EP0091554B1 - Lift groups control comprising a device for the down peak traffic control - Google Patents

Abstract

By means of the group control the average time losses for the passengers resulting from the waiting time at the floors and the return travel time are minimized. Therefore, the number of entering stops causing a minimum of time losses is determined per elevator car on the basis of calculations. The number of entering stops is stored in monitoring or control counters by means of which the allocation of down hall calls is limited to the number stored for each car. The down hall calls are combined by means of a switching circuit to form groups of chronologically inputted or incoming hall calls of a volume corresponding to the number of hall calls respectively stored in the monitoring or control counter. In the case of an increase in the hall calls, the earliest group of hall calls is first increased and the latest group of hall calls last. The increase of numbers in the group occurs by transfer of a hall call from the next later group of hall calls and the latest hall call is allocated to the latest group of hall calls. Thus, groups of hall calls are formed, each of which have the same size until the control counting state or level of the monitoring or control counter is reached. The groups of hall calls are allocated to the different cars such that the average time losses of the passengers become a minimum.

Description

The invention relates to a group control for elevators with a device for controlling the downward peak traffic, by means of which the storey calls to be allocated to each car of the elevator group can be limited to a predetermined number in the downward direction.

Group controls with such facilities have the purpose of controlling the lifts of the group in such a way that there are short, balanced waiting times in the event of an extreme mass traffic flow towards the ground floor or another main stop, for example when the work is staggered in an office building or at the end of visiting hours in hospitals of passengers can be reached. In this case, the device can be activated by means of a timer or by means of a measuring device which determines the flow of traffic in the direction of the main stop, and at the same time the operation of calls in the upward direction can be reduced or completely prevented.

In a known group control according to DE-A-18 03 648, the floors are divided into fixed zones in groups. The elevator system goes into down peak operation when a certain number of down calls in more than one zone is exceeded or when a down car is fully occupied. Here, an allocation device compares the number of registered downward calls with the number of cabins used to settle the same. If the quotient of both numbers exceeds a certain size, an additional cabin is used in each case.

The known control now works in such a way that the first car, for example assigned to an upper zone with down calls, travels to the highest call of this zone, while the second car, also assigned to this zone, serves the highest down call of a lower section of the same zone. When the first car is assigned to the upper zone, this is switched off by the downward peak traffic, whereby if there are simultaneous down calls in a lower zone, the second car is assigned to the lower zone and serves the highest call of this zone, although the number of predetermined down calls in the upper zone is exceeded. In this way, alternate, preferred operation of the zones is to be achieved and balanced waiting times are to be achieved.

With this known control it is intended to assign each cabin only a certain number of downward calls for operation, with the determination of this certain number and thus the boarding stops per cabin as well as the alternating, preferred treatment of the zones being assumed to achieve minimal waiting times. However, it now emerges from what has been described above that in some cases the predetermined number of boarding stops of a cabin can be exceeded considerably, so that minimal waiting times can hardly be achieved. A further disadvantage is the fact that the cabins which are fully occupied by servicing down calls of the upper zone sections can no longer serve existing down calls of the lower zone sections, so that additional means must be used to eliminate this disadvantage.

One difficulty in designing such controls is determining the optimal number of boarding stops per cabin. Since there are certain uncertainties in this regard, a small number, for example two, is assumed in practice, and it is accepted that this number may be considerably exceeded.

With US-A-2 104 478 a group control according to the preamble has become known, in which a method similar to the principle of zone control is used for the distribution of the floor calls to the individual cars of the elevator group. The floor calls are assigned to the next car traveling in the desired direction. A quota relay is assigned to each car, by means of which, for example, the downward floor calls to be allocated to a car can be limited to a predetermined number during the downward peak traffic. In the case of such controls, the allocation of the floor calls to the cabins is only dependent on the position and direction of the calls, whereas the age of the calls is practically not taken into account in the allocation procedure, so that relatively large average waiting times of the passengers can result.

The object on which the invention is based is to eliminate the difficulties in determining the optimum number of boarding stops per car in order to remedy the disadvantages described above and to allocate the corresponding number of floor calls in the downward direction to the cars in such a way that the average of the mean waiting time and the return time is average System time of a passenger in the collective operation, for example for the purpose of emptying a building, a minimum is reached and the conveying capacity of the elevator group is increased.

This object is achieved with the features specified in claim 1. In the group control for elevators according to the invention, calculation bases are used, with the aid of which the number of boarding steps per car can be determined for which the average system time reaches minimum values. The largest number of these boarding stops is stored in a control counter, by means of which the allocation of floor calls in the downward direction to those in the Control counter stored number per cabin is limited. The floor calls are combined by means of a circuit to groups of calls entered one after the other in the amount of the number stored in the control counter, the call groups being assigned to the cabin that can serve the top call of a call group the fastest. The call groups are formed in such a way that when the number of calls increases, the oldest call group is enlarged first, the youngest and the last one is increased by taking over a call from the next younger call group and the youngest call is assigned to the youngest call group, call groups being the same Extent are formed until the control counter reading is reached.

The advantages achieved with the invention are essentially to be seen in the fact that the proposed circuit for call group formation enables minimum average system times to be achieved, with the aid of the proposed calculation bases the most favorable number of boarding steps can be determined for achieving the minimum average system time of a passenger. From the basis of the calculation, it can also be concluded with advantage that a reduction in the waiting time by increasing the number of boarding stops would be inappropriate, since the system time would increase significantly. A further advantage is achieved in that the call group size is adapted to the respective traffic conditions by determining the most frequently occurring boarding rate and thus the expected arrival load, making it possible to increase the conveying capacity of the elevator group with approximately the same minimum system time.

• Fig. 1 eine schematische Darstellung der erfindungsgemässen Gruppensteuerung für einen Aufzug einer aus drei Aufzügen bestehenden Aufzugsgruppe,
• Fig. 2 ein Schaltschema einer Übertragungseinrichtung für die Weiterleitung von Abwärts-Stockwerkrufen in der zeitlichen Reihenfolge der Eingabe,
• Fig. 3 eine schematische Darstellung zur Veranschaulichung der Rufgruppenbildung zu verschiedenen Zeitpunkten,
• Fig. 4 ein Diagramm der Förderleistung HC, der mittleren Wartezeit W, der Rückfahrzeit T und der durchschnittlichen Systemzeit D eines Fahrgastes jeweils in Abhängigkeit von der Anzahl Zusteigehalte B einer Aufzugskabine,
• Fig. 5 ein Diagramm der Kabinenumlaufzeit RTT und der Wartezeit W bei L = 3, 6 und 12 Aussteigern jeweils in Abhängigkeit von den Zusteigehalten B und
• Fig. 6 ein Diagramm der durchschnittlichen Systemzeit D bei L = 2, 3, 4, 6, 8, 10, 12 und 13 Aussteigern in Abhängigkeit von den Zusteigehalten B.

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

• 1 shows a schematic representation of the group control according to the invention for an elevator of an elevator group consisting of three elevators,
• 2 shows a circuit diagram of a transmission device for the forwarding of downstairs calls in the chronological order of the input,
• 3 shows a schematic illustration to illustrate the formation of call groups at different times,
• 4 shows a diagram of the conveying capacity HC, the mean waiting time W, the return time T and the average system time D of a passenger in each case as a function of the number of boarding steps B of an elevator car,
• Fig. 5 is a diagram of the car round trip time RTT and the waiting time W for L = 3, 6 and 12 dropouts depending on the boarding levels B and
• 6 shows a diagram of the average system time D with L = 2, 3, 4, 6, 8, 10, 12 and 13 dropouts as a function of the boarding hold B.

In FIG. I, I denotes an elevator shaft of an elevator a of an elevator group consisting of, for example, three elevators a, b and c. A conveyor machine 2 drives a car 4 guided in the elevator shaft 1 via a conveyor cable 3, fifteen floors E1 to E15 being operated in accordance with the elevator system selected as an example. The carrier is controlled by a drive control 5 known from European patent application No. 0026406, 5 being a microcomputer system by means of which the setpoint generation, the control functions and the initiation of the stop are implemented, and 6 symbolizing the measuring and actuating elements which are connected to the microcomputer system 5 via a first interface IF1. The microcomputer systems 5 of the individual elevators a, b, c are connected to one another via a comparison device 7 and a second interface IF2 as well as via a party line transmission system 8 and a third interface IF3 and in this way form one known from European Patent Application No. 0032213 Group control. With this group control, the assignments of the elevators a, b, c to the floor calls stored in a floor call memory RAM1 can be optimized in terms of time. Here, the microprocessor CPU of the microprocessor system 5 during a scanning cycle of a first scanner R1 on each floor, whether there is a floor call or not, from the distance between the floor and the car position indicated by a selector R3, the intermediate stops to be expected within this distance and the current cabin load is calculated as a sum proportional to the time lost by waiting passengers. The cabin load at the time of the calculation is corrected in such a way that the expected boarding and disembarking operations, derived from the number of boarding and disembarking passengers in the past, are taken into account in future intermediate stops. This total loss time, also called operating costs, is stored in a cost memory RAM2. During a cost comparison cycle by means of a second scanner R2, the operating costs of all the elevators are compared with one another via the comparison device 7, an allocation instruction in the form of a 1-bit data word, which designates that floor, can be stored in an allocation memory RAM3 of the elevator with the lowest operating costs. to which the elevator a, b, c in question is optimally assigned in terms of time.

A circuit arrangement 9 for the input of floor calls into the microcomputer system 5 consists of a peripheral unit 10, one Sampling and comparison device 11 and a DMA module DMA. The peripheral unit 10 is connected on the input side during the downward peak traffic via a transmission device 12, described in more detail below with reference to FIG. 2, for the forwarding of the downstairs calls in the chronological order of their input to downstairs callers 13. The peripheral unit 10 is also connected to the address bus AB and to a data input conductor CRUIN of a serial input and output bus CRU of the microcomputer system 5. The scanning and comparison device 11 is connected to the address bus AB, the data input conductor CRUIN, the second interface 1F2 and the DMA module DMA, which in turn is connected to the serial input / output bus CRU, the address bus AB and the control bus StB of the microcomputer system 5 stands. The circuit arrangement 9 operates in such a way that the microprocessor CPU of the microprocessor system 5 signals its readiness to accept interruptions by means of an enable signal. The scanning and comparison device 11 and the DMA module DMA are activated by the release signal, whereupon the inputs of the peripheral unit 10 are scanned by addresses of a DMA address register DMA-R. The switching state of the downstairs call transmitter 13 is compared with a switching state stored under the same address in the comparison device 11. In the event of inequality, an interruption request for the registration or deletion of a floor call is generated and the stored switching state is matched to that of the down floor call transmitter 13.

With 14 a circuit is designated, by means of which call groups are formed after switching to downward peak traffic. The circuit 14 consists of a waiting list RAM4 in the form of a read-write memory, in which the addresses of the downstairs calls are stored in the chronological order of the input, from a control counter which limits the number of calls of a call group or the number of boarding stops B of a car CC and from a priority counter PC, by means of which the priority of the elevators a, b, c is determined in relation to the cheapest operating costs determined in each case in a comparison. The circuit 14 also consists of a first data counter DC1 for addressing the memory locations of the waiting list RAM4, a second data counter DC2 for the transfer of the addresses stored in the waiting list RAM4 to the address bus AB and a buffer ZS for the transfer of the addresses of the DMA address register in the waiting list RAM4. The memories RAM4, ZS and counters CC, PC, DC1, DC2 are connected to the microcomputer system 5 via the address bus AB, the control bus StB and a data bus DB, the counters CC, PC, DC1, DC2 e.g. Registers of the microprocessor CPU or the counter CC, PC can also be RAM memory chips.

A load measuring device 15 arranged in the cabin 4 is connected to the microcomputer system 5 via the interface IF1. In the case of downward peak traffic, the load differences for each boarding level are calculated from the data determined by the load measuring device 15, and the average number of boarders per boarding level - also called boarding rate BR - is determined by forming the arithmetic mean from the sum of the load differences and the number of boarding levels B. The most frequently occurring boarding rate BR is stored in a RAM memory location RAM5 of the circuit 14 in order to be used to determine the number of calls of a call group or boarding level B, as described in more detail below with reference to FIGS. 4 to 6.

According to FIG. 2, the transmission device 12 for forwarding the downstairs calls in the chronological order of their input consists of shift registers 16, which, for example, each consist of twelve JK flip-flops and are assigned to the downstairs call transmitters 13. The down floor call transmitters 13 are connected on the one hand to the inputs D of the shift register 16 and on the other hand to the positive pole of a voltage source. Each JK flip-flop of the shift register 16 is assigned a NOR gate 17, an OR gate 18, a further OR gate 19 and, with the exception of the last JK flip-flops, an AND gate 20, the NOR -, OR and AND gates 17, 18, 20 each have two inputs and the further OR gate 19 has 16 inputs corresponding to the number of shift registers. One input of the NOR gate 17 is connected to a conductor 21 carrying a clock signal 0 and the other input is connected to the output of the AND gate 20. The output of the NOR gate 17 is connected via one input of the OR gate 18 to the clock terminals C of the JK flip-flops of the shift register 16, the other input of the OR gate 18 to an output of the DMA block DMA in Connection is established. The outputs Q of the JK flip-flops of the shift register 16 are connected to the inputs of the further OR gates 19, the outputs of which are connected to an input of the AND gates 20, the other inputs of the AND gates 20 each having the outputs of the preceding AND gates 20 are connected. The outputs Q of the last JK flip-flops of the shift register 16 are also connected to the set connections S of RS flip-flops 22, which are assigned to the crossing points of a matrix 23 of the peripheral unit 10 are. The outputs Q of the RS flip-flops 22 are each connected to an input of an AND element 24 having two inputs, the other input of which is connected to a row conductor ZL and the output of which is connected to a column conductor SL of the matrix 23. The row conductors ZL are activated via a row drive 25, the information from the RS flip-flop 22 being taken over by a gap receiver 26, the outputs of which are connected to the inputs of a multiplexer 27.

The transmission device 12 and the circuit 14 according to the above descriptions work as follows:

After switching over to downward peak traffic and actuating the downstairs call transmitters 13, for example of the floors E13, E14, E15 in the chronological order E14-E13-E15, the output Q of the shift register 16 assigned to the floor E14 is first increased. Here, the clock signal 0 at this JK flip-flop is interrupted via the logic elements 17, 18, 19 assigned to the last JK flip-flop, so that its output Q remains at a high potential. When the next time-related information arrives from the floor E13 at the output Q of the penultimate JK flip-flop concerned, the clock signal 0 is also interrupted for this via the associated logic elements 17 to 20. In the same way, the next following information is blocked by floor E15 at output Q of the third-to-last JK flip-flop in question. When scanning using the addresses of the DMA address register DMA-R, the information appearing at the output Z of the multiplexer 27 of the floor E14 is brought to the data input conductor CRUIN via a bus driver 28. It is now assumed that no call was saved for floor E14. In this case, an interrupt request is generated and this floor call is written into the floor call memory RAM1 in the course of an interrupt program. When the end address of the DMA address register DMA-R is reached, the information from the shift registers 16 is shifted by one level via the OR elements 18 by means of a signal. The output Q of the shift register 16 assigned to the floor E14 is thus set low and that of the assigned to the floor E13 is raised, so that the call which is second in time is ready for takeover.

The waiting list RAM4 of the circuit 14 is now filled in such a way that, after the oldest call from the floor E14 has been registered, the start address A1 stored in a read-only memory EPROM of the microcomputer system 5 is loaded into the first data counter DC1 while continuing the interrupt program. Then the address of the oldest call, which may be the same as floor number E14 for the purpose of simplifying the description, is taken over by the DMA register DMA-R into the intermediate memory ZS and written into the memory space of the waiting list RAM4 designated by the data counter DC1 (FIG. 1). The data counter DC1 is then incremented so that it displays the address A2. In the case of the elevator group on which the description example is based, with three elevators a, b, c, the interrupt program is completed when the data counter DC1 <A3, so that the interrupted program can be continued.

After the addresses E14, E13, E15 of the three calls at addresses A1, A2, A3 have been registered in the RAM4 waiting list and the data counter DC1 = A4, a program for optimal assignment of the oldest call from floor E14 to one of the three lifts a, b, c called. The procedure is similar to that described at the beginning, but the calculation of the service costs and their comparison is only carried out for the floor in question. Now, for example, the elevator b may have the lowest operating costs, so that an allocation instruction is written into its allocation memory RAM3 at the address E14 and its priority counter PC is set to first priority. In the subsequent assignment procedure for the two elevators a, c and the second oldest call from floor E13, elevator a may be the cheapest, so that an allocation instruction is written into its allocation memory RAM3 at address E13 and its priority counter PC is set to second priority (FIG. 1 ). The most recent call from the floor E15 is thus assigned to the elevator c, an allocation instruction being written into the associated allocation memory RAM3 at the address E15 and the priority counter PC being set to third priority.

With a control counter CC = 1 indicating the maximum number of boarders B, the assignment of the downstairs calls and thus the formation of call groups to one call each would be ended with the above-described. For further incoming downstairs calls, allocation instructions would therefore no longer be written into the allocation memory RAM3 of the elevators a, b, c. However, it is assumed that the control counter CC indicates the boarding number B = 3, the determination of which is explained in more detail in the following descriptions of FIGS. 4 to 6. When a fourth downstairs call arrives and the data counter DC1 = A5, a program for forming call groups associated with elevators a, b, c with more than one call is therefore called, each call group being formed from successive calls. The formation of the call groups is explained in more detail below with reference to FIG. 3 explained, assuming, for example, that a further six downstairs calls are entered in the chronological order E10-E8-E12-E9-E11-E7.

After the fourth call from the floor E10 has been written into the floor call memory RAM1, the elevator b identified by its priority counter PC, which indicates the first priority and to which the oldest call has already been allocated, is also assigned the second oldest call from the floor E13. This is done in such a way that the floor address E13 stored under the address A2 in the waiting list RAM4 is brought to the address bus AB via the second data counter DC2 and an allocation instruction in the form of a 1-bit data word "1" in the allocation location RAM3 1 "is registered (time I). In elevator a, which is identified by its priority counter PC, which indicates the second priority, the assignment instruction for the second oldest call is deleted and one for the third oldest call is registered from floor E15 (time I). In the case of the elevator c having the third priority, the assignment instruction for the third oldest call is deleted and an assignment instruction for the fourth call is written in from the floor E10 (time I).

After the fifth call from the floor E8 has been written into the floor call memory RAM1 and the data counter reading DC1 = A6, an assignment instruction for the fourth call from the floor E10 is written into the allocation memory RAM3 of the elevator a (time 11). At elevator c, the assignment instruction for this call is deleted and one for the call from floor E8 is entered (time 11).

After the sixth call from the floor E12 has been written into the floor call memory RAM1 and when the data counter DC1 = A7, an allocation instruction for this call is written into the allocation memory RAM3 of the elevator c (time 111).

In the manner described above, call groups can be formed according to the selected example, which, for elevator a, from the allocation instructions for the calls of floors E10, E8, E12, for elevator b from the allocation instructions for the calls of floors E14, E13, E15 and for elevator c consist of the assignment instructions for the calls to floors E9, E11, E7 (time VI).

When serving the floor calls of a call group, the cabin serves the highest call of the group first. This is achieved by counting the coincidences of the leading selector position and the floor calls that do not match in the direction and comparing the sum with the control counter reading, the highest floor of the group being found if the number of coincidences is identical with the control counter reading.

When the control counter reading is reduced, for example because the boarding rate BR is too high, a program for reducing the call groups is called. Here, based on the example described above, when the boarding contents change from B = 3 to, for example, B = 2 for elevator b, the third call is assigned to elevator a, the sixth call assigned to this being assigned to elevator c. The ninth call contained in the call group of the elevator c is deleted by deleting the corresponding assignment instruction, but remains in the waiting list RAM4. After completing the call group conversion, the data counter DC1 is decremented by one position to the status DC1 = A9. The call groups now consist of the assignment instructions for calls from floors E15, E10, E8 for elevator a, the assignment instructions for calls to floors E14, E13 for elevator b and the assignment instructions for calls for floors E12, E9 for elevator c , E11. After all calls of the waiting list RAM4 have been dealt with, the call identified by the data counter reading DC = A9 from the floor E7 is written into the waiting list RAM4 under the address DC = A1. Thereafter, the calls stored in the transmission device 12 can be released for input into the microcomputer system 5 and the waiting list RAM4 can be refilled.

gegeben, wobei

die Kabinenumlaufzeit in Sekunden bedeutet, und wobei im einzelnen

• n die Anzahl der Kabinen in der

Aufzugsgruppe,

• L die Anzahl Aussteiger im Erdgeschoss,
• h die Stockwerkshöhe,
• v die Fahrgeschwindigkeit einer Kabine,
• F die Anzahl Stockwerke über Erdgeschoss,
• B die Anzahl der Zusteigehalte über

Erdgeschoss und

• t den Zeitverlust pro Halt einer Kabine

bedeuten.4 shows the boarding contents B of the cabins of the elevator group on the horizontal axis and the conveying capacity HC of the elevator group in persons per minute on the vertical axis. The relationship between the delivery rate HC and the boarding levels B is shown by means of the characteristic curves HC and by the relationship

given where

means the car round trip time in seconds, and in particular

• n the number of cabins in the

Elevator group,

• L the number of dropouts on the ground floor,
• h the floor height,
• v the driving speed of a cabin,
• F the number of floors above ground floor,
• B the number of boarding stops above

Ground floor and

• t the loss of time per stop in a cabin

mean.

gegeben, wobei die Buchstaben die gleiche Bedeutung wie bei der Förderleistung HC nach der ersten Gleichung G1.1 besitzen. In der dritten Gleichung G1.3, mittels welcher die Wartezeit W für den oberen Belastungsbereich der Kabinen errechnet werden kann, ist der Faktor F/B eine Häufigkeitszahl, die bei einer gewählten Anzahl B Zusteigehalte angibt, wieviel Umläufe nötig sind, um alle Stockwerke F über Erdgeschoss zu bedienen. Mit BR sind Linien gleicher Zusteigeraten des Förderleistungs-Kennlinienfeldes bezeichnet, wobei unter Zusteigerate die durchschnittliche Anzahl zusteigende Personen bei einem Zusteigehalt zu verstehen ist.On the vertical axis, the average waiting time W of a passenger to get into the cabin, the return time T to the ground floor and the average system time D that the passenger spends in the elevator system until they get out are plotted in seconds. The relationship between these times and the boarding levels B is shown by means of the characteristic curves W, T and D and by the equations

given, the letters have the same meaning as for the delivery rate HC according to the first equation G1.1. In the third equation G1.3, by means of which the waiting time W for the upper load range of the cabins can be calculated, the factor F / B is a frequency number which, for a selected number B of boarding steps, indicates how many round trips are necessary to cover all floors F to operate via ground floor. BR is used to denote lines of the same rate of boarding in the performance characteristic field, the rate of boarding being understood to mean the average number of people boarding at a boarding rate.

und dessen Gleichsetzung mit Null wie folgt ermittelt:

The number of B boardings at which the average system time D reaches a minimum is determined by the formation of the differential quotient

and its equation with zero is determined as follows:

The characteristic curves HC, W, T and D of FIG. 4 were based, for example, on an elevator group which, in four cabins with a driving speed of v = 2.5 m / s and a maximum number of exits of L = 13 people, twelve floors above the ground floor served. The various characteristic curves HC relate to the conveyance capacities HC with L = 2, 3, 4, 6, 8, 10, 12 and 13 dropouts. The characteristic curves W, T and D are shown for L = 13 dropouts. In the case of smaller numbers of dropouts, characteristic curves W, T and D deviate downwards, the characteristic curves for the waiting time W and the system time D being ascertainable as described below with reference to FIGS. 5 and 6.

besitzt.In Fig. 5, the boarding levels B of the cabins of the elevator group are plotted on the horizontal axis and the car round trip time RTT and the average waiting time W of a passenger until entering the cabin are plotted in seconds on the vertical axis. The relationship between the cabin round trip time RTT and the boarding hold B is given by the second equation Eq. 2 and represented by means of the characteristic curves RTT ₃ , RTT ₆ and RTT ₁₂ for L = 3, 6 and 12 dropouts. BR denotes straight lines of the same boarding rate, with the boarding rate, as in the case of the conveying capacity characteristics according to FIG. 4, to be understood as the number of people boarding at a boarding rate. The straight lines BR intersect at a point P1 which, at B = 0, has the ordinate RTT = according to the second equation Eq

owns.

gesetzt werden kann. Mit RTT =

The relationship between the average waiting time W and the boarding hold B is given for twelve dropouts by the third equation Eq. 3 and represented by the characteristic curve W ₁₂ . Assuming that, similarly to the RTT characteristics of the cabin round trip time, straight lines BR 'with the same rate of ascent of a waiting time characteristic field also intersect at one point, further characteristic curves for fewer dropouts can be determined graphically from the W ₁₂ characteristic curve for twelve dropouts. For example, the intersection of the boarding levels B = 1,2,3,6 and the straight line BR '= 6,3,2,1 give the characteristic curve W ₆ for six dropouts. The ordinate of the intersection designated P2 the straight BR 'results from the consideration that only one dropout approximates

can be set. With RTT =

at B = 0, the ordinate of point P2 is W =

besitzt. Es ist jedoch auch möglich, die Systemzeit D bei kleineren Aussteigerzahlen L rechnerisch zu ermitteln, indem in die fünfte Gleichung Gl.5 die gemäss Fig. 5 graphisch ermittelten Wartezeiten W eingesetzt werden. Die Minima D_mi_n der Systemzeit-Kennlinien liegen auf einer Geraden m, welche unter einem spitzen Winkel zur Zeitachse verläuft. Hieraus ist ersichtlich, dass die optimale Anzahl Zusteigehalte B in Abhängigkei der Anzahl Aussteiger L einen Bereich von ein bis vier Zusteigehalte umfasst.6, the boarding levels B of the cabins are again plotted on the horizontal axis, while the vertical axis is assigned to the system time D in seconds. D ₁₃ denotes the system time characteristic for thirteen dropouts according to the fifth equation Eq. 5. Other system time characteristics 0 ₁₂ , D ₁₀ , D ₈ , Ds, D ₄ , D ₃ , D ₂ for L = 12, 10, 8, 6, 4, 3 and 2 dropouts are similar to the waiting time characteristics according to Fig. 5 determined by straight lines BR of the same boarding rates, the straight lines BR intersecting at a point P3 which, at the boarding level B = 0 according to the fifth equation Eq. 5, the ordinate D =

owns. However, it is also possible to calculate the system time D for smaller numbers of dropouts L by inserting the waiting times W graphically determined according to FIG. 5 into the fifth equation Eq. The minima D _m i _{n of} the system time characteristics lie on a straight line m, which runs at an acute angle to the time axis. It can be seen from this that the optimum number of boarding stops B, depending on the number of dropouts L, ranges from one to four boarding stops.

worin L_max die Nennlast der Kabine bedeutet. Ist nun beispielsweise die im Mikrocomputersystem 5 (Fig. 1) errechnete und gespeicherte Zusteigerate BR = 3,2, so wird gemäss der neunten Gleichung Gl.9 die durchschnittliche Anzahl Aussteiger L' = 11,4. Mit Hilfe der ersten fünf Gleichungen Gl.1 bis Gl.5 können nun die Förderleistung HC, die Wartezeit W und die Systemzeit D bei der Zusteigehaltzahl B = 3,6 ermittelt werden (Punkte P4, P5 und P6, Fig. 4).When designing the control of such an elevator system, the calculation bases described above result in a number of boarding steps B = 3.6 per car initially determined according to the seventh equation Eq. Assuming that the maximum number of dropouts L can be expected in the case of downward peak traffic in 50% of all trips and that the last boarding level B is omitted for the remaining trips, so that the maximum number of dropouts L is reduced by a boarding rate BR Number of dropouts too

where L _{max is} the nominal load of the cabin. If, for example, the boarding rate BR = 3.2 calculated and stored in the microcomputer system 5 (FIG. 1), then according to the ninth equation Eq. 9 the average number of dropouts L '= 11.4. With the help of the first five equations Eq. 1 to Eq.5, the delivery rate HC, the waiting time W and the system time D can be determined at the ascent rate B = 3.6 (points P4, P5 and P6, Fig. 4).

With the boarding number B = 3.6, the control counters CC of the circuits 14 of the elevators 2, b, c may be set to B = 4 via the party line transmission system 8 (FIG. 1). Since, as assumed above, the average boarding rate BR = 3.2, the expected arrival load L _max of thirteen people is not exceeded, so that the number of boarding stops B = 4 and thus the number of floor calls allocated per cabin for the further course of the control process can be maintained. If an average boarding rate of, for example, BR = 3.6 is determined, the maximum permissible arrival load L of thirteen people would be exceeded with four boarding stops. In this case, by calling up a corresponding program in the microcomputer system 5, the status of the control counter CC is reduced to an ascent rate B = 3, which is also in the minimum range of the system time D, the conveying capacity HC being improved, the waiting time W increasing only slightly and the system time D somewhat is reduced (points P4 ', P5' and P6 ', Fig. 4).

If the control system is designed without taking into account the relationships described above and the number of boarding stops is empirically determined to be, for example, B = 3, then with reference to the above example, the boarding capacity is not fully utilized with a boarding rate of BR = 3.2 and the delivery rate is correspondingly lower (point P7, Fig. 4). With a boarding rate of 5, for example, only two boarding stops are possible, so that the third floor call assigned is overrun.

Claims (6)

1. Group control for lifts with an equipment for the control of the peak downward traffic, by means of which equipment the floor calls, which are to be allocated to each cage (4) of the lift group, in downward direction are limitable to a predetermined number, characterised thereby,

- that the equipment for the control of the peak downward traffic displays a switching circuit (14) with a check counter (CC), in which the predetermined number of downward floor calls is stored, for each cage (4),

- that a waiting list (RAM4), in which the downward floor calls are stored in the sequence of input, is provided in the switching circuit (14),

- that the switching circuit (14) is connected with an allocation store (RAM3), which displays storage places, which are associated with the storage spaces of a floor call store (RAM1) and in which call groups are formed through storage of allocation instructions limited to the check counter state, wherein the allocation instructions are associated with successive downward floor calls of the waiting list (RAM4).

- that the switching circuit displays a priority counter (PC) and that in the case of n lifts and on the storage of the nth call in the waiting list (RAM4), the respective oldest call one after the other has through storage of an allocation instruction that cage (4) allocated to it, which can serve this most rapidly, wherein the priority counter (PC) of the cage (4) concerned is settable to a priority number corresponding to the age of the call, and

- that on the arrival of further calls, the call groups are increased by one call one after the other in sequence of priority in such a manner that the respective oldest call of a call group is transferred into the call group of the cage of next higher priority and the youngest call is allocated to the call group of the cage of lowest priority, wherein respective call groups of equal extent are producible until the check counter state is reached.

2. Group control for lifts according to claim 1, characterised thereby,

- that the switching circuit (14) is connected with a computer and each cage displays a load- measuring equipment (15) connected to the computer (15), wherein the computer for each boarding halt calculates the difference between arrival and departure load and determines a mean boarding rate (BR) through formation of the arithmetic mean of the load differences of the last boarding halts,

-that a storage space (RAM5) is provided, in which the mean boarding rate (BR) is stored, and

- that the switching circuit (14) is connected - with a comparator which compares the product of the mean boarding rate (BR) and the number of boarding halts (B) indicated by the check counter (CC) with a limit value, wherein on this being exceeded, the number of boarding halts (B) indicated by the check counter (CC) is reduced.

3. Group control for lifts according to claim 1, characterised thereby, that the waiting list (RAM4) is a read-write store, in which addresses, associated with the floors, of the downward floor calls are recordable, wherein a data counter (DC1) for the addressing of the storage places of the waiting list (RAM4) is provided.

4. Group control for lifts according to claim 1, characterised thereby, that the allocation store (RAM3) is a read-write store and the allocation instructions are 1-bit data words.

5. Group control for lifts according to the claims 2 to 4, characterised thereby, that the computer and the comparator are formed by a microcomputer system (5), in which the waiting list (RAM4), the allocation store (RAM3), the check counter (CC), the priority counter (PC) and the data counter (DC1) are integrated.

6. Group control for lifts according to claim 1, characterised thereby, that the determination of the certain number, which is stored in the check counter (CC) of downward floor calls or boarding halts (B) for each cage takes place according to the relationship

wherein F signifies the number of floors above the ground floor,

n the number of the cages of the lift group,

h the floor height,

v the speed of travel of a cage,

t the loss of time for each halt of a cage and

L signifies the number of persons alighting on the ground floor.

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