EP0301178B1 - Lift control device - Google Patents

Description

The invention relates to a control device for an elevator installation with at least one elevator which has a car provided with at least one compartment, at least one main stop comprising a number of adjacent main floors corresponding to the number of compartments being provided and for calling cabs to the floors and for entering Destination input command input devices are available, and the elevator only executes travel requests to a specific group of destination floors.

Such devices make it possible to implement and operate inexpensive, high-performance elevator systems, with elevator users benefiting from fast operation.

A control device for elevators with double cabins according to US Pat. No. 3,625,311 is known, in which the double cabins are designed such that two adjacent floors can be operated simultaneously. In this case, the filling of a building should be achieved in the shortest possible time with approximately even occupancy of the double cabins by the passengers entering the upper cabin to the even-numbered destination floors and the odd-numbered ones to the lower cabin at the main stopping point, whereby the cabin callers for each do not target floors assigned to the cabin are blocked. As soon as the cabin has to stop on an upper floor after leaving the main stop, the block is lifted so that a person boarding can go up to any destination floor. The lifting of the destination floor block triggered by a floor stop has the disadvantage that passengers arriving at the main stop in the wrong car has risen, but by subsequently actuating the car call transmitter, the desired destination floors can be reached, which greatly reduces the performance of the elevator system.

According to US Pat. No. 3,080,944, a control device for elevators with single cabins is known, which switches to zone operation when there is a high volume of traffic. A first zone comprises the lower floors, a second zone comprises the upper floors. A first group of elevators serves the floors allocated to the first zone, a second group of elevators serves the floors allocated to the second zone. The car call buttons on the floors outside the respective zone are electrically blocked, which means that only trips to the floors located within the respective zone are carried out. In zone operation, the first group of elevators does not answer floor calls on the ascending journey and only the AB floor calls within the first zone on the descending journey. The second group of elevators answers all floor calls on the ascending journey and only the AB floor calls within the second zone on the descending journey.

The disadvantage of this known device is that elevators of the second group stop on the ascending journey due to floor calls from the first zone even if there are no executable destination requests. The resulting unnecessary stops reduce the performance of the elevator system.

The invention, as characterized in the claims, solves the problem of proposing a control device with which the performance of elevators with target floor groups is improved.

The advantage achieved by the invention can essentially be seen in the fact that the passengers are practically forced to behave correctly while using the lift system. Another advantage is that elevators can only be used for permitted journeys, which increases the performance of the elevator system.

• Fig. 1 eine perspektivische Darstellung von drei Stockwerken einer Aufzugsgruppe mit zwei mit Doppelkabinen versehenen Aufzügen,
• Fig. 2 eine schematische Darstellung der Steuereinrichtung für einen Aufzug einer aus zwei Aufzügen bestehenden Aufzugsgruppe,
• Fig. 3 ein Schaltschema einer Rufregistriereinrichtung mit Tastenfeld der Steuereinrichtung gemäss Fig. 2,
• Fig. 4 eine schematische Darstellung der Struktur eines einem Aufzug zugeordneten Zielstockwerkrufspeichers der Steuereinrichtung gemäss Fig. 2 und eine Koinzidenzschaltung für die Rufzuteilung,
• Fig. 5 eine schematische Darstellung von Schaltkreisen zur Ansteuerung von Anzeigen, die die wartenden Passagiere darüber informieren, ob einer ankommenden Kabine die gewünschten Zielstockwerke zugeteilt sind oder nicht,
• Fig. 6 ein Schaltschema einer Rufregistriereinrichtung mit 10er-Tastatur der Steuereinrichtung gemäss Fig. 2.,
• Fig. 7 eine Aufzugsgruppe mit zwei mit Einfachkabinen versehenen Aufzügen bei Zonenbetrieb und
• Fig. 8 ein Schaltschema einer Rufregistriereinrichtung mit Tastenfeld und Tasten für alle Zielstockwerke.

The invention is explained in more detail below with reference to drawings. Show it:

• 1 is a perspective view of three floors of an elevator group with two elevators provided with double cabins,
• 2 shows a schematic representation of the control device for an elevator of an elevator group consisting of two elevators,
• 3 shows a circuit diagram of a call registration device with keypad of the control device according to FIG. 2,
• 4 shows a schematic representation of the structure of a destination storey call memory associated with an elevator of the control device according to FIG. 2 and a coincidence circuit for the call allocation,
• 5 shows a schematic representation of circuits for actuating displays which inform the waiting passengers about whether or not the desired destination floors are assigned to an arriving cabin,
• 6 shows a circuit diagram of a call registration device with a 10-key keyboard of the control device according to FIG. 2,
• Fig. 7 is an elevator group with two elevators provided with single cabins during zone operation and
• Fig. 8 is a circuit diagram of a call registration device with keypad and keys for all destination floors.

1 to 6 show an elevator group with multiple cabin elevators, in which only target floors of a certain group of target floors can be entered on a main stop HH per main floor. An elevator a and an elevator b with a multiple cabin, hereinafter referred to as double cabin 4, serve one floor E0, one floor E1 and further floors E2 to En. T0 to Tn denote the shaft doors of the floors E0 to En that close the elevator shaft. The double cabin 4 has a lower compartment 4.1 and an upper compartment 4.2. In the exemplary embodiment, the main stop HH of the elevators a and b comprises the main floors E0 and E1. On the floors E2 to En there is a call registration device 9 with a keypad 20 which has a key for each destination floor. The keypad 20 of the main floor E0 is only equipped with keys for the even-numbered target floors, the keypad 20 of the main floor E1 is only equipped with keys for the odd-numbered target floors. With 14 an indicator is designated, which shows the waiting passengers whether an arriving compartment 4.1; 4.2 for the up calls, the down calls or not intended for boarding.

In a further embodiment variant, instead of the keypad 20, the call registration device 9 can be provided with a pulse generator according to CH-PS 162 810 in the manner of a telephone number dialer, which is connected to call memory via a device for converting the pulse generator numbers into floor numbers.

In a further embodiment variant, instead of the keypad 20, the call registration device 9 can be provided with a 10-key keyboard according to FIG. 6, which has keys for the input of numbers and control characters, and the is connected to call memory via a device for converting the 10-digit keyboard numbers into floor numbers.

In the pulse generator variant as well as in the 10-key keyboard variant, means are provided for the main floor E0 or main floor E1 which prevent the acceptance of floor calls on even-numbered or odd-numbered destination floors.

In FIG. 1, the lower compartment 4.1 of the double cabin 4 of the elevator a, which is in the process of ascending, is shown when the floor is on the floor E2. Two passengers P with selected destination floors E4 and E6 have already boarded the main floor E0. At the same time, the lower compartment 4.1 of the double car 4 of the elevator b, which is in the process of descending, moves in on the floor E2. A passenger P leaves compartment 4.1, a passenger P with destination floor E0 remains in compartment 4.1. Without indicator 14, the two passengers P with destination floor E7 and E9 waiting on floor E2 would not know whether elevator a or elevator b served their destination floor. The arrow upward, which lights up green on the display 14 of the elevator a when compartment 4.1 arrives, indicates to the passengers P which elevator their target floors have been allocated for operation. A red X-symbol appears on the display 14 of the elevator b on the floor E2, which indicates to the waiting passengers P that they must not get in, since the elevator b has not been assigned any destination floors desired for operation on the floor E2. To determine the cabin load, compartment 4.1; 4.2 a load measuring device 7; 8 on. It is also used to record passengers P who have boarded without entering their destination floor. In section 4.1; 4.2, a position indicator (not shown) is arranged, which indicates the respective stopping floor to the cabin passengers.

In FIG. 2, 1 is an elevator shaft of elevator a, which consists of two elevators a and b, for example Called elevator group. A conveyor machine 2 drives, via a conveyor cable 3, the double cabin 4 guided in the elevator shaft 1 with the lower compartment 4.1 and the upper compartment 4.2, n floors E0 to En being served, of which only the top floors En-4 to En are shown. The carrier 2 is controlled by a drive system 6, the setpoint generation, the control functions and the initiation of the stop being implemented by means of a microcomputer system 5. The drive system 6 is connected to the microcomputer system 5 via a first interface IF1. The compartments 4.1; 4.2 have load measuring devices 7; 8, which are also connected to the microcomputer system 5 via the first interface IF1. Call registering devices 9, which are described in greater detail below with reference to FIGS. 3 and 6, are provided on the floors, by means of which calls can be entered for trips to desired target floors. The call registration devices 9 are connected via an address bus AB and a data input conductor CRUIN of a serial input / output bus CRU to the microcomputer system 5 and to an input device which has become known from EP-B-0 062 141 and which consists of a comparison device 10 and a DMA module DMA. The call registration devices 9 are also connected via lines 11 to the microcomputer system and the input device of the elevator b.

The microcomputer system 5 consists of a storey call memory RAM1, a destination storey call memory RAM2 described in more detail below with reference to FIG. 4, and the current cabin load P _M of compartment 4.1; 4.2 memory RAM3, one memory RAM4 for UP and DOWN direction of travel, one allocation memory RAM5 for UP and DOWN direction of travel, a program memory EPROM and a microprocessor CPU via the address bus AB, a data bus DB and a control bus STB is connected to the memories RAM1 to RAM5, EPROM. With R1 and R2 are one denotes the first and a second scanner of a scanner, the scanner R1, R2 being registers by means of which addresses corresponding to the floor numbers and the direction of travel are formed. R3 denotes a selector in the form of a further register which, when the car is moving, displays the address of the floor on which the car could still stop. As is known from the drive control mentioned above, the selector addresses are assigned target paths which are compared with a target path generated in a setpoint generator. If the paths are identical and a stop command is present, the delay phase is initiated. If there is no stop command, the selector R3 is switched to the next floor.

The microcomputer systems 5 of the individual elevators a; b are connected to one another via a cost comparison device 12 known from EP-B-0 050 304 and a second interface IF2 and via a partyline transmission system 13 known from EP-B-0 050 305 and a third interface IF3.

3, the call registration device 9 of the floor E2 is explained in more detail. A keypad 20 is provided per floor, which has a key for each target floor. The button for floor E2 is not shown in FIG. 3.

The keypad 20 of the main floor E0 is only equipped with keys for the even-numbered target floors, the keypad 20 of the main floor E1 is only equipped with keys for the odd-numbered target floors. In a further embodiment variant, a call registration device 9 with a keypad 20 is provided on the main stop HH per elevator, which has only keys for even-numbered or odd-numbered destination floors that lie within a certain zone. In another In the case of zone operation, at least one call registration device 9 according to FIG. 8, common to elevator a and elevator b, is provided with a keypad 20 which has buttons for all destination floors. In this embodiment variant, the passengers are informed by means of a display which is not explained in more detail and which is not shown, which group of destination floors is served by which elevator.

Both further variants of the call registration device 9 also allow zone operation in elevator groups with multiple-cabin elevators, which is explained in more detail in FIG. 7. The design variant with keypad and keys for all destination floors allows zone operation with zones that can be adapted to the traffic volume and / or blocking of even or odd numbered destination floor calls from the main stop HH.

The keys 20.0; 20.1 ... 20.n of the target floors E0; E1 ... En are with the inputs S the call memory 27.0; 27.1 ... 27.n in connection. The outputs Q of the call memory 27.0; 27.1 ... 27.n are connected to inputs of a multiplexer 28 and an OR gate 29, the output of which is connected to the first input of the multiplexer 28. The multiplexer 28 is also connected to the address bus AB and is connected on the output side to the data input conductor CRUIN. The outputs Q of the call memory 27.0; 27.1 ... 27.n are connected via lines 11 to multiplexer 28 and OR gate 29 of elevator b.

Via the multiplexer 28, the call memory 27.0; 27.1 ... 27.n are scanned and stored calls are transmitted to the microcomputer system 5 of the elevator in question. If at least one call is present, the first input of the multiplexer 28 is activated via the OR gate 29 and the assigned address is interpreted as the address of a floor call. The other entrances of the Addresses assigned to multiplexers 28 are interpreted as addresses of destination floor calls.

As is known from EP-B-0 062 141 mentioned in the description of FIG. 2, the calls are transferred to the microcomputer system 5 in such a way that the microprocessor CPU signals its readiness to accept interrupt requests CINT by means of an enable signal CIEN. The DMA module is activated by the enable signal and takes control of the address bus AB and the serial input / output bus CRU. Using the addresses now generated by the DMA module, the call memories 27.0; 27.1 ... 27.n of the call registration devices 9 and a read-write memory flag RAM of the comparison device 10 are queried. In the comparison device 10, the content of the call memory 27.0; 27.1 ... 27.n and the assigned memory locations of the read-write memory Flag-RAM compared with each other. If they are not equal, the DMA operation is ended and an interrupt request CINT is generated. The microprocessor CPU now executes an interrupt program, which reads the data bit located on the data input line CRUIN and at the address located on the address bus AB in the storey call memory RAM1 or in the destination storey call memory RAM2 and via a data line D₀ of the data bus DB in the read-write memory Register RAM flag.

4, the destination storey call memory RAM2 consists of a first memory RAM2 ', which has memory locations corresponding to the number of floors, and in which calls which have already been allocated are stored. RAM2.0, RAM2.1 ... RAM2.n designate further memories assigned to floors E0, E1 ... En, which also have memory locations corresponding to the number of floors. In the further memories RAM2.0, RAM2.1 ... RAM2.n, only the calls entered on the relevant floors are entered using the method described in the previous section transmitted that have not yet been assigned to a specific cabin. The first memory RAM2 ', the further memories RAM2.0, RAM2.1 ... RAM2.n, the storey call memory RAM1 and the allocation memory RAM5 are interconnected via a coincidence circuit symbolized by AND gates 50 and 51. The coincidence circuit formed by the microprocessor CPU on the basis of a program at each position of the second scanner R2 has the effect that, when an assignment instruction and a floor call on the same floor coincide, the calls stored in the allocated further memory are transferred to the first memory RAM2 ', with which they are allocated and are released for scanning by the selector R3. According to the selected example, only the allocation memory RAM5 for the UP direction of travel is shown in FIG. 4.

The allocation of a floor call and the calls entered on a floor for desired target floors is carried out in a manner similar to that in EP-B-0 032 213 recognized in the prior art.

In FIG. 5, 15 designates circuits which are assigned to the floors and are connected on the input side to the group control device 5 and on the output side to indicators 14 arranged on the floors. The circuits 15 shown only for the floor E7 consist of a first and a second AND gate 15.1 each having three inputs; 15.2, a third, fourth and fifth AND gate 15.3 each having two inputs; 15.4; 15.5 and a NOT link 15.6. The first and second AND gate 15.1; 15.2 are each connected via an input to an output of the selector R3 assigned to the relevant floor, and via another input to a conductor 17 which carries a stop signal when stopping on a floor. The first AND gate 15.1 is via a further input at the output of the memory cell of the storey call memory RAM1 assigned to the relevant floor connected. The further input of the second AND gate 15.2 is connected to the output of the memory cell of the destination storey call memory RAM2 assigned to the same floor. The output of the first AND gate 15.1 is with an input of the fourth and fifth AND gate 15.4; 15.5 connected. The other input of the fourth AND gate 15.4 is connected to a conductor 18 carrying an upward travel signal, while the other input of the fifth AND gate 15.5 is connected to a conductor 19 carrying a downward travel signal. The output of the fourth AND gate 15.4 is connected to a first input e1 and that of the fifth AND gate 15.5 to a second input e2 of the indicator 14. One input of the third AND gate 15.3 is connected to the output of the second AND gate 15.2, while the other input is connected via the NOT gate 15.6 to the output of the memory cell of the storey call memory RAM1 assigned to the floor in question. The output of the third AND gate 15.3 is connected to a third input e3 of the indicator 14.

The indicator 14 consists of a first and a second display element in the form of an upward or Down arrow, and from another display element signaling a ban on boarding in the form of an X character. The display elements are formed by light-emitting diodes which are attached to a print (not shown further) and are covered by a plate which is perforated in accordance with the display symbols. When activating the display elements via the relevant inputs e1; e2; e3, the first and second display elements light up green and the other display element lights up red.

It is assumed that the upward-moving section 4.2 of the elevator a has been assigned a floor call for floor E7 and two calls entered on this floor for target floors E10 and E12, these in Floor or destination floor call memory RAM1; Calls stored in RAM2 are marked with "1" in accordance with the usual logical symbols. Since the selector signal, the stop signal and the upward travel signal are logic "1" when the compartment 4.2 on the floor E7 is logic "1" according to the logic chosen, for example, the first and fourth AND gates 15.1; 15.4 and the first input e1 of the indicator 14, the first display element is activated. Here, the up arrow lights up green, indicating to the waiting passengers that compartment 4.2 will service the calls you have entered.

The position detectors, not shown, arranged in the compartments are controlled by circuits similar to the circuit 15. The selector R3 shown in FIG. 5 signals that floor on which the moving cabin 4 could still stop if a stop command was present. The position indicator indicating the respective stopping floor can be controlled by logically combining this information with the information present on the conductor 17.

6 shows a call registration device 9 provided for the floor E0, which has a 10-key keyboard 20 instead of the keypad 20. In the case of elevator groups with multiple-cabin elevators, this embodiment variant of the call registration device 9 also allows zone operation, which is explained in more detail in FIG. 7, with zones which can be adapted to the traffic volume and / or blocking of the even-numbered or odd-numbered destination floor calls of the main stop HH. At least one call registration device 9 according to FIG. 6 is attached to the floors E0 and E1 forming the main stop HH. The main stop HH is not limited to the floors mentioned. In the case of multi-cabin elevators, those floors are normally used Main stop HH, which have a high volume of traffic.

6, the call registration device 9, which is designed, for example, for one- and two-digit calls, consists of a keyboard 20 which has ten keys for the numbers 1 ... 9 and 0 for the call input to desired destination floors. An eleventh key labeled "-" can be used, for example, as a pre-selection key for calls for floors below the ground floor, the ground floor being identified by the number 0. A twelfth key labeled "C" could be used for other purposes such as can be used as a preselection key for the coded entry of calls. The keys of the digits 1 ... 9 and 0 are at the first inputs of first AND gates 21.1 ... 21.9; 21.0 connected, the outputs of which have inputs S from key memories 23.1 ... 23.9; 23.0 are connected for storing a digit entered first. The keys of the digits 1 ... 9 and 0 are also with first inputs of second AND gates 22.1 ... 22.9; 22.0 connected, whose outputs with inputs S of key memories 24.1 ... 24.9; 24.0 are connected to the storage of a second entered digit. RS flip-flops, for example, can be used as the key memory. The outputs Q of all the key memories are connected to the inputs of a combinatorial logic 25, the outputs of which at the first inputs of third AND gates 26.1; 26.2 ... 26.n are connected, the call memories 27.1; 27.2 ... 27.n, in the form of, for example, RS flip-flops.

erfüllen, wobei die Eingangsvariablen 1′; 2′; 3′.... die erste eingegebene Ziffer und 1˝; 2˝; 3˝... die zweite eingegebene Ziffer bedeuten und die Ausgangsvariablen 1; 13 die gewählten Zielstockwerke E1; E13 bezeichnen.The combinatorial logic 25 works in such a way that when a single-digit call is entered, one of the floors E1; E2 ... E9 assigned call memory 27.1; 27.2 ... 27.9, and when entering a two-digit call one of the floors E10; E11 ... En assigned call memory 27.10; 27.11 ... 27.n is set. If, for example, calls for the Stories E1 and E13 are entered, the combinatorial logic 25 needs the equations

meet, where the input variables 1 '; 2 ′; 3 ′ .... the first digit entered and 1˝; 2˝; 3˝ ... mean the second digit entered and the output variables 1; 13 the selected target floors E1; Designate E13.

The outputs Q of the call memory 27.1; 27.2 ... 27.n are at the first inputs of fourth AND gates 60.1; 60.2 ... 60.n connected, which are connected on the output side to inputs of a multiplexer 28 and an OR gate 29, the output of which is connected to the first input of the multiplexer 28. The multiplexer 28 is also connected to the address bus AB and is connected on the output side to the data input conductor CRUIN. The outputs Q of the call memory 27.1; 27.2 ... 27.n are connected via lines 11 to multiplexer 28 and OR gate 29 of elevator b. To the third inputs of the third AND gates 26.1; 26.2 ... 26.n are leaders ENS.1; ENS.2 ... ENS.n connected. The second inputs of the fourth AND gates 60.1; 60.2 ... 60.n stand with the ladder ENZ.1; ENZ.2 ... ENZ.n in connection.

30 designates a time limit switch for the call input, which consists of a monoflop 31, a first and second delay element 32; 33, a first, second and third NOT link 34; 35; 36 and a first and a second AND gate 37 each having two inputs; 38 exists. The keys of the digits 1 ... 9 and 0 are connected to the input e of the monoflop 31 via an OR gate 39, a further delay gate 40 and a further AND gate 41 having two inputs. The output a of the monoflop 31 is at Input of the first delay element 32, at second inputs of the second AND elements 22.1 ... 22.9; 22.0 and via a further NOT element 42 at second inputs of the first AND elements 21.1 ... 21.9; 21.0 connected. The output of the first delay element 32 is connected to the input of the second delay element 33, the output of which is connected via the first NOT element 34 to the second input of the further AND element 41. Logic modules connected in series, for example, can be used as delay elements, the delay time resulting from the signal transit time. The output a of the monoflop 31 is connected via the second NOT gate 35 to an input of the first AND gate 37, the second input of which at the output of the first delay element 32 and the output of which at the second inputs of the call memories 27.1; 27.2 ... 27.n upstream third AND gates 26.1; 26.2 ... 26.n is connected. The output of the first delay element 32 is connected via the third NOT element 36 to an input of the second AND element 38, the second input of which is connected to the output of the second delay element 33 and the output of which is connected to reset connections R of the key memory.

The call registration device 9 described above operates as follows:

When a call is entered for, for example, floor E13, the key of number 1 is initially pressed, a short pulse being generated and because of the first AND gates 21.1... 21.9; 21.0 only the key memory 23.1 is set. After a delay caused by the further delay element 40, the monoflop 31 is switched, so that the output of the further NOT element 42 is set low and the key memories 23.1 ... 23.9; 23.0 for the input of the first number assigned to the first AND elements 21.1 ... 21.9; 21.0 can be blocked. At the same time, the key memories 24.1 ... 24.9; 24.0 for entering the second digit assigned second AND gates 22.1 ... 22.9; 22.0 released. It is now assumed that the switch-on time of the monoflop 31 is, for example, one second and the key of the number 3 is still pressed during this time. Here, the key memory 24.3 is set so that the combinatorial logic 25 has the input variables 1 ′ and 3˝ and the output variable 13 assigned to the call memory 27.13 for floor E13.

Due to the falling edges of the output signals of the monoflop 31 and the first delay element 32, a pulse is generated at the output of the first AND element 37, by means of which the third AND elements 26.1; 26.2 ... 26.n are released and the call memory 27.13 assigned to floor E13 is set if the line ENS.13 is at logic "1". Likewise, a further pulse is generated by the falling edges of the output signals of the first and second delay elements 32 and 33 at the output of the second AND element 38, by means of which all the key memories are reset. With the falling edge of the second delay element 33, the monoflop 31 is released via the first NOT element 34 and the further AND element 41, so that a further call can be entered.

In order to block the even-numbered or odd-numbered destination floor calls in the main stop HH, the heads ENS.1; ENS.2 ... ENS.n manually or automatically with a logical "0" or a logical "1". Accordingly, the lines ENZ.1; ENZ.2 ... ENZ.n set to logic "1" or logic "0" so that the third AND elements 26.1; 26.2 ... 26.n and the fourth AND gate 60.1; 60.2 ... 60.n only release even-numbered or odd-numbered target floors. In zone operation, in addition to blocking even-numbered or odd-numbered destination storey calls at the main stop HH, a first zone Za with, for example, the destination storeys E1; E2 ... E19 assigned to the elevator a by the fourth AND elements 60.1; 60.2 ... 60.19 using cables ENZ.1; ENZ.2 ... ENZ.19 are released. A second zone Zb with the target floors E20; E21 ... En is assigned to elevator b in an analogous manner. By means of a display, not explained in detail and not shown, the elevator passengers at the main stop HH find out which group of destination floors is served by which elevator.

The fourth AND gates 60.1; 60.2 ... 60.n sampled and those in the call memories 27.1; 27.2 ... 27.n stored calls are transmitted to the microcomputer system 5 of the elevator in question. If at least one call is present, the first input of the multiplexer 28 is activated via the OR gate 29 and the assigned address is interpreted as the address of a floor call. The addresses assigned to the other inputs of multiplexer 28 are interpreted as addresses of car calls, with, for example, a first part of the address serving as the destination floor and a second part of the address as the selection code of the multiplexer in question and denoting the floor on which the call for the destination floor was entered.

FIG. 7 shows an elevator group with single-cabin elevators, in which only target floors of a specific group of target floors can be entered at the main stop HH per elevator. The elevator group with elevator a and elevator b in zone operation is essentially controlled by the devices explained in FIGS. 2 to 6. The conveying machine 2 drives the single cabin 4 guided in the elevator shaft 1 via the conveyor cable 3. Indicators 14 arranged on the floors show the waiting passengers whether an arriving cabin 4 is intended for the up calls, the down calls or not at all for boarding. The structure and mode of operation of the indicator 14 is shown in more detail in FIG. 5 explained. Call registration devices 9 are provided on the floors, by means of which calls can be entered for trips to the desired destination floors. At least two call registration devices 9 are arranged on the main stop HH comprising the floor E0, and at least one call registration device 9 is arranged on the remaining floors. The structure and mode of operation of the call registration device 9 is explained in more detail in FIG. 3. According to FIG. 7, a first call registration device 9 with a keypad is provided on the main stop HH, which has keys for entering destination floors which lie within the first zone Za assigned to the elevator a. The keypad of a second call registration device 9, which is arranged on the main stop HH, has keys for inputting destination floors which lie within the second zone Zb assigned to the elevator b. In the case of the call registration devices 9 arranged on the main stop HH, the lines 11 shown in FIG. 3 are omitted. On the floors E1 to E20, call registration devices 9 are provided with key fields which have a key for each destination floor, the destination floor choice per floor via one Elevators a and b common call registration device 9 takes place.

In the exemplary embodiment in FIG. 7, only the destination floors E1 to E10 of the first zone Za can be entered at the main stop HH by means of the first call registration device 9 of the elevator a. If, for example, a passenger wants to travel from the main stop HH to the floor E19, he must enter his destination floor by means of the second call registration device 9 of the elevator b. In buildings with heavy traffic from the main stop HH to floors E1 to E5, for example, is a first zone Za that only comprises these floors and a second zone Zb comprising the same and / or the remaining floors is provided.

In a further embodiment variant, at least one call registration device 9 common to elevator a and elevator b according to FIG. 8 is provided instead of the first and second call registration device 9 of FIG. 7 on the main stop HH. The keypad 20 has keys 20.1; 20.2 ... 20.n for all target floors. The destination floors of zone a and zone b are entered via a keypad 20 common to the elevators. The circuitry of FIG. 8 corresponds in structure and function to that of FIG. 6. In elevator groups with single-cabin elevators, the ones shown in FIG. 8 lines shown ENS.1; ENS.2 ... ENS.n.

In a further embodiment variant, instead of the keypad, the call registration device 9 can be provided with a pulse generator according to CH-PS 162 810 in the manner of a telephone number dialer, which is connected to call memory via a device for converting the pulse generator numbers into floor numbers. In the pulse generator variant, means are provided for the main floor E0 to prevent travel to floors that are outside the zones assigned to the elevators.

In a further embodiment variant, instead of the keypad, the call registration device 9 can be provided with a 10-key keyboard according to FIG. 6, which has keys for entering numbers and control characters, and which has a device for converting the 10-key keyboard numbers into floor numbers Call memory is connected. In the case of elevator groups with single-car elevators, the lines ENS.1 shown in FIG. 6 are omitted; ENS.2 ... ENS.n. At least one call registration device 9 according to FIG. 6 is provided on the main floor E0 forming the main stop HH. The main stop HH is not limited to the floor mentioned. Usually at Single cabin elevators on the floor to the main stop HH with a high volume of traffic.

With the call registration device 9 according to FIG. 6 and according to FIG. 8, zones adaptable to the traffic volume can be formed. Zones are created manually or automatically using lines ENZ.1; ENZ.2 ... ENZ.n to which the corresponding signals are applied. This prevents stored destination floor calls that lie outside the zones assigned to the elevators from being recognized by the multiplexer (28).

By means of a display (not explained in more detail and not shown), the elevator passengers on the main stop HH can find out which group of destination floors is served by which elevator.

Claims (12)

1. Control equipment for a lift installation with at least one lift (a; b) which displays a cage (4) provided with at least one compartment (4.1; 4.2), wherein at least one main stopping place (HH) is provided, which covers a number of adjacent mainfloors (E0; E1) corresponding to the number of compartments and command input devices are present for the calling of cages to the floors and for the input of travel destination wishes and the lift (a; b) carries out only travel wishes to one certain group of destination floors, characterised thereby, that the command input devices are exclusively call registered equipments (9) arranged externally of the cage (4) on the floors (E0; E1...En) and that means are provided for the prevention of the execution of travel wishes at least in direction of travel away from the main stopping place (HH) to destination floors lying outside the certain group of destination floors.

2. Control equipment according to patent claim 1, characterised thereby that at least one call registering equipment (9) with a key field (20), which displays keys for the input of destination floor calls and is connected to call stores (27.0; 27.1...27.n), is provided on each floor of the lift installation.

3. Control equipment according to patent claim 1 and 2, characterised thereby, that the means for the prevention of the execution of travel wishes from the main stopping place (HH) to destination floors lying outside the certain group of destination floors display a call registering equipment (9) with a key field (20), which displays only keys for destination floors allocated to the certain group of destination floors.

4. Control equipment according to patent claim 1, characterised thereby, that at least one call registering equipment (9), which displays a manually actuable pulse generator in the manner of a telephone number selector and is connected to call stores (27.0; 27.1... 27.n) by way of an equipment for the conversion of the pulse numbers into destinatation floor calls, is provided on each floor of the lift installation.

5. Control equipment according to patent claim 1, characterised thereby, that at least one call registering equipment (9) with a decade keyboard, which displays keys for the input of numerals and control symbols and which is connected to call stores (27.0; 27.1...27.n) by way of an equipment for the conversion of the decade keyboard numbers into destination floor calls, is provided on each floor of the lift installation.

6. Control equipment according to patent claim 1 and one of the patent claims 2, 4 or 5, characterised thereby, that the means for the prevention of the execution of travel wishes from the main stopping place (HH) to destination floors lying outside the certain group of destination floors display a call registering equipment (9) with a device for the freeing of the destination floor calls allocated to the certain group of destination floors and for the blocking of the destination floor calls lying outside the certain group of destination floors.

7. Control equipment according to patent claim 6, characterised thereby, that the device for the freeing or blocking of destination floor calls displays lines (ENS.1; ENS.2... ENS.n; ENZ.1; ENZ.2... ENZ.n), which are connected to the inputs of logical switching circuits and acted on manually or automatically by appropriate signals.

8. Control equipment according to patent claim 1 and one of the patent claims 4 and 5, characterised thereby, that the call registering equipment (9) of the main stopping place (HH) displays an indication which indicates which lift serves which certain group of destination floors.

9. Control equipment according to patent claim 1, characterised thereby, that in the case of a lift group with two lifts, the certain group of destination floors allocated to a first lift (a; b) covers a first zone (Za) adaptable to the traffic volume and having at least one destination floor and that the certain group of destination floors allocated to a second lift (b; a) covers a second zone (Zb) with the same and/or the remaining destination floors.

10. Control equipment according to patent claim 1, characterised thereby, that in the case of multi-cage lifts, the certain group of destination floorsallocated to the lower main floor (E0) covers the even-numbered destination floors and that the certain group of destination floors allocated to the upper main floor (E1) covers the oddnumbered destination floors.

11. Control equipment according to patent claim 1, characterised thereby, that in the case of multi-cage lifts, the certain group of destination floors allocated to the lower main floor (E0) covers the odd-numbered destination floors and that the certain group of destination floors allocated to the upper main floor (E1) cover the evennumbered destination floors.
12. Control equipment according to patent claim 9, characterised thereby, that in the case of multi-cage lifts, the certain group of destination floors allocated to the first lift (a; b) covers the destionation floors, which are allocated to the lower main floor (E0) and the upper main floor (E1) and which lie within the first zone (Za), and that the certain group of destination floors allocated to the second lift (b; a) covers the destination floors, which are allocated to the lower main floor (E0) and the upper main floor (E1) and which lie within the second zone (Zb).

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