EP3564173A1 - Device for supporting a cabin holder - Google Patents

Abstract

The invention comprises a support device for supporting a car carrier of an elevator car arrangement against tipping. The elevator car arrangement (1) includes a car carrier (2), a car structure (3) and at least one insulator (4). The cabin carrier (2) comprises at least two rollers (5) which are designed to deflect at least one suspension element (6) and. The cabin support (2) is connected to the cabin structure (3) via the at least one insulator (4). The elevator car arrangement (1) contains one or more support devices (9), a lower end region of each of these one or more support devices (9) being connected to the car carrier (2), and an upper end region of these one or more support devices (9) at most the cabin structure and / or is supported on the rail system via guide shoes.

Description

The invention relates to an elevator car assembly according to the preamble of the independent claim. In particular, the elevator car arrangement comprises a supporting device for supporting a car carrier against tilting.

Such a device can be used in elevator systems with at least one cabin. A cabin can be built cheaply when the suspension element is passed under the cabin. In this case, a cabin carrier is often used, which serves to accommodate the rollers, which deflect the support means under the cabin. These moving components create structure-borne noise that spreads on the cabin car. In order to isolate the cabin structure from the structure-borne noise, the cabin carrier is connected to the cabin structure via insulation elements.

The ride comfort for a passenger in the cabin is also influenced, among other things, by the structure-borne noise, which is transmitted through the cabin structure to the air inside the cabin. The structure-borne noise on the one hand reaches the cabin via the suspension means, and on the other hand it can be caused by the running-in of the suspension element on the rollers or as bearing noise in the roller bearings. All of this structure-borne noise is then transmitted to the support structure via the axes of the rollers.

It is therefore important to keep the transmission of structure-borne noise, which is present on the car carrier, from the car carrier to the cabin structure.

In order to keep this sound transmission as low as possible, the concept prevails in the prior art of only connecting the cabin carrier to the cabin structure at a few points via insulation elements. This procedure, however, allows the car carrier relatively easily to tilt an axle which runs parallel to the course of the suspension means under the car. In particular, the distances of the insulators perpendicular to this axis are very short. This causes even a small, caused by different Tragmittelspannungen, moment large differences in force at the insulators and thus relatively large deformations. The moment has to be taken up otherwise.

The EP 2 300 347 shows a cabin, as described above, while a cabin structure is shown with a car carrier. The car carrier is also isolated connected to the cabin structure. Such a design responds to differences in tension in the traction means with the tilting of the cabin carrier.

The tilting of the cabin carrier may not exceed a certain value, otherwise there is a risk that the suspension element jumps from the role. An object of the claimed invention is therefore to keep the car carrier in its horizontal orientation, and thereby to keep the entry angle of the support means within the allowable range.

In the following, solutions and proposals for a corresponding embodiment of an elevator car arrangement are given, which solve at least parts of the task. Furthermore, advantageous additional or alternative developments and refinements are specified or described.

The invention includes an elevator cab assembly including a car carrier, a cabin structure, and at least one isolator. The cabin structure includes at least one cabin floor, a cabin wall and at least one car door. The car carrier comprises at least two rollers which are designed for deflecting a suspension element. The car carrier is connected to the cabin structure via at least one insulator. The elevator car assembly is characterized in that it includes one or more outriggers, each having a lower end portion of said one or more outriggers connected to the car carrier and an upper end portion of said one or more outriggers at most on the cabin structure and / or over guide shoes on the rail system is supported.

Preferably, the cabin carrier is located below the cabin. The roles of the cabin carrier may be attached directly or indirectly to the cabin carrier. The cabin support is preferably elongated. Its length essentially corresponds to the width of the cabin. Its width is substantially equal to the width defined by the one or more side-by-side support means.

For example, even more elements can be attached to the cabin support, such as For example, the safety gear, the release mechanism of the safety gear or the lower guide shoes.

Preferably, the cabin structure comprises all elements that directly overlie the passenger compartment. A cabin structure consists of a floor, which is built up in several layers. This floor is able to transmit at least the weight of the transported persons and goods to the connections to the cabin carrier. The cabin walls covered the interior of the cabin towards the shaft. The cabin wall may have a framework-like support structure. In addition to the elements already mentioned, this can also be the cabin roof, for example. For the purposes of the invention, an upper yoke, which clearly stands out in terms of function or structure from the cab roof, should not be regarded as part of the cabin structure.

Preferably, the insulator is a member having at least a portion of elastomer capable of producing a slightly elastic connection. However, springs, rope loops, foams, gas bellows or other components serving as insulation can also be used as insulator, for example.

Advantageously, the cabin structure stands on several insulators. Advantageously, four insulators, or an integer multiple thereof, are arranged near the corners of the car frame, which is mainly rectangular in a view from above.

One aspect of this invention is therefore to counteract the moment that acts on the car carrier by the unequal suspension medium stresses via a long supporting device. This support device preferably extends upwards, since it can develop the maximum length in this direction. The support device is preferably designed such that it is designed to be very stable against bending. Preferably, the support devices is designed as a hollow, U or hat profile and preferably made of a metallic material.

A lower end region of the supporting device is connected to the cabin carrier. Advantageously, the connection is able to absorb the moments that are transmitted by the diagonal train on the cabin carrier, and by the insulators between the car carrier and cabin structure in sufficient mass can transfer to the outrigger.

For the support, that is, for the maintenance of the vertical orientation of the upper end portion of the support device, three variants are described below.

Preferably, the upper guide shoe is attached to the support device. As a result, the vertical orientation of the guide rail is transferred to the orientation of the supporting device. Such support can also be done without an additional support of the upper end portion of the support device relative to the cabin structure. As a result, the structure-borne noise, which is generated at the upper guide shoe, safely prevented from the cabin structure. The support device is firmly connected in this case only with the car carrier. Further support to the cabin structure is not necessary.

In addition, the upper end region preferably additionally supports itself with respect to the cabin structure. Since the support device is indeed relatively long, it could deform so much due to the forces acting on it or show such large vibration amplitudes that it uncontrollably on the cabin structure, so for example on the cabin wall, collides or rubs. This would be extremely disturbing and can be prevented by an elastic connection between the upper end portion of the supporting device and the cabin structure via insulators. Preferably, the insulators are made of elastomers. An important feature of the insulators is that they provide a compliant connection between the support and the cabin structure. As insulators, other construction elements are conceivable. These could be for example springs, rope loops, foams, gas bellows or other components of the insulation of structure-borne sound. The insulators on the outrigger need not be similar or equal to the insulators between cab support and cabin structure.

Alternatively, it would also be possible to support the upper end region of the supporting device only on the cabin structure, that is not also via a guide shoe on the rail system. This could be useful if the support device is designed rather short, and therefore does not reach up to the top of the cabin.

Advantageously, the support device in this case via elastomeric insulators supported on the cabin structure. Alternatively, however, cheaper or otherwise advantageous variants of such more flexible connections between the supporting device and the cabin structure could also be used. These could be, for example, springs, rope loops, foams, gas bellows or other components serving for insulation. Alternatively, it is also possible to completely dispense with an insulation between the cabin structure and the supporting device. Advantageously, in such a construction, the upper guide shoe on the side of this support device is not attached to the support device, but directly or via insulators to the cabin structure.

If a plurality of supporting devices are installed, the upper end areas of these supporting devices are supported at most on the cabin structure and / or via guide shoes on the rail system. Therefore, it is explicitly excluded that support the support directly or indirectly, such as over an upper yoke of a catch frame, mutually support.

Preferably, the upper end portion of this one or more support devices is supported via insulators on the cabin structure.

Preferably, the insulators between the support device and the cabin structure are a component with at least a portion of elastomers. Alternatively, however, springs, rope loops, foams, gas bellows or other components serving as insulation can also be used as insulator, for example. The insulators between the support and the cabin structure may differ from the insulators between the car carrier and the cabin structure.

Preferably, both ends of the car carrier are connected to at least one supporting device.

Advantageously, a support device is mounted on both sides of the cabin, thereby further components such as guide shoes or wall elements can be performed uniformly. Otherwise it would be necessary to design the construction on the side with the support device differently than on the side without support device.

Preferably, at least one of the guide shoes of the elevator car is attached to the support device.

The attachment of the guide shoe to the support device is advantageous because the guide shoe vertically aligns the support device along guide rails. In addition, the structure-borne noise resulting from the sliding on the guide shoe, not directly affect the cabin structure, but is isolated from it.

Advantageously, the lower guide shoes of the elevator car are fastened to the car carrier.

Through the connection to the cabin carrier, the executives can be safely initiated. The car carrier is designed to absorb the forces and structure-borne noise transmitted by the guide shoes.

Preferably, the connection between the lower end region of these one or more support devices and the cabin support is in each case designed such that the angle between the axes of the rollers of the car carrier and the vertical orientation of the support device is adjustable.

This makes it possible to compensate for manufacturing tolerances of the cabin carrier, the supporting device or the cabin structure.

For example, such an adjustability could be realized in that the supporting device has a plurality of slots in the region of the contact with the car carrier. The screw connection between the car carrier and the support device is done through these slots. If the support device is now to be adjusted, the screws can be easily released, then the support device can be properly aligned, and the screws can be tightened again.

Alternatively, however, the supporting device could also be rotatably mounted on a pin. In this case, the orientation can then be locked against rotation by a locking screw in a slot. Or the alignment is adjusted via a set screw, which acts on a lever arm.

Advantageously, the safety gears are attached to the cabin support. The cabin carrier is designed to accommodate even large forces.

• Figur 1 den Seitenriss einer Kabine nach dem Stand der Technik,
• Figur 2 den Frontriss einer Kabine nach dem Stand der Technik.
• Figur 3 den Seitenriss einer Kabine nach dem Stand der Technik, mit überhöht dargestellter Rotation des Kabinenträgers.
• Figur 4 den Frontriss einer Ausführungsform der Kabine.
• Figur 5 den Seitenriss der in Figur 4 gezeigten Kabine.
• Figur 6 eine bevorzuge Variante, bei der die oberen Führungsschuhe and der Abstützvorrichtung befestigt sind.
• Figur 7 eine alternative Variante, bei der die oberen Führungsschuhe and der Kabinenstruktur befestigt sind.

Further embodiments will be described with reference to the following figures. Show it:

• FIG. 1 the side elevation of a cabin according to the prior art,
• FIG. 2 the front crack of a cabin according to the prior art.
• FIG. 3 the side elevation of a cabin according to the prior art, with exaggerated rotation of the car carrier.
• FIG. 4 the front crack of an embodiment of the cabin.
• FIG. 5 the side elevation of in FIG. 4 shown cabin.
• FIG. 6 a preferred variant in which the upper guide shoes are attached to the support device.
• FIG. 7 an alternative variant in which the upper guide shoes are attached to the cabin structure.

The in the Figures 1 and 2 Prior art shown is often used for rather cheap cabins. The structure-borne noise generating components, that is to say the rollers 5 and the guide shoes 7, are fastened on the cabin support 2. This cabin carrier 2 is connected exclusively to the cabin structure 3 via insulators 4, wherein the cabin structure 3 forms the actual passenger compartment of the elevator car arrangement 1. The cabin structure features a cabin floor, cabin walls and a cabin ceiling. The car doors are also attached to the cabin structure 3, respectively. The lower guide shoes 7, since they also generate structure-borne noise, are also mounted on the cabin support 2. The upper guide shoes 7, however, must be attached to the cabin structure 3 become. This compound may be designed to be insulating or not. The weight of the elevator car assembly 1 is transmitted via the rollers 5 to the support means 6. The rollers 5 are connected to the car carrier 2. The elevator car assembly 1 is guided over the guide rails 99.

FIG. 3 shows a, greatly exaggerated, representation of the problem to be solved. When using a plurality of support means 6, an uneven distribution of the tension on the support means 6 may occur. Uneven forces thus act on the insulators 4 and the insulators 4 deform to different degrees. As a result, the car carrier 2 tilts easily. Together with the cabin carrier 2 also tilt the rollers (in Fig. 3 hidden) and thus the support means 6 no longer runs perpendicular to the roller axes on the rollers 5. Therefore, there is an increased risk that the support means 6 from the role (in Fig. 3 covered) jumps.

FIGS. 4 and 5 show the application of a support device to such a cabin. A lower end region of the support device 9 is connected to the car carrier 2. An upper end region of the support device 9 is supported on the cabin structure 3. A tilting of the car carrier 2 would lead to a large displacement of the upper end region of the support device 9 relative to the cabin structure. Such a shift is prevented because the support device 9 is connected via an insulator 4 to the cabin structure 3. As a result, the support device 9 prevents tilting of the car carrier 2. The support means 6 thus runs essentially at right angles to the axis of the rollers 5. The insulators 4 are now evenly loaded due to the support device 9.

FIG. 6 shows a preferred embodiment of the support device 9. The support device 9 extends substantially over the entire height of the cabin structure. As a result, the effect against the tilting of the cabin carrier 2 is optimal. Since the upper guide shoes are attached to the support device, the support device is supported not only relative to the cabin structure 3, but also against the, not shown, rail system. The symmetrical arrangement of the support device has the advantage that the forces are distributed evenly, and that the same type of guide shoe can be mounted on the two sides of the cabin. This only has to be done a type of guide shoe may be used, rather than different types for mounting on the support and for mounting to the cabin structure. This simplifies the logistics and the assembly of the guide shoes.

FIG. 7 shows an alternative embodiment of the support device 9. The support device 9 is made relatively short. This makes it relatively cheap. The upper guide shoes 7 are now fastened to the cabin structure 3 via insulators 4. The support device is supported by insulators on the cabin structure 3. Alternatively, a direct connection to the cabin structure 3 is possible.

Claims (6)

Elevator cab arrangement (1) comprising a car carrier (2), a cabin structure (3) and at least one isolator (4),
wherein the cabin structure (3) includes at least one cabin floor, a cabin wall and at least one cabin door,
wherein the car carrier (2) comprises at least two rollers (5), which are designed to deflect at least one support means (6) and
wherein the cabin carrier (2) is connected to the cabin structure (3) via the at least one insulator (4),
characterized in that the elevator car assembly (1) includes one or more support devices (9)
wherein in each case a lower end region of said one or more support devices (9) is connected to the car carrier (2), and
wherein an upper end region of said one or more support devices (9) is supported at most on the cabin structure and / or on guide shoes on the rail system. Elevator cab arrangement according to claim 1, characterized in that the upper end region of this one or more support devices (9) is supported on the cabin structure via insulators (4). Elevator car arrangement according to one of claims 1 or 2, characterized in that both ends of the car carrier (2) are connected to at least one supporting device (9). Elevator cab arrangement according to one of claims 1 to 3, characterized in that
at least one of the guide shoes (7) of the elevator car is fastened to the supporting device (9). Elevator cab arrangement according to one of claims 1 to 4, characterized in that
the lower guide shoes (7) of the elevator car are fastened to the cabin support (2). Elevator cab arrangement according to one of claims 1 to 5, characterized in that
the connection between the lower end region of these one or more support devices (9) and the cabin support (2) is in each case designed such that the angle between the axes of the rollers of the car carrier (2) and the vertical orientation of the support device (9) is adjustable.

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