EP3261970A1 - Elevator system having a plurality of shafts and a plurality of cabs and an additional cab-accommodating shaft - Google Patents

Abstract

The invention relates to an elevator system (100, 200, 300), comprising a number of elevator shafts (110, 120), which extend vertically over a plurality of stories of a building having the elevator system (100, 200, 300), a number of cabs (115, 125), wherein the number of cabs (115, 125) is designed to be moved in the number of elevator shafts (110, 120) and to switch between elevator shafts (111, 112; 121, 122) of the number of elevator shafts (110, 120), and one or more additional cab-accommodating shafts (130, 230) for accommodating at least one cab (131) each, of which cab-accommodating shafts each extends vertically over fewer stories than one of the elevator shafts (111, 112; 121, 122) of the number of elevator shafts (110, 120).

Description

 Elevator system with several shafts and several cabins and

 additional cabin receiving shaft

description

The present invention relates to an elevator system and a method of operating an elevator system having a number of elevator shafts extending vertically over a plurality of floors of a building having the elevator system and having a number of cabins adapted to travel in the number of elevator shafts be and switch between elevator shafts of the first number of elevator shafts. State of the art

In elevator systems with several elevator shafts, cabins can often change between these elevator shafts and be moved in several elevator shafts. Thus, a high transport capacity (handling capacity, HC) can be achieved and a plurality of transport operations can be performed by the elevator system in particular simultaneously. Such elevator systems are referred to, for example, as shaft-changing multi-car systems. A maintenance or repair of individual cabins of such an elevator system is not readily possible. Often individual lift shafts or even the entire elevator system must be taken out of service to maintain individual cabins or make repairs to it. This is associated with great effort and high costs. If cabs are not serviced and have a fault during operation, there is a risk of these cabs becoming stuck in a hoistway. These defective cabs can obstruct the rest of the elevator car cabins. If necessary, this hoistway or the entire elevator system must be taken out of service to remove or repair the faulty cabin.

In US 3,658,155 an elevator system is shown in which the shaft doors are one cabin width set back from the track, so that cabins can pass another car in front of a door. Transport operations of other cabins therefore need not be interrupted if a cab stops in front of a shaft door. However, a maintenance of cabins is not possible there.

EP 1 616 832 A2 discloses an elevator system with three or four elevator shafts located directly next to one another. Due to the spatial proximity, a comprehensive change of the elevator cars between the individual elevator shafts via a plurality of transition zones is possible during operation. Such a transition zone can be designed as a depot zone, in which also maintenance and repair work is carried out.

Due to structural specifications, the elevator shafts of modern skyscrapers are not always in the immediate vicinity of each other. Thus, access areas to elevators are often designed as long corridors to which the entrances to the elevator shafts are provided on the right and left. These corridors represent a spatial separation of the elevator shafts arranged to the right and left of the corridor. Lift shafts are also often located in different building tracts and are separated from each other by useable space and / or technical functional spaces. It is an object of the present invention to increase the efficiency of elevator systems in the form of shaft-changing multi-car systems. Disclosure of the invention

According to the invention, an elevator system and a method for operating an elevator system with the features of the independent patent claims are proposed. Advantageous embodiments are the subject of the dependent claims and the following description. Embodiments and advantages of the elevator system according to the invention and the method according to the invention will become apparent from the following description in an analogous manner.

The elevator system has a number of elevator shafts extending vertically over a plurality of floors of a building having the elevator system. A number of cabins are arranged to travel in the number of elevator shafts and to switch between the elevator shafts of the number of elevator shafts. In other words, the elevator system has a shaft-changing multi-car system.

The elevator system has one or more, i. at least one additional car receiving shaft for receiving at least one car vertically extending over less floors than one of the elevator shafts of the number of elevator shafts, preferably as the lowest of the elevator shafts of the number of elevator shafts. The elevator system is preferably set up to move and store at least one cabin of the number of cars in the additional at least one car receiving shaft. The cabin (s) mounted in the at least one cabin receiving shaft are in particular not available for transport operations in the number of elevator shafts.

A cab reception shaft offers a variety of ways to improve the operation of the elevator system. For example, maintenance and / or repair work can be carried out in a cabin receiving shaft become. Defective cabins can be stored in a cabin receiving shaft. Unnecessary cabins can be parked in a cab reception shaft. Individual cabins may be taken out of service or disabled and stored in a cab reception shaft. Cabins stored in a cabin receiving shaft can also be put back into service and used for transport operations in the number of elevator shafts. A car receiving shaft may be located at a convenient location or on suitable floors of the building having the elevator system. The elevator system can also have a plurality of such car receiving shafts. The normal operation of the elevator system is not affected. The fact that it is an additional cabin receiving shaft, this can also be structurally separated from the rest of the elevator system, in particular by (in particular fire-retardant or refractory) doors or gates, so that the safety of the elevator system by the storage or particular maintenance of cabins in the cabin receiving shaft is not affected.

The cabins are not assigned to special elevator shafts, but in particular can be conveniently moved as required in all elevator shafts of the number of elevator shafts. For this purpose, appropriate connection paths are provided between the elevator shafts of the number of elevator shafts, for example in the form of horizontal elevator shafts. Such connection paths can be provided, for example, only at certain locations or in certain floors of the building having the elevator system. Only certain elevator shafts of the number of elevator shafts can be connected to one another in each case so that corresponding cabins can only change between these connected elevator shafts. However, all elevator shafts of the number of elevator shafts can also be connected to one another, so that in particular all the cabins can switch between all elevator shafts. The invention is particularly applicable to elevator systems which comprise a first number of elevator shafts and a second number of elevator shafts, with a shaft-free space being provided horizontally between the first number and the second number. This shaft-free intermediate space may be formed, for example, by the utility space, technical functional space and / or other traffic space, the usual vertical elevator shafts being excluded under other traffic space. The shaft-free intermediate space can in this case have a horizontal extension between the numbers of elevator shafts of at least 5 m, preferably at least 10 m. If the numbers of elevator shafts are arranged in different building sections, then the distance can also be at least 40 m. At least one of the car receiving shafts is now designed as, in particular horizontal, connecting shaft, which connects the first number with the second number, overcoming the shaft-free gap.

Through this connection, an exchange of cabins of spaced numbers of elevator shafts can now be carried out. As a result, resources of the individual numbers can be used together and so synergy effects are created, although the elevator shafts can otherwise be arranged separately from each other and operated separately. In particular, a single workshop can thus be provided (see also the following description of the maintenance area) into which the elevator cars of the entire building can be moved and can then be serviced there. Also, an adjustment of the amount of cars per number of elevator shafts may be changed for different operating modes, although the shafts are otherwise spatially separated.

In particular, the cabins are moved only in special elevator shafts of the number of elevator shafts only up and in others Elevator shafts of the number of elevator shafts only down. This is similar to a circulating Pater Noster operation.

Advantageously, at least one car receiving shaft is designed as a maintenance area for servicing and / or repairing cabs of the elevator system. The at least one cabin is advantageously maintained and / or repaired in the cabin receiving shaft. In the cabin receiving shaft particularly expedient tools and components for maintenance and / or repair are provided. In particular, the cabin receiving shaft represents a service area. The cabins can be maintained or repaired automatically or manually. In the course of maintenance, it is checked, in particular, whether safety functions of the respective cabin bring required services and satisfy given safety guidelines.

Maintenance and / or repair work can thus be carried out on the cabs of the elevator system with little effort and cost, without the entire elevator system or at least individual elevator shafts must be taken out of service. The elevator system can be operated regularly and yet maintenance and / or repair work can be carried out. To be serviced or repaired cabins are moved for this purpose in the cabin receiving shaft and there maintained or repaired and the other cabins are still operated in the elevator shafts regular and perform there transport operations. Thus, a regular maintenance and easy repair of the cabins of the elevator system can be made possible. The risk of cabins having a defect during normal operation can be reduced.

If the car receiving shaft is large enough to support a plurality of cars therein, or if the elevator system has a plurality of car receiving wells, a plurality of cars can be serviced at the same time. Maintenance and repair work can thus be carried out even faster and more effectively.

Preferably, a brake system of the at least one car is maintained in a car receiving shaft. For example, brakes can be tested and it can be checked whether the brakes meet given safety guidelines. For example, brake pads can be changed. Preferably, a guide roller of the at least one car is changed in a car receiving shaft. In particular, guide rollers can be replaced, which have a high wear.

Advantageously, the at least one cabin is moved at predetermined maintenance intervals in a cabin receiving shaft and maintained there. For example, the maintenance interval can be one day or even one week. Thus, a regular, weekly or even daily maintenance of the cabins are possible. In particular, thus an automatic or fully automatic maintenance of the cabins is realized. In particular, all cabins of the elevator system are moved and maintained at the end of their maintenance interval in a cabin receiving shaft.

Preferably, the at least one cabin is moved in dependence of operating parameters of the elevator system in a cabin receiving shaft and stored there. Thus, individual cabins can be taken out of service according to certain criteria and stored in the cabin receiving shaft. For example, cabins can be stored in the car receiving shaft, which are not required for transport operations in the respective number of elevator shafts. In particular, the operating parameters can provide information about how many cabins are required to carry out the transport operations. For example, the Operating parameters Information about a required handling capacity (HC), ie a required transport capacity for performing all transport operations.

Preferably, a cabin receiving shaft has an interior whose largest horizontal extent is greater than its largest vertical extent. In other words, the car receiving shaft extends substantially horizontally or perpendicular to the elevator shafts of the elevator system. This is particularly space-saving in the vertical direction. At the same time, it can extend vertically over the height of a floor or even in the manner of a maintenance or storage hall over several floors of the building having the elevator system. In particular, cabins within the horizontally extending car receiving shaft can only be moved horizontally but not vertically. In particular, several cabins can be stored side by side in the horizontally extending cabin receiving shaft.

Also preferably, a cabin receiving shaft on an interior, the largest horizontal extent is smaller than the largest vertical extent. In other words, the car receiving shaft extends substantially vertically or parallel to the elevator shafts of the elevator system. This is particularly space-saving in the horizontal direction. In particular, cabins within this vertically extending cabin receiving shaft can only be moved vertically but not horizontally. In particular, several cabins can be stored one above the other in the vertically extending cabin receiving shaft.

Preferably, a car receiving shaft extends at least partially over a basement of a building having the elevator system. The basement is often inaccessible to visitors to the building and is therefore likely to be used for noisy maintenance. Also, the space used there for the cabin receiving shaft is inexpensive because it does not have valuable sales, office or living space to be withdrawn. Of the Cabin receiving shaft can thus be arranged inconspicuously and space-saving in the basement.

Advantageously, a car receiving shaft extends at least partially over a technical level or via a service floor of a building having the elevator system. This technical projectile is intended in particular for maintenance, repair and / or service work and usually also not accessible to visitors. It is therefore suitable for possibly noisy maintenance. Also, the space used there for the cabin receiving shaft is inexpensive because it does not have valuable sales, office or living space to be withdrawn. In particular, suitable tools are stored in the technical projectile. The technical projectile is provided in particular for machines or systems for supplying the elevator system with the building. For example, an air-conditioning system, a ventilation system, a heating, a power and / or water supply of the building can be arranged in the technical floor.

In an advantageous development, the elevator system has a first number and a second number of elevator shafts extending vertically over a plurality of floors of the building having the elevator system. A first number of cars is arranged to travel in the first number of elevator shafts and to change between the elevator shafts of the first number of elevator shafts. Likewise, a second number of cars is arranged to be moved in the second number of elevator shafts and to change between the elevator shafts of the second number of elevator shafts. Of the first number of cars, transportation is performed in the first number of elevator shafts, and of the second number of cars, transportation is performed in the second number of elevator shafts. In other words, this embodiment of the elevator system has two shaft-changing multi-car systems. The at least one cabin receiving shaft is as Connecting shaft which connects the first number of elevator shafts and the second number of elevator shafts cabin exchanging formed.

The statements made above for the number of elevator shafts and the number of cabins advantageously also apply to the first and second number of elevator shafts and cabins.

Further advantages and embodiments of the invention will become apparent from the description and the accompanying drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

The invention is illustrated schematically by means of embodiments in the drawing and will be described below with reference to the drawing. figure description

Figures 1 and 2 each show schematically a preferred embodiment of an elevator system according to the invention, each of which is adapted to carry out a preferred embodiment of a method according to the invention.

Figure 3 shows a further preferred embodiment of an elevator system according to the invention, which is adapted to carry out a preferred embodiment of a method according to the invention. 1 shows a preferred embodiment of an elevator system according to the invention is shown schematically and designated 100. The elevator system 100 is configured to carry out a preferred embodiment of a method according to the invention.

The elevator system 100 has a first number 110 of vertically extending elevator shafts 110. In this example, two elevator shafts 111 and 112 form the first number of elevator shafts 110. The elevator shafts 111 and 112 are connected to one another via connection paths 113 and 114. The connecting paths 113, 114 are arranged in a top or in the lowest floor of a building comprising the elevator system 100. The lowest floor is, for example, a basement, for example, the top floor is the tenth floor. In the first number of elevator shafts 110, a first number of cabins 115 is movable. The cabins 115 may alternate between the elevator shafts 111 and 112 via the connection paths 113 and 114. The cabins 115 are moved in the elevator shaft 112, for example, only upwards and in the elevator shaft 111, for example, only downwards. The cabins 115 are operated in the first number of elevator shafts 110 as a first bay-changing multi-car system.

The elevator system 100 further includes a second number of vertically extending elevator shafts 120. Two elevator shafts 121 and 122 form this second number of elevator shafts 120. Analogous to the elevator shafts 111 and 112, the elevator shafts 121 and 122 are also connected to one another via connection paths 123 and 124.

Analogous to the first number of elevator shafts 110, a second number of cabins 125 can be moved in the second number of elevator shafts 120. The cabins 125 may be connected between the elevator shafts 121 and 122 via the Change connection paths 123 and 124. The cabins 125 are moved in the elevator shaft 121, for example, only upwards and in the elevator shaft 122, for example, only down. The cabins 125 are operated in the second number of elevator shafts 120 as a second bay-changing multi-car system.

Between the first number 110 and the second number 120 a chess-free space 118 is arranged, in which, for example, offices, corridors, house installation rooms, etc. are provided. A smallest distance D between the elevator shaft 111 of the first number 110, which is located closest to the second number 120, and the elevator shaft 113 of the second number 120, which is located closest to the first number 110, is e.g. 5 m. In almost all floors a corridor is designed as a traffic area in this example. A cabin receiving shaft designed here as a connection shaft 130 for accommodating at least one cabin connects the first and the second number of elevator shafts 110 and 120 to one another leading to the cabin. Individual cabins both the first number of cabins 115 and the second number of cabins 125 can be moved into this connection shaft 130 and stored there.

The connection shaft 130 is formed in this example as a horizontally extending elevator shaft. The connection shaft 130 is arranged in the basement of the elevator system 100 having building.

If a cabin of the first number of cabins 115 is located in the elevator shaft 111 and in the basement, this cabin can be moved into the connection shaft 130. In FIG. 1, this is a car 116. Analogously, a car of the second number of cars 125 can be moved into the connection shaft 130 when this car is in the car Elevator shaft 121 and located in the basement. In FIG. 1, this is a cabin 126.

In the example shown in FIG. 1, a cabin 131 is located in the connection shaft and is stored there. For example, this cabin 131 may be a cabin of the first number of cabins 115. The connection shaft 130 in the example of Figure 1 provides sufficient space to store three cabins next to each other. The connection shaft 130 is further formed as a maintenance area for servicing and repairing cabs of the elevator system 100. In particular, by means of the connection shaft 130 a regular, automatic maintenance of the cabins 115 and 125 of the elevator system 100 is made possible. The connection shaft 130 also has accesses for maintenance personnel in particular. The maintenance of cabins can therefore be carried out manually in particular. In the example of FIG. 1, up to three cabins can be stored and maintained next to each other in the connection shaft 130 at the same time. For this purpose, all cabins 115 and 125 of the elevator system are moved into the connection shaft 130 at predetermined maintenance intervals and are maintained there. If a defect in one of the cabins is detected in the course of the maintenance, a repair of the corresponding cabin is carried out. For example, the maintenance interval may be one day, so that all cars 115 and 125 of the elevator system 100 are serviced daily. Thus, cabins of the elevator system 100 can be prevented from failing during regular operation and possibly hindering other cabs.

If one or more cabins are serviced in the connection shaft 130, the remaining cabins of the elevator system 100 will become in the meantime In the course of regular transport operations in the respective elevator shafts 111, 112, 21 and 122, respectively.

Despite the physical separation of the first number 110 and the second number 120 of elevator shafts, a single maintenance area is sufficient to service and repair all the cars in the elevator system.

The elevator system 100 furthermore has, in particular, a control unit 140, which is set up to control the individual cars 115 and 125 of the elevator system 100. Furthermore, the control unit 140 is in particular configured to perform a preferred embodiment of the method according to the invention. In particular, the control unit 140 is set up to move the individual cars 115 and 125 into the connection shaft 130 after the respective maintenance interval has expired and to wait there automatically.

In FIG. 2, a further preferred embodiment of the elevator system according to the invention is shown schematically analogously to FIG. 1 and designated by 200. The same reference numerals in Figures 1 and 2 denote the same or identical elements.

The elevator system 200 has, in addition to the connection shaft 130, a cabin receiving shaft designed here as a second connection shaft 230. This second connection shaft is arranged, for example, in the top, tenth floor of the elevator system 100 having the building. For example, this top floor can be designed as a technical floor or as a service floor.

The second connection shaft 230 is in particular analogous to the connection shaft 130 also as a horizontally extending Elevator shaft and further as a maintenance area for servicing and repair of cabins of the elevator system 100 formed.

If a car of the first number of cabins 115 is located in the hoistway 111 and on the top floor, this car can be moved into the connection shaft 230. In FIG. 1, this is a car 117. Similarly, a car of the second number of cars 125 can be moved into the connecting shaft 230 when this car is in the hoistway 121 and in the uppermost floor. In FIG. 1, this is a cabin 127.

For example, the second connection shaft 230 also provides space for supporting three cabins next to one another. Thus, a total of up to six cabins can be stored and / or serviced simultaneously in the connection shafts 130 and 230.

FIG. 3 shows a further preferred embodiment 300 of an elevator system, which substantially corresponds to the elevator system 200 according to FIG. 2, but instead of only two has a bay-changing multi-car system 110. Accordingly, the car receiving wells 130, 230 are also not formed as connection shafts. All the other advantages and features described with respect to the elevator system 200 also apply to the elevator system 300. The car containment shafts 130, 230 of all of the drawer systems 100, 200 and 300 shown, in particular, provide physically separate shafts from the remaining elevator shafts 111, 112, 121 and 122 in particular, for example, by means of a door from the other elevator shafts 111, 112, 121 are separable. This door can be designed, for example, fireproof. The car receiving shafts 130, 230 have in particular also access doors for maintenance personnel. LIST OF REFERENCE NUMBERS

100 elevator system

110 first number of vertically extending elevator shafts

111 elevator shaft

 112 elevator shaft

 113 Connecting path between elevator shafts

 114 Connection path between elevator shafts

115 first number of cabins

 116 cabin

 117 cabin

 118 bay-free space

 120 second number of vertically extending elevator shafts 121 elevator shaft

 122 elevator shaft

 123 Connecting path between elevator shafts

 124 Connecting path between elevator shafts

 125 second number of cabins

126 cabin

 127 cab

 130 Connecting shaft, cabin receiving shaft

 140 control unit

 200 elevator system

230 second connecting shaft, car receiving shaft

300 elevator system

Claims

claims

An elevator system (100, 200, 300) having a number of elevator shafts (110, 120) extending vertically over a plurality of floors of a building comprising the elevator system (100, 200, 300) and having a number of cabins (115, 125 ), wherein the number of cars (115, 125) is arranged to be moved in the number of elevator shafts (110, 120) and between elevator shafts (111, 112; 121, 122) of the number of elevator shafts (110, 120) switch,

 with one or more additional car receiving shafts (130, 230) for accommodating at least one cabin (131), each of which extends vertically over less floors than one of the elevator shafts (111, 112, 121, 122) of the number of elevator shafts (110 , 120).

Elevator system (100, 200, 300) according to the preceding claim, comprising a first number (110) of elevator shafts (111, 112) and a second number (120) of elevator shafts (121, 122), being horizontal between the first Number (110) and the second number (120) a shaft-free

Interspace (118) is provided, wherein at least one of

Cabin receiving wells (130, 230) is formed as a connection shaft connecting the first number (110, 120) with the second number (120), overcoming the shaft-free space (118).

3. elevator system (100, 200, 300) according to the preceding claim, wherein the shaft-free space (118) is formed by work space, technical function space and / or other traffic space and / or that the shaft-free space (118) has a horizontal extent (D ) between Numbers (110, 120) of the elevator shafts of at least 5m, preferably at least 10m.

An elevator system (100, 200, 300) according to any one of the preceding claims, wherein at least one of the one or more car receiving wells (130, 230) serves as a maintenance well for servicing and / or repairing

Cabins (115, 125) of the elevator system (100, 200, 300) is formed.

5. An elevator system (100, 200, 300) according to any one of the preceding claims, wherein at least one of the one or more car receiving wells

(130, 230) has an interior whose largest horizontal extent is greater than its largest vertical extent.

6. elevator system (100, 200, 300) according to claim 1 to 4, wherein at least one of the one or more car receiving wells (130, 230) a

Interior having the largest horizontal extent is smaller than its largest vertical extent.

The elevator system (100, 200, 300) of any one of the preceding claims, wherein at least one of the one or more

 Cabin receiving wells (130, 230) extends at least partially over a basement of the elevator system (100, 200, 300) having the building.

The elevator system (100, 200, 300) of any one of the preceding claims, wherein at least one of the one or more

 Cabin receiving wells (130, 230) at least partially over

Technical projectile of the elevator system (100, 200, 300) having the building extends.

9. elevator system (100, 200, 300) according to one of the preceding claims, which is adapted to at least one cabin (131) of the number of cabins (115, 125) into the one or more cabin receiving wells (130, 230) and to store there.

An elevator system (100, 200, 300) as claimed in any one of the preceding claims, comprising a first number of vertically extending over a plurality of floors of the building comprising the elevator system (100, 200, 300)

Elevator shafts (110) having a first number of cabins (115) adapted to travel in the first number of elevator shafts (110) and between elevator shafts (111, 112) of the first number of shafts

To change elevator shafts (115), and

 a second number of vertically extending over a plurality of floors of the elevator system (100, 200, 300) having the building

Elevator shafts (120) having a second number of cars (125) arranged to travel in the second number of elevator shafts (120) and between elevator shafts (121, 122) of the second number of

Changing elevator shafts (120),

 having,

 wherein at least one of the one or more

Cabin receiving wells (130, 230) as a connection shaft (130, 230) containing the first number of elevator shafts (110) and the second number of

Elevator shafts (120) connects to each other, is formed.

A method of operating an elevator system (100, 200, 300) according to any one of the preceding claims, wherein at least one cabin (131) moves the number of cars (115, 125) into the one or more car receiving wells (130, 230) and stored there.

12. The method of claim 11, wherein the at least one cabin (131) in the one or more cabin receiving wells (130, 230) is serviced and / or repaired.

13. The method of claim 11 or 12, wherein the at least one cabin (131) at predetermined maintenance intervals in the one or more car receiving wells (130, 230) is moved.

14. The method according to any one of claims 11 to 13, wherein the at least one cabin (131) in dependence on operating parameters of the elevator system (100, 200, 300) in the cabin receiving shaft (130, 230) and stored there.