RU2588411C2 - Suspension and traction connecting device for elevators - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: suspension system for connecting support structure and support structure (14) of elevator installation, having housing and hitch plate (32). Housing has two spaced-apart side walls (30), whereby side walls are arranged to accommodate part of support structure between side walls. Each side wall has receiving opening (38) having a longitudinal shape. Hitch plate has at least one fixture configured to couple to sheave arrangement (22) for suspension means. Each receiving opening is has dimensions to accommodate movable part of hitch plate so that hitch plate passes between side walls for rotation about a vertical axis. Elevator installation comprises said means. Method consists in use of said means for connection of supporting structure of elevator installation and suspension means.

EFFECT: simplified modification of elevator installation.

18 cl, 10 dwg

Description

 [0001] The various embodiments described herein generally relate to elevator installations. In particular, the various embodiments described herein relate to a system and method for connecting a suspension means and a supporting structure of an elevator installation.

[0002] In one example of a known elevator installation, a suspension means, such as a cable or flat ribbon cable, is connected between the counterweight and the elevator car. The drive motor drives the suspension means to thereby move the counterweight and the elevator car up and down along the elevator shaft. A suspension means is wound around at least one pulley system that can be mounted on an elevator car or a counterweight, or both. A pulley system, for example, is mounted on an elevator car body.

[0003] US Pat. No. 7,665,580 describes several pulley systems located adjacent to each other on a counterweight or elevator car. Each pulley system has a U-shaped carrier element in which a bypass roller and a spherical seat are located. A bypass roller is installed between the legs of the U-shaped supporting element, and the spherical socket is in a bend connecting the two legs. A flat belt suspension means is wound around a bypass roller. The connecting bolt is part of the spherical socket and extends from the supporting element in the direction of the supporting structure of the counterweight or elevator car. The connecting bolt is fixed in the through hole of the supporting structure. In addition, each pulley system independently rotates and adjusts around an axis parallel to the branch direction of the respective suspension means.

[0004] Although such pulley systems have various advantages, for example, because they rotate independently, these pulley systems may not be suitable for certain applications. For example, if the elevator installation is to be modernized and the existing elevator car body and counterweight must be preserved without any changes, it may not be possible to provide the housing, for example, the necessary through holes for the connecting bolts or it is not possible to attach the pulley systems to various places in the elevator shaft. Thus, there is a need for alternative technology for connecting the suspension means to the elevator car or counterweight, which overcomes these disadvantages.

[0005] Accordingly, an aspect of such an alternative technology includes a system for connecting the suspension means and the supporting structure of the elevator installation. The system includes a housing and fittings. The housing has two spaced side walls, where the side walls are located to accommodate part of the cross member of the supporting structure between the side walls. Each side wall has a receiving hole having an oblong shape. The shape has at least one mount configured to be connected to the belt device for the suspension means. Each receiving hole has dimensions for placement with the possibility of moving the section of the gusset so that the gusset passes between the side walls and can rotate around a vertical axis.

[0006] Another aspect includes an elevator installation having a suspension means, a pulley device connected to the suspension means, a supporting structure and a connecting system configured to connect the pulley device and the supporting structure. The connecting system comprises a housing and a fitting. The housing has two spaced side walls, while the side walls are located to accommodate part of the cross member of the supporting structure between the side walls. Each side wall has an elongated receiving hole. The fitting has at least one mount configured to be connected to a pulley device for a suspension means. Each receiving hole has dimensions for placement with the possibility of moving the section of the gusset so that the gusset passes between the side walls and can rotate around a vertical axis.

[0007] Another aspect includes a method of connecting the suspension means and the supporting structure of the elevator system. The shape is located above the part of the supporting structure, and the side walls are mounted on the fitting so that the sections of the shape are rotatably rotated in the receiving holes of the side walls and part of the supporting structure extends between the side walls. The side walls are located opposite each other and extend in parallel planes. In addition, the pulley device is mounted to the gusset, while the pulley device is configured to accommodate the suspension means.

[0008] In one embodiment, the gusset is rounded. The rounded shape allows you to adjust the gusset to the desired angle in the range between approximately 0 ° to approximately 360 °. This provides high flexibility and ease of use of the system.

[0009] The round shaped sections extend through the receiving openings of the shaped. This installation of the side walls to the gusset provides a secure fit between these components, which can be easily checked and tested by the installer.

[00010] At least one gusset mount has an opening sized to accommodate the shaft of the pulley fixture. Preferably, this allows the pulley system to be mounted “from above”, that is, in the vertical direction, while the coupling system is already mounted to the supporting structure, which also facilitates the installation procedure.

[00011] In one of the exemplary embodiments described herein, several holes are located along a straight line. This linear arrangement of the holes corresponds to the location of the suspension means in the elevator shaft, facilitating their alignment with the connection system.

[00012] In one embodiment, a predetermined number of longitudinal elements extends between the side walls and interconnects the side walls. Each side wall has a corresponding number of passes, each places with the possibility of removal the final section of the longitudinal element. This helps in assembling the element-by-element coupling system around the supporting structure.

[00013] In addition, each side wall has an upper part containing a receiving hole, and a lower part having a hole for the transverse beam. The transverse beam, or group of transverse beams, is thus attached to the connecting system and carries a supporting structure.

[00014] In one embodiment, the first set screws extend through the gusset and are configured to press against the upper surface of the supporting structure to vertically position the connecting system with respect to the supporting structure. The second set screws pass through the side walls to press against the sides of the supporting structure for horizontal arrangement of the connecting system. These two sets of set screws allow separate alignment of the connecting system with respect to the supporting structure, which also helps to facilitate installation.

[00015] Each set screw may have a bearing surface pressed against a supporting structure that includes a material that dampens vibration. Preferably, the abutment surface prevents (or at least dampens) vibrations from propagating them into the supporting structure and the elevator car.

[00016] New features of the features and steps of the method of the present invention are set forth in the claims below. However, the invention itself, as well as its other features and advantages, is easier to understand with reference to the detailed description that follows when reading along with the attached graphic materials, where:

in FIG. 1 is a schematic illustration of one embodiment of an elevator installation with a pulley device and a system for connecting a suspension means and a supporting structure;

in FIG. 2 is a schematic illustration of one embodiment of a pulley system and a system for connecting the suspension means and the supporting structure shown in FIG. one;

in FIG. 3 is a schematic illustration of one embodiment of a system for connecting the suspension means and the supporting structure shown in FIG. 2;

in FIG. 4 and 5 are schematic side views of a system for connecting the suspension means and the supporting structure of FIG. 3;

in FIG. 6 is a schematic top view of a system for connecting the suspension means and the supporting structure of FIG. 3;

in FIG. 7 is a schematic bottom view of a system for connecting the suspension means and the supporting structure of FIG. 3;

in FIG. 8 is a flowchart of one embodiment of a system installation procedure for connecting a suspension means and a supporting structure;

in FIG. 9 schematically shows the location of a pulley system mounted perpendicular to the line connecting the center line of the elevator car to the center line of the counterweight;

in FIG. 10 schematically shows the arrangement of FIG. 9 with a bevel from the perpendicular.

[00017] In FIG. 1 schematically shows one embodiment of an elevator installation 1 installed in a multi-story building. The elevator installation 1 comprises a cabin 2, connected by means of a suspension means 4 with a counterweight 6, while the cabin 2 and the counterweight 6 are arranged to move up and down in opposite directions along a vertically extending shaft 8. The drive 10 is located below the shaft of the shaft and next to the structure 20 Depending on whether the elevator installation 1 is equipped with a machine room, the structure 20 can be made in the form of a floor of a separate engine room, in which there is a drive 10 or a supporting structure made under yshey mine; the space under the roof of the shaft is sometimes called the upper space. In the latter case, the structure 20 is attached to the shaft wall to support the actuator 10 in the immediate vicinity of the shaft wall.

[00018] The drive 10 is configured to drive the suspension means 4 to move the cabin 2 and the counterweight 6. In one embodiment, the elevator installation 1 is in the form of an elevator with a traction sheave, i.e. the pulley drive is connected to the drive 10 and acts on the suspension means 4 by means of traction between the pulley drive and the suspension means 4. In such an embodiment, the suspension means 4 serves as the suspension and traction means.

[00019] The elevator installation 1 further includes a supporting structure 14, which carries the cab 2. The supporting structure 14 — also called “suspension” —contains a cross member, traverse or housing that at least partially surrounds the cab 2. Cabin 2, empty or loaded with cargo or passengers, represents the load of the carried load-bearing structure 14. It should be understood that cabin 2 comprises at least one door on one side of cabin 2, however, for ease of illustration, FIG. 1 does not show doors or any other component of cab 2.

[00020] A system 12 for connecting the suspension means 4 and the supporting structure 14 connects the supporting structure 14 and the suspension means 4. This system is hereinafter also referred to as the connecting system 12. It should be understood that the connecting system 12 can be performed on the counterweight 6 for connecting the counterweight 6, or the counterweight body 6, and the suspension means 4. The elevator installation 1 can thus have a connecting system 12 on the supporting structure 14 or the counterweight 6, or both.

[00021] In the illustrated elevator installation 1 of FIG. 1, the terminal ends of the suspension means 4 are mounted at attachment points 16, 18 with the structure 20. Starting from the attachment point 16, the suspension means 4 goes down, goes around the pulley system 22 of the system 12 and goes up in the direction of the drive 10. There, the suspension means 4 bypasses around the drive pulley 24 of the drive 10 and passes in the direction of the bypass roller 26 located next to the drive 10 above the structure 20. The bypass roller 26 guides the suspension means 4 to the side so that the up and down movement of the counterweight 6 does not interfere with the upward movement and down cab 2. On the guide roller 26, the suspension means 4 passes down, goes around the pulley 28 on the counterweight 6 and goes up to the attachment point 18. This configuration of the suspension means 4 is usually called the configuration 2: 1. It should be understood that in other embodiments of the elevator installation 1, other configurations may be used, for example, 1: 1 or 4: 1; the number of pulleys, rollers, and attachment points may thus vary depending on the particular embodiment.

[00022] Regardless of any particular cable configuration or design of the elevator installation 1, the suspension means 4 may have one of several configurations. In one embodiment, the suspension means 4 has a tape type configuration in which several metal cords are fully or partially integrated into the elastomeric coating. This configuration has a profile where the width is greater than its height. The surface of such a suspension means 4 may be flat or have longitudinal grooves. In another embodiment of the suspension means 4 with such a profile, cords of non-metallic materials, such as aramid fibers, are fully or partially embedded in the elastomeric material. In yet another embodiment, the suspension means 4 may have a circular configuration in which individual metallic or non-metallic cords are twisted into a cable. Such a round suspension means may be uncovered or coated with an elastomeric material.

[00023] It should be understood that the elevator installation 1 in some embodiments comprises more than one suspension means 4. The amount of suspension means 4 used in the elevator installation 1 depends, for example, on the load capacity of the car 2. In the embodiments described in FIG. 4-7, the elevator installation 1 includes five suspension means 4, each of which has a tape type configuration, as defined above. The number of suspension means 4 affects the number of pulleys and rollers used in the elevator installation 1. Each pulley and roller usually affects only one suspension means 4.

[00024] FIG. 2 shows a schematic illustration of one embodiment of a pulley system 22, and a coupling system 12 is shown in FIG. 1. In the case where the number of suspension means 4 is five, the pulley device 22 comprises five separate pulleys 22a. These individual pulleys 22a are arranged in parallel and can be positioned at an angle that is not perpendicular to the linear arrangement of the holes in the gusset 32 (described below with reference to FIGS. 3 and 6). Each individual pulley 22a comprises a U-shaped housing with a pulley roller 22b mounted between the legs of the U-shaped housing. A suspension means 4 goes around the pulley roller 22b. The connecting bolt 22c is part of a spherical socket and extends from the housing toward the connecting system 12. The pulley system 22, in one embodiment, is similar to the pulley system that is described in US 7,665,580 and described above.

[00025] With reference to FIG. 2 and FIG. 3, where the connecting system 12 of FIG. 2 without a pulley device 22, the connecting system 12 comprises a housing that has two spaced side walls 30 that extend in parallel planes. The side walls 30 are arranged to receive part of the cross member of the supporting structure 14 (shown in broken lines in FIG. 2) between the side walls 30. The side walls 30 are arranged substantially parallel to each other. Each side wall 30 has a receiving hole 38. In the shown embodiment, each receiving hole 38 has an oblong shape. The rods 34 connect the side walls 30 to each other and, therefore, allow the cross-member to be positioned between the side walls 30. The rods 34 extend in a direction that is substantially perpendicular to the parallel planes of the side walls 30 and allow the side walls 30 to be adjusted for reliable fastening along the width of the supporting structure 14 .

[00026] As shown, for example, in FIG. 2, each side wall 30 has a generally rectangular shape, with through holes for rods 34 located in corners of a rectangular shape. In the shown embodiment, the connecting system 12 contains four rods 34, each of which has a rounded profile. However, it should be understood that more or fewer rods 34 may be used, or that the rods 34 may have a different profile, for example a non-circular profile, while the rods 34 securely fix the cross between the side walls 30.

[00027] As shown in FIG. 2-7, the longitudinal elements 34 extend between the side walls 30 and connect the side walls 30 to each other. Each side wall 30 has a corresponding number of passes, which are openings into which the longitudinal elements 34 are inserted.

[00028] The connecting system 12 comprises a gusset 32 that extends between the side walls 30 in a direction substantially perpendicular to the plane of the side walls 30. Each receiving hole 38 of the side walls 30 has special dimensions for receiving the gusset section 32 in motion so that the gusset 32 extends between the side walls 30 and could rotate around a vertical axis. The receiving hole 38 allows the chamfer 32, for example, to rotate 360 ° in any position necessary for proper alignment of the suspension means 4. The receiving hole 38 may also have a different shape if it fixes the chuck 32, and provides rotation of the chuck 32. The chamfer 32 has, at least one fastener configured to be connected to the pulley device 22. The fastener comprises, in one embodiment, a through hole for the connecting bolt 22c. In the embodiment shown, the gusset 32 has five through holes for accommodating the five connecting bolts 22c. It should be understood that not all through holes of the gusset 32 must be used, in the illustrated embodiment, up to five connecting bolts 22c can be used, others can use less than five.

[00029] In the various embodiments described herein, the chamfer 32 and the receiving holes 38 are located in close proximity to the end of each side wall 30. This end of each side wall 30 is hereinafter referred to as the upper end, while the opposite end of each side wall 30, referred to as the lower end. The reference to the upper and lower ends corresponds to the orientation of the connecting system 12 inside the shaft 8, as well as to the up and down movements of the cab 2.

[00030] In the immediate vicinity of the lower ends, each side wall 30 has at least one hole 46 configured to accommodate the transverse beam 36. The transverse beam 36 passes through the hole 46 of each side wall 30 parallel to the gusset 32 and in a direction perpendicular to the side the walls 30. The transverse beam 36 is fixed in the holes 46, for example, by means of bolts and nuts, or by any other means, against unintentional movements. In the shown embodiment, the connecting system 12 contains four transverse beams 36. However, it should be understood that the number of transverse beams 36 may vary, for example, due to changes in the load requirements of a particular elevator installation 1.

[00031] The location of the side walls 30, rods 34, gussets 32, and transverse beams 36 results in a housing structure having an opening with a substantially rectangular profile. This opening of the connecting system 12 is dimensioned to accommodate the cross member of the supporting structure 14. As shown in FIG. 2 and FIG. 3, a guss 32 is located above the cross member, and the transverse beams 36 are located under the cross member. In use, the cross member and the transverse beams 36 are pressed against each other, for example, the transverse beams 36 carry a supporting structure.

[00032] For fixing and / or adjusting the position of the cross member in the hole, the connecting system 12 comprises set screws 40, 40a, 48, 48a that are pressed against the cross member, as shown in FIG. 4. Each side wall 30 has an opening 42 through which a set screw 40 (40a) passes, as shown, for example, in FIG. 2, there was only one visible hole 42. In the embodiment shown, the hole 42 is a vertical cut made to vertically align the set screw 40 with respect to the cross member. The set screws 40, 40a are pressed against the side walls of the cross member and allow the connecting system 12 to be adjusted with respect to the cross member of the supporting structure 14. The set screws 48, 48 a pass, for example, through the through holes, through the gusset 32 and are pressed against the upper surfaces of the cross member. The corner sections 50 are mounted on the side walls 30 and are generally L-shaped. The short legs of the corner elements 50 mounted on the side walls 30, and each long leg has a longitudinal slot so large as to receive the set screws 48, 48a. The long legs are essentially parallel to the upper surface of the gusset 32. The set screws 48, 48a are movable along the longitudinal slots in order to provide a horizontal arrangement of the gusset 32.

[00033] FIG. 4-7 are a plan view (section, side view, top view, bottom view) of the connecting system 12 of FIG. 3. The cross section in FIG. 4 shows the rectangular hole of the connecting system 12 and the location of the cross member in this hole. The shape 32 extends on both sides of the side walls 30. The set screws 40, 40a pass through the side walls 30, and the set screws 48, 48a pass through the gusset 32, all of which are pressed against the cross member. The purpose of using the set screws 40, 40a, 48, 48a is to fix the position of the connecting system 12 with respect to the cross member of the supporting structure 14 so that, for example, in case the suspension means 4 ever sags (for example, when a buffer is hit or installed safety), the connecting system 12 will not move from its original position along the cross member of the supporting structure 14. Each set screw 40, 40a, 48, 48a has a cup-shaped bearing surface that interacts with the cross member. The supporting surface may be made of a material (eg, plastic or rubber) that is hard enough to fix the position of the connecting system 12, but also soft enough to absorb vibrations; it is preferable that the vibrations from the suspension means 4 not, or at least with a low value, extend across the cross member and therefore not into the cab 2. The rest of each set screw 40, 40a, 48, 48a is made of metal.

[00034] In the immediate vicinity of the abutment surface, each set screw 40, 40a, 48, 48a has a pair of (counter) nuts to allow adjustment and fixation of the length of the set screws 40, 40a, 48, 48a extending from the bottom of the gusset 32. The connecting bolts 22c pass through a gusset 32, where each connecting bolt 22c has a pair of nuts in the immediate vicinity of the abutment surface to allow adjustment and fixing of the connecting bolts 22c. In the embodiment shown, an additional washer plate 56 may be located between the lower portion of the gusset 32 and the nuts. It should be understood that instead of using such separate longitudinal plates of the washer, separate washers can be used.

[00035] The side view of FIG. 5 shows the arrangement of the transverse beams 36 in the hole 46 of the side wall 30. In the shown embodiment, the transverse beams 36 are evenly distributed. In other embodiments, implementation, however, this distance may be different. The illustrated embodiment of the side wall 30 has additional holes or cutouts 44 to minimize the weight of the side wall 30. However, it should be understood that in other embodiments, the side wall 30 does not have such holes or cuts 44.

[00036] The top view of FIG. 6 shows that the gusset 32 has a predetermined through hole pattern. The connecting bolts 22c are arranged in a line that extends at an angle with respect to the side walls 30. The angle can be adjusted from approximately 0 ° to approximately 360 °, depending on the particular embodiment. In addition to the through holes for the connecting bolts 22c, the gusset 32 has additional through holes 52 that are arranged in a line that runs perpendicular to the line along which the connecting bolts 22c are located. The difference between the line of through holes 52 and the line of through holes in which the connecting bolts 22c are located is that the line of through holes 52 has an even number of evenly distributed holes that are used when the number of suspension means is 2 or 4, and the line of through holes in of which the connecting bolts 22c are located, have an odd number of evenly distributed holes that are used when one, three or five suspension means 4 are used. In the embodiment of FIG. 3, this gusset 32 can be used when the number of suspension means 4 is five or less. That is, one chamfer 32 can be used for five pendant means 4. It should also be understood that if more than five pendant means 4 are needed, then a similar but larger size with a large number of through holes can be used. An additional line of through holes 52 may also be provided. This additional line of through holes 52 may be formed at any desired angle. The shape 32 may have other through holes 54, which are located along the boundary of the gusset 32 and are located specifically for alignment with the corner elements 50. These additional through holes 52, 54 provide additional flexibility in positioning the gusset 32.

[00037] The shape 32 has a rounded shape of a given diameter and thickness. In one embodiment, its diameter is about 500 mm, and its thickness is in the range from about 50 mm to about 60 mm, for example, about 50.8 mm. For such a face 32, the side walls 30 are spaced in a range of about 100 mm to about 350 mm and have heights of 450 mm and 580 mm, for example 453 mm and 574 mm. The shape 32 is made of steel, for example, low carbon steel or any other material that has sufficient mechanical strength to support the forces arising during normal load plus a predetermined safety factor. It should be understood that the gusset material, diameter and thickness, and the number of through holes can be selected depending on the load requirements. The same applies to the distance between the side walls 30 and their height. Preferably, the cutter 32 can rotate 360 °. Other shapes, such as a non-circular shape, may have a reduced radius of rotation.

[00038] The bottom view of FIG. 7 shows once again the arrangement of the transverse beams 36 and the plate 56 of the washer indicated with reference to FIG. 4. A pair (bottom) of rods 34 extends under the transverse beams 36, as shown in FIG. 7, and the pair (top) of the rods 34 extends over the gusset 32, as shown in FIG. 6. After adjustment, the rods 34 are attached to the side walls 30, for example, with the help of nuts screwed onto the ends of the threaded rods 34, or any other means of attachment.

[00039] After describing various embodiments of the connecting system 12 and the pulley device 22, a method for connecting the suspension means 4 and the supporting structure 14 is described below. Briefly, the gusset 32 is located above the part of the girder 14 and the side walls 30 are mounted on the gusset 32 in such so that the sections of the gusset 32 are rotatably located in the receiving hole 38 of the side walls 30 and a part of the supporting structure 14 extends between the side walls 30. The side walls are opposite each other and pass in parallel flat planes. In addition, the system of the pulley device 22 is attached to the gusset 32, while the pulley device 22 is configured to accommodate the suspension means 4.

[00040] Referring to a more detailed description, FIG. 8 is a flowchart of one embodiment of a method of installing a connecting system 12 and a pulley device 22. This method can be performed by upgrading the elevator installation, for example, by an installer working on the roof of the cab 2. Cab 2 was fixed by attaching the supporting structure 14 to guides, and, in case of modernization, any suspension means, for example, has been removed.

[00041] In step S1, the gusset 32 is located above the cross member (or traverse). The shape 32 can be lifted and / or fixed above the cross member, for example, placed in the center, along the length of the cross member.

[00042] In step S2, the required hole pattern is selected and the contact angle is determined. The contact angle is the angle at which the gusset 32 must be placed for the alignment of the suspension means 4, i.e. to offset any curvature of the suspension means 4 between the cab 2 and the counterweight 6. In one embodiment, the hole pattern is shown in FIG. 6, i.e., five suspension means 4 arranged in a row are selected.

[00043] The contact angle depends on the location of the counterweight 6 in the shaft and the position of the actuator 10 (base plate), for example, in the engine room. Typically, the linear pulley device 22 is mounted perpendicular to the line that connects the center of the cab 2 to the center line of the counterweight 6, as shown in a plan view from FIG. 9. However, for some installations this is not possible, and the linear arrangement is beveled from perpendicular, as shown in the top view in FIG. 10. In these cases, each pulley 22a in a specific pulley arrangement 22 is rotated so that the (flat, band) suspension means 4 are sufficiently parallel to the imaginary line connecting the center of the elevator car and the counterweight. An optimal contact angle is a combination of the angle through which the through holes in the gusset 32 form a cross member and the angle at which each individual pulley 22a is mounted so that only the smallest curvature is transmitted to the flat suspension means 4. The specified contact angle cannot be the final angle; it should be understood that the gusset 32 can rotate and fine-tune at any time during the installation procedures.

[00044] In step S3, the components of the connecting system 12 are defined. A side wall 30 is mounted on each side of the cross member, nuts and washers are mounted on each side of each rod 34 to establish the absolute minimum width of the distance between the side walls 30. These sides of the rods 34 have in one embodiment threaded parts. After installation, these nuts and washers are placed on the inside of the side walls 30, as shown in FIG. 3. The side walls 30 should be located symmetrically with respect to the center of the profile 32. The nuts and washers located on the rods 34 are attached to the rods 34 as much as necessary to achieve this position.

[00045] In step S4, the components of the connecting system 12 are pre-assembled. The side walls 30 are initially loosely mounted around the cross member and the gusset 32 is inserted into the holes 38 of the side wall 30. One way to achieve this initial fit is to insert the gusset 32 into the hole 38 of one side walls 30, insert the rods 34 into their respective holes of these side walls 30 and place the second side wall 30 on the rods 34 with a gusset 32 inserted in the hole 38 of this side wall 30.

[00046] In step S5, the transverse beams 36 are inserted into the hole 46 of each side wall 30. The transverse beams 36 are fixed in the hole 46 of one side wall 30.

[00047] In step S6, the set screws 48, 48a are mounted on the gusset 32. The set screws 48, 48a are adjusted with the rest on the surface of the cross member. The height of the chamfer 32 is set so as to ensure a proper fit for the transverse beams under the cross member 36. The set screws 48, 48a are then adjusted to fit the chute 32 above the cross member.

[00048] As mentioned above, each side wall 30 may be formed by four separate plates. In such an embodiment, these plates may be attached to rods 34 on each side of the cross member.

[00049] In step S7, once the proper fit is checked, the assembly is then checked and all threaded connections are tightened. Then it is again verified that the fixed fit is made without any risk to work, that the gusset 32 is in the center and secured in the holes 38 of the side walls 30. In one embodiment, the gusset 32 protrude approximately 31.75 mm further than the outside of the side walls 30.

[00050] In step S8, the connecting bolts 22c, together with the pulleys 22a, are mounted on the gusset 32 and secured to the lower side of the gusset 32 by means of nuts and cotter pins. After installation, the connecting bolts 22c pass through the gusset 32 towards the pulley device 22, as shown in FIG. 2.

[00051] In step S9, the suspension means 4 is inserted (secured) in each pulley 22a. Pulleys 22 are adjusted and secured, as necessary. This step is repeated until all the suspension means 4 are inserted into the pulleys 22a.

[00052] In step SI0, the set screws 40, 40a are inserted into the holes 42. The set screws 40, 40a are adjusted to press the cross member for the horizontal arrangement of the connecting system 12 with respect to the cross member.

[00053] Various components of the connecting system 12 are described with reference to FIG. 2-7 are made in the connecting system 12 as a modular design. The modular design of the connecting system 12 greatly facilitates the installation process. Each individual component is relatively lightweight and can be operated separately. In one embodiment, each side wall 30 may be formed by separate wall panels. As shown, for example, in FIG. 3 and 4, each side wall 30 is formed by four thin and therefore lightweight wall panels. It should be understood that the number of individual wall panels may vary depending on certain load requirements.

[00054] In addition, the individual components of the connecting system 12 can be individually replaced, if necessary. These components can be selected depending on specific or modified load requirements.

[00055] It will become apparent that a system and method has been disclosed for connecting a suspension means and a supporting structure of an elevator installation that are fully consistent with the objects, means, and advantages set forth herein before. For example, the connecting system 12 serves as an interface between the suspension means 4 and the cabin 2 and, in particular, is preferred for upgrading the elevator installation, where the existing elevator car and the counterweight must be stored without any modifications. The connecting system 12 with its rotating gusset 32 is designed to accommodate any installation angle on the side of the elevator car and the counterweight, which is due to the different layout of the shaft. In addition, the connecting system 12, due to its rectangular opening (see FIG. 4), accommodates various cross-section profiles. The connection formed by the connecting system 12 does not require drilling in place (for example, drilling a cross member) and does not require modification of the cross member or crosshead.

Claims (18)

1. A system for connecting a suspension means and a supporting structure of an elevator installation, comprising:
a case having two spaced side walls, the side walls being arranged to accommodate part of the supporting structure between the side walls, and each side wall has a receiving hole of a given shape, and
a fitting in which there is at least one fixture configured to be connected to a pulley arrangement for a suspension means,
where each receiving hole has dimensions for placement with the possibility of moving sections of the gusset so that the gusset passes between the side walls and can rotate around a vertical axis. 2. The system according to claim 1, characterized in that the gusset has a rounded shape. 3. The system according to claim 2, characterized in that the sections of the round gusset pass through the receiving holes. 4. The system according to p. 2, characterized in that the gusset is configured to rotate in the range from approximately 0 ° to approximately 360 °. 5. The system according to p. 1, characterized in that at least one mount contains a hole that is sized to accommodate the shaft of the pulley device. 6. The system according to p. 5, characterized in that several holes are located along two straight perpendicular lines. 7. The system under item 1, characterized in that it further comprises a predetermined number of longitudinal elements passing between the side walls and connecting the side walls. 8. The system according to p. 7, characterized in that each side wall has a corresponding number of passages, each of which places the final section of the longitudinal element with the possibility of its removal. 9. The system according to claim 1, characterized in that each side wall has an upper part containing a receiving hole, and a lower part having an opening for the transverse beam. 10. The system according to p. 1, characterized in that it further comprises the first set screws passing through the gusset, and configured to press against the upper surface of the cross member of the supporting structure for vertical
the location of the system with respect to the supporting structure, and second set screws passing through the side walls to press against the side walls of the cross member of the supporting structure for horizontal arrangement of the system. 11. The system according to p. 10, characterized in that each set screw has a supporting surface pressed against the supporting structure, which contains the material selected to reduce vibration. 12. An elevator installation comprising:
suspension means;
a pulley device connected to the suspension means;
supporting structure; and
a connecting system configured to connect a pulley device and a supporting structure, where the connecting system comprises:
a housing having two spaced side walls, where the side walls are arranged to accommodate part of the supporting structure between the side walls, and where each side wall has a receiving hole of a given shape; and
a gusset having at least one mount configured to be connected to a pulley device,
where each receiving hole has dimensions for placement with the possibility of moving sections of the gusset so that the gusset passes between the side walls and can rotate around a vertical axis. 13. Installation according to p. 12, characterized in that the gusset has a rounded shape. 14. Installation according to p. 13, characterized in that the sections of the round gusset pass through the receiving holes. 15. Installation according to claim 13, characterized in that the gusset is configured to rotate in the range from about 0 ° to about 360 °. 16. The method of connecting the suspension means and the supporting structure of the elevator installation, including:
the location of the gusset over a part of the supporting structure;
the installation of the side walls on the gusset so that the sections of the gusset are rotatably located in the receiving holes of the side walls, and part of the supporting structure extends between the side walls, while the side walls are located opposite each other and extend in parallel planes; and
the installation of the pulley device on the face, while the pulley device is configured to accommodate the suspension means. 17. The method according to p. 16, characterized in that the installation of the side walls includes connecting the side walls by means of rods and inserting a transverse beam into the hole in the lower part and on each side wall, while the transverse beam passes under part of the supporting structure. 18. The method according to p. 16, characterized in that it further includes the installation of set screws on the gusset to secure the vertical position of the gusset relative to the part of the supporting structure and the installation of set screws on the side walls to secure the horizontal position of the part of the supporting structure with respect to the side walls.

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