EP1367018A2 - Elevator system with a plurality of self-moving cabins and at least three parallel shafts - Google Patents

Abstract

The system has a number of individually driven cabins, first and second vertical elevator shafts (10,12) with entrances (14) and a storage shaft (11) between them enabling movement of cabins between shafts, a control system and a drive arrangement. The elevator shafts are arranged with entrances in a plane. The control system and drive arrangement can move empty cabins through transitions to make them available in the shafts as required. AN Independent claim is also included for the following: (a) a method of operating an inventive elevator system.

Description

The invention relates to a lift with mehereren self-propelled Cabins and at least three juxtaposed, vertical elevator shafts and a method for Operating such a lift.

There are various approaches to the arrangement of elevator shafts an elevator system. Some examples are in the Figures 1A - 1D shown in a schematic plan view.

In FIG. 1A, two vertical elevator shafts are 1 and 2 shown, which are arranged side by side. In each of the both shafts 1 and 2 moves at least one elevator car 3 up or down. Each slot 1, 2 has one Shaft door 4.

FIG. 1B shows a further arrangement, which in turn two vertical elevator shafts 5 and 6, the are arranged side by side. Each of the elevator shafts 5 and 6 has two in the direction of the shaft depth arranged shaft areas. An elevator car 3, which is in front of one of the shafts 5, 6 moves (as in left slot 5 shown), operates the bay doors 4. One Elevator car 3, located in the rear of one of Shafts 5, 6 moved (as shown in the right shaft 6), does not provide access to any of the landing doors 4. It can be several elevator cars 3 in circulation.

Japanese Patent Application Publication No. JP 6080324 shows an arrangement with two adjacent ones Wells, similar to those shown in FIG. 1B. Different to In FIG. 1B, each of the manholes points in the direction of Shaft depth three successive shaft areas on. Only the front shaft area has access to the shaft doors, similar to Figure 1B. An extension of the concept of Figure 1B is the Japanese patent application with the publication number JP 6080352. In Direction of the shaft depth has the arrangement according to JP 6080352 several shaft areas and horizontal or inclined running transitions on. Bay doors are located both in the front shaft wall (as in Figure 1B), as well as in the rear shaft wall. The elevator cars need therefore on two opposite sides access openings exhibit.

Another arrangement is shown in Figure 1C. These Arrangement has a vertical elevator shaft 7. Left and right in this elevator shaft 7 elevator cars can 3 are moved up or down. In the middle shaft area 9 no shaft doors 4 are provided. There can be two Promotion approaches are distinguished, resulting in a let realize such a shaft 7. Either the middle shaft area 9 only to change the elevator cars 3 from left to right, or vice versa, or the central area 9 also becomes vertical Transport and / or storage of the elevator cars 3 used.

U.S. Patent 3,658,155 discloses an arrangement described, which is comparable to the variant in Figure 1C is. According to this US patent, the middle Area between the left shaft area and the right one Shaft area for temporary parking of the elevator cars used. The elevator cars move along a central conveyor. An elevator car can be uncoupled and parked in the middle area.

Japanese Patent Application Publication No. JP 09077418 shows an arrangement with three side by side lying shaft areas, similar to that shown in Figure 1C. The left shaft area is for uphill and the right shaft area used for downward driving. Of the middle manhole area is for fast downhill driving used, but has no shaft doors to Ein- and Get off. Behind the three adjacent ones Shaft areas are located at the shaft head and at Manhole foot each a cross connection shaft for changing over the cabins between the three vertical shaft areas. The elevator cabins are located in the right and left shaft area moved together in the vertical direction. In the middle shaft area is a self-sufficient vertical movement possible.

Japanese Patent Application Publication No. JP 2000185885 shows an arrangement with four side by side lying shaft areas, similar to that shown in Figure 1C. One major difference is that the Shaft areas arranged individually and only at an angle extending transition points are connected.

A variant of the arrangement shown in FIG. 1C is in FIG Figure 1D indicated. The shaft 7 has three full-fledged Shaft areas that lie next to each other. Not only that Left and right shaft area have landing doors 4 on, but the middle shaft area also has landing doors 8th.

What distinguishes the drive of the elevator cars 3 is different one two basic approaches. Either the elevator cabins 3 in common at least in the vertical direction promoted, or the cabins can be moved individually become. The latter approach results in an additional Flexibility.

It is a disadvantage of some of the known well arrangements, that the elevator cars when transferring from a Lane to another, or when switching from one to another Elevator shaft in the other elevator shaft. Transverse accelerations subject to passenger occupied elevator cars. Such lateral accelerations are for the passengers uncomfortable. Also, such is Over transfer associated with strong shocks, which as can be distracting. These factors can be one Uncertainty of passengers cause, especially the passenger is in a closed cabin and no Visual contact or reference to the outside has.

Other arrangements, in turn, have a relatively large size Required space, without the transport performance significantly increase, or the construction costs are large. Some of the known arrangements require stops and / or Shaft doors on several side walls of a shaft. The is expensive from a construction perspective. In addition, the Passengers may change direction or when changing, go around one shaft to another Enter elevator car.

It is a task in view of the known arrangements the present invention, an elevator system and a to provide the corresponding method that has the disadvantages reduced or completely avoided by the prior art.

It is in particular a task, an elevator system and a to provide appropriate method in which the passengers are not distracting Influences are subject.

The solution of the task is done by the features of Claim 1 and by the features of claim 10.

Advantageous developments of the elevator system according to the invention are dependent on the dependent claims 2 to 9 and defined by the dependent claims 11 to 16.

Fig. 1A - 1D

schematische Draufsichten verschiedener bekannter Aufzugssysteme;

Fig. 2

eine schematische Frontansicht eines ersten Aufzugssystems gemäss Erfindung;

Fig. 3

eine schematische Schnittansicht des ersten Aufzugssystems gemäss Erfindung;

Fig. 4

eine schematische Seitenansicht eines Ausschnitts des ersten Aufzugssystems gemäss Erfindung;

Fig. 5

eine schematische Schnittansicht eines weiteren Aufzugssystems gemäss Erfindung;

Fig. 6A - 6B

schematische Seitenansichten eines Ausschnitts eines weiteren Aufzugssystems gemäss Erfindung;

Fig. 7

eine schematische Schnittansicht eines weiteren Aufzugssystems gemäss Erfindung.

In the following the invention will be described in detail by means of embodiments and with reference to the drawing. Show it:

Fig. 1A - 1D

schematic plan views of various known elevator systems;

Fig. 2

a schematic front view of a first elevator system according to the invention;

Fig. 3

a schematic sectional view of the first elevator system according to the invention;

Fig. 4

a schematic side view of a section of the first elevator system according to the invention;

Fig. 5

a schematic sectional view of another elevator system according to the invention;

Figs. 6A-6B

schematic side views of a section of a further elevator system according to the invention;

Fig. 7

a schematic sectional view of another elevator system according to the invention.

A first embodiment of the invention is related described with Figures 2 and 3. It is an elevator system shown the three side by side vertical Lift shafts 10, 11 and 12 has. There will be a total of five floors served 13.1 - 13.5. Inside the elevator shafts 10, 11 and 12 are several individually powered elevator cars 16 (see Figure 3). The two Outside arranged elevator shafts 10 and 12 have Access openings 14 on, all in one through the Lying on the plane of the drawing. The access openings 14 are usually provided with shaft doors. Of the arranged in the middle elevator shaft 11 serves as vertical depository shaft and has transitions 15 (e.g. of bushings), which is a shifting of the elevator cars 16 between two adjacent elevator shafts enable. An elevator car 16 can for Example through a passage 15 from the elevator shaft 10 or from the elevator shaft 12 in the depository shaft 11th to be moved. The elevator cars 16 can also from the Depot shaft 11 in one of the two outer elevator shafts 10 or 12 are moved.

According to the invention elevator cars 16 in a first the two outer elevator shafts (for example in the elevator shaft 10) provided if a request call for an upward drive in the elevator control received. If a request call for a downward journey enters, one of the elevator cars 16 in the second of two outside arranged elevator shafts (for example in Elevator shaft 12) are provided. The plant is like that designed that a change of an empty elevator car 16 from one of the two outer elevator shafts 10, 12 in the middle arranged Depotschacht 11 only takes place when the elevator car 16 is empty. Empty elevator cabins 16 are deposited in the depository shaft 11. The Elevator control is preferably designed so that a Demand-dependent provision of empty elevator cars 16 he follows. For this purpose, empty elevator cars 16 in the depository shaft 11 in waiting positions in the area of Transitions 15 deposited to be in case of a request call to enable a quick deployment.

It was for the elevator system a rectangular floor plan chosen, since this arrangement of the three elevator shafts 10, 11, 12 a good capacity with acceptable space utilization guaranteed.

According to another embodiment, each of the elevator cars 16 a self-sufficient, cabin-side linear drive 21, 22, which allows the elevator cars 16 independently in the vertical direction in the vertical elevator shafts 10, 11, 12 to move. Such a system is in FIG. 4 shows a section through the elevator shaft 10 shows. At the rear shaft wall 20 is a non-energized driving part 23 (e.g., the secondary part a linear motor drive) arranged at which the Linear drive 21, 22 moves along. The linear drive 21, 22 has a drive, which allows the Linear drive 21, 22 to control so that this one Upward or downward travel of the elevator car 16 in causes the corresponding elevator shaft. The control the linear drive 21, 22 takes place under consideration a request call, for example, by pressing a call button can be triggered.

In a further embodiment, an elevator car 16 an additional drive on to the elevator car 16th automatically in the horizontal direction from an elevator shaft 10 or 12 in the depot shaft 11 in or out to move the depository shaft 11 out.

Alternatively, the existing linear drive 21, 22, the vertical movement of the elevator cars 16 is used so be pivoted, that this linear drive 21, 22 also for effecting horizontal displacement between adjacent ones Elevator shafts can be used. Preferably takes place this panning together with a panning of one Section of the non-energized drive part 23, since the sole pivoting of the linear drive 21, 22 a release of the linear drive 21, 22 from the non-energized drive part 23 would be necessary. Such a release is consuming, as enormous adhesive forces between the linear drive 21, 22 and the non-energized drive part 23 prevail.

According to another embodiment of the invention the elevator system has a control system 40 as shown in FIG 5 schematically shown. The control system 40 is so designed to use a so-called demand profile is to provide the demand-dependent provision of empty elevator cars 36.1 - 36.3. Such a demand profile can be fixed, or it can be dynamic to adjust. Preferably, the demand profile is in one Memory 38 stored. Particularly suitable is a demand profile, given the certain basic requirement pattern are, however, by watching the daily Develop elevator operation automatically.

A simple example should clarify this. At a Elevator system in an office building fall at the start of work numerous ascents to the various offices at. The demand profile is according to the invention designed that several empty elevator cabins 36.1 - 36.3 in be deposited at the bottom of the depository 31, so enough empty elevator cars 36.1 - 36.3 for the upcoming Uphill rides ready. In the evening or at work are several empty elevator cars 36.1 - 36.3 im used upper and middle shaft area, as numerous Passengers leave their offices and head towards the ground floor 13.2 or underground car park 13.1. An automatically adapting Control system 40 may consider, for example, that there are differences in passenger behavior between summer and winter can give. It is also conceivable that the Requirements profile during the vacation-absence so adjusts that in the morning is recorded how many ascents were requested, then on the same day in the evening possibly less lift cabins 36.1 - 36.3 than usual provide.

The elevator system according to the embodiment shown in FIG has three juxtaposed elevator shafts 30, 31, 32, of which the middle shaft as vertical depot shaft 31 is used. In the example shown there in the area of the lowest floor 13.1 (underground car park), in the Floor 13.3 and the top floor 13.5 Transitions 35 which are a displacement of the elevator cars 36.1. 36.3 between two adjacent elevator shafts 30, 31, 32 allow. The control system 40 includes in the example shown, a memory 38, for example Needs profile (s). On each of the floors 13.1 - 13.5 there is a panel 41.1 - 41.5 with the Need one of the elevator cars 36.1 - 36.3 requested can be. In the embodiment shown, the Panels 41.1 - 41.5 via a communication link 37 with connected to the control system 40. Each of the elevator cabins 36.1 - 36.3 has a control unit 39, the over Communication links 42.1 - 42.3 with the central Control system 40 of the elevator system can be connected. The Components 37, 38, 40 39, 41.1 - 41.5, 42.1 - 42.3, and 43 are referred to collectively as elevator control. The Communication links 37 and 42.1 - 42.3 are shown in FIG 5 only shown schematically. Usually it is at the communication links 37 and 42.1 - 42.3 order Bus connections or parallel wiring.

After a request call, for example, by pressing the up button on the panel 41.1 was triggered, this is Request call via the communication links 37 the control system 40 transmitted. The control system 40 selects an elevator car 36.3 located near the Floor 41.1 is located and it is empty. About the communication connection 42.3 instructs the control system 40 the control unit 39 of the elevator car 36.3. This can For example, by the control system 40 of the Control unit 39 of the elevator car 36.3 a requirement profile then transfers that from the control unit 39 is independently implemented. In this case, the Control unit 39 can be designed to be intelligent To be able to carry out the requirement profile independently. In In another embodiment, the control units 39 are subordinate to the control system 40 and therefore need less expensive to interpret.

The control unit 39 activates and controls the self-sufficient Linear drive of the elevator car 36.3 so that they are different from the depository shaft 31 in which it is located according to FIG. 5, through the passage 35 in the left elevator shaft 30 moves, which is intended for upward travel. The Elevator car 36.3 then stops independently at the floor 41.1, from which the request call was made to there the cabin doors (if any) and landing doors to open. After the passenger the elevator car 36.3 enter and a floor button on the cabin panel 43 in the Cab has pressed, close the doors and the Elevator car 36.3 is set in motion. At the desired Destination floor stops the elevator car 36.3 to the Passenger to get off. After that, the moves Elevator car 36.3 through the nearest passage 35 back to the depository shaft 31 if the control system 40 the control unit 39 of the elevator car 36.3 a corresponding Request profile. Otherwise can the elevator car 36.3, for example, in the elevator shaft 30th remain until a new requirement profile of the Control system 40 passed to the control unit 39 becomes.

• Vermeiden von Kollisionen der Aufzugskabinen 36.1 - 36.3;
• bedarfsabhängiges Bereitstellen der Aufzugskabinen 36.1
• 36.3 in den Aufzugsschächten 30, 32;
• bedarfsabhängiges Bereitstellen der Aufzugskabinen 36.1 - 36.3 im Depotschacht 31;
• Richtungsumkehr in den Aufzugsschächten 30, 31, 32;
• Sonderverkehr im Wartungsfall oder bei anderen Störungen, usw.

It is obvious that there are different variants of the elevator control that can be implemented in such an elevator system. Preferably, the control system 40 maintains some authority over the control units 39 of the elevator cars 36.1-36.3. This is advantageous for the following reasons:

• Avoiding collisions of elevator cars 36.1 - 36.3;
• Dependent provision of the elevator cars 36.1
• 36.3 in the elevator shafts 30, 32;
• demand-dependent provision of the elevator cars 36.1 - 36.3 in the deposit shaft 31;
• Direction reversal in the elevator shafts 30, 31, 32;
• Special traffic in case of maintenance or other malfunctions, etc.

According to a further embodiment of the invention that is Elevator system designed so that before performing a Change of an elevator car from one of the shafts into one another shaft is checked, whether the appropriate Elevator car is empty. For this purpose, sensors can be used in or attached to the elevator car. Only then stops the elevator car at the height of a passage and the Chute change is initiated and executed.

Another embodiment according to the invention is in the Figures 6A and 6B shown as a side view. The elevator car 56 carries on a lower suspension 59 a lower one Roller pair 57 (only one of the wheels of the roller pair 57 is can be seen in the figure). Another pair of rollers 58 is diagonally opposite to an upper edge of the elevator car 56 stored (only one of the wheels of the roller pair 58th can be seen in the figure). These pairs of rollers 57, 58 lead the elevator car 56 along the guide rails 53rd and 55. For this purpose, the pairs of rollers 57, 58 possibly be provided with flange, so a guide in Movement direction is guaranteed. Preferably the cabin-side drive (not in Figures 6A, 6B shown) on the rear side 66 of the elevator car 56 arranged. This eccentric arrangement of the drive on the cab rear 66 leads to a torque (as in 6A indicated by the arrow 67), so that the Storage of the elevator car 56 only the two roller pairs 57, 58 are necessary. This torque acts clockwise and is so big in every driving situation that the roles of the Roller pairs 57, 58 are loaded on pressure. The torque arises from the power of the cab-side drive and off of gravity.

When performing a change of the elevator car 56 of an elevator shaft 50 into an adjacent shaft, The following steps are performed after the Elevator car 56 is empty and at a predetermined position was stopped in the elevator shaft 50. This condition is shown in FIG. 6A. To the elevator car 56 in the to move adjacent bay, the Elevator car 56 with horizontal guide element 62, 64 in Brought in contact. For this purpose are at the elevator car 56th Engagement elements 63, 65 are provided. The horizontal Guide elements 62, 64 are located in the area of one Passage. The engagement member 63 in Figure 6A is about the lower cabin edge postponed and the elevator car 56 slightly lowered so that these are over the engagement element 63 is supported on the guide element 62.

From the supporting force and the weight of the elevator car 56 results in a torque which the elevator car 56th about a lying at the elements 62, 63 fulcrum against tilts clockwise (as indicated by arrow 68 in FIG. 6B indicated) until it with its engagement element 65 on Guide element 64 is present. As a result of this tilting movement the guide rollers 57, 58 are disengaged (contact) with the guide rails and the elevator car 56 can be moved horizontally.

This tilting movement is preferably by eliminating the Torque (arrow 67), which emanates from the drive. If the drive is turned off, this torque is eliminated and the elevator car 56 tilts due to its own weight counterclockwise, as shown in Figure 6B. The However, tilting movement can also be due to mechanical or electro-mechanical Be created or supported.

The re-erection of the elevator car 56 after a horizontal displacement can be achieved by generating a Upward force in the cabin-side drive done.

Due to the slight tilting of the elevator car 56 are the Rolls of the lower pair of rollers 57 to the right of the Guide rail 53 moves away. At the same time that moves upper roller pair 58 to the left of the guide rail 55th path. In other words, the two pairs of rollers 57, 58 of Elevator car 56 are by tilting from the shaft side attached guide rails 53, 55 away. While tilting, the engagement member 63 makes contact with an executed as an elongated angle iron horizontal Guide element 62 ago. In the concrete example that is Engaging member 63 on a horizontal leg of the Guide element 62 on. The diagonally opposite attached engagement member 65 makes contact with the Guide element 64 ago by it against this element 64 is pressed.

After the tilting is completed, the pairs of rollers 57, 58 no leadership function anymore. The elevator car 56 can now along the guide elements 62, 64 perpendicular to the longitudinal direction of the elevator shaft 50 (i.e. Drawing plane in, or out of this plane).

The embodiment shown in FIGS. 6A and 6B offers different advantages. In a cab-bound drive Usually there is the problem that the driving force outside the cabin's center of gravity attacks. This can be too tilting the elevator car cause jerky Can trigger movements while driving. The herein proposed embodiment converts this disadvantage an advantage around because the drive torque during the ride is used to the pairs of rollers 57, 58 to press against the guides 53, 55. Once the executives can no longer be used, these forces be canceled by switching off the drive. This allows easy release of the pairs of rollers 57, 58 of the Guides 53, 55. The chosen type of guidance is the vertical ride despite the eccentric drive very much comfortable. The leadership of the elevator car 56 and the Change from shaft to shaft comes in accordance with the invention relatively few moving parts. That's the solution robust and cost-effective.

Moving the elevator car 56 along the guide elements 62, 64 may by the elevator car 56 itself done by a drive of the cabin ensures, or the Displacement can be done by (funding) means, which are in the Area of implementation are located in the elevator shaft.

In a further embodiment, the production takes place the contact between elements on the elevator car and Guide elements in the elevator shaft by mechanical or electro-mechanical means. In this case, no need Tilting movement of the elevator car to be executed because by the mechanical or electro-mechanical means both the separation of the roller pairs from the guide rails, as well as the production of the contact accomplished can be.

Another embodiment is characterized in that before shutting off the cab drive a slider or a similar means (e.g., the engaging member 63) on the Elevator car 56 is extended to a shaft side Antidote (e.g., guide member 62) in contact to step. This agent may be designed to be a slump of the elevator car 56 prevents and / or it serves as a rotation axis for the tilting movement to be performed.

In a further embodiment, which in Figure 7 schematically is shown, are at least four elevator shafts 70 - 72 and 77 are present, of which at least one elevator shaft 77 is provided for long-distance trips. Preferably, there is a lift shaft for long-distance trips in the upward direction (e.g., the elevator shaft 77) and a lift shaft for long-distance travel in the downward direction. These elevator shafts (e.g., the hoistway 77) can serve as a fast lane. Delays on long-distance trips can be avoided as far as possible.

The number of transitions 74 to the long-distance shafts 77 may be less than the number of transitions 75 between the elevator shafts 70, 72 and the depository shaft 71, since in these long-distance shafts 77, like the name already expressed, preferably only traveled long distances become. A change from a hoistway 77 for Long distance trips to another elevator shaft 72 takes place only after a long-distance journey has ended, So for example on the top floor 73.10 or at lowest floor 73.1. It is an advantage of the arrangement with long-distance shafts, that time-consuming long-distance trips not by waiting in the first floor 73.1 Elevator cabs 76.2 be hampered. Short journeys are preferably in the two elevator shafts 70 and 72nd executed, between which the vertical depot shaft 71 is arranged. With this arrangement, the elevator cars can 76.1 and 76.3 immediately after an order has been completed is transferred to the depository shaft 71.

In the example shown, two elevator cars 76.1 are in Elevator shaft 70 in the upward direction and two elevator cars 76.3 in the elevator shaft 72 traveling in the downward direction. Six elevator cars 76.2 are located in the depository shaft 71. An elevator car 76.4 moves in fast long-distance travel in the elevator shaft 77 upwards.

Instead of a self-sufficient cabin-side linear drive the elevator cars can also be equipped with a friction wheel drive, Gear drive, rack drive or the like provided be.

The arrangement according to the invention is particularly advantageous because they are based on a combination of two essential parameters based. The parameters are supported in the claimed Arrangement especially. For one, the vertical offers Depot shaft has the merit of unused elevator cabins can be removed from the shaft traffic. The vertical execution and arrangement of the depot as medium Schacht needs little space. These can be the transitions between the elevator shafts and the depot shaft so be arranged that every floor within a given time is reached. The elevator cabins can also distributed and provided away from passenger traffic become.

The vertical deposit slot offers the advantage of having additional Elevator cabs are stowable in the elevator system, the can be requested if necessary. Also, according to Invention of one-way operation will continue indefinitely as always elevator cars provided from the depot shaft can be. Linger empty elevator cabins preferably only as long as just needed in the vertical Elevator shafts.

The inventive arrangement provides a high level of comfort for the passengers as shakes are avoided and the passengers are not exposed to lateral acceleration.

According to the invention, all shaft doors are in a single arranged vertically. This will be rides of the Elevator cabins in the direction of the normal to this plane avoided. Transverse accelerations of loaded elevator cars are also avoided by the fact that the elevator cars only in the empty (unloading) state a change of one Run shaft to another shaft.

According to the invention, the directions of travel in each shaft be specified. Preferably, one of the shafts exclusive for uphill and another shaft for downhill driving reserved.

It is according to the invention an arrangement and a method provided good services at a reasonable price allow construction costs. The invention offers a great flexibility, because in case of need at different Make empty elevator cabins are provided can.

The more transitions between adjacent elevator shafts be provided, the more flexible the traffic concept the elevator system are designed.

According to the invention, one of the elevator shafts (preferably the middle shaft) as alternative and depot shaft. This elevator shaft does not need to have accesses.

The use of a depository has the advantage that only in each case the currently required number of elevator cars in Circulation must be kept. This has for example one Influence on the entire energy balance of an elevator installation. In addition, the wear is reduced because the elevator cars are not constantly in use.

Advantages of the invention are that the shaft cross-sectional area at the same traffic as at a conventional shaft arrangement considerably reduced. The waiting times in front of the elevator shafts and the dwell time in the elevator cars is shorter by the invention. The Construction costs can be compared to traditional approaches be lowered.

Claims (16)

Method for operating an elevator installation with three vertical elevator shafts (10, 11, 12, 30, 31, 32, 70, 71, 72, 77) arranged side by side and a plurality of individually driven elevator cars (16, 36.1-36.3, 56, 76.1) 76.4), wherein the two outer elevator shafts (10, 12) have access openings (14) which lie in one plane, and the elevator shaft (11, 31, 71) arranged in the middle has transitions (15, 35, 74, 75). which permit a displacement of the elevator cars (16; 36.1-36.3; 56; 76.1-76.4) between two adjoining elevator shafts (10, 11, 12; 30, 31, 32; 70, 71, 72, 77),
the method comprising the following steps: a) providing one of the elevator cars (16; 36.1-36.3; 56; 76.1-76.4) in a first of the two outer elevator shafts (10; 30; 70) if a request call for an upward journey is received, b) providing one of the elevator cars (16; 36.1-36.3; 56; 76.1-76.4) in the second of the two outer elevator shafts (12; 32; 72) if a request call for a downward travel is received. c) carrying out a change of an empty elevator car (16, 36.1-36.3, 56, 76.1-76.4) from one of the two outer elevator shafts (10, 12, 30, 32, 70, 72) into the elevator shaft (11 31; 71) for depositing the empty elevator car (16; 36.1-36.3; 56; 76.1-76.4) in the elevator shaft (11; 31; 71) arranged in the middle, d) provision of empty elevator cars (16; 36.1-36.3; 56; 76.1-76.4) in the center elevator shaft (11; 31; 71) in waiting positions in the area of the transitions (15; 35; 74, 75) in the case of a request call to allow a fast deployment. Method according to claim 1, wherein each of the elevator cars (16; 36.1-36.3; 56; 76.1-76.4) has a self-sufficient cabin-side drive (21, 22) enabling the elevator cars (16; 36.1-36.3; 56; 76.1-76.4 ) independently in the vertical direction in the vertical elevator shafts (10, 11, 12, 30, 31, 32, 70, 71, 72, 77),
the method comprising the following step: Driving the drive (21, 22) to cause an upward movement or a downward movement of an elevator car (16; 36.1-36.3; 56; 76.1-76.4), depending on the request call. A method according to claim 1 or 2, wherein each of the elevator cars (16; 36.1-36.3; 56; 76.1-76.4) either has a further drive to move the elevator cars (16; 36.1-36.3; 56; 76.1-76.4) independently in a horizontal direction between two elevator shafts (10, 10) arranged side by side. 11, 12, 30, 31, 32, 70, 71, 72, 77), or wherein the drive (21, 22) is designed to move the elevator cars (16; 36.1-36.3; 56; 76.1-76.4) independently in the horizontal direction between two elevator shafts (10, 11, 12; 30, 31, 32; 70 , 71, 72, 77). A method according to claim 1, 2 or 3, wherein the drive is a linear drive and wherein prior to moving an elevator car (16; 36.1-36.3; 56; 76.1-76.4) the following step is carried out: Swiveling the linear drive (21, 22) of the elevator car (16; 36.1 - 36.3; 56; 76.1 - 76.4). Method according to one of the preceding claims, characterized in that the following additional step is carried out: Considering a stored demand profile to enable on-demand provision of empty elevator cars (16; 36.1-36.3; 56; 76.1-76.4). Method according to one of the preceding claims, characterized in that before carrying out a change, the following additional steps are carried out: Stopping the elevator car (16; 36.1-36.3; 56; 76.1-76.4) at the level of a passage (15; 35; 74, 75), Check that the corresponding elevator car (16; 36.1-36.3; 56; 76.1-76.4) is empty. Method according to one of claims 1, 2 or 3, characterized in that before performing a change, the following additional steps are carried out: Establishing contact between engagement elements (63, 65) on the elevator car (16; 36.1-36.3; 56; 76.1-76.4) and horizontal guide elements (62, 64) located in the region of a passage (15; 35; 74, 75). located in the elevator shaft, Tilting the elevator car (16; 36.1-36.3; 56; 76.1-76.4) to remove pairs of rollers (57, 58) of the elevator car (16; 36.1-36.3; 56; 76.1-76.4) from shaft-mounted guide rails (53, 55) , Method according to one of Claims 2 to 7, characterized in that each of the elevator cars (16; 36.1-36.3; 76.1-76.4) has a control unit (39) which, via a communication link (42.1-42.3), has a control system (40) Elevator system is connectable, wherein the method comprises the following further steps: Receiving a request call by the control system (40), Selecting an available elevator car (16; 36.1-36.3; 76.1-76.4), Transmitting control information from the control system (40) via the communication link (42.1-42.3) to the control unit (39) of the available elevator car (16; 36.1-36.3; 76.1-76.4), Actuating the cabin-side drive (21, 22) of the available elevator car (16; 36.1-36.3; 76.1-76.4) by the control unit (39) to move the elevator car (16; 36.1-36.3; 76.1-76.4) to the access openings (14 ) of the floor (13.1 - 13.5; 73.1 - 73.10) from which the request call has been received. Method according to Claim 8, characterized in that the control system (40) carries out software-controlled steps for the traffic-dependent control and provision of the elevator cars (16; 36.1-36.3; 76.1-76.4). Elevator system with a plurality of individually powered elevator cars (16; 36.1-36.3; 56; 76.1-76.4), a first vertical elevator shaft (10; 30; 70) having access openings (14), a second vertical elevator shaft (12; 32; 72) having access openings (14), a vertical deposit shaft (11; 31; 71) disposed between the first vertical elevator shaft (10; 30; 70) and the second vertical elevator shaft (12; 32; 72) and the transitions (15; 35; 74,75). which permit a displacement of the elevator cars (16; 36.1-36.3; 56; 76.1-76.4) between two adjoining elevator shafts (10, 11, 12; 30, 31, 32; 70, 71, 72, 77), a control system (39, 40) and drive means (21, 22), wherein the first elevator shaft (10; 30; 70) and the second elevator shaft (12; 32; 72) are arranged so that the access openings (14) lie in one plane, and
wherein by the control system (39, 40) and the drive means (21, 22) empty elevator cars (16; 36.1 - 36.3; 56; 76.1- 76.4) through the transitions (15; 35; 74, 75) are slidable, and
wherein by the control system (39, 40) and the drive means (21, 22) empty elevator cars (16, 36.1 36.3; 56; 76.1-76.4) in case of need in the first elevator shaft (10; 30; 70) and the second elevator shaft (12; 32; 72) can be provided. Elevator installation according to claim 10, characterized in that each of the elevator cars (16; 36.1-36.3; 56; 76.1-76.4) has a self-sufficient cabin-side drive (21, 22) enabling the elevator cars (16; 36.1-36.3; 56; 76.1-76.4) independently in the vertical direction in the vertical elevator shafts (10, 12; 30, 32; 70, 72, 77) and in the deposit shaft (11; 31; 71). Elevator installation according to claim 11, characterized in that the self-sufficient cabin-side drive is a linear drive (21, 22), each of the elevator cars (16; 36.1-36.3; 56; 76.1-76.4) either has a further drive to move the elevator cars (16; 36.1-36.3; 56; 76.1-76.4) autonomously in the horizontal direction between two elevator shafts (10, 10) arranged side by side. 11, 12, 30, 31, 32, 70, 71, 72, 77), or in that the linear drive (21, 22) is designed to move the elevator cars (16; 36.1-36.3; 56; 76.1-76.4) independently in the horizontal direction between two adjoining elevator shafts (10, 11, 12; 30, 31, 32; 70 , 71, 72, 77). Elevator installation according to claim 12, characterized in that the elevator installation comprises means for swiveling the linear drive (21, 22). Elevator installation according to one of Claims 10 to 13, characterized in that each of the elevator cars (16; 36.1-36.3; 56; 76.1-76.4) has means for establishing contact between engagement elements (63, 65) on the elevator car (16; 36.1-36.3 56; 76.1-76.4) and horizontal guide elements (62, 64), wherein the horizontal guide elements (62, 64) in the region of a passage (15, 35, 74, 75) in the elevator shaft (10, 11, 12, 30 , 31, 32; 70, 71, 72, 77). Elevator installation according to one of Claims 10 to 13, characterized in that each of the elevator cars (16; 36.1-36.3; 56; 76.1-76.4) has means for tilting the elevator car (16; 36.1-36.3; 56; 76.1-76.4) Roll pairs (57, 58) of the elevator car (16; 36.1 - 36.3; 56; 76.1- 76.4) of shaft side mounted guide rails (53, 55) to remove. Elevator installation according to one of claims 10 to 15, characterized in that one of the vertical elevator shafts is designed as a long-distance shaft.

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