calculates, as is known, for example, from EP-A 0 356 731, from elevator-specific data a sum corresponding to the waiting time of all passengers, also called service costs, which is used as the basis for the call allocation process. The cabin 2 has a load measuring device 7, which is also connected to the microcomputer system 5. On the floors, for example, call registration and display devices 8 known from EP-A-0 320 583 are provided, which have 10 keyboards, by means of which calls for trips to desired destination floors can be entered. In the method of programmed input assumed, for example, the call registration and display devices 8 are connected via an address bus ab and a data input conductor DL to the microcomputer system 5. The call registration and display devices 8 of a floor are connected to one another and can be assigned to more than one elevator of the group, those of elevator C being connected to the microcomputer system 5 of elevator D via coupling elements in the form of multiplexers 9. 10 denotes a door drive arranged on the cabin 2, which is connected to the microcomputer system 5 for the purpose of controlling the opening and closing and the keeping open time of the cabin and shaft doors. The microcomputer systems 5 of the individual elevators in the group are connected to one another via a comparison device 11 known from EP-B-0 050 304 and a party line transmission system 12 known from EP-B-0 050 305 and form together with the call registration and display devices 8 is a group controller similar to the aforementioned EP-A 0 356 731. The call registration and display devices 8 are also connected to the microcomputer systems 5 via a first conductor L1 and a second conductor L2. As described in more detail below with reference to FIGS. 3 and 4, information can be transmitted to the microcomputer systems 5 via the conductor L1, by means of which the group control can be switched over to an operating mode suitable for physically disabled passengers. As can be seen from the following description of FIG. 7, a signal can be transmitted via the second conductor L2, by means of which the microcomputer systems 5 can identify an actuated call registration and display device 8.

The part of the microcomputer system 5 which is schematically shown in FIG. 2 and is assigned to elevator A, for example, has a call memory RAM1 and a first and second allocation memory RAM2, RAM3 which have memory locations corresponding to the number of floors for each direction of travel, only those assigned to the upward calls Memory are shown. The call memory RAM1 consists of a first and a second memory RAM1.1, RAM1.2, wherein in the first memory RAM1.1 the calls denoting the respective input storey and in the second memory RAM1.2 the calls identifying the destination storeys are stored, and wherein the first memory RAM1.1 is assigned to the first allocation memory RAM2 and the second memory RAM1.2 to the second allocation memory RAM3. R1 denotes an operating cost register intended for storing the operating costs and R2 denotes a cabin position register. A selector R3 in the form of a further register forms addresses corresponding to the floor numbers, by means of which the memory locations of the memories RAM1.1, RAM1.2, RAM.2 and RAM3 can be addressed. While the selector R3 in each case indicates the floor on which the moving car 2 could still stop, the car position register R2 in each case shows the floor in the area of which the car 2 is actually located. The call memory RAM1 and the first and second allocation memories RAM2, RAM3 are read-write memories which are connected to the bus SB of the microcomputer system 5. A load storage device, which is also connected to the bus SB, is designated by 13 and is described in more detail below. The calls stored in the call memory RAM1 according to example Fig. 2 and the allocation instructions stored in the allocation memories RAM2, RAM3 are symbolically marked with "1", with the floors E2, E3, E5 and E11 being allocated (dashed connecting line) and at E10 and E13 are new, not yet assigned calls (hatched fields). With 14 is a travel time memory and with 15 one Door time memory called, which are also connected to the bus SB. The memories 14, 15 known from EP-A 0 356 731 cited above are read-write memories in which data for the calculation of the service costs are stored. In this case, the travel times of the relevant car between a certain floor and every other floor are stored in the travel time memory 14, while the door opening and closing times of the relevant elevator are stored in the door time memory 15 for each floor. In a further memory 16 connected to the bus SB, the times required by a physically handicapped passenger on one floor for the paths between the respectively activated call registration and display device 8 and the shaft doors of the elevators are stored. A first comparator 17, which is formed, for example, by the processor of the microcomputer system 5, is connected on the input side to the travel time memory 14 and the further memory 16. The service cost register R1 is connected to the comparison device 11 via a switching device 18 in the form of tristate buffers. Each floor is assigned a circuit 20, described in more detail below, which is connected on the input side to the memory cells of the second memory RAM1.2, the load memory 13 and the output of the first comparator 17 relating to the respective floor when the operating mode for physically disabled passengers is selected. On the output side, the circuit 20 is connected to the activation connections of the tristate buffers.

The load memory 13, which is also known from EP-PA 88106273, consists of a read-write memory in the form of a matrix which has exactly as many rows as floors and three columns S1, S2, S3. The first column S1 of the matrix is assigned to the calls of the same direction lying in front of the cabin 2, the second column S2 to the opposite direction calls and the third column S3 to the calls of the same direction lying behind the cabin 2 in the direction of travel. Load values are in the storage locations of the load storage 13 in the form stored a number of people who are in the cabin 2 when leaving or driving past a floor. For a more detailed explanation, it is assumed in FIG. 2, for example, that the car 2 is in the upward travel in the area of the floor E4 and that upward calls have been entered on the floors E2, E3 and E10. After the calls have been transferred to the first and second memories RAM1.1, RAM1.2, a sum is formed from the number of calls (beginners) entered on a floor and the number of calls (dropouts) that designate this floor and a load value stored in the load memory 13. The first column S1 of the load accumulator 13 will therefore have the load values shown in FIG. 2 due to the selected number of people entering and exiting. For example, from five entrants on floor E2, two entrants on floor E3 and three exits on floor E5, the load value "4" results for floor E10. When calculating the operating costs, the computer can call up the number of passengers in the cabin 2 at a future stop from the load store 13. In addition, it can be determined on the basis of the stored load values whether an overload 2 would occur if a certain floor were allocated to a cabin.

As described above, when the load store 13 is created, the entered calls are used to infer the future passengers entering and exiting the cabin 2 and the resulting loads. However, it would now be possible for passengers to enter their call more than once, or for passengers who have not entered a call to board. In these cases, the saved load values must be corrected. For this purpose, the load storage device 13 is connected to the load measuring device 7 of the cabin 2 via the microcomputer system 5 (FIG. 1). In the first case, as many of the same destination calls are deleted on the relevant floor as the difference between the stored load value and the actually measured cabin load. Then all saved load values between the entry floor and corrected the destination floor of the call entered more than once. In the second case, the stored load values must be increased, it being assumed that the passenger who has not entered a call wants to drive to a destination which is characterized by a call already entered by another passenger. If several calls have been entered, it is assumed that the conscious passenger wants to drive to the most distant destination.

The circuit 20 consists of a first and a second AND gate 21, 22, a first and a second OR gate 23, 24, a NOT gate 25, a NOR gate 26 and a second comparator 27. A first input of the first AND Link 21 is connected via the NOT link 25 to the memory cell of the second memory RAM1.2 assigned to the relevant floor. A second input of the first AND gate 21 is connected to the output of the second comparator 27, one input of which is connected to the relevant memory cell of the load store 13 and a load limit value L _{max is} fed via the other input thereof. A third input of the first AND gate 21 is connected to the output of the first comparator 17. A first input of the second AND gate 22 is connected to the first input of the first AND gate 21, and a second input is connected to the output of the second comparator 27. A third input of the second AND gate 22 is connected to the output of the NOR gate 26, the first input of which is connected to the output of the first comparator 17. The second input of the NOR gate 26 is connected to the output of the first OR gate 23, the first input of which is connected to the output of the first AND gate 21 and the second, third and fourth inputs of which are connected to the outputs of the first AND gates 21 of the circuits 20 assigned to the elevators B, C and D are connected. The output of the first AND gate 21 is connected to a first input of the second OR gate 24, the second input of which is connected to the output of the second AND gate 22 and the output of which is connected to the activation connections of the tristate buffer 18.

The circuit 20 formed by the microcomputer system 5, for example on the basis of a program, is activated in each case when switching to the operating mode suitable for physically handicapped passengers for the call input storey concerned.

In FIG. 3, 30 denotes the shaft doors of the elevators A, B, C of the elevator group assumed, for example, arranged on one floor. Call registering and display devices 8 are provided between the shaft doors 30 and, as described in detail in EP-A 0 320 583, for the purpose of displaying the selected car and location of the elevator in question, via control circuits 31, 32, address buses and module release lines ce are connected to the microcomputer systems 5 assigned to the elevators. The call registration and display devices 8 each have a further button 33, shown on a larger scale in FIG. 4. The outputs of the call registration and display devices 8 assigned to the keys 33 are connected via tristate buffers 34, 35 to an input of an OR gate 36, the output of which is connected to the first conductors L1. The activation connections of the tristate buffers 34, 35 are connected to the respective output of a decoder 37 which is assigned to a specific floor and which is connected to the address bus ab, for example of the elevator A.

4, the call registration and display device 8, as already known from EP-A-0 320 583, has a keyboard 40 for entering calls for desired destination floors and a display field 41 in which four display elements 42, 43, 44, 45 are arranged. Here, the first display element 42 signals the number of the destination floor entered in each case, the second display element 43 in the form of a letter the selected elevator and the third and fourth display elements 44, 45 in the form of an arrow each indicate the position of the selected elevator in relation to the actuated keyboard. The one suitable for switching to that for physically disabled passengers Operating mode provided further button 33 is provided with a wheelchair symbol, which is attached in a scannable form so that visually impaired people can find and press this button. The key 33 is connected in a manner not shown, similarly as known from the above-mentioned document, to a memory element which is connected on the output side to the first conductor L1 as indicated in the description of FIG. 3.

5, the shaft doors 30 of the elevators A, B, C and D of the elevator group assumed, for example, may have the same distances from one another, the call registration and display devices 8 each being arranged in the middle between two shaft doors 30. With t is a time derived from experience, which a physically disabled passenger needs for the route between the call registration and display device 8 actuated by him and the respectively adjacent shaft door 30. In the arrangement chosen, for example, a physically disabled person would need a time of 5 t to actuate the call registration and display device 8 between the elevators A and B and the allocation of the elevator D to the relevant shaft door 30.

The further memories 16 (FIG. 2) assigned to the elevators A, B, C and D have, according to FIG. 6, a number of memory locations corresponding to the number of call registration and display devices 8 provided on one floor. 5, the further memories 16 each have three memory locations, which are designated AB, BC and CD in the order of the elevators. The stored times entered in FIG. 6 result from the definition of the time t given in the description of FIG. 5, wherein the time 5t mentioned as an example can be found in the memory location AB of the further memory 16 assigned to the elevator D.

7, 50 denotes the multiplexers assigned to the elevators and call registration and display devices 8 of a floor, which have a number of inputs corresponding to the number of call registration and display devices 8 of a floor, the inputs assigned to the same call registration and display device 8 in each case all multiplexers 50 are interconnected. One input each of the multiplexers 50 is connected to the output of an AND gate 51, the inputs of which are connected to outputs Q of memory cells 52 of the associated call registration and display device 8. The multiplexers 50 are connected to the address buses from the assigned microcomputer system 5 and are connected on the output side to the further memory 16 of the assigned microcomputer system via the second conductor L2 (FIG. 2). The other outputs Q of the memory cells 52 are, as is known from EP-A-0 320 583 and EP-B-0 246 395, for the purpose of querying the calls entered on one floor with inputs of multiplexers 53 of the respective call registration and display devices 8 connected.

The device described above works as follows:
It may be assumed that a passenger using a wheelchair is on floor E10 between the shaft doors of elevators B and C and, after selecting the operating mode, presses the further key 33 to enter a call for floor E13 (FIG. 3) . When scanning the call registration and display devices 8 for newly entered calls, the memory element connected to the further key 33 is first queried. Here, when the address for floor E10 occurs, the tristate buffer 35 is activated by means of the decoder 37, so that the stored information is transmitted via the OR gate 36 and the first conductor L1 into the microcomputer systems 5 of all elevators (FIG. 3) and from The microprocessors are interpreted to mean that the following call is for disabled passengers suitable operating mode must be processed. After the transmission of the call, a call characterizing the input floor E10 is written into the first memory RAM1.1 and a call characterizing the destination floor E13 is written into the second memory RAM1.2 of the call memory RAM1 of all elevators (FIG. 2). The multiplexers 50 are then queried (FIG. 7). When the call registration and display device 8 located between the elevators B and C is actuated, the output of the assigned AND gate 51 and thus also the relevant inputs of all multiplexers 50 become logic "0". When the address assigned to the respective input occurs, the microprocessors of the microcomputer systems 5 interpret the signal "0", which is located on the second conductor L2 in such a way that the content of the memory location BC of the further memory 16 is fed to the one input of the first comparator 17 got to. Then, depending on the car position contained in the car position register R2 and the address of the call input storey E10, the assigned travel time is taken from the travel time memory 14 and fed to the other input of the first comparator 17 (FIG. 2). It may now be assumed that the travel time of the elevator A is longer than the time 3t (FIG. 6) stored in the memory location BC of the further memory 16 and the output of the first comparator 17 is logically "1". Furthermore, it should be assumed that no call is stored in the second memory RAM1.2 of the elevator A for the floor E10, so that no dropouts are to be expected, which means that a first condition for the cabin selection is met and at the first input of the first AND gate 21 logic "1" appears (Fig. 2). The cabins may be of a size that a wheelchair would have enough space with a load limit L _max <5 people. If the load falls below the load limit value, the output of the second comparator 27 may be logic "1", so that, according to the example, a load value corresponding to four people is stored in the load memory 13 of the elevator A, a second condition for the selection is fulfilled and at the second input of the first AND gate 21 occurs logically "1". With logic "1" at the exit of the first Comparator 17 and therefore also at the third input of the first AND gate 21, a third condition for the cabin selection is fulfilled, the switching device 18 being switched to the conductive state via the second OR gate 24, so that the elevator A can take part in the call allocation process .

After the load values of the load storage devices 13 have been corrected in accordance with the newly entered call on floor E10, the operating costs for the input and destination floors are calculated for all elevators, for example using a formula known from EP-A 0 356 731 already mentioned . As already mentioned above, the computer takes the number of people in the cabin from the load memory 13, the travel time memory 14 the travel times of the cabin from the current position to the input or destination floor and the door time memory 15 door opening and closing times. Immediately after the calculation, the service costs are transferred to the service cost register R1 and compared with the service costs of the other elevators by means of the comparison device 11, for example, according to EP-B-0050304. The comparison and the allocation of calls exclude those elevators in which at least one condition for the cabin selection is not fulfilled, since the switching device 18 cannot be switched to the conductive state. It may now be assumed that elevator A has the lowest operating costs, so that in the first allocation memory RAM2 on floor E10 and in the second allocation memory RAM3 on floor E13, an allocation instruction is written (dashed arrows, FIG. 2). Immediately after the assignment, the selected elevator A and its position are displayed in the display field 41 of the call registration and display device 8 actuated by the wheelchair user (FIG. 4), whereupon the latter goes to the appropriately labeled landing door and arrives there before the selected cabin arrives. After the selection procedure has ended, the controller operates in the normal operating mode, but no more calls are assigned to the selected booth until it has reached the call input storey E10.

If, for example, none of the elevators A, B, C and D meets the third condition and only the first and second conditions for elevator A, the output of the first comparator 17 and the output of the first OR gate 23 become logic "0" "(Fig. 2). Logically "1" appears at the output of the NOR gate 26 and at the third input of the second AND gate 22, so that the switching device 18 is switched to the conductive state via the second OR gate 24. At the same time, the "1" state present at the output of the NOR slide 26 is interpreted by the microprocessor in such a way that the door hold-open time of the selected cabin is so much when entering floor E10 and outputting the control signals for the door drive 11 (FIG. 1) must be extended so that a disabled passenger can still board. In this case, a door closing button arranged in the cabin can be rendered ineffective for the duration of the extended door hold-open time, so that premature closing by passengers in the cabin and thus premature departure of the cabin is prevented.

Acoustic signaling can be provided for visually impaired people. It is thus possible that after actuation of the further key 33 and input of the call for a desired floor, a first acoustic signal confirming the selection of a cabin is generated in the call registration and display device 8 and a second acoustic signal after, for example, 0.5 seconds before the selected cabin arrives at the landing door of the elevator in question, so that a visually impaired person is guided on the right path. It is also possible for a third acoustic signal to be emitted each time a floor is traversed when the selected car is traveling between the call input and destination floors is generated so that visually impaired passengers can count on arrival at the destination floor. The generation of the third acoustic signal is ended when the visually impaired has reached the target floor.

If the key 33 is not pressed, the control operates in the normal operating mode. Here, the output of the first comparator 17 is connected directly to the switching device 18 (FIG. 2). In this case, the further memory 16 connected to the one input of the first comparator 17 can have additional memory locations in which passengers who are not physically disabled are stored appropriate times for the distances between the respectively activated call registration and display device 8 and the shaft doors of the elevators.

Claims (6)

Device for selecting an elevator car for the physically handicapped in elevators with immediate assignment of destination calls, with call registration and display devices (8) arranged on the floors, which have a keyboard for entering calls for desired destination floors, with each elevator a call memory assigned to an elevator group (RAM1) , which are connected to the call registration and display devices (8), a call characterizing the input floor and a call characterizing the destination floor being stored in the call memories (RAM1) with load memories (13) in when a call is entered on a floor which per floor the number of people present in the respective elevator car is stored, with the travel time memories (14) and computers assigned to the elevators and a comparison device (11), the computer calculating service costs corresponding to the waiting times of passengers from elevator-specific data, and m with an operating cost register (R1) connected to the computer and the comparing device (11) and allocation memories (RAM2, RAM3) assigned to the call memory (RAM1), the operating costs being compared with each other and the elevator car concerned with the call in question by writing an allocation instruction into the allocation memory (RAM2, RAM3) is allocated, which has the lowest operating costs, and the elevator in question and its position is displayed on a display panel of the actuated call registration and display device (8) immediately after the call allocation,
characterized, - that for each elevator a circuit (20) is provided which is connected on the input side to a second memory (RAM1.2) of the call memory (RAM1) and the load memory (13) which stores the calls for the destination floors, - That the circuit (20) is connected on the input side to the output of a first comparator (17) which is connected on the input side to the travel time memory (14) and a further memory (16), the further memory (16) being used by physically disabled passengers Times for the paths between the respectively activated call registration and display device (8) and the shaft doors (30) of the elevators are stored, - that the circuit (20) is connected on the output side to a switching device (18) arranged between the service cost register (R1) and the comparison device (11), - Where there is no exit call in the second memory (RAM1.2) and with a load that is less than a load limit (L _max ), as well as with a travel time of the elevator car that is greater than the time that a physically disabled passenger has to reach the landing door (30) of the elevator in question, the switching device (18) is actuated and the elevator can take part in the comparison, and - That the keyboards (40) of the call registration and display devices (8) have a further key (33), by means of which the circuits (20) of a floor can be activated. Device for selecting an elevator car according to claim 1, the elevator car being accessible via doors which are actuated automatically by means of a door drive (10) when stopping on one floor,
characterized, - That the circuit (20) is on the output side with the door drive (10) in operative connection, being in the absence of an exit call in the second memory (RAM1.2) and with a load that is less than a load limit (L _max ), as well as one Driving time of the Elevator cabin, which is less than the time it takes a physically disabled passenger to reach the landing door (30) of the elevator in question, the switching device (18) is actuated so that the elevator can take part in the comparison and the door hold-open time of the selected cabin is extended . Device for selecting an elevator car, according to claim 2, wherein the call memory (RAM1), the load memory (13) and the travel time memory (14) are components of the microcomputer systems (5) assigned to the elevators,
characterized, - That the further memory (16) and the first comparator (17) are further components of the microcomputer systems (5), - That the outputs of the call registration and display devices (8) assigned to the further buttons (33) are connected via tristate buffers (34, 35) and an OR gate (36) to first conductors (L1) which are connected to the microcomputer systems ( 5) communicate, - that the activation connections of the tristate buffers (34, 35) are connected to the respective output of a decoder (37) assigned to a specific floor, which is connected on the input side to an address bus (ab) of a microcomputer system (5), - When pressing the further button (33) on a floor and the corresponding address occurs, the information read by the microcomputer systems (5) via the first conductor (L1) causes the circuits (20) assigned to the floor in question to be activated. Device for selecting an elevator car, according to claim 3,
characterized, - That the circuit (20) from a first and second AND gate (21, 22), a first and second OR gate (23, 24), a NOT gate (25), a NOR gate (26) and a second comparator (27), - That a first input of the first AND gate (21) is connected via the NOT gate (25) to the memory cell of the second memory (RAM1.2) of the call memory (RAM1) assigned to the relevant floor, - That a second input of the first AND gate (21) is connected to the output of the second comparator (27), one input of which is connected to the relevant memory cell of the load store (13) and the other input of which is the load limit value (L _max ) is fed - That a third input of the first AND gate (21) is connected to the output of the first comparator (17), - That a first input of the second AND gate (22) is connected to the first input of the first AND gate (21) and a second input is connected to the output of the second comparator (27), - That a third input of the second AND gate (22) is connected to the output of the NOR gate (26), the first input of which is connected to the output of the first comparator (17), - That a second input of the NOR gate (26) is connected to the output of the first OR gate (23), the first input of which is connected to the output of the first AND gate (21) and the remaining inputs of which are connected to the outputs of the first AND gates (21) of further elevators (B, C, D) associated circuits (20) are connected, and - That the output of the first AND gate (21) is connected to a first input of the second OR gate (24), the second input of which is connected to the output of the second AND gate (22), and its output is connected to the switching device ( 18) is connected. Device for selecting an elevator car, according to claim 1,
characterized,
that after actuation of the further key (33) and input of a call, a first acoustic signal confirming the selection of a cabin is generated in the call registration and display device (8) and a short time later a second acoustic signal before the arrival of the selected cabin the landing door (30) of the elevator in question sounds. Device for selecting an elevator car, according to claim 1,
characterized,
that a third acoustic signal is generated when the selected car travels between the call input and the destination floor each time it passes through a floor and is switched off again after reaching the destination floor.

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