Elevator cage support structure and modular elevator including same

The elevator cage support structure and associated bracket systems address the challenges of prolonged installation and safety risks in modular elevator construction by providing stable and easy-to-install support for the cage and scaffolding, enhancing safety and reducing construction time and costs.

WO2026146758A1PCT designated stage Publication Date: 2026-07-09HYUNDAI ELEVATOR CO LTD

Patent Information

Authority / Receiving Office
WO · WO
Patent Type
Applications
Current Assignee / Owner
HYUNDAI ELEVATOR CO LTD
Filing Date
2025-08-25
Publication Date
2026-07-09

AI Technical Summary

Technical Problem

Conventional elevator construction methods involve on-site assembly, leading to prolonged installation periods, increased safety risks, and delayed schedules due to the lack of a dedicated support structure for the elevator cage during modular elevator installation, which complicates vertical work and increases operating costs.

Method used

An elevator cage support structure with a fixed bracket portion detachably coupled to the frame and a support beam positioned in the elevator shaft, along with a bracket structure for scaffolding installation and a control panel adjustment bracket, enabling stable support and easy installation, dismantling, and maintenance of the elevator cage and scaffolding.

Benefits of technology

Facilitates efficient and safe installation and maintenance of modular elevators by providing stable support, reducing construction time, improving safety, and allowing for easy repositioning and adjustment of components, thereby enhancing overall construction efficiency and reducing costs.

✦ Generated by Eureka AI based on patent content.

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Abstract

An elevator cage support structure according to one embodiment of the present invention comprises: a fixing bracket unit detachably coupled to a frame of a modular elevator; and a support beam positioned in a hoistway to support a cage of the elevator and coupled to the fixing bracket.
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Description

Elevator cage support structure and modular elevator including the same

[0001] The present invention relates to an elevator cage support structure and a modular elevator including the same, and more specifically, to an elevator cage support structure that provides a stable support structure for the cage for the installation and maintenance of the elevator cage during the construction of a modular elevator, and a modular elevator including the same.

[0002] Conventional elevator construction methods have involved assembling and installing the elevator components on-site after the building's steel frame has been completed.

[0003] Consequently, the installation period is prolonged as it takes a significant amount of time to install elevators on-site. Furthermore, the risk of safety accidents due to working at heights is high during elevator installation, which leads to increased operating costs at the site and can prolong the installation duration.

[0004] In addition, due to the specialized nature of elevator installation, on-site work is primarily carried out vertically; since vertical work makes it impossible to perform installations simultaneously in the up and down directions, the construction schedule may be delayed.

[0005] Modular elevators are being developed to solve this problem.

[0006] Meanwhile, during the installation process of the modular elevator, the cage must be supported after being inserted into the elevator shaft until roping.

[0007] However, conventionally, there is no dedicated support structure to support the elevator cage, so it is not possible to support the elevator cage stably and efficiently, and it has the problem of causing safety accidents.

[0008] The present invention is intended to provide an elevator cage support structure capable of stably supporting a cage during the installation process of a modular elevator as a beam supporting the cage is fixed by a bracket, and a modular elevator including the same.

[0009] In addition, the present invention is intended to provide an elevator cage support structure that is simple in structure, easy to install, and can be easily dismantled after the cage is roping, and a modular elevator including the same.

[0010] In addition, the present invention is intended to provide an elevator cage support structure capable of easily supporting the cage for maintenance even after the construction of a modular elevator, and a modular elevator including the same.

[0011] In addition, the present invention aims to provide a bracket structure for scaffolding installation that enables easier and safer installation of scaffolding for the construction and maintenance of a modular elevator, and a modular elevator including the same.

[0012] In addition, the present invention is intended to provide a bracket structure for scaffolding installation that ensures rigidity and stability by supporting the upper and lower parts of the scaffolding, and a modular elevator including the same.

[0013] In addition, the present invention is intended to provide a modular elevator that is detachably coupled to the frame of a steel-framed modular elevator.

[0014] In addition, the present invention is intended to provide a bracket structure for scaffolding installation that allows scaffolding to be easily and quickly mounted at any time even after the elevator has been installed, and a modular elevator including the same.

[0015] In addition, the present invention is intended to provide a bracket structure capable of positioning a control panel and a modular elevator including the same.

[0016] In addition, the present invention is intended to provide a control panel adjustment bracket structure capable of safely moving a control panel from a manufacturing plant to a construction site and stably fixing its position after movement, and a modular elevator modular including the same.

[0017] In addition, the present invention is intended to provide a control panel adjustment bracket structure capable of easily and accurately moving the control panel and stably fixing it after movement, and a modular elevator including the same.

[0018] In addition, the present invention is intended to provide a control panel adjustment bracket structure with secured structural strength and durability, and a modular elevator including the same.

[0019] In addition, the present invention is intended to provide an electronic device including a cable connection structure capable of efficiently performing module-unit cable division and inter-floor connection, and a modular elevator including the same.

[0020] In addition, the present invention is intended to provide an electronic device comprising a limit switch cam capable of accurately positioning a limit switch cam at a predetermined location on the floor surface to detect and operate the precise position of the elevator on each floor, and a modular elevator comprising the same.

[0021] In addition, the present invention is intended to provide an electronic device including a hatch cable hanger that can prevent damage and tangling of cables and improve ease of management by organizing cable wiring inside the hatch, and a modular elevator including the same.

[0022] In addition, the present invention is intended to provide a modular electronic device that simplifies the installation and connection of electronic devices and reduces installation time, and a modular elevator including the same.

[0023] In addition, the present invention aims to provide a cable terminal block capable of stably transmitting a signal without performance degradation when a cable is connected between a hoisting machine and a control panel in a modular elevator, and a modular elevator including the same.

[0024] In addition, the present invention is intended to provide a cable terminal block that can reduce noise and signal loss that may occur due to cable splitting, and a modular elevator including the same.

[0025] In addition, the present invention is intended to provide a cable terminal block that is easy to install and maintain and can be easily assembled on-site due to the characteristics of modular construction, and a modular elevator including the same.

[0026] An elevator cage support structure according to one embodiment of the present invention includes a fixed bracket portion detachably coupled to the frame of a modular elevator, and a support beam positioned in the elevator shaft to support the elevator cage and coupled to the fixed bracket.

[0027] In addition, in an elevator cage support structure, the fixed bracket portion includes a first fixed bracket coupled to the frame, and the first fixed bracket includes a first support beam support portion that fixes and supports the lower part of the support beam and a first frame fixing portion that fixes and supports the frame, and the first frame fixing portion is located on both sides of the first support beam support portion, and the first support beam support portion may be extended to protrude vertically from the first frame fixing portion.

[0028] In addition, in the elevator cage support structure, the first frame fixing part may have a first frame coupling hole into which a fixing part is inserted so as to be detachably coupled to the frame.

[0029] In addition, in the elevator cage support structure, the first support beam support includes an upright portion and a flat plate portion, the upright portion is connected to the first frame fixing portion so as to extend vertically from the first frame fixing portion, and the flat plate portion can be connected to the upright portion.

[0030] In addition, in the elevator cage support structure, a support beam coupling hole is formed in the flat plate portion for fixing the support beam by a fixing member, and a fixing bracket coupling hole corresponding to the support beam coupling hole is formed in the support beam, and the fixing member can be coupled to the fixing bracket coupling hole and the support beam coupling hole.

[0031] In addition, in the elevator cage support structure, the fixed bracket portion includes a second fixed bracket coupled to the frame, and the second fixed bracket may include a second support beam support portion that supports the lower part of the support beam, a second frame fixing portion that is fixed and supported to the frame, and a cover support portion that covers and supports the upper and side parts of the support beam.

[0032] In addition, in the elevator cage support structure, the second frame fixing member is located on both sides of the second support beam support member, the second support beam support member is extended to protrude vertically from the second frame fixing member, and the cover support member can be coupled to the second support beam support member and protrude upward to form an internal space.

[0033] In addition, in the elevator cage support structure, the internal space may be formed to correspond to the support beam so that the support beam can be inserted.

[0034] In addition, in the elevator cage support structure, the fixed bracket portion includes a first fixed bracket and a second fixed bracket, and the first fixed bracket and the second fixed bracket are each coupled to a horizontal frame, and the first fixed bracket and the second fixed bracket can support and fix both sides of the support beam.

[0035] A modular elevator according to one embodiment of the present invention may include an elevator cage support structure and a horizontal frame to which the elevator cage support structure is detachably coupled.

[0036] In addition, in a modular elevator, the elevator cage support structure can be coupled to an intermediate floor elevator module.

[0037] In addition, in a modular elevator, the fixing bracket of the elevator cage support structure can be connected to horizontal frames located on both sides of the elevator shaft.

[0038] A modular elevator according to another embodiment of the present invention may include a bracket structure for scaffolding installation that is detachably coupled to the horizontal frame and a scaffolding coupled to the bracket structure for scaffolding installation.

[0039] A modular elevator according to another embodiment of the present invention may include a support bracket portion of a control panel adjustment bracket structure coupled to the frame of the modular elevator and a control panel coupled to a movable bracket portion of the control panel adjustment bracket structure.

[0040] A modular elevator according to another embodiment of the present invention may further include an electronic device coupled to the frame of the modular elevator. The cable connection structure of the electronic device may have a connection portion arranged to correspond to each floor of a plurality of intermediate floor elevator modules.

[0041] A modular elevator according to yet another embodiment of the present invention may include a beam coupled and supported to the frame of the modular elevator and a cable terminal block seated and coupled to the beam.

[0042] The present invention facilitates easy installation and dismantling, reduces working time and costs, and shortens elevator construction and maintenance time.

[0043] In addition, it can improve on-site work safety and enhance installation quality.

[0044] In addition, scaffolding installation is easy, and as installation time is reduced, elevator construction and maintenance time is shortened.

[0045] In addition, worker safety is guaranteed as the safety of the scaffolding's joint structure is ensured.

[0046] In addition, cost savings can be achieved as the bracket structure for scaffolding installation can be recycled.

[0047] In addition, the ability to adjust the position of the control panel improves installation stability and construction efficiency.

[0048] In addition, as the control panel slides and allows for position adjustment, work time is shortened and the burden on the operator is reduced.

[0049] In addition, safety and durability are improved as the position of the control panel is simply and stably fixed by a stopper.

[0050] In addition, space utilization is improved as the control panel can be installed and repositioned within the limited space of the modular elevator frame.

[0051] In addition, through modular cable division and inter-layer connection structures, cable management efficiency is enhanced, and not only are installation and maintenance tasks simplified, but cable management efficiency is also increased.

[0052] In addition, the precise placement of the limit switch cams enables accurate detection of the elevator's position, ensuring safe and accurate operation; this not only enhances elevator safety but also increases passenger safety.

[0053] In addition, the application of hatch cable hangers prevents damage and tangling of cables and improves the ease of cable wiring management.

[0054] In addition, the modular electronic device structure enables easy on-site installation, which shortens installation time and reduces overall installation costs.

[0055] In addition, the reliability of the modular elevator is improved as the problem of performance degradation caused by cable splitting is fundamentally resolved.

[0056] In addition, by minimizing cable noise, the quality of signals transmitted to the control panel is maintained, and work efficiency is improved through a structure designed for easy on-site installation and maintenance.

[0057] FIG. 1 is a schematic diagram illustrating an elevator cage support structure according to an embodiment of the present invention.

[0058] Figure 2 is a schematic exploded view of the elevator cage support structure illustrated in Figure 1.

[0059] FIG. 3 is a schematic diagram of the usage state of an elevator cage support structure according to an embodiment of the present invention.

[0060] FIG. 4 is a schematic diagram illustrating a modular elevator including an elevator cage support structure according to an embodiment of the present invention.

[0061] FIG. 5 is a schematic diagram illustrating a bracket structure for scaffolding installation according to another embodiment of the present invention.

[0062] FIG. 6 is a schematic diagram showing the lower bracket in the bracket structure for scaffolding installation shown in FIG. 5.

[0063] FIG. 7 is a schematic diagram showing the lower bracket in the bracket structure for scaffolding installation shown in FIG. 5.

[0064] FIG. 8 is a schematic diagram of the usage state of a bracket structure for scaffolding installation according to another embodiment of the present invention.

[0065] FIG. 9 is a schematic diagram illustrating a modular elevator including a bracket structure for scaffolding installation according to another embodiment of the present invention.

[0066] FIG. 10 is a schematic diagram illustrating a control panel adjustment bracket according to another embodiment of the present invention.

[0067] FIG. 11 is an exploded view schematically illustrating the control panel adjustment bracket shown in FIG. 10.

[0068] FIG. 12 is a schematic first usage state diagram of a control panel adjustment bracket according to another embodiment of the present invention.

[0069] FIG. 13 is a schematic second usage state diagram of a control panel adjustment bracket according to another embodiment of the present invention.

[0070] FIG. 14 is a schematic diagram illustrating a modular elevator including a control panel adjustment bracket according to another embodiment of the present invention.

[0071] FIG. 15 is a schematic diagram illustrating a cable connection structure according to another embodiment of the present invention.

[0072] FIG. 16 is a schematic diagram illustrating a limit switch cam according to another embodiment of the present invention.

[0073] FIG. 17 is a schematic diagram illustrating a hatch cable hanger according to another embodiment of the present invention.

[0074] FIG. 18 is a schematic diagram illustrating an electronic device including a cable connection structure according to another embodiment of the present invention and a modular elevator including the same.

[0075] FIG. 19 is a schematic diagram illustrating a cable terminal block according to yet another embodiment of the present invention.

[0076] FIG. 20 is a perspective view illustrating a cable input port and a terminal connection part according to yet another embodiment of the present invention.

[0077] FIG. 21 is a perspective view illustrating a terminal connection portion according to yet another embodiment of the present invention.

[0078] FIG. 22 is a schematic diagram of the usage state of a cable terminal block according to yet another embodiment of the present invention.

[0079] FIG. 23 is a schematic diagram illustrating an elevator including a cable terminal block according to yet another embodiment of the present invention.

[0080] Embodiments of the present invention are described below with reference to the attached drawings so that those skilled in the art can easily implement them. However, the present invention may be embodied in various different forms and is not limited to the embodiments described herein.

[0081] In addition, to clearly explain the invention in the drawings, parts unrelated to the explanation have been omitted, and similar parts throughout the specification have been given similar reference numerals.

[0082] Throughout the specification, when a part is described as "comprising" a certain component, this means that, unless specifically stated otherwise, it does not exclude other components but may include additional components.

[0083] It should be understood that the technology described in the present invention is not intended to limit specific embodiments and includes various modifications, equivalents, and / or alternatives to the embodiments of the present invention.

[0084] The expression “configured to” as used in the present invention may be replaced, depending on the context, with, for example, “suitable for,” “having the capacity to,” “designed to,” “adapted to,” “made to,” or “capable of.” The term “configured to” may not necessarily mean only that which is “specifically designed to” in hardware. Instead, in some situations, the expression “device configured to” may mean that the device is “capable of” together with other devices or components.

[0085] The prior art described in the present invention is incorporated herein by reference in its entirety, and it will be understood that a person skilled in the art may apply the contents described in the prior art to the parts briefly described in the present invention.

[0086] Each component included in each embodiment in this specification can be combined with one another between embodiments.

[0087]

[0088] [Description of the composition of the elevator cage support structure]

[0089] FIG. 1 is a schematic diagram illustrating an elevator cage support structure according to an embodiment of the present invention, and FIG. 2 is a schematic exploded diagram of the elevator cage support structure illustrated in FIG. 1.

[0090] More specifically, the elevator cage support structure (1000) is intended to support the cage for the installation and maintenance of the elevator cage and is detachably coupled to the frame of the modular elevator. The frame can be exemplified by the horizontal frame (HF1, HF2 in FIG. 3 and 4) in this embodiment.

[0091] As described above, the elevator cage support structure (1000) includes a support beam (1110) and a fixed bracket part (1120).

[0092] The support beam (1110) is for supporting the elevator cage and is located in the elevator shaft, and can be implemented as an H-shaped beam as shown in FIG. 1.

[0093] The support beam (1110) is seated and connected to the fixed bracket part (1120).

[0094] The fixed bracket part (1120) is for fixing the support beam (1110) to the horizontal frame of the elevator.

[0095] The fixed bracket portion (1120) may include a first fixed bracket (1121) and a second fixed bracket (1122).

[0096] The first fixing bracket (1121) and the second fixing bracket (1122) are intended to support and fix the support beam (1110) while connected to the horizontal frame.

[0097] The first fixing bracket (1121) and the second fixing bracket (1122) can each support and fix both sides of the support beam (1110).

[0098] Additionally, both sides of the support beam (1110) may be supported and fixed with the first fixing bracket (1121), and both sides of the support beam (1110) may be supported and fixed with the second fixing bracket (1122).

[0099] FIGS. 1 to 5 illustrate an embodiment thereof in which a first fixing bracket (1121) and a second fixing bracket (1122) each support and fix both sides of a support beam (1110).

[0100] The first fixed bracket (1121) includes a first support beam support part (1121a) and a first frame fixing part (1121b).

[0101] The first frame fixing part (1121b) is located on both sides of the first support beam support part (1121a), and the first support beam support part (1121a) can be extended to protrude vertically from the first frame fixing part (1121b). The structure protruding vertically can facilitate the safe distribution of gravity loads and can be particularly advantageous for stably supporting the load of the cage.

[0102] The first support beam support part (1121a) is for fixing and supporting the lower part of the support beam (1110).

[0103] The first support beam support member (1121a) includes an upright member (1121a') and a flat plate member (1121a"), the upright member (1121a') is connected to the first frame fixing member (1121b) so as to extend vertically from the first frame fixing member (1121b), and the flat plate member (1121a") is connected to the upright member (1121a').

[0104] A support beam coupling hole (1221a"1) is formed in the flat plate portion (1121a"). The support beam coupling hole (1221a"1) is for inserting a fixing member (not shown).

[0105] A fixing bracket coupling hole (1111) corresponding to a supporting beam coupling hole (1221a"1) is formed in the supporting beam (1110). A fixing member is coupled to the fixing bracket coupling hole (1111) and the supporting beam coupling hole (1221a"1).

[0106] The first frame fixing part (1121b) is intended to be fixed and supported on the horizontal frame.

[0107] A first frame coupling hole (1121b') is formed in the first frame fixing part (1121b).

[0108] The first frame coupling hole (1121b') is for inserting a fixing member (not shown), and the fixing member is coupled to the horizontal frame so as to be detachably attached through the first frame coupling hole (1121b').

[0109] A support beam (1110) is inserted and fixed in the second fixed bracket (1122).

[0110] To this end, the second fixed bracket (1122) includes a second support beam support (1122a), a second frame fixing part (1122b), and a cover support part (1122c).

[0111] The second frame fixing part (1122b) is located on both sides of the second support beam support part (1122a), and the second support beam support part (1122a) can be extended to protrude vertically from the second frame fixing part (1122b).

[0112] The second support beam support (1122a) is intended to support the lower part of the support beam (1110).

[0113] The second support beam support (1122a) includes an upright section (1122a') and a flat plate section (1122a"), the upright section (1122a') is connected to the second frame fixing section (1122b), and the flat plate section (1122a") is connected to the upright section (1122a').

[0114] The second frame fixing part (1122b) is intended to be fixed and supported on the horizontal frame.

[0115] A second frame coupling hole (1122b') is formed in the second frame fixing part (1122b).

[0116] The second frame coupling hole (1122b') is for inserting a fixing member (not shown), and the fixing member is coupled to the horizontal frame so as to be detachably attached through the second frame coupling hole (1222b').

[0117] The cover support (1122c) is intended to cover and support the upper and side portions of the support beam (1110).

[0118] The cover support (1122c) is coupled to the second support beam support (1122a) and protrudes upward to form an internal space (1122c').

[0119] The internal space is formed to correspond to the support beam (1110) so that the support beam (1110) can be inserted.

[0120] The second support beam support portion (1122a), the second frame fixing portion (1122b), and the cover support portion (1122c) of the second fixing bracket (1122) are formed integrally, and the support beam (1110) can be inserted into the internal space portion (1122c') of the cover support portion (1122c).

[0121] In this case, the lower part of the support beam (1110) is supported by the second support beam support part (1122a), and the side and upper part of the support beam (1110) are supported by the cover support part (1122c).

[0122]

[0123] [Example of operation of elevator cage support structure]

[0124] FIG. 3 is a schematic diagram of the usage state of an elevator cage support structure according to one embodiment of the present invention.

[0125] As described above, the elevator cage support structure (1000) is connected to the horizontal frame (HF) of the modular elevator (ME).

[0126] More specifically, the fixed bracket part (1120) is coupled to the horizontal frame (HF1, HF2), and the support beam (1110) is fixed to the fixed bracket part (1120).

[0127] At this time, the support beam (1110) is positioned to cross the elevator shaft. To this end, the fixed bracket portion (1120) is connected to horizontal frames (HF) located on both sides of the elevator shaft.

[0128] Additionally, a first fixing bracket (1121) may be attached to a horizontal frame (HF1) located on one side of the elevator shaft, and a second fixing bracket (1122) may be attached to a horizontal frame (HF2) located on one side of the elevator shaft.

[0129] Meanwhile, after the installation of the cage is completed, the elevator cage support structure (1000) may be removed, and only the support beam (1110) may be removed for future maintenance.

[0130] FIG. 4 is a schematic diagram illustrating a modular elevator including an elevator cage support structure.

[0131] As described above, the modular elevator (100) includes a plurality of elevator modules (100a, 100b, 100c). The plurality of elevator modules (100a, 100b, 100c) may include a top floor elevator module (100a), a middle floor elevator module (100b), and a bottom floor elevator module (100c).

[0132] A machine room (100a1) in which a hoisting machine, control panel, inverter, etc. are placed may be constructed in the top floor elevator module (100a). The bottom floor elevator module (100c) may be constructed as a pit module so as to be inserted into the ground.

[0133] The lower floor elevator module (100c) may have a buffer and a pit screen (100c1) installed.

[0134] The middle floor elevator module (100b) is located between the top floor elevator module (100a) and the bottom floor elevator module (100c).

[0135] The intermediate floor elevator module (100b) may include a plurality of intermediate floor elevator modules (110). Each of the plurality of intermediate floor elevator modules (110) may be coupled to a building module (200) corresponding to the floor.

[0136] And multiple intermediate floor elevator modules (110) and building modules (200) can be combined in a combined state in a stacking direction (V).

[0137] A plurality of intermediate floor elevator modules (110) include a rail section (111) that guides the operation of the elevator car.

[0138] A modular elevator according to one embodiment of the present invention includes an elevator cage support structure (1000) coupled to a plurality of intermediate floor elevator modules.

[0139] An elevator cage support structure (1000) is detachably connected to the horizontal frame (HF) of the intermediate floor elevator module (110).

[0140] More specifically, the elevator cage support structure (1000) includes a support beam (1110) and a fixed bracket part (1120).

[0141] The support beam (1110) is supported by the fixed bracket part (1120).

[0142] The fixed bracket part (1120) is connected to the horizontal frame (HF).

[0143] At this time, the fixed bracket is connected to the horizontal frames located on both sides relative to the elevator shaft.

[0144] As the modular elevator according to one embodiment of the present invention is constructed as described above, the elevator cage support structure (1000) can stably and easily support the elevator cage until the cage is roping, thereby improving the safety and efficiency of the installation work.

[0145] Additionally, the modular elevator (100) can remove only the support beam (1110) after the cage is roping.

[0146]

[0147] [Another embodiment: Application of a bracket structure for scaffolding installation]

[0148] FIG. 5 is a schematic diagram illustrating a bracket structure for scaffolding installation according to another embodiment of the present invention.

[0149] More specifically, the bracket structure (3000) for scaffolding installation is for supporting scaffolding for elevator installation and maintenance and is coupled to the frame of the modular elevator.

[0150] As described above, the bracket structure (3000) for scaffolding installation includes an upper bracket (3100) and a lower bracket (3200).

[0151] The upper bracket (3100) supports the upper part of the scaffolding and is connected to the lower bracket (3200).

[0152] The lower bracket (3200) is detachably connected to the frame of the modular elevator and supports the lower part of the scaffolding.

[0153] The upper bracket (3100) can be detachably connected to the lower bracket (3200).

[0154] FIG. 5 shows a bracket structure (3000) for scaffolding installation according to another embodiment of the present invention. As the upper and lower parts of the scaffolding are supported by the bracket structure (3000) for scaffolding installation, the scaffolding is stably supported without shaking on the modular elevator and is detachably coupled.

[0155] Hereinafter, the detailed technical configuration and organic coupling structure of the bracket structure for scaffolding installation will be described in more detail with reference to FIGS. 6 to 8.

[0156] FIG. 6 is a schematic diagram showing the lower bracket in the bracket structure for scaffolding installation shown in FIG. 5.

[0157] More specifically, the lower bracket (3200) is coupled to the frame of the modular elevator (ME, 100 in FIG. 8 and 9) and is intended to support the lower part of the scaffolding. The frame can be exemplified by the horizontal frame (HF) in this embodiment.

[0158] As described above, the lower bracket (3200) includes a mounting plate portion (3210) and a support plate portion (3220). The mounting plate portion (3210) may be formed to extend in a direction perpendicular to the support plate portion (3220).

[0159] The mounting plate (3210) has a mounting groove (3211) formed therein so that the scaffolding can be mounted. The mounting groove (3211) can be formed to correspond to the size and shape of the scaffolding.

[0160] An upper bracket coupling hole (3212) is formed in the mounting plate (3210).

[0161] The upper bracket coupling hole (3212) is for inserting a fixing member (not shown) for coupling with the upper bracket (3100).

[0162] The upper bracket coupling hole (3212) is formed to correspond to the lower bracket coupling hole (1121 in FIG. 3) of the upper bracket (3100).

[0163] The fixing member is inserted and coupled into the upper bracket coupling hole (3212) and the lower bracket coupling hole (3121) while positioned so that the upper bracket coupling hole (3212) and the lower bracket coupling hole face each other.

[0164] Additionally, the mounting groove (3211) may be formed to extend upward from the mounting plate (3210) so that the scaffolding is inserted and seated on the upper part of the mounting plate (3210).

[0165] The support plate (3220) is connected to and supported by the horizontal frame (HF) of the modular elevator (ME).

[0166] To this end, a frame coupling hole (3221) is formed in the support plate portion (3220).

[0167] The frame coupling hole (3221) is for inserting a fixing member (not shown), and the fixing member is coupled to the horizontal frame (HF) through the frame coupling hole (3221).

[0168] FIG. 7 is a schematic diagram showing the upper bracket in the bracket structure for scaffolding installation shown in FIG. 5.

[0169] More specifically, the upper bracket (3100) is fixed to the lower bracket (3200) to support the upper part of the scaffolding.

[0170] As described above, the upper bracket (3100) includes a pressure plate portion (3110) and a connecting plate portion (3120).

[0171] The pressure plate portion (3110) is intended to support the upper part of the scaffolding that is seated in the mounting groove portion (3211) formed in the mounting plate portion (3210) of the lower bracket (3200).

[0172] The connecting plate portion (3120) extends downward from the pressure plate portion (3110) and is intended to be connected to the lower bracket (3200).

[0173] A lower bracket coupling hole (3121) is formed in the coupling plate portion (3120).

[0174] The lower bracket coupling hole (3121) is for inserting a fixing member (not shown) to be coupled to the lower bracket (3200).

[0175] The lower bracket coupling hole (3121) corresponds to the upper bracket coupling hole (3212).

[0176]

[0177] [Example of operation of a bracket structure for scaffolding installation according to another embodiment]

[0178] FIG. 8 is a schematic diagram of the usage state of a bracket structure for scaffolding installation according to another embodiment of the present invention.

[0179] As described above, the bracket structure (3000) for scaffolding installation is connected to the horizontal frame (HF) of the modular elevator (ME, 100).

[0180] The scaffolding (S) is inserted into a mounting groove (shown as 1211 in FIG. 2) formed in the mounting plate portion (3210) of the lower bracket (3200).

[0181] The upper bracket (3100) supports the upper part of the scaffolding (S) and is fixed to the lower bracket (3200).

[0182] The bracket structure (3000) for installing scaffolding is connected to both sides of the horizontal frame (HF) of the modular elevator (100). And both sides of the scaffolding (S) are connected to and supported by the bracket structure (3000) for installing scaffolding.

[0183] In addition, a plurality of bracket structures (3000) for scaffolding installation can be connected to the horizontal frame (HF) of the modular elevator (ME).

[0184] After the scaffolding is installed on the bracket structure (3000) for scaffolding installation, the scaffolding platform can be installed.

[0185] Meanwhile, after the construction of the modular elevator is completed, only the scaffolding (S) is removed, and the bracket structure (3000) for installing the scaffolding is maintained in a mounted state, and the scaffolding (S) can be attached during maintenance of the modular elevator.

[0186] Additionally, after the construction of the modular elevator is completed, the bracket structure (3000) for scaffolding installation is removed, and during maintenance of the modular elevator, the bracket structure (3000) for scaffolding installation and the scaffolding (S) can be combined by connecting it to the horizontal frame (HF) of the modular elevator.

[0187] FIG. 9 is a schematic diagram illustrating a modular elevator including a bracket structure for scaffolding installation according to another embodiment of the present invention.

[0188] As described above, the modular elevator (100) includes a plurality of elevator modules (100a, 100b, 100c). The plurality of elevator modules (100a, 100b, 100c) may include a top floor elevator module (100a), a middle floor elevator module (100b), and a bottom floor elevator module (100c).

[0189] A machine room (100a1) in which a hoisting machine, control panel, inverter, etc. are placed may be constructed in the top floor elevator module (100a). The bottom floor elevator module (100c) may be constructed as a pit module so as to be inserted into the ground.

[0190] The lower floor elevator module (100c) may have a buffer and a pit screen (100c1) installed.

[0191] The middle floor elevator module (100b) is located between the top floor elevator module (100a) and the bottom floor elevator module (100c).

[0192] The intermediate floor elevator module (100b) may include a plurality of intermediate floor elevator modules (110). Each of the plurality of intermediate floor elevator modules (110) may be coupled to a building module (200) corresponding to the floor.

[0193] And multiple intermediate floor elevator modules (110) and building modules (200) can be combined in a combined state in a stacking direction (V).

[0194] A plurality of intermediate floor elevator modules (110) include a rail section (111) that guides the operation of the elevator car.

[0195] A modular elevator according to another embodiment of the present invention includes a bracket structure (3000) for scaffolding installation that is coupled to a plurality of intermediate floor elevator modules.

[0196] The bracket structure (3000) for scaffolding installation includes an upper bracket (3100) and a lower bracket (3200).

[0197] A bracket structure (3000) for installing scaffolding is detachably connected to the horizontal frame (HF) of the intermediate floor elevator module (110), and scaffolding (S) is supported on the bracket structure (3000).

[0198] When the scaffolding (S) is connected to the scaffolding installation bracket structure (3000), the scaffolding (S) is positioned to cross the elevator shaft. To this end, the scaffolding installation bracket structure (3000) is connected to horizontal frames (HF) located on both sides of the elevator shaft.

[0199] Additionally, the lower bracket (3200) is coupled to the horizontal frame (HF), a scaffold (S) is inserted into the frame coupling hole (3221) of the lower bracket (3200), and the coupling member is fixed to the horizontal frame (HF).

[0200] The upper bracket (3100) supports the upper part of the scaffolding (S) and is connected to the lower bracket (3200).

[0201]

[0202] [Another embodiment: Application of control panel adjustment bracket]

[0203] FIG. 10 is a schematic diagram illustrating a control panel adjustment bracket according to another embodiment of the present invention.

[0204] FIG. 11 is an exploded view schematically illustrating the control panel adjustment bracket shown in FIG. 10.

[0205] As described above, the control panel adjustment bracket structure (4000) includes a moving bracket part (4100) and a supporting bracket part (4200).

[0206] More specifically, a control panel is coupled to the movable bracket part (4100), and the support bracket part (4200) supports the movable bracket part (4100) so that it can slide and is coupled to the modular elevator frame.

[0207] The movable bracket part (4100) is guided and moved by the support bracket part (4200), and its position is fixed.

[0208] The moving bracket part (4100) includes a support plate part (4110) and a slide moving part (4120).

[0209] A control panel is supported and coupled to one side of the support plate (4110), and a slide moving part (4120) is coupled to the other side of the support plate (4110).

[0210] Additionally, the slide moving part (4120) can be connected to both sides based on the center of the support plate part (4110).

[0211] The slide moving part (4120) is supported by the support bracket part (4200) and guided to move. A guide groove (4121) is formed in the slide moving part (4120) that is supported by the support bracket part.

[0212] The support bracket portion (4200) includes a frame coupling portion (4210), a slide guide portion (4220), and a stopper (4230). The frame coupling portion (4210) is intended to be coupled to the frame of a modular elevator. To this end, a frame coupling hole (4211) is formed in the frame coupling portion (4210).

[0213] One side of the frame connecting part (4210) is connected to the frame, and the other side of the frame connecting part (4210) is connected to the slide guide part (4220).

[0214] The slide guide portion (4220) is formed to correspond to the guide groove (4121) of the slide moving portion (4120).

[0215] The stopper (4230) is intended to restrict the movement of the slide moving part (4120) moving along the slide guide part (4220).

[0216] The stopper (4230) is coupled to the frame coupling part (4210) or the slide guide part (4220) so as to be optionally detachable along the movement path of the slide moving part (4120).

[0217] FIGS. 10 and 11 illustrate an embodiment thereof in which a stopper (4230) is coupled to a frame coupling part (4210).

[0218] A fixing member through hole (4231) is formed in the stopper (4230), and a fixing member coupling part (4212) corresponding to the fixing member through hole (4231) is formed in the frame coupling part (4210).

[0219] A plurality of fixed member coupling parts (4212) may be formed along the movement path of the slide movement part (4120) of the movable bracket part (4100).

[0220] A control panel adjustment bracket structure (4000) according to another embodiment of the present invention is formed as described above, and a movable bracket part (4100) on which a control panel is mounted moves along a support bracket part (4200) coupled to a frame in the inner and outer directions of the frame (indicated by arrow M).

[0221]

[0222] [Example of operation of a control panel adjustment bracket according to another embodiment]

[0223] FIG. 12 is a schematic first usage state diagram of a control panel adjustment bracket according to another embodiment of the present invention.

[0224] As described above, a control panel (CP) is coupled to the control panel adjustment bracket structure (4000), and the control panel adjustment bracket structure (4000) is coupled to the frame (F) of the modular elevator (ME).

[0225] More specifically, the support bracket portion (4200) of the control panel adjustment bracket structure (4000) is coupled to the frame (F) so that the movable bracket portion (4100) can slide in the outer and inner directions of the frame (F) of the modular elevator (ME).

[0226] Additionally, the stopper (4230) restricts movement while positioned so that the control panel (CP) is not exposed to the outside of the frame (F) of the modular elevator (ME).

[0227] Accordingly, when the frame (F) of the modular elevator (ME) is moved for the construction of the modular elevator, the control panel adjustment bracket structure (4000) maintains a safe state so that the control panel is not damaged.

[0228] FIG. 13 is a schematic second usage state diagram of a control panel adjustment bracket according to another embodiment of the present invention.

[0229] As described above, after transportation for the construction of the modular elevator is completed, the control panel (CP) is slid outward from the frame (F) of the modular elevator (ME). Then, with the control panel (CP) exposed to the outside, the stopper (4230) is connected to the frame joint (4210) to restrict the movement of the control panel (CP).

[0230] Accordingly, the control panel (CP) is securely fixed to the installation area of ​​the frame (F) of the modular elevator (ME).

[0231] FIG. 14 is a schematic diagram illustrating a modular elevator including a control panel adjustment bracket according to another embodiment of the present invention.

[0232] As described above, the modular elevator (100) includes a plurality of elevator modules (100a, 100b, 100c). The plurality of elevator modules (100a, 100b, 100c) may include a top floor elevator module (100a), a middle floor elevator module (100b), and a bottom floor elevator module (100c).

[0233] A machine room (100a1) in which a hoisting machine, control panel, inverter, etc. are placed may be constructed in the top floor elevator module (100a). The bottom floor elevator module (100c) may be constructed as a pit module so as to be inserted into the ground.

[0234] The lower floor elevator module (100c) may have a buffer and a pit screen (100c1) installed.

[0235] The middle floor elevator module (100b) is located between the top floor elevator module (100a) and the bottom floor elevator module (100c).

[0236] The intermediate floor elevator module (100b) may include a plurality of intermediate floor elevator modules (110). Each of the plurality of intermediate floor elevator modules (110) may be coupled to a building module (200) corresponding to the floor.

[0237] And multiple intermediate floor elevator modules (110) and building modules (200) can be combined in a combined state in a stacking direction (V).

[0238] A plurality of intermediate floor elevator modules (110) include a rail section (111) that guides the operation of the elevator car.

[0239] A modular elevator according to another embodiment of the present invention includes a control panel adjustment bracket structure (4000) coupled to a plurality of intermediate floor elevator modules.

[0240] A control panel adjustment bracket structure (4000) with a control panel (CP) is attached to the frame (F) of the intermediate floor elevator module (110).

[0241] The control panel (CP) of the intermediate floor elevator module (110) is maintained in a state where it protrudes from the frame (F) or is located inside the frame, depending on the position where the stopper (4230) restricts the movement of the moving bracket part.

[0242] Additionally, the control panel adjustment bracket structure (4000) enables adjustment of the protruding position of the control panel (CP) from the modular elevator (ME).

[0243]

[0244] [Another embodiment: Application of cable connection structure]

[0245] FIG. 15 is a schematic diagram illustrating a cable connection structure according to another embodiment of the present invention.

[0246] The cable connection structure (5000) divides the cable by module corresponding to each floor of the modular elevator and is an inter-floor connection structure between modules.

[0247] As described above, the cable connection structure (5000) includes a first terminal portion (5100), a second terminal portion (5200), and a connection portion (5300).

[0248] A first terminal part (5100) is connected to one side of the connection part (5300), and a second terminal part (5200) is connected to the other side of the connection part (5300).

[0249] The connection part (5300) includes a plurality of connection part modules corresponding to each module of the modular elevator.

[0250] More specifically, the first terminal portion (5100) forms one end of the cable of the modular elevator.

[0251] The first terminal section (5100) includes a first terminal (5110), a first terminal cable (5120), and a connection terminal (5130).

[0252] The first terminal (5110) is connected to an electronic device of the modular elevator, the connection terminal (5130) is connected to the connection part (5300), and the first terminal cable (5120) connects the first terminal (5110) and the connection terminal (5130).

[0253] The second terminal section (5200) forms the other terminal of the cable of the modular elevator.

[0254] The second terminal section (5200) includes a second terminal (5210), a first terminal cable (5220), and a connection terminal (5230).

[0255] The second terminal (5210) is connected to an electronic device of the modular elevator, the connection terminal (5230) is connected to the connection part (5300), and the second terminal cable (5220) connects the second terminal (5210) and the connection terminal (5230).

[0256] The connecting part (5300) includes a plurality of connecting part modules (5300a, 5300b, 5300c, 5300d) corresponding to the modules of the modular elevator, and FIG. 1 illustrates a connecting part (5300) including four connecting part modules as an example thereof.

[0257] In addition, two of the multiple connection modules (5300a, 5300b, 5300c, 5300d) may be formed symmetrically to each other.

[0258] The connection module (5300a, 5300b, 5300c, 5300d) includes a first connection terminal (5310a, 5310b, 5310c, 5310d), a second connection terminal (5320a, 5320b, 5320c, 5320d), and a connection cable (5330a, 5330b, 5330c, 5330d).

[0259] The first connection terminal (5310a, 5310b, 5310c, 5310d) forms one side terminal of the connection module (5300a, 5300b, 5300c, 5300d), and the second connection terminal (5320a, 5320b, 5320c, 5320d) forms the other side terminal of the connection module (5300a, 5300b, 5300c, 5300d).

[0260] The connecting cables (5330a, 5330b, 5330c, 5330d) connect the first connecting terminal (5310a, 5310b, 5310c, 5310d) and the second connecting terminal (5320a, 5320b, 5320c, 5320d).

[0261] That is, a first connection terminal (5310a, 5310b, 5310c, 5310d) is connected to one side of the connection cable (5330a, 5330b, 5330c, 5310d), and a second connection terminal (5320a, 5320b, 5320c, 5320d) is connected to the other side of the connection cable (5330a, 5330b, 5330c, 5330d).

[0262] In addition, the connection modules (5300a, 5300b, 5300c, 5300d) have the first connection terminal and the second connection terminal of adjacent connection modules connected to each other.

[0263] Among the connection modules (5300a, 5300b, 5300c, 5300d), the connection module (5300a) located at one end is connected to the first terminal (5100), and the connection module (5300d) located at the other end is connected to the second terminal (5200).

[0264] To this end, the first connection terminal (5310a) of the connection module (5300a) located at one end is connected to the connection terminal (5130) of the first terminal part (5100), and the second connection terminal (5320d) of the connection module (5300d) located at the other end is connected to the connection terminal (5230) of the second terminal part (5200).

[0265] As the cable connection structure (5000) according to another embodiment of the present invention is formed as described above, signal interference of the cable is minimized and the length of the cable can be adjusted, thereby enabling an optimized design according to the design structure of the modular elevator.

[0266] FIG. 16 is a schematic diagram illustrating a limit switch cam according to yet another embodiment of the present invention. FIG. 16 (a) is a schematic diagram according to one embodiment, and FIG. 16 (b) is a schematic diagram according to another embodiment.

[0267] FIG. 16 (a) and FIG. 16 (b) illustrate an embodiment in which the position of the bracket fixed according to the cam arrangement is changed.

[0268] More specifically, the limit switch cam (6000) is installed at a designated location on each floor of the modular elevator. It is intended to accurately detect when the elevator car reaches the corresponding floor and to ensure the safe boarding and alighting of passengers.

[0269] To this end, the limit switch cam (6000) includes a fixed bracket (6100) and a movement limiting bracket (6200).

[0270] The fixed bracket (6100) is intended to be fixed to the frame of the elevator module.

[0271] The movement restriction bracket (6200) is intended to verify the correct position of the elevator car and restrict its movement.

[0272] FIG. 17 is a schematic diagram illustrating a hatch cable hanger according to another embodiment of the present invention.

[0273] The hatch cable hanger (7000) is installed inside the hatch of a modular elevator and is intended to fix cables at regular intervals to prevent tangling or damage to the cables and to efficiently manage the cable wiring inside the hatch.

[0274] As described above, the hatch cable hanger (7000) includes a frame fixing part (7100) and a cable fixing part (7200).

[0275] More specifically, the frame fixing part (7100) is fixed to the frame of the modular elevator.

[0276] Additionally, the frame fixing part (7100) can be located at the modular elevator landing and fixed to a frame extending in the direction of the elevator car's ascent.

[0277] The cable fixing part (7200) is intended to fix a cable arranged in the extension direction of the frame. The cable fixing part (7200) may be made of an elastic material to press the internal cable.

[0278]

[0279] [Operational example of a cable connection structure according to yet another embodiment]

[0280] FIG. 18 is a schematic diagram illustrating an electronic device including a cable connection structure according to another embodiment of the present invention and a modular elevator including the same.

[0281] As described above, the modular elevator (100) includes a plurality of elevator modules (100a, 100b, 100c). The plurality of elevator modules (100a, 100b, 100c) may include a top floor elevator module (100a), a middle floor elevator module (100b), and a bottom floor elevator module (100c).

[0282] A machine room (100a1) in which a hoisting machine, control panel, inverter, etc. are placed may be constructed in the top floor elevator module (100a). The bottom floor elevator module (100c) may be constructed as a pit module so as to be inserted into the ground.

[0283] The lower floor elevator module (100c) may have a buffer and a pit screen (100c1) installed.

[0284] The middle floor elevator module (100b) is located between the top floor elevator module (100a) and the bottom floor elevator module (100c).

[0285] The intermediate floor elevator module (100b) may include a plurality of intermediate floor elevator modules (110). Each of the plurality of intermediate floor elevator modules (110) may be coupled to a building module (200) corresponding to the floor.

[0286] And multiple intermediate floor elevator modules (110) and building modules (200) can be combined in a combined state in a stacking direction (V).

[0287] A plurality of intermediate floor elevator modules (110) include a rail section (111) that guides the operation of the elevator car.

[0288] A modular elevator (100) according to another embodiment of the present invention includes a cable connection structure (shown as 5000 in FIG. 15), a limit switch cam (6000), and a hatch cable hanger (7000).

[0289] More specifically, the cable connection structure (5000) may have a connection part (5300) arranged to correspond to each floor of a plurality of intermediate floor elevator modules (110), a first terminal part (5100) arranged in the top floor elevator module (100a), and a second terminal part (5200) arranged in the bottom floor elevator module (100c).

[0290] Additionally, the limit switch cam (6000) is coupled to the frame (MF) of each floor of the multiple intermediate floor elevator modules (110).

[0291] The limit switch cam (6000) can be positioned to operate when the elevator car is located at a point 90 to 99 mm from the floor level of each floor.

[0292] The hatch cable hanger (7000) is connected to the hoistway frame (RF) of each floor of the multiple intermediate floor elevator modules (110). That is, the hatch cable hanger (7000) extends in the direction of the elevator car and is connected to the hoistway frame (RF) located in the hoistway.

[0293] Additionally, the hatch cable hanger (7000) can be connected to the middle point of the elevator shaft frame (RF) of each floor.

[0294] As the modular elevator according to another embodiment of the present invention is constructed as described above, it is possible to design an electronic device structure suited to the modular construction method, thereby minimizing on-site installation time and facilitating maintenance.

[0295] In addition, the structure of cable connections and electronic devices is standardized to fit each layer module, making it possible to provide them in a modular form.

[0296]

[0297] [Another embodiment: Application of cable terminal block]

[0298] FIG. 19 is a schematic diagram illustrating a cable terminal block according to yet another embodiment of the present invention.

[0299] As described above, the cable terminal block (2000) is located between the hoist and the control panel and is intended to connect the cables of the hoist and the control panel.

[0300] More specifically, the cable terminal block (2000) includes a block body (2100), a cable input port (2200), and a terminal connection part (2300).

[0301] The block body (2100) forms the outer periphery of the cable terminal block (2000).

[0302] The block body (2100) can be made of a material that shields the noise of the cable.

[0303] The cable input port (2200) can be formed on the outside of the block body (2100).

[0304] The cable input port (2200) may be a circular port. The cable input port (2200) accommodates various types of cables, such as encoder and brake cables.

[0305] FIG. 19 is yet another embodiment thereof, wherein the cable input port (2200) includes a first port (2210), a second port (2220), and a third port (2230), and the first port (2210) is formed to be larger than the second port (2220) and the third port (2230).

[0306] FIG. 20 is a perspective view illustrating a cable input port and a terminal connection part according to yet another embodiment of the present invention.

[0307] As described above, the cable input port (2200) has a shielding structure that can minimize noise generation of the cable (10).

[0308] The cable (10) input through the cable input port (2200) can pass through the cable input port (2200) and the individual cable (20) can be exposed. Accordingly, the cable (10) is configured so that the cable sheath (unmarked) is removed inside the block body (2100) made of a noise-shielding material, thereby minimizing noise generation.

[0309] FIG. 21 is a perspective view illustrating a terminal connection portion according to yet another embodiment of the present invention.

[0310] As described above, the terminal connection part (2300) is formed inside the block body (2100) and is designed so that the cable contained in the block body (2100) can be stably fixed and connected.

[0311] Through the structure of the terminal connection part (2300) as described above, signal loss of the cable is prevented, and stable signal transmission to the control panel (CP) becomes possible.

[0312] The terminal connection part (2300) may be provided with a connection terminal (not shown) to which an individual cable (20) can be securely connected. Accordingly, the individual cable (20) contained within the block body (2100) can be connected to the connection terminal, thereby being stably fixed and connected.

[0313]

[0314] [Operational example of a cable terminal block according to yet another embodiment]

[0315] FIG. 22 is a schematic diagram of the usage state of a cable terminal block according to yet another embodiment of the present invention.

[0316] As described above, the cable terminal block (2000) is connected to the beam (B) connected to the elevator frame (F).

[0317] More specifically, the cable terminal block (2000) is seated and coupled to the upper part of the beam (B).

[0318] Additionally, a hoist (TM) is positioned adjacent to the cable terminal block (2000).

[0319] The cable terminal block (2000) is located between the hoist (TM) and the control panel (not shown). The cable terminal block (2000) connects the cable between the hoist (TM) and the control panel (CP). Meanwhile, the cable terminal block (2000) can be connected to the beam (B) by fixing bolts or welding.

[0320] Through this, the cable terminal block (2000) can serve as a major connection interface between the control panel (not shown) and the hoist (TM) by being placed at the top position where electrical connectivity is concentrated in the modular system.

[0321] FIG. 23 is a schematic diagram illustrating an elevator including a cable terminal block according to yet another embodiment of the present invention.

[0322] As described above, the modular elevator (100) includes a plurality of elevator modules (100a, 100b, 100c). The plurality of elevator modules (100a, 100b, 100c) may include a top floor elevator module (100a), a middle floor elevator module (100b), and a bottom floor elevator module (100c).

[0323] A machine room (100a1) in which a hoisting machine, control panel, inverter, etc. are placed may be constructed in the top floor elevator module (100a). The bottom floor elevator module (100c) may be constructed as a pit module so as to be inserted into the ground.

[0324] The lower floor elevator module (100c) may have a buffer and a pit screen (100c1) installed.

[0325] The middle floor elevator module (100b) is located between the top floor elevator module (100a) and the bottom floor elevator module (100c).

[0326] The intermediate floor elevator module (100b) may include a plurality of intermediate floor elevator modules (110). Each of the plurality of intermediate floor elevator modules (110) may be coupled to a building module (200) corresponding to the floor.

[0327] And multiple intermediate floor elevator modules (110) and building modules (200) can be combined in a combined state in a stacking direction (V).

[0328] A plurality of intermediate floor elevator modules (110) include a rail section (111) that guides the operation of the elevator car.

[0329] A modular elevator according to yet another embodiment of the present invention includes a cable terminal block (2000) coupled to the top floor elevator module.

[0330] More specifically, a cable terminal block (2000) is attached to the frame (TP) of the top floor elevator module.

[0331] The cable terminal block (2000) is seated and coupled to the beam (B), and the beam (B) is coupled and supported to the frame (TP) of the top floor elevator module.

[0332] Additionally, the beam (B) can be connected to and supported by the frame (TP) of the top floor elevator module so as to cross the elevator shaft.

[0333] A hoist (TM) is positioned adjacent to the cable terminal block (2000).

[0334] The cable terminal block (2000) is located between the hoist (TM) and the control panel (CP).

[0335] The cable terminal block (2000) connects the cable between the hoist (TM) and the control panel (CP).

[0336] Accordingly, the wiring direction and placement path of the cable terminal block (2000) can be optimized in the transverse direction of the elevator shaft to reduce the length of the cable, straighten the wiring, and increase ease of maintenance.

[0337] The cable terminal block (2000) can be connected to the frame (TP) with the beam (B) already connected. That is, the terminal block (1000) and the beam (B) are integrated into a modular unit, allowing for rapid installation in the factory-assembled state during on-site installation.

[0338] In a modular elevator according to yet another embodiment of the present invention, a cable terminal block is coupled to the top floor elevator module, thereby ensuring signal safety between divided cables as a central medium for signal transmission between the hoist (TM) and the control panel (CP), and minimizing noise generation in the cables, so that the quality of the signal transmitted to the control panel (CP) can be maintained.

[0339] In addition, the cable terminal block acts as a hub between split cables, making installation and maintenance easier, which improves work efficiency and increases safety at the construction site of the modular elevator. Accordingly, the cable terminal block has the advantage of simultaneously achieving a balance between electrical quality and construction efficiency.

[0340] Although the embodiments have been described above with reference to the limited drawings, those skilled in the art can apply various technical modifications and variations based on the above. For example, appropriate results may be achieved even if the described techniques are performed in a different order than described, and / or the components of the described system, structure, device, etc. are combined or assembled in a form different from described, or replaced or substituted by other components or equivalents.

[0341] Therefore, other implementations, other embodiments, and equivalents to the claims also fall within the scope of the claims set forth below.

Claims

A fixed bracket part detachably coupled to the frame of a modular elevator; A support beam positioned in the elevator shaft to support the elevator cage and coupled to the fixed bracket. Elevator cage support structure. In Article 1, The above fixed bracket portion includes a first fixed bracket coupled to the frame, and The first fixing bracket includes a first support beam support member that fixes and supports the lower part of the support beam, and a first frame fixing member that fixes and supports the frame. The first frame fixing part is located on both sides of the first support beam support part, and the first support beam support part is extended to protrude vertically from the first frame fixing part. Elevator cage support structure. In Article 2, The first frame fixing part has a first frame coupling hole formed therein into which a fixing member is inserted so as to be detachably coupled to the frame. Elevator cage support structure. In Article 2, The above-mentioned first support beam support includes an upright portion and a flat plate portion, and The above-mentioned standing portion is formed to protrude vertically from the first frame fixing portion, and The above-mentioned flat plate is connected to the standing part Elevator cage support structure. In Article 4, A support beam coupling hole is formed in the above-mentioned flat plate portion to fix the support beam by a fixing member, and A fixing bracket coupling hole corresponding to the support beam coupling hole for the above is formed in the support beam, and The above fixing member is coupled to the above fixing bracket coupling hole and the above support beam coupling hole. Elevator cage support structure. In Article 1, The above fixed bracket portion includes a second fixed bracket coupled to the frame, and The second fixing bracket comprises a second support beam support member that supports the lower part of the support beam, a second frame fixing member that is fixed and supported to a frame, and a cover support member that covers and supports the upper and side parts of the support beam. Elevator cage support structure. In Article 6, The second frame fixing part is located on both sides of the second support beam support part, and the second support beam support part is extended to protrude vertically from the second frame fixing part. The above cover support is coupled to the second support beam support and protrudes upward to form an internal space. Elevator cage support structure. In Article 7, The above internal space is formed to correspond to the support beam so that the support beam can be inserted. Elevator cage support structure. In Article 1, The above fixed bracket portion includes a first fixed bracket and a second fixed bracket, and The first fixing bracket and the second fixing bracket are each coupled to a horizontal frame, and the first fixing bracket and the second fixing bracket support and fix both sides of the support beam. Elevator cage support structure. An elevator cage support structure according to any one of claims 1 to 9; and The above elevator cage support structure includes a horizontal frame that is detachably coupled thereto. Modular elevator. In Article 10, The above elevator cage support structure is coupled to the intermediate floor elevator module. Modular elevator. In Article 11, The fixing brackets of the above elevator cage support structure are respectively connected to horizontal frames located on both sides with respect to the elevator shaft. Modular elevator. In Article 10, A bracket structure for scaffolding installation that is detachably coupled to the horizontal frame; and A scaffold further comprising a bracket structure for scaffold installation, the above scaffold further comprising a scaffold Modular elevator. In Article 10, A support bracket portion of a control panel adjustment bracket structure coupled to the frame of the above-mentioned modular elevator; and A control panel further comprising a movable bracket portion of the above-mentioned control panel adjustment bracket structure, Modular elevator. In Article 10, It further includes electronic devices coupled to the frame of the above-mentioned modular elevator, and The cable connection structure of the above electronic device has a connection portion arranged to correspond to each floor of a plurality of intermediate floor elevator modules, Modular elevator. In Article 10, A beam connected to and supported by the frame of the above-mentioned modular elevator; and A cable terminal block further comprising a cable terminal block seated and coupled to the above beam, Modular elevator.