JP2024099881A - Elevator apparatus and the same installation method - Google Patents

Abstract

An elevator device capable of moving a machine room upward without using a tower crane, and an installation method thereof are provided.
[Solution] The elevator comprises a car 1 that rises and falls inside a hoistway 10, a machine room 5 from which the car 1 is suspended, a car guide rail 12 that guides the car 1 as it rises and falls, a lifting unit 8 that moves the machine room 5 upward, and a work scaffolding 9 used to install the car guide rail 12.
[Selected Figure] Figure 1

Description

This disclosure relates to an elevator device and an installation method thereof.

A construction elevator is known in which the machine room moves upwards in stages as construction work moves from the lower floors to the upper floors (for example, Patent Document 1).

Special Publication No. 59-34633

In conventional construction elevators, a tower crane is used to move the machine room upwards. When a tower crane is used to move the machine room, the tower crane cannot be used for building construction work, which creates the problem of extending the construction period for the building.

Therefore, the present disclosure aims to provide an elevator device and an installation method thereof that can move the machine room upward without using a tower crane.

The elevator system disclosed herein comprises a car that moves up and down inside the elevator shaft, a machine room from which the car is suspended, a car guide rail that guides the car as it moves up and down, a lifting unit that moves the machine room upward, and a work platform used to install the car guide rail.

The installation method of the elevator device disclosed herein includes a first step of installing the car guide rails on a work scaffold installed in a hoistway through which the car ascends and descends, with the longitudinal direction of the car guide rails vertical; a second step of moving the lifting unit upward; a third step of connecting the lifting unit and the machine room from which the car is suspended using a connecting member; and a fourth step of moving the connecting member upward to move the machine room upward.

The elevator device and installation method disclosed herein allow the machine room to be moved upward without using a tower crane.

FIG. 1 is a diagram illustrating a configuration of an elevator device according to a first embodiment. FIG. 2 is a diagram showing a configuration example of a deck plate in the first embodiment. 11A and 11B are diagrams illustrating another configuration example of the deck plate in the first embodiment. FIG. 2 is a side view showing a main part of the lifting unit in the first embodiment. 4A to 4C are diagrams illustrating the first and second steps of the method for moving a lifting unit in embodiment 1. 13A to 13C are diagrams illustrating the third and fourth steps of the method for moving the lifting unit in embodiment 1. 13A to 13C are diagrams illustrating the fifth and sixth steps of the method for moving the lifting unit in embodiment 1. 4A to 4C are diagrams illustrating a first step and a second step of the method for moving a machine room in the first embodiment. 11A to 11D are diagrams illustrating the third to fifth steps of the method for moving the machine room in the first embodiment. 13A to 13C are diagrams illustrating the sixth to eighth steps of the method for moving a machine room in the first embodiment. 11A to 11C are diagrams illustrating the 9th to 11th steps of the method for moving a machine room in the first embodiment. FIG. 2 is a diagram illustrating an example of the configuration of a machine room and a fixed member in the elevator apparatus of the first embodiment. FIG. 2 is a diagram illustrating a configuration of an elevator device according to a modified example of the first embodiment. FIG. 13 is a diagram illustrating a schematic configuration of an elevator device according to a second embodiment. FIG. 13 is a diagram showing a schematic configuration of a lifting body lifting device used in an elevator apparatus of embodiment 2. A diagram showing the configuration of a main part of a beam member used in an elevator apparatus of embodiment 2. 13 is a diagram showing the configuration of the main parts of a beam member used in an elevator device of embodiment 2, and is a diagram explaining the procedure for changing the fixed position of the suspension plate. FIG. FIG. 13 is a diagram illustrating a configuration of an elevator device according to a modified example of the second embodiment. FIG. 13 is a diagram showing a schematic configuration of a lifting body lifting device used in an elevator apparatus according to a modified example of embodiment 2. FIG. 13 is a diagram showing a schematic configuration of a lifting body lifting device used in an elevator apparatus according to a modified example of embodiment 2.

The embodiments for implementing the subject matter of this disclosure will be described with reference to the attached drawings. In each drawing, the same or corresponding parts are given the same reference numerals, and duplicated descriptions are appropriately simplified or omitted. Note that the subject matter of this disclosure is not limited to the following embodiments, and any of the components of the embodiments may be modified or omitted without departing from the spirit of this disclosure.

Embodiment 1.
Fig. 1 is a diagram showing a schematic configuration of an elevator device according to a first embodiment. Fig. 1(a) is a front view of the elevator device, and Fig. 1(b) is a side view of the elevator device. Fig. 1 shows a state in which a machine room 5 is moved upward. A hoistway 10 for an elevator device 100 is provided in a building. The hoistway 10 is a vertically long space spanning multiple floors.

The elevator device 100 includes a car 1, a counterweight 15, a machine room 5, and a lifting unit 8 in a hoistway 10. The car 1 and the counterweight 15 are located below the machine room 5, and the lifting unit 8 is located above the machine room 5.

The elevator device 100 is particularly suitable for use in construction work. The elevator device 100 transports materials or personnel required for construction work during the construction period of a building. As the construction work of a building progresses from the lower floors to the upper floors, the elevator device 100 can use the lifting unit 8 to move the machine room 5 upward in the hoistway 10 in stages. Furthermore, the elevator device 100 can move the machine room 5 upward and install it without using a tower crane. Note that a tower crane is a temporary lifting machine used to transport heavy objects at construction sites. A tower crane is used by moving the crane body upward to match the height of the building under construction.

The car 1 has a car body 20 and a car hoist 21. The car hoist 21 is provided on the upper part of the car body 20 and is rotatable. The car 1 can also be called a first lifting body.

The counterweight 15 has a counterweight body 22 and a counterweight hoist 23. The counterweight hoist 23 is provided on the upper part of the weight body 22 and is rotatable. The counterweight 15 can also be called a second lifting body.

The machine room 5 houses the hoist 4, the winding device 3, and the control device 16. In FIG. 1, the machine room 5 is installed on a fixed member 25. The fixed member 25 is fixed to the building structure and limits the downward movement of the machine room 5.

The hoist 4 has a drive sheave 18, a hoist motor (not shown), and a pair of hoist brakes (not shown). The hoist motor rotates the drive sheave 18. The pair of hoist brakes keep the drive sheave 18 stationary. The pair of hoist brakes also brake the rotation of the drive sheave 18.

The suspension body 2 is wound around the drive sheave 18 of the hoist 4. Multiple ropes or multiple belts are used as the suspension body 2.

The winding device 3 winds up a portion of one end of the suspension body 2 .
The control device 16 outputs a control signal to the hoist 4 to control the hoist 4. During normal operation of the car 1, the control device 16 controls the hoist 4 to control the operation of the car 1.

The car 1 and counterweight 15 are suspended in the hoistway 10 by the suspension 2. A pair of car guide rails 12 are provided in the hoistway 10 along the direction of movement of the car 1 (i.e., the vertical direction). The ascent and descent of the car 1 is guided by the car guide rails 12. In addition, a pair of counterweight guide rails 32 (see Figures 2 and 3) are provided in the hoistway 10 along the direction of movement of the counterweight 15. The ascent and descent of the counterweight 8 is guided by the counterweight guide rails 32.

The lifting device 24 for the lifting body lifts the car 1 of the lifting body. When moving the machine room 5 upward, the car 1 is suspended from the machine room 5 via the lifting device 24 for the lifting body and the chain 6. The lifting device 24 for the lifting body is, for example, a rod, a chain, a rope, or a winch.

The support platform 29 is installed when the machine room 5 is moved upward. The support platform 29 is installed at a position corresponding to the bottom of the counterweight 15 in the hoistway 10, and restricts the counterweight 15 from moving downward when the machine room 5 moves upward.

The suspension body 2 has a first end (not shown) and a second end 2b. The first end is one end in the length direction of the suspension body 2 and is located inside the winding device 3. The second end 2b is the other end in the length direction of the suspension body 2 and is connected to the bottom of the machine room 5.

The suspension body 2 is wound around the car hoist 21, the drive sheave 18, and the counterweight hoist 23 in order from the first end in the winding device 3, and reaches the second end 2b in the machine room 5. As shown in FIG. 1, the roping system of the elevator device 100 is a 2:1 roping system.

The lifting unit 8 is disposed at a position above the machine room 5. In FIG. 1, only the electric chain block 8A, the hydraulic jack 8B, the upper support beam 8C, and the lower support beam 8D are shown as components of the lifting unit 8. Details of the configuration of the lifting unit 8 will be described later with reference to FIG. 2.

In FIG. 1, the lower end of the chain 7 suspended from the lifting unit 8 is connected to the top of the machine room 5. The chain 7 is pulled out from an electric chain block 8A. The machine room 5 can be moved upward in the hoistway 10 by the electric chain block 8A. The machine room 5 is raised in stages according to the progress of the building construction work.

The deck plate 9 is a work platform on which the elevator equipment 100 installation workers perform their work. The deck plate 9 is installed in the hoistway 10 at a position above the lifting unit 8. In FIG. 1, two deck plates are installed, but it is sufficient to install at least one deck plate. By installing multiple deck plates, the installation workers can stack the car guide rails 12, which will be described later, continuously in the height direction.

Figure 2 shows an example of the configuration of a deck plate in embodiment 1. Figure 2(a) is a perspective view, and Figure 2(b) is a plan view. Figure 2 shows a state in which a deck plate 9a is suspended over two beam members 27. Note that the deck plate 9a in the plan view of Figure 2(b) is shown in a simplified form with the uneven shape of its surface omitted.

The beam member 27 is, for example, an I-shaped steel beam. The deck plate 9a is fixed to the beam member 27 at the point where it contacts the beam member 27, for example, by using a screw. Note that in the example of FIG. 2, the deck plate 9a is suspended between the two beam members 27, but it may be suspended between the landing of the elevator device and the beam member 27.

The deck plate 9a shown in FIG. 2 is a corrugated steel plate with rows of flat-bottomed recesses and flat-topped protrusions. The deck plate 9a is fixed to the beam member 27 by screws (not shown) at the recesses that contact the beam member 27.

The deck plate 9a has multiple openings. In FIG. 2, it has two openings 9a1 for passing the counterweight guide rail 32, two openings 9a2 for passing the car guide rail 12 and the piano wire 30, and two openings 9a3 for passing the piano wire 30. The piano wire 30 is used to indicate the reference position when installing the car guide rail 12.

As the building construction work progresses from the lower floors to the upper floors, the installation workers stack the upper floor car guide rail 12b on top of the lower floor car guide rail 12a, connecting the lower floor car guide rail 12a and the upper floor car guide rail 12b (see Figure 8). In this specification, when there is no need to distinguish between the lower floor car guide rail 12a and the upper floor car guide rail 12b, they will be described as car guide rail 12. The horizontal cross section of the car guide rail 12 is T-shaped. As the building construction work progresses from the lower floors to the upper floors, the installation workers stack the counterweight guide rail 32b on the upper floor on top of the counterweight guide rail 32a on the lower floor, and connect the counterweight guide rail 32a on the lower floor to the counterweight guide rail 32b on the upper floor (not shown).

Figure 3 is a perspective view showing another example of the configuration of the deck plate in the first embodiment. The deck plate 9b shown in Figure 3 differs from the deck plate 9a shown in Figure 2 in that the deck plate 9b is a steel plate with flat upper and lower surfaces. The plan view of the deck plate 9b is the same as the plan view of the deck plate 9a shown in Figure 2 (a). That is, the deck plate 9b also has two openings 9b1 for passing the counterweight guide rail 32, two openings 9b2 for passing the car guide rail 12 and the piano wire 30, and two openings 9b3 for passing the piano wire 30.

In the first embodiment, deck plate 9 is either deck plate 9a or deck plate 9b. However, as long as the deck plate 9 has openings through which the car guide rail 12 and the counterweight guide rail 32 can pass and can be used as a work scaffold, it is not limited to deck plate 9a or deck plate 9b.

Figure 4 is a side view showing the main parts of the lifting unit in embodiment 1. The lifting unit 8 has an electric chain block 8A, a hydraulic jack 8B, an upper support beam 8C, a lower support beam 8D, a guide shoe 8E, and a chain block 8F.

The upper support beam 8C is expandable and contractable in the horizontal direction, and is configured so that its length can be changed in the horizontal direction. The length of the upper support beam 8C can be shortened by storing both end portions 8C2 of the upper support beam 8C in the upper support beam main body 8C1. The length of the upper support beam 8C can also be lengthened by protruding both end portions 8C2 stored in the upper support beam main body 8C1 from the upper support beam main body 8C1.

Like the upper support beam 8C, the lower support beam 8D is expandable and contractable in the horizontal direction, and is configured so that its length can be changed in the horizontal direction. The length of the lower support beam 8D can be shortened by storing both longitudinal ends 8D2 of the lower support beam 8D in the lower support beam main body 8D1. The length of the lower support beam 8D can also be lengthened by protruding both longitudinal ends 8D2 stored in the lower support beam main body 8D1 from the lower support beam main body 8D1.

The configuration for enabling the lower support beam 8D to expand and contract horizontally may be such that both ends 8D2 are stored inside the lower support beam main body 8D1, or the lower support beam main body 8D1 is stored inside both ends 8D2, or some other configuration may be used. The same configuration is also applicable to the upper support beam 8C, allowing it to expand and contract horizontally.

Support beam receivers 11 that support the lifting unit 8 are provided within the hoistway 10. A plurality of support beam receivers 11 are provided in the height direction (i.e., vertical direction, up-down direction) within the hoistway 10. The support beam receivers 11 have an upper surface that limits the upward movement of the upper support beam 8C, and a lower surface that limits the downward movement of the upper support beam 8C. The support beam receivers 11, for example, have a U-shaped cross section. In FIG. 4, the support beam receivers 11 have a U-shaped cross section, but it is sufficient that they are members with a cross-sectional shape that have a lower surface that limits the downward movement of at least the upper support beam 8C and the lower support beam 8D.

In FIG. 4, the upper support beam 8C has both ends 8C2 protruding from the upper support beam body 8C1, and both ends 8C2 of the upper support beam 8C are placed on the support beam receivers 11. The movement of the upper support beam 8C in the vertical direction is restricted by the support beam receivers 11.

The lower support beam 8D has both ends 8D2 protruding from the lower support beam body 8D1. Both ends 8D2 of the lower support beam 8D are placed on the support beam receivers 11. The support beam receivers 11 on which both ends 8D2 of the lower support beam 8D are placed are one level lower than the support beam receivers 11 on which both ends 8C2 of the upper support beam 8C are placed. The vertical movement of the lower support beam 8D is also restricted by the support beam receivers 11.

The guide shoes 8E are positioned so as to contact the car guide rails 12. The pair of car guide rails 12 guide the lifting unit 8 as it rises and falls. The guide shoes 8E enable the lifting unit 8 to rise and fall stably.

The hydraulic jack 8B is provided between the upper support beam 8C and the lower support beam 8D. The hydraulic jack 8B contracts when pressure is applied in the vertical direction, and expands when no pressure is applied in the vertical direction. The hydraulic jack 8B functions as an elastic body. The hydraulic jack 8B is provided at a position closer to the longitudinal center of the upper support beam 8C and the lower support beam 8D than the position where the chain block 8F described later is provided. As described above, FIG. 4 shows a state in which the vertical distance between the upper support beam 8C and the lower support beam 8D is narrowed. Therefore, in FIG. 4, the hydraulic jack 8B is in a compressed state. The hydraulic jack 8B functions as a jack that widens the vertical distance between the upper support beam 8C and the lower support beam 8D from a first distance to a second distance that is wider than the first distance.

Note that in Figs. 5 to 7 described below, Figs. 5(a), 7(e) and 7(f) show a state in which the vertical distance between the upper support beam 8C and the lower support beam 8D is a first distance, and Figs. 5(b), 6(c) and 7(d) show a state in which the vertical distance between the upper support beam 8C and the lower support beam 8D is a second distance.

The chain block 8F has a chain and connects the upper support beam 8C and the lower support beam 8D with the chain. The chain block 8F is provided near both ends of the upper support beam main body 8C1 and the upper support beam main body 8C1. The chain block 8F can move the lower support beam 8D upward with the chain. Figure 4 shows a state in which the lower support beam 8D is moved upward by the chain block 8F, narrowing the vertical distance between the upper support beam 8C and the lower support beam 8D. The chain block 8F functions as a traction device that narrows the vertical distance between the upper support beam 8C and the lower support beam 8D from a second distance to a first distance that is narrower than the second distance.

The electric chain block 8A is mounted on the lower support beam 8D near the center of the lower support beam 8D in the longitudinal direction. The electric chain block 8A has a chain 7 (see FIG. 1, etc.). The electric chain block 8A can electrically pay out the chain 7 downward (see FIG. 10 described below). The electric chain block 8A can also electrically wind up the chain 7 upward. The electric chain block 8A can move the machine room 5 upward by connecting the lower end of the chain 7 paid out downward to the upper end of the machine room 5 and winding the chain 7 upward. The chain 7 functions as a connecting member that connects the lifting unit 8 and the machine room 5.

Next, the procedure for moving the lifting unit 8 upward will be described with reference to Figures 5 to 7. Figures 5 to 7 are side views showing the main parts of the lifting unit in embodiment 1, and are diagrams explaining the method of moving the lifting unit. Figure 5(a) is a diagram explaining the first step of the method of moving the lifting unit, and Figure 5(b) is a diagram explaining the second step. Figure 6(c) is a diagram explaining the third step of the method of moving the lifting unit, and Figure 6(d) is a diagram explaining the fourth step. Figure 7(e) is a diagram explaining the fifth step of the method of moving the lifting unit, and Figure 7(f) is a diagram explaining the sixth step.

In the first step shown in FIG. 5(a), the installation worker stores both longitudinal ends 8C2 of the upper support beam 8C in the upper support beam body 8C1 from the state shown in FIG. 4. As a result, both longitudinal ends 8C2 of the upper support beam 8C move to positions away from the support beam receivers 11 that restrict the up-down movement of the upper support beam 8C, and are released from the hold by the support beam receivers 11. Then, the second step shown in FIG. 5(b) is performed.

In the second step shown in FIG. 5(b), the installation worker operates the chain block 8F from the state shown in FIG. 5(a) in the direction of letting out the chain of the chain block 8F. When the chain of the chain block 8F is let out, the upper support beam 8C is lifted upward by the restoring force of the hydraulic jack 8B. FIG. 5(b) shows the state in which the upper support beam 8C has been lifted up to the position of the support beam receiver 11, one step higher, by the restoring force of the hydraulic jack 8B. Then, the third step shown in FIG. 6(c) is carried out.

In the third step shown in FIG. 6(c), the installation worker protrudes both longitudinal ends 8C2 of the upper support beam 8C, which are stored in the upper support beam main body 8C1, from the state shown in FIG. 5(b) and inserts them into the support beam receiver 11. The lifting unit 8 shown in FIG. 6(c) shows a state in which both ends 8C2 of the upper support beam 8C are inserted and held in the support beam receiver 11. Then, the fourth step shown in FIG. 6(d) is performed.

In the fourth step shown in FIG. 6(d), the installation worker stores both longitudinal ends 8D2 of the lower support beam 8D in the lower support beam body 8D1 from the state shown in FIG. 6(c). As a result, both longitudinal ends 8D2 of the lower support beam 8D move to positions away from the support beam receivers 11 that restrict the vertical movement of the lower support beam 8D, and are released from the support beam receivers 11. Then, the fifth step shown in FIG. 7(e) is performed.

In the fifth step shown in FIG. 7(e), the installer operates the chain block 8F from the position shown in FIG. 6(d) in the direction of winding up the chain of the chain block 8F. When the chain of the chain block 8F is wound up, the lower support beam 8D is lifted upward. The lifting unit 8 shown in FIG. 7(e) shows a state in which the chain of the chain block 8F has been wound up and the lower support beam 8D has been moved upward. Then, the sixth step shown in FIG. 7(f) is carried out.

In the sixth step shown in FIG. 7(f), the installation worker protrudes both longitudinal ends 8D2 of the lower support beam 8D, which are stored in the lower support beam main body 8D1, from the state shown in FIG. 7(e) and inserts them into the support beam receiver 11. The lifting unit 8 shown in FIG. 7(f) shows a state in which both ends 8D2 of the lower support beam 8D are inserted and held in the support beam receiver 11.

As explained using Figures 5 to 7, the chain block 8F and the hydraulic jack 8B function as a moving mechanism that alternately moves the upper support beam 8C and the lower support beam 8D upward.

Furthermore, the procedure described using Figures 5 to 7 can be used to widen or narrow the vertical distance between the upper support beam 8C and the lower support beam 8D. By repeating this operation, the lifting unit 8 can be moved upward along the car guide rail 12.

Next, a procedure for moving the machine room 5 upward will be described with reference to Figures 8 to 11. Figures 8 to 11 are side views that show a schematic configuration of the main parts of the elevator system of the first embodiment, and are diagrams that explain a method for moving the machine room. The elevator system 100 of the first embodiment is installed using the method for moving the machine room shown in Figures 8 to 11.
8 to 11, only the electric chain block 8A, hydraulic jack 8B, upper support beam 8C, and lower support beam 8D are shown as components of the lifting unit 8, and the guide shoes 8E and chain block 8F are not shown.

Figure 8(a) is a diagram explaining the first step of the method for moving the machine room, and Figure 8(b) is a diagram explaining the second step. Figure 9(c) is a diagram explaining the third step of the method for moving the machine room, Figure 9(d) is a diagram explaining the fourth step, and Figure 9(e) is a diagram explaining the fifth step. Figure 10(f) is a diagram explaining the sixth step of the method for moving the machine room, Figure 10(g) is a diagram explaining the seventh step, and Figure 10(h) is a diagram explaining the eighth step. Figure 11(i) is a diagram explaining the ninth step of the method for moving the machine room, Figure 11(j) is a diagram explaining the tenth step, and Figure 11(k) is a diagram explaining the eleventh step.

In the first step shown in FIG. 8(a), an installation worker installs the deck plate 9 above the lifting unit 8 in the hoistway 10. FIG. 8(a) shows an example in which the deck plate 9 is installed in two locations in the vertical direction. The deck plate 9 is, for example, the deck plate 9a described using FIG. 2, or the deck plate 9b described using FIG. 3. The deck plate 9 is fixed, for example, to the floor of the elevator hall or to a beam in the hoistway 10 using screws or the like. The deck plate 9 can be removed from inside the hoistway 10.

Here, as shown in FIG. 8(a), the lower end of the chain 7 pulled out from the electric chain block 8A is above the upper surface of the machine room 5. In other words, the lower end of the chain 7 is separated from the upper surface of the machine room 5, and the chain 7 is not connected to the machine room 5. Also, in FIG. 8(a), the upper ends of the pair of car guide rails 12a are located below the lifting unit 8. Then, the second process shown in FIG. 8(b) is carried out.

In the second step shown in FIG. 8(b), the installation worker connects a new pair of car guide rails 12b to the top of the pair of car guide rails 12a that are installed below the deck plate 9. The installation worker uses the deck plate 9 as a work platform and performs the work of connecting the car guide rails 12b to the top of the car guide rails 12a. The car guide rails 12b are lifted to the top of the car guide rails 12a using a rail bracket (not shown) that fixes the car guide rails 12 to the hoistway 10, or a hoist attached to a beam member (not shown) in the hoistway 10. Then, the third step shown in FIG. 9(c) is performed.

In the third step shown in Fig. 9(c), the installer stores both longitudinal ends of the upper support beam 8C in the upper support beam body from the state shown in Fig. 8(b). As a result, both longitudinal ends of the upper support beam 8C move to positions away from the support beam receivers 11 that restrict the up-down movement of the upper support beam 8C, and are released from the support beam receivers 11.
This third step is similar to the first step of the method for moving the lifting unit 8 described with reference to Fig. 5(a) . Thereafter, a fourth step shown in Fig. 9(d) is carried out.

In the fourth step shown in FIG. 9(d), the installer operates the chain block 8F from the state shown in FIG. 9(c) in the direction of letting out the chain of the chain block 8F. When the chain of the chain block 8F is let out, the upper support beam 8C is lifted upward by the restoring force of the hydraulic jack 8B. FIG. 9(d) shows the state in which the upper support beam 8C has been lifted up to the position of the support beam receiver 11 one step higher by the restoring force of the hydraulic jack 8B. This fourth step is the same as the second step of the method of moving the lifting unit 8 described using FIG. 5(b). Then, the fifth step shown in FIG. 9(e) is carried out.

In the fifth step shown in FIG. 9(e), the installer inserts both longitudinal ends of the upper support beam 8C, which are stored in the upper support beam body, into the support beam receiver 11 by protruding them from the upper support beam body from the state shown in FIG. 9(d). The lifting unit 8 shown in FIG. 9(e) shows a state in which both ends of the upper support beam 8C are inserted and held in the support beam receiver 11. This fifth step is the same as the third step of the method of moving the lifting unit 8 described using FIG. 6(c). Then, the sixth step shown in FIG. 10(f) is carried out.

In the sixth step shown in FIG. 10(f), the installation worker stores both longitudinal ends of the lower support beam 8D from the state shown in FIG. 9(e) into the lower support beam body. As a result, both longitudinal ends of the lower support beam 8D move to a position away from the support beam receiver 11 that restricts the vertical movement of the lower support beam 8D, and are released from the support beam receiver 11. This sixth step is the same as the fourth step of the method of moving the lifting unit 8 described using FIG. 6(d). Then, the seventh step shown in FIG. 10(g) is performed.

In the seventh step shown in FIG. 10(g), the installer operates the chain block 8F from the state shown in FIG. 10(f) in the direction of winding up the chain of the chain block 8F. When the chain of the chain block 8F is wound up, the lower support beam 8D is lifted upward. The lifting unit 8 shown in FIG. 10(g) shows a state in which the chain of the chain block 8F has been wound up and the lower support beam 8D has been moved upward. This seventh step is the same as the fifth step of the method of moving the lifting unit 8 described using FIG. 7(e). Then, the eighth step shown in FIG. 10(h) is carried out.

In the eighth step shown in FIG. 10(h), the installer inserts both longitudinal ends of the lower support beam 8D, which are stored in the lower support beam body, into the support beam receiver 11 by protruding them from the upper support beam body from the state shown in FIG. 7(e). The lifting unit 8 shown in FIG. 10(h) shows a state in which both ends of the lower support beam 8D are inserted and held in the support beam receiver 11. This eighth step is the same as the sixth step of the lifting unit movement method described using FIG. 7(f). Then, the ninth step shown in FIG. 11(i) is carried out.

In the ninth step shown in FIG. 11(i), the installer operates the electric chain block 8A to electrically pay out the chain 7 of the electric chain block 8A downward from the lifting unit 8, and hangs the lower end of the chain 7 down to the top of the machine room 5. Next, the installer connects the lower end of the chain 7 to a member (not shown) provided on the top surface of the machine room 5. After that, the tenth step shown in FIG. 11(j) is performed.

In step 10 shown in FIG. 11(j), the installer operates the electric chain block 8A to electrically wind up the chain 7 of the electric chain block 8A toward the lifting unit, thereby lifting the machine room 5. In other words, this operation causes the machine room 5 to rise from the fixing member 25 provided below the machine room 5 and become suspended by the chain 7. Next, the installer removes the fixing member 25. The attachment and removal of the fixing member 25 to the machine room 5 will be described later with reference to FIG. 12. Then, step 11 shown in FIG. 11(k) is performed.

In the eleventh step shown in FIG. 11(k), the installer operates the electric chain block 8A to wind up the chain 7, and moves the machine room 5 suspended by the chain 7 upward. The installer then attaches the fixing member 25 below the machine room 5. The fixing member 25 restricts the downward movement of the machine room 5.

In addition, in step 11, if the machine room 5 interferes with the deck plate 9 when being moved upward, the deck plate 9 is removed before the machine room 5 is moved upward.

When the machine room 5 is moved upward, the control device 16 releases the machine brake of the hoist 4. At this time, as the machine room 5 moves upward, the drive sheave 18 rotates as a driven pulley in the clockwise direction in FIG. 1, and the suspended body 2 is supplied to the counterweight 15 side relative to the drive sheave 18. The suspended body 2 is pulled out from the winding device 3 into the hoistway 10 by a length corresponding to the amount of movement of the machine room 5.

A withdrawal prevention mechanism (not shown) is provided in the winding device 3 or the machine room 5. During normal operation of the car 1, the withdrawal prevention mechanism prevents the suspension body 2 from being withdrawn from the winding device 3.
On the other hand, when the machine room 5 is moved upward, the withdrawal prevention mechanism is released. In the released state of the withdrawal prevention mechanism, the holding force of the winding device 3 to the suspension body 2 is smaller than the traction force between the drive sheave 18 and the suspension body 2.

After performing step 11 shown in FIG. 11(k), the installer releases the connection between the chain 7 and the machine room 5, and winds up the chain 7 with the electric chain block 8A. The installer then removes the deck plate 9 directly above the lifting unit 8, and performs steps 1 to 11 described with reference to FIGS. 8 to 11, thereby moving the machine room 5 further upward.

The first step can be understood as a step of installing the car guide rails 12, the second to eighth steps as steps of moving the lifting unit 8 upward, the ninth step as a step of connecting the lifting unit and the machine room from which the car is suspended using a connecting member, and the tenth and eleventh steps as steps of moving the machine room upward by moving the connecting member upward.

Here, an example of a method for attaching and detaching the fixing member 25 to and from the machine chamber 5 will be described with reference to FIG.
Fig. 12 is a diagram for explaining an example of the configuration of the machine room 5 and the fixing member 25 in the elevator system of the first embodiment. Fig. 12(a) is a diagram showing a state in which the fixing member 25 is attached to the bottom of the machine room 5. Fig. 12(b) is a diagram showing a state in which the fixing member 25 is removed from the bottom of the machine room 5. Fig. 12(c) is a diagram showing a state in which the fixing member 25 is in the middle of being attached to the bottom of the machine room 5 or in the middle of being removed from the bottom of the machine room 5. In Fig. 12, the fixing member 25 is an I-beam.

As shown in FIG. 12, the machine room 5 has a support member 26 attached to its bottom. The support member 26 has a roller portion 26B and a roller holding portion 26A that holds the roller portion 26B at the bottom of the machine room 5. The pair of roller holding portions 26A are attached so that the roller portions 26B face each other. In the example of FIG. 12, the pair of roller holding portions 26A are provided in two parallel rows, and the support member 26 can have two fixed members 25 attached to it.

The roller portion 26B rotates when the fixing member 25 is attached and removed, so the force required to attach and remove the fixing member 25 can be reduced.

When fixing the machine room 5 to the hoistway 10, the installer inserts the fixing member 25 from the side so that the upper part of the fixing member 25 rests on the roller portion 26B of the support member 26, as shown in Figures 12(a) and 12(c). After inserting the fixing member 25, the installer places the fixing member 25 on a receiving portion (not shown) provided in the hoistway 10 or on the floor. The fixing member 25 has a through hole (not shown). After placing the fixing member 25 on the receiving portion, the installer passes a bolt through the through hole to fix the fixing member 25 to the receiving portion.

When removing the attachment between the machine room 5 and the elevator shaft 10, the installer removes the bolt passed through the through hole and operates the electric chain block 8A to wind up the chain 7 so that the machine room 5 is suspended by the chain 7. In this state, the installer removes the fixing member 25 by pulling it out laterally (i.e., horizontally).

According to the elevator device 100 and its installation method of the first embodiment, the machine room 5 can be moved upward by the lifting unit 8. Therefore, the elevator device 100 can be installed in a building from the early stages of construction, and as the height of the building increases, the machine room 5 can be raised in stages to increase the length of the ascent and descent stroke of the elevator device 100.

In addition, according to the elevator device 100 and its installation method of the first embodiment, when moving the machine room 5 upward, a tower crane for building construction work is not used, but the lifting unit 8 is used. Therefore, a tower crane can be used for construction work even during the process of moving the machine room 5 upward. This makes it possible to shorten the construction work period for the building and complete the work early.

Furthermore, according to the elevator device 100 and the installation method thereof of the first embodiment, a work scaffold is provided for installing the car guide rail 12, and the car guide rail 12 is installed with its longitudinal direction vertical, so that the work of extending the car guide rail 12 upward can be performed smoothly. Furthermore, according to the elevator device 100 and the installation method thereof of the first embodiment, a work scaffold is provided for installing the counterweight guide rail 32, and the counterweight guide rail 32 is installed with its longitudinal direction vertical, so that the work of extending the counterweight guide rail 32 upward can be performed smoothly.

A variation of the first embodiment.
Fig. 13 is a side view showing a schematic configuration of an elevator apparatus in a modified example of the first embodiment. Fig. 13(a) shows a state immediately before the deck plate 19 is lifted upward, Fig. 13(b) shows a state in which the deck plate 19 is attached to the hoistway 10, and Fig. 13(c) shows a state in which the deck plate 19 is lifted upward. The elevator apparatus 200 in the modified example of the first embodiment differs from the elevator apparatus 100 in the first embodiment in the configuration of the deck plate. In this modified example of the first embodiment, as shown in Fig. 13(a), when the machine room 5 moves upward, the elevator moves through the hoistway 10 while loading the deck plate 19 on the lifting unit 8.

As shown in Figures 13(b) and 13(c), the deck plate 19 has a deck plate body 19B and a link mechanism 19A. In a side view, the link mechanism 19A is provided on the outer side of the deck plate body 19B in the longitudinal direction (i.e., both ends in the longitudinal direction). The link mechanism 19A has a 1/4 arc shape centered on the rotation axis 19A1 at the part where it contacts the deck plate body 19B. Although not shown, the deck plate 19 has an opening similar to that of the deck plate 9 of the elevator device of the first embodiment described above.

As shown in FIG. 13(b), when the deck plate 19 is placed on the receiving part 17 provided on the elevator shaft 10 or the floor, both ends of the link mechanism 19A come into contact with the receiving part 17. In this state, the rotation of the link mechanism 19A is restricted, and the deck plate 19 becomes linear in the horizontal direction.

As shown in FIG. 13(c), when the deck plate 19 is lifted upward from below, the link mechanism 19A rotates around the rotation axis 19A1 due to the moment caused by its own weight, and the angle it forms with the deck plate main body 19B becomes 90 degrees. The width h of the deck plate 19 becomes smaller than the distance H between the receiving parts 17 (in other words, the width of the elevator shaft 10).

In this way, when the deck plate 19 is pushed up from below, the link mechanisms 19A at both ends of the deck plate 19 are structured to bend downward under their own weight. The deck plate 19 can be moved upward without coming into contact with the wall surface of the elevator shaft 10.

The elevator device 200 and its installation method according to the modified example of the first embodiment can provide the same effects as the elevator device 100 according to the first embodiment described above.

In addition, according to the elevator device 200 and its installation method of the modified example of the first embodiment, when the lifting unit 8 is moved upward, the deck plate 19 that has been used can be collected while being loaded on the lifting unit 8. This makes it possible to shorten the installation work time of the elevator device 200.

The deck plate 19 used in the elevator device 200 of the modified embodiment of the first embodiment can also be used in the elevator device 300 of the second embodiment described below.

Embodiment 2.
FIG. 14 is a diagram showing a schematic configuration of an elevator apparatus according to a second embodiment. FIG. 14(a) is a front view of the elevator apparatus, and FIG. 14(b) is a side view of the elevator apparatus. The elevator apparatus 300 according to the second embodiment differs from the elevator apparatus 100 according to the first embodiment in the configuration of the connecting member connecting the lifting unit 8 and the machine room 5. Specifically, in the elevator apparatus 100 according to the first embodiment, the connecting member connecting the lifting unit 8 and the machine room 5 is a chain 7, whereas in the elevator apparatus 300 according to the second embodiment, the connecting member connecting the lifting unit 8 and the machine room 5 has a lifting body lifting device 31 and a hoisting jig 13. That is, the machine room 5 is suspended from the lifting unit 8 via the lifting body lifting device 31 and the hoisting jig 13. The elevator apparatus 300 according to the second embodiment also differs from the elevator apparatus 100 according to the first embodiment in that it does not include an electric chain block 8A. In the following description, the lifting body lifting device 31 will also be referred to as a first connecting member, and the hanging jig 13 will also be referred to as a second connecting member.

When the machine room 5 is moved upward, the suspension body 2 is pulled out from the winding device 3 into the elevator shaft 10. This may cause the weight balance (i.e., the position of the center of gravity) of the machine room 5 to change. The connecting member of the second embodiment makes it possible to suspend the machine room 5 horizontally and stably, even if the weight balance (i.e., the position of the center of gravity) changes in this way.

As shown in FIG. 14(a), the lifting device 31 is configured to be able to move the chain 7 in the left-right direction (i.e., horizontal direction) when viewed from the front. The detailed configuration of the lifting device 31 will be described later with reference to FIG. 15.

The hanging jig 13 includes a beam member 13a, a chain equalizer 13b, and a chain 13c. The lower end of the chain 7 is connected to the upper part of the beam member 13a. The chain 7 is also referred to as a first chain, and the chain 13c is also referred to as a second chain.
The chain equalizer 13b is provided at the lower part of the beam member 13a. In the example of FIG. 14, two chain equalizers 13b are provided. A chain 13c is hung on each of the two chain equalizers 13b. The chains 13c are suspended in two directions from the chain equalizers 13b. The lower end of the chain 13c is connected to a member (not shown) provided on the upper surface of the machine room 5. The positions at which the chain 13c is connected to the members provided on the upper surface of the machine room 5 are near both ends in the left-right direction of the machine room 5 in the side view of FIG. 14(b). The detailed configuration of the suspension jig 13 will be described later with reference to FIG. 16 and FIG. 17.

The chain equalizer 13b has a function of swinging the chain 13c hung on the chain equalizer 13b, and can adjust the weight balance in the left-right direction of the machine room 5 in the side view of FIG. 14(b). Therefore, the chain equalizer 13b can also be called a balance adjustment mechanism.

Figure 15 is a diagram showing a schematic configuration of a lifting device for a lifting body used in an elevator system according to embodiment 2. Figure 15(a) is a front view of the lifting device for a lifting body, Figure 15(b) is a side view of the lifting device for a lifting body, and Figure 15(c) is a perspective view of a main part of the lifting device for a lifting body.

The lifting body lifting device 31 has a winch 31a, an arm 31b, a C-shaped steel 31c, and a roller 31d.
As shown in FIG. 15(a), two arms 31b are attached to the upper part of the winch 31a in the longitudinal direction of the winch 31a. One end of the arms 31b is attached to the winch 31a. As shown in FIG. 15(b), a roller 31d is rotatably attached to the other end of the arms 31b. The rotation shaft of the roller 31d passes through the arms 31b. As shown in FIG. 15(b), two rollers 31d are provided for one arm 31b so as to sandwich the arm 31b. The two rollers 31d and the rotation shaft connecting them can be collectively referred to as a roller part. The upper part of the C-shaped steel 31c is attached to the lower support beam 8D. The chain 7 is drawn out from the lower side of the winch 31a.

The roller 31d can be rotated with its bottom surface in contact with the C-shaped steel 31c. By rotating the roller 31d, the position of the winch 31a can be moved left and right (in other words, horizontally) when viewed from the front. This allows the position of the chain 7 that is pulled out from the winch 31a and suspends the machine room 5 via the suspending jig 13 to be moved left and right (in other words, horizontally) when viewed from the front. This allows the suspension position by the chain 7 to be adjusted to match the center of gravity of the machine room 5. Therefore, the roller 31d of the lifting body lifting device 31 functions as a position adjustment mechanism. The roller 31d can also be called a first position adjustment mechanism.

Figure 16 is a diagram showing the configuration of the main parts of the hanging jig used in the elevator device of embodiment 2. Figure 16(a) is a side view of the main parts of the hanging jig, Figure 16(b) is a perspective view of the main parts of the hanging jig, and Figure 16(c) is a diagram explaining the configuration of the shackle member. Note that part of the configuration shown in Figure 16(a) is omitted in Figure 16(b).

The hoisting jig 13 has a beam member 13a, a hoisting plate 13h, a shackle member 13i, an upper ring member 13d, and a pair of lower ring members 13e. A hook (not shown) provided at the lower end of the chain 7 shown in Figures 14 and 15 is hung on the upper ring member 13d. In this way, the hoisting jig 13 is suspended from the lifting unit 8 via the lifting body lifting device 24. Also, the upper end of the chain equalizer 13b shown in Figure 14 is connected to the lower ring member 13e. Also, as shown in Figure 14, the machine room 5 is suspended from the beam member 13a via the chain equalizer 13b and the chain 13c suspended from the chain equalizer 13b.

As shown in FIG. 16B, the hanging plate 13h is attached in a state where it is sandwiched between two beam members 13a. The two beam members 13a are fixed by a fixing member 13j. The beam members 13a have through-holes 13f, and the two beam members 13a and the fixing member 13j are fixed by inserting fastening members 13g into the through-holes 13f. The beam members 13a have a plurality of through-holes 13f formed along the longitudinal direction and the lateral direction. The installation worker can change the fixing position of the hanging plate 13h relative to the beam members 13a by changing the through-holes 13f into which the fastening members 13g are inserted. The installation worker fixes the hanging plate 13h by the fastening members 13g at the through-holes 13f at a position where the machine room 5 can be suspended from the center of gravity. Here, the center of gravity suspension means suspension of the center of gravity of the machine room 5 in order to suspend the machine room 5 while keeping it horizontal.
The pair of lower ring members 13e are hung on mounting members 13p provided between the two beam members 13a.

The hanging plate 13h may be provided with multiple through holes (not shown), and the hanging plate 13h may be fixed with fastening members 13g at positions that match the hole positions of the through holes 13f. In the example of FIG. 16, the through holes 13f are multiple round holes, but the through holes 13f may also be long holes that are long in the longitudinal direction.

Figure 16 (c) is a diagram showing an example of the configuration of the shackle member 13i. The hanging plate 13h and the upper ring member 13d are connected, for example, using the shackle member 13i. The shackle member 13i has a U-shaped member 13i1, a bolt 13i2, and a nut 13i3. With the upper ring member 13d hung on the U-shaped member 13i1, the bolt 13i2 is inserted into the through hole provided in the U-shaped member 13i1 and the through hole 13h1 provided in the upper part of the hanging plate 13h, and is connected to the nut 13i3, whereby the hanging plate 13h and the upper ring member 13d are connected via the shackle member 13i.

Next, the procedure for moving the fixed position of the hanging plate 13h of the hanging jig 13 will be described with reference to Figures 17(a) and 17(b). Figure 17 is a diagram showing the configuration of the main parts of a beam member used in an elevator device of embodiment 2. Figure 17(a) is a diagram showing the state before the fixed position of the hanging plate 13h is moved, and Figure 17(b) is a diagram showing the state after the fixed position of the hanging plate 13h is moved.

Member 13o is fixed to hanging plate 13h. Pedestal 13k is fixed to beam member 13a. Member 13o and pedestal 13k are connected by a rod screw 13n, which passes through member 13o. As shown in Figures 7(a) and 7(b), a jack-up nut 13l is attached to rod screw 13n so as to sandwich member 13o from the left and right. In addition, a lock nut 13m is attached to the outside of jack-up nut 13l to rod screw 13n.

When moving the fixed position between the hanging plate 13h and the beam member 13a, the installer first loosens the fastening member 13g. Next, the installer loosens the left and right lock nuts 13m of the member 13o. Next, the installer rotates the jack-up nut 13l and moves the hanging plate 13h to a position where the center of gravity of the machine room 5 can be suspended. Next, the installer tightens the left and right jack-up nuts 13l of the member 13o to secure it, and then tightens the left and right lock nuts 13m to secure it. Next, the installer secures the hanging plate 13h at the through-hole 13f with the fastening member 13g.

At this time, the installation worker fixes the hanging plate 13h at the penetration part 13f on the right side of the original position, thereby moving the fixed position of the hanging plate 13h relative to the beam member 13a and adjusting the hanging position of the chain 7 to be above the center of gravity of the machine room 5. This allows the machine room 5 to be suspended from its center of gravity, and prevents excessive load from acting on the car guide rail 12. Therefore, the hanging plate 13h and the beam member 13a function as a position adjustment mechanism. The hanging plate 13h and the beam member 13a can also be referred to as a second position adjustment mechanism.

The process of adjusting the fixed position of the beam member 13a relative to the hanging plate 13h is performed in the eleventh step shown in FIG. 11(k) before or after the suspended body 2 is pulled out from the winding device 3 into the elevator shaft 10.

According to the elevator device 300 and its installation method of the second embodiment, the lifting unit 8 can move the machine room 5 upward. Therefore, the elevator device 300 can be installed in a building from the early stages of construction, and as the height of the building increases, the machine room 5 can be raised in stages to increase the length of the ascent and descent stroke of the elevator device 300.

In addition, according to the elevator device 300 and its installation method of the second embodiment, when moving the machine room 5 upward, a tower crane for building construction work is not used, but a lifting unit 8 is used. Therefore, a tower crane can be used for construction work even during the process of moving the machine room 5 upward. This makes it possible to shorten the construction work period for the building and complete the work early.

Furthermore, according to the elevator device 300 and the installation method thereof of the second embodiment, a work scaffold is provided for installing the car guide rail 12, and the car guide rail 12 is installed with its longitudinal direction vertical, so that the work of extending the car guide rail 12 upward can be performed smoothly. Furthermore, according to the elevator device 300 and the installation method thereof of the second embodiment, a work scaffold is provided for installing the counterweight guide rail 32, and the counterweight guide rail 32 is installed with its longitudinal direction vertical, so that the work of extending the counterweight guide rail 32 upward can be performed smoothly.

Furthermore, according to the elevator device 300 and its installation method of embodiment 2, the lifting unit 8 has a position adjustment mechanism that can adjust the position at which the machine room 5 is suspended so as to match the position of the center of gravity of the machine room 5, thereby preventing a rotational moment from acting on the machine room 5 and preventing an excessive load from acting on the car guide rail 12. This makes it possible to prevent damage to the elevator device 300 or the equipment used in its installation.

A variation of the second embodiment.
FIG. 18 is a diagram showing a schematic configuration of an elevator device according to a modification of the second embodiment. FIG. 18(a) is a front view of the elevator device, and FIG. 18(b) is a side view of the elevator device. In the elevator device 301 according to the modification of the second embodiment, the connecting member connecting the lifting unit 8 and the machine room 5 has the lifting body lifting device 33 and the hoisting jig 13. That is, the machine room 5 is suspended from the lifting unit 8 via the lifting body lifting device 33 and the hoisting jig 13. The elevator device 301 according to the modification of the second embodiment differs from the elevator device 300 according to the second embodiment in that the elevator device 301 includes the lifting body lifting device 33 instead of the lifting body lifting device 31. That is, the configuration of the lifting body lifting device 33 differs from the configuration of the lifting body lifting device 31.

As shown in FIG. 18(a), the lifting body lifting device 33 is configured to be able to move the chain 7 in the left-right direction (i.e., horizontal direction) when viewed from the front. Furthermore, as shown in FIG. 18(b), the lifting body lifting device 33 is configured to be able to move the chain 7 in the left-right direction (i.e., horizontal direction) when viewed from the side. In other words, the lifting body lifting device 33 is configured to be able to move the chain 7 in two orthogonal directions in the horizontal direction. The detailed configuration of the lifting body lifting device 33 will be described later using FIG. 19 and FIG. 20.

Figures 19 and 20 are diagrams showing the configuration of a lifting device for a lifting body used in an elevator device according to a modified example of embodiment 2. Figure 19(a) is a front view of the lifting device for a lifting body, Figure 20(b) is a side view of the lifting device for a lifting body, and Figure 20(c) is a perspective view of the main parts of the lifting device for a lifting body.

The lifting body lifting device 33 has a winch 33a, an arm portion 33b1, a C-shaped steel 33c1, a roller 33d1, and a mounting member 33e.
As shown in FIG. 19(a), two arms 33b1 are attached to the upper part of the winch 33a in the longitudinal direction of the winch 33a. One end of the arms 33b1 is attached to the winch 33a. As shown in FIG. 20(b), a roller 33d1 is rotatably attached to the other end of the arms 33b1. The rotation shaft of the roller 33d1 passes through the arms 33b1. As shown in FIG. 20(b), two rollers 33d1 are provided for one arm 33b1 so as to sandwich the arm 33b1. The two rollers 33d1 and the rotation shaft connecting them can be collectively referred to as a roller part. The upper part of the C-shaped steel 33c1 is attached to the mounting member 33e. A chain 7 is drawn out from the lower side of the winch 33a.

The roller 33d1 can be rotated with its bottom surface in contact with the C-shaped steel 33c1. By rotating the roller 33d1, the position of the winch 33a can be moved left and right (in other words, horizontally) when viewed from the front. This allows the position of the chain 7 that is pulled out from the winch 33a and suspends the machine room 5 via the suspending jig 13 to be moved left and right (in other words, horizontally) when viewed from the front. This allows the suspension position by the chain 7 to be adjusted to match the center of gravity of the machine room 5. Therefore, the roller 33d1 of the lifting body lifting device 33 functions as a position adjustment mechanism. The roller 33d1 can also be called a third position adjustment mechanism.

The lifting body lifting device 33 further has an arm portion 33b2, a C-shaped steel 33c2, and a roller 33d2.
As shown in FIG. 19(a) and FIG. 20(b), the upper part of the C-shaped steel 33c1 is attached to the mounting member 33e. Four arms 33b2 are attached to the upper part of the mounting member 33e in the longitudinal direction of the mounting member 33e. One end of the arms 33b2 is attached to the mounting member 33e. As shown in FIG. 20(b), a roller 33d2 is rotatably attached to the other end of the arms 33b2. The rotation axis of the roller 33d2 passes through the arm 33b2. As shown in FIG. 20(b), two rollers 33d2 are provided for one arm 33b2 so as to sandwich the arm 33b2. The two rollers 33d2 and the rotation axis connecting them can be collectively referred to as a roller part. The upper part of the C-shaped steel 33c2 is attached to the lower support beam 8D.

The roller 33d2 can be rotated with its bottom surface in contact with the C-shaped steel 33c2. The position of the winch 33a can be moved left and right (in other words, horizontally) in a side view by rotating the roller 33d2. This allows the position of the chain 7 that is pulled out from the winch 33a and suspends the machine room 5 via the suspending jig 13 to be moved left and right (in other words, horizontally) in a side view. This allows the suspension position by the chain 7 to be adjusted to match the center of gravity of the machine room 5. Therefore, the roller 33d2 of the lifting body lifting device 33 functions as a position adjustment mechanism. The roller 33d2 can also be called a fourth position adjustment mechanism.

According to the elevator device 301 and its installation method of the modified example of the second embodiment, the lifting unit 8 has a position adjustment mechanism that can adjust the position at which the machine room 5 is suspended so as to match the position of the center of gravity of the machine room 5, thereby preventing a rotational moment from acting on the machine room 5 and preventing an excessive load from acting on the car guide rail 12. This makes it possible to prevent damage to the elevator device 301 or the equipment used in its installation.

Furthermore, according to the elevator device 301 and its installation method of the modified example of the second embodiment, the position adjustment mechanism that can adjust the position at which the lifting unit 8 suspends the machine room 5 to match the position of the center of gravity of the machine room 5 has a third position adjustment mechanism (i.e., roller 33d1) that can be adjusted in a first direction (i.e., left-right direction in a front view) in the horizontal direction, and a fourth position adjustment mechanism (i.e., roller 33d2) that can be adjusted in a second direction perpendicular to the first direction (i.e., left-right direction in a side view) in the horizontal direction, so that it is possible to adjust the position in two perpendicular directions, and the range in which the position can be adjusted can be expanded.

In the above embodiment 1, the method of moving the lifting unit 8 upward was described using Figures 5 to 7, but the lifting unit 8 can be moved downward by performing the reverse procedure (i.e., from step 4 to step 1) from the state in which the lifting unit 8 has been moved upward. Therefore, the method of moving the machine room 5 upward described using Figures 8 to 11 can also be performed by performing the reverse procedure (from step 11 to step 1) to move the machine room 5 downward. In this way, the machine room 5 can be sequentially moved downward to perform dismantling work for the elevator devices 100, 200, and 300.

In each of the above embodiments, examples using chains 6, 7, and 13c have been described, but some or all of these chains may be replaced with wires, ropes, etc.

In addition, in each of the above embodiments, an example has been described in which a hydraulic jack 8B is used as a jack, but the hydraulic jack 8B may be any jack that is disposed between the upper support beam 8C and the lower support beam 8D, and that contracts and becomes lower when a vertical force is applied between the upper support beam 8C and the lower support beam 8D, and expands and becomes higher when the vertical force between the upper support beam 8C and the lower support beam 8D is removed, thereby enabling the upper support beam 8C to be lifted.

Below, examples of aspects that may be included in the present disclosure are set forth as appendices.
(Appendix 1)
The car ascends and descends inside the elevator,
a machine room for suspending the car;
A car guide rail for guiding the lifting and lowering of the car;
A lifting unit for moving the machine room upward;
A work scaffold used for installing the car guide rail;
An elevator device comprising:
(Appendix 2)
The lifting unit comprises:
An upper beam member;
A lower beam member;
a moving mechanism that alternately moves the upper beam member and the lower beam member upward;
2. The elevator apparatus of claim 1, comprising:
(Appendix 3)
The moving mechanism includes:
a jack provided between the upper beam member and the lower beam member and configured to widen a distance between the upper beam member and the lower beam member from a first distance to a second distance wider than the first distance;
a traction device provided between the upper beam member and the lower beam member and configured to narrow a distance between the upper beam member and the lower beam member from the second distance to the first distance;
3. The elevator apparatus of claim 2, comprising:
(Appendix 4)
The elevator shaft is provided with a beam support that limits downward movement of the upper beam member and the lower beam member,
Each of the upper beam member and the lower beam member is configured to be extendable and contractable in a horizontal direction,
Each of the upper beam member and the lower beam member is held by the beam receiver when extended in the horizontal direction, and is released from the hold by the beam receiver when contracted in the horizontal direction.
4. The elevator apparatus according to claim 2 or 3.
(Appendix 5)
A connecting member is provided to connect the lifting unit and the machine room,
The connecting member has a position adjustment mechanism that can adjust the position at which the lifting unit suspends the machine room to the position of the center of gravity of the machine room.
5. An elevator apparatus according to any one of claims 2 to 4.
(Appendix 6)
The connecting member has a first connecting member connected to the lifting unit and a second connecting member suspended from the first connecting member, the first connecting member can adjust the suspension position of the second connecting member in the horizontal direction, and the second connecting member can adjust the suspension position of the machine room in the horizontal direction.
12. The elevator apparatus of claim 5 or 11.
(Appendix 7)
The first connecting member includes a first chain and a roller portion that can adjust a hanging position of the second connecting member by the first chain in a horizontal direction,
The second connecting member includes a second chain connected to the machine room, a hanging plate connected to a lower portion of the first chain, and a beam plate fixed to the hanging plate and connected to an upper portion of the second chain,
The beam plate is capable of adjusting a horizontal fixed position of the beam plate relative to the hanging plate.
7. The elevator apparatus of claim 6.
(Appendix 8)
The second chain is connected to the beam plate via a chain equalizer.
8. The elevator apparatus of claim 7.
(Appendix 9)
The work scaffold includes a work scaffold main body and a link mechanism, and the link mechanism is configured to rotate relative to the work scaffold main body due to its own weight.
9. An elevator apparatus according to any one of claims 1 to 8.
(Appendix 10)
The work scaffold has an opening into which the car guide rail can be inserted with the longitudinal direction of the car guide rail vertical.
10. An elevator apparatus according to any one of claims 1 to 9.
(Appendix 11)
The car ascends and descends inside the elevator,
a machine room for suspending the car;
a lifting unit having an upper beam member, a lower beam member, and a moving mechanism for alternately moving the upper beam member and the lower beam member upward, and for moving the machine room upward;
A connecting member that connects the lifting unit and the machine room,
The connecting member has a position adjustment mechanism that can adjust the position at which the lifting unit suspends the machine room to the position of the center of gravity of the machine room.
Elevator equipment.
(Appendix 12)
A first step of installing a car guide rail in a working scaffold installed in a hoistway through which a car is raised and lowered, with the longitudinal direction of the car guide rail being vertical;
a second step of moving the lifting unit upward;
a third step of connecting the lifting unit and a machine room that suspends the car using a connecting member;
and a fourth step of moving the connecting member upward to thereby move the machine room upward.
(Appendix 13)
The lifting unit includes an upper beam member and a lower beam member,
The second step comprises:
a first holding step of holding the upper beam member and the lower beam member at a first interval;
a second holding step of moving the upper beam member upward to hold the upper beam member and the lower beam member at a second distance wider than the first distance;
a third holding step of moving the lower beam member upward to hold the upper beam member and the lower beam member at the first interval;
13. The method of installing an elevator apparatus according to claim 12, comprising:
(Appendix 14)
The lifting unit includes an upper beam member and a lower beam member,
The elevator shaft is provided with a beam support that limits vertical movement of the upper beam member and the lower beam member,
The second step comprises:
A step of extending the upper beam member in a horizontal direction and holding it on the beam support;
A step of horizontally contracting the upper beam member to release the support by the beam receiver;
A step of extending the lower beam member in a horizontal direction and holding it on the beam support;
a step of horizontally contracting the lower beam member to release the support by the beam receiver;
13. The method of installing an elevator apparatus according to claim 12, comprising:
(Appendix 15)
The lifting unit includes an upper beam member and a lower beam member,
The elevator shaft is provided with a beam support that limits downward movement of the upper beam member and the lower beam member,
The second step comprises:
A step of horizontally contracting the upper beam member to release the support by the beam receiver;
a step of moving the upper beam member upward by a jack provided between the upper beam member and the lower beam member;
A step of extending the upper beam member in a horizontal direction and holding it on the beam support;
a step of horizontally contracting the lower beam member to release the support by the beam receiver;
moving the lower beam member upward by a traction device provided between the upper beam member and the lower beam member;
A step of extending the lower beam member in a horizontal direction and holding it on the beam support;
13. The method of installing an elevator apparatus according to claim 12, comprising:
(Appendix 16)
The third step includes a step of adjusting a position at which the lifting unit suspends the machine room so as to match the position of a center of gravity of the machine room.
16. An installation method for an elevator apparatus according to any one of claims 12 to 15.
(Appendix 17)
The second step includes a step of loading the work scaffold on the lifting unit.
17. An installation method for an elevator apparatus according to any one of claims 12 to 16.

100, 200, 300 Elevator device, 1 Cage, 2 Suspension body, 3 Winding device, 4 Hoist, 5 Machine room, 6 Chain, 7 Chain, 8 Lifting unit, 8A Electric chain block, 6B Hydraulic jack, 8C Upper support beam (upper beam member), 8C1 Upper support beam main body, 8C2 Upper support beam end, 8D Lower support beam (lower beam member), 8D1 Lower support beam main body, 8D2 Lower support beam end, 8E Guide shoe, 8F Chain block, 9, 9a, 9b, 19 Deck plate (work scaffold), 9a1, 9a2, 9a3, 9b1, 9b2, 9b3 Opening, 19A Link mechanism, 19B Deck plate main body, 19A1 Rotating shaft, 10 Hoistway, 11 Support beam support (beam support), 12 cage guide rail, 12a cage guide rail, 12b cage guide rail, 13 lifting jig, 13a beam member, 13b chain equalizer, 13c chain, 13d upper ring member, 13e lower ring member, 13f penetration portion, 13g fastening member, 13h lifting plate, 13h1 penetration portion, 13i shackle member, 13i1 U-shaped member, 13i2 bolt, 13i3 nut, 13j fixing member, 13k base, 13l jack-up nut, 13m lock nut, 13n rod screw, 13o member, 13p mounting member, 15 counterweight, 16 control device, 17 receiving portion, Description of the Reference Signs 18 Drive sheave, 20 Cage body, 21 Cage hoist, 22 Counterweight body, 23 Counterweight hoist, 24 Lifting body lifting device, 25 Fixing member, 26 Support member, 26A Member, 26B Roller portion, 27 Beam member, 29 Support base, 30 Piano wire, 31 Lifting body lifting device, 31a Winch, 31b Arm portion, 31c C-shaped steel, 31d Roller, 32 Counterweight guide rail, 33 Lifting body lifting device, 33a Winch, 33b1, 33b2 Arm portion, 33c1, 33c2 C-shaped steel, 33d1, 33d2 Roller, 33e Mounting member

The elevator apparatus of the present disclosure comprises a car that rises and falls inside a hoistway, a machine room from which the car is suspended, a car guide rail that guides the rise and fall of the car, a lifting unit that moves the machine room upward, and a work scaffolding used to install the car guide rail , wherein the lifting unit comprises an upper beam member, a lower beam member, and a moving mechanism that moves the upper beam member and the lower beam member alternately upward, and the moving mechanism comprises a jack that is provided between the upper beam member and the lower beam member and expands the distance between the upper beam member and the lower beam member from a first distance to a second distance wider than the first distance, and a traction device that is provided between the upper beam member and the lower beam member and narrows the distance between the upper beam member and the lower beam member from the second distance to the first distance.

The installation method of the elevator apparatus of the present disclosure includes a first step of installing a car guide rail with a longitudinal direction of the car guide rail vertical on a work scaffold installed in a hoistway through which a car is raised and lowered, a second step of moving a lifting unit upward, a third step of connecting the lifting unit and a machine room from which the car is suspended using a connecting member, and a fourth step of moving the machine room upward by moving the connecting member upward , the lifting unit including an upper beam member and a lower beam member, and the hoistway including a vertical direction of the upper beam member and the lower beam member. The second step includes a step of horizontally contracting the upper beam member to release the support by the beam support, a step of moving the upper beam member upward using a jack provided between the upper beam member and the lower beam member, a step of extending the upper beam member horizontally to hold it in the beam support, a step of horizontally contracting the lower beam member to release the support by the beam support, a step of moving the lower beam member upward using a traction device provided between the upper beam member and the lower beam member, and a step of extending the lower beam member horizontally to hold it in the beam support.

Claims (17)

The car ascends and descends inside the elevator,
a machine room for suspending the car;
A car guide rail for guiding the lifting and lowering of the car;
A lifting unit for moving the machine room upward;
A work scaffold used for installing the car guide rail;
An elevator device comprising: The lifting unit comprises:
An upper beam member;
A lower beam member;
a moving mechanism that alternately moves the upper beam member and the lower beam member upward;
The elevator apparatus of claim 1 . The moving mechanism includes:
a jack provided between the upper beam member and the lower beam member and configured to widen a distance between the upper beam member and the lower beam member from a first distance to a second distance wider than the first distance;
a traction device provided between the upper beam member and the lower beam member and configured to narrow a distance between the upper beam member and the lower beam member from the second distance to the first distance;
The elevator apparatus of claim 2 . The elevator shaft is provided with a beam support that limits downward movement of the upper beam member and the lower beam member,
Each of the upper beam member and the lower beam member is configured to be extendable and contractable in a horizontal direction,
Each of the upper beam member and the lower beam member is held by the beam receiver when extended in the horizontal direction, and is released from the hold by the beam receiver when contracted in the horizontal direction.
3. The elevator system of claim 2. A connecting member is provided to connect the lifting unit and the machine room,
The connecting member has a position adjustment mechanism that can adjust the position at which the lifting unit suspends the machine room to the position of the center of gravity of the machine room.
3. The elevator system of claim 2. The connecting member has a first connecting member connected to the lifting unit and a second connecting member suspended from the first connecting member, the first connecting member can adjust the suspension position of the second connecting member in the horizontal direction, and the second connecting member can adjust the suspension position of the machine room in the horizontal direction.
6. An elevator system according to claim 5. The first connecting member includes a first chain and a roller portion that can adjust a hanging position of the second connecting member by the first chain in a horizontal direction,
The second connecting member includes a second chain connected to the machine room, a hanging plate connected to a lower portion of the first chain, and a beam plate fixed to the hanging plate and connected to an upper portion of the second chain,
The beam plate is capable of adjusting a horizontal fixed position of the beam plate relative to the hanging plate.
7. The elevator system of claim 6. The second chain is connected to the beam plate via a chain equalizer.
8. An elevator system according to claim 7. The work scaffold includes a work scaffold main body and a link mechanism, and the link mechanism is configured to rotate relative to the work scaffold main body due to its own weight.
An elevator apparatus according to any one of claims 1 to 8. The work scaffold has an opening into which the car guide rail can be inserted with the longitudinal direction of the car guide rail vertical.
2. The elevator system of claim 1. The car ascends and descends inside the elevator,
a machine room for suspending the car;
a lifting unit having an upper beam member, a lower beam member, and a moving mechanism for moving the upper beam member and the lower beam member alternately upward, and for moving the machine room upward;
A connecting member that connects the lifting unit and the machine room,
The connecting member has a position adjustment mechanism that can adjust the position at which the lifting unit suspends the machine room to the position of the center of gravity of the machine room.
Elevator equipment. A first step of installing a car guide rail in a working scaffold installed in a hoistway through which a car is raised and lowered, with the longitudinal direction of the car guide rail being vertical;
a second step of moving the lifting unit upward;
a third step of connecting the lifting unit and a machine room that suspends the car using a connecting member;
a fourth step of moving the connecting member upward to thereby move the machine chamber upward;
An elevator installation method comprising: The lifting unit includes an upper beam member and a lower beam member,
The second step comprises:
a first holding step of holding the upper beam member and the lower beam member at a first interval;
a second holding step of moving the upper beam member upward to hold the upper beam member and the lower beam member at a second distance wider than the first distance;
a third holding step of moving the lower beam member upward to hold the upper beam member and the lower beam member at the first interval;
13. The method of claim 12, comprising: The lifting unit includes an upper beam member and a lower beam member,
The elevator shaft is provided with a beam support that limits downward movement of the upper beam member and the lower beam member,
The second step comprises:
A step of extending the upper beam member in a horizontal direction and holding it on the beam support;
A step of horizontally contracting the upper beam member to release the support by the beam receiver;
A step of extending the lower beam member in a horizontal direction and holding it on the beam support;
a step of horizontally contracting the lower beam member to release the support by the beam receiver;
13. The method of claim 12, further comprising: The lifting unit includes an upper beam member and a lower beam member,
The elevator shaft is provided with a beam support that limits vertical movement of the upper beam member and the lower beam member,
The second step comprises:
A step of horizontally contracting the upper beam member to release the support by the beam receiver;
a step of moving the upper beam member upward by a jack provided between the upper beam member and the lower beam member;
A step of extending the upper beam member in a horizontal direction and holding it on the beam support;
a step of horizontally contracting the lower beam member to release the support by the beam receiver;
moving the lower beam member upward by a traction device provided between the upper beam member and the lower beam member;
A step of extending the lower beam member in a horizontal direction and holding it on the beam support;
13. The method of claim 12, further comprising: The third step includes a step of adjusting a position at which the lifting unit suspends the machine room so as to match the position of a center of gravity of the machine room.
13. A method for installing an elevator system according to claim 12. The second step includes a step of loading the work scaffold on the lifting unit.
A method for installing an elevator apparatus according to any one of claims 12 to 16.

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