JP2017065904A - Scaffold for installation work of elevator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a scaffold for the installation work of an elevator which is reduced in weight by suppressing an increase of the number of part items, and can ascend and descend a work floor after installation.SOLUTION: A scaffold for installation work comprises: a columnar support attached to a car stop in a fixed state; a foundation part which is fixed to the columnar support at its one end, and protrudes to a depth side while separating from the car stop in a hoistway; a work floor part attached to a salient part salient toward the inside of the hoistway of the foundation part so as to be liftable; a lift mechanism which is supported to the foundation part at a pivot so as to be turntable, arranged while extending to the depth side in the hoistway from the car stop side, sets a car stop side end part as a power point which a worker operates, and has a fulcrum with the depth side end part as an operation point at which a load is applied to the work floor part; and a fixing device which fixes the work floor part to the foundation part.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a scaffold for installation work that is used by being installed in a landing so as to protrude into a hoistway during installation work of an elevator.

  When installing the elevator, there is an operation of attaching and detaching the lifting beam to access the top of the hoistway, but in other operations, the operation is performed at least 2 m below the top.

  In view of such a situation, there has been proposed a scaffold for installation work in which the height position of the work floor can be adjusted so that the worker can work in an appropriate posture (see, for example, Patent Documents 1 and 2).

JP-A-2-52886 JP 2005-89148 A

  In the conventional installation work scaffold described in Patent Document 1, the height of the work floor can be adjusted at the time of installation, but the height of the work floor cannot be adjusted after the installation once. Therefore, if the height of the work floor is changed, it is necessary to disassemble and reassemble the installation work scaffold, which causes a problem that the installation workability of the elevator is lowered.

  In the conventional installation work scaffold described in Patent Document 2, it is configured to build a high-level second-stage work floor using additional parts as necessary after installation. The number increases and the mass increases. When an elevator is installed, an operator must manually transport a conventional installation work scaffold with an increased mass to the top floor, which increases the operator's transportation work load.

  The present invention has been made to solve the above-described problems, and has an object to obtain a scaffold for installation work of an elevator capable of reducing the weight by suppressing an increase in the number of parts and allowing the work floor to be raised and lowered after installation. To do.

  An elevator installation scaffolding according to the present invention includes a support column fixedly attached to a landing, a base fixed at one end to the support column, and protruding to the far side away from the landing in the hoistway. A working floor portion that is attached to the projecting portion of the foundation portion into the hoistway so as to be movable up and down, and a fulcrum is rotatably supported by the base portion and extends from the landing side to the inner side of the hoistway. The lifting mechanism part having a lever with the landing side end as a force point for the operator to operate and the back side end as an action point for applying a load to the work floor, and the work floor as the above A fixing device for fixing to the base portion.

  According to this invention, the work floor portion is attached to the projecting portion into the hoistway of the base portion, one end of which is fixed to the column portion, so as to be movable up and down. Therefore, since the height of the work floor can be changed after the installation work scaffold is installed, it is not necessary to disassemble and reassemble the installed work scaffold, and the installation workability of the elevator is improved. Furthermore, additional parts for changing the height of the work floor are not required, and the installation work scaffold can be reduced in weight. Therefore, the transportation work load of the worker who transports the installation work scaffold to the top floor is reduced.

It is a perspective view which shows the scaffold for installation work which concerns on Embodiment 1 of this invention. It is a side view which shows the state which installed the scaffold for installation work which concerns on Embodiment 1 of this invention in the hoistway. It is principal part sectional drawing which shows the fixed part periphery of the scaffold for installation work concerning Embodiment 1 of this invention. It is a top view explaining the structure of the remote control fixing device in the scaffold for installation work concerning Embodiment 1 of this invention. It is a rear view explaining the structure of the remote control fixing device in the scaffold for installation work concerning Embodiment 1 of this invention. It is a schematic diagram which shows the movable range of the raising / lowering mechanism part in the scaffold for installation work which concerns on Embodiment 1 of this invention. It is a schematic diagram which shows the relationship between the position of the lever action point in the scaffold for installation work concerning Embodiment 1 of this invention, and the position of the gravity center of a work floor part. It is a principal part schematic diagram which shows the lever action periphery in the scaffold for installation work which concerns on Embodiment 2 of this invention. It is a side view which shows the assembly of the base part and work floor part in the scaffold for installation work which concerns on Embodiment 3 of this invention. It is a side view which shows the assembly of the base part and work floor part in the scaffold for installation work which concerns on Embodiment 4 of this invention. It is a front view which shows the assembly of the base part and work floor part in the scaffold for installation work which concerns on Embodiment 4 of this invention. It is a side view which shows the assembly of the base part and work floor part in the scaffold for installation work which concerns on Embodiment 5 of this invention. It is a front view which shows the assembly of the base part and work floor part in the scaffold for installation work which concerns on Embodiment 5 of this invention. It is a principal part perspective view explaining the connection state with the leg part of the lever work floor part in the scaffold for installation work which concerns on Embodiment 5 of this invention. It is a principal part side view explaining the connection state with the leg part of the lever work floor part in the scaffold for installation work which concerns on Embodiment 5 of this invention. It is a principal part perspective view explaining the connection state with the leg part of the lever work floor part in the scaffold for installation work which concerns on Embodiment 6 of this invention. It is a principal part side view explaining the connection state with the leg part of the lever work floor part in the scaffold for installation work which concerns on Embodiment 6 of this invention. It is a side view which shows the assembly of the base part and work floor part in the scaffold for installation work which concerns on Embodiment 7 of this invention. It is a rear view which shows the assembly of the base part and work floor part in the scaffold for installation work which concerns on Embodiment 7 of this invention. It is a top view which shows the raising / lowering mechanism part in the scaffold for installation work which concerns on Embodiment 7 of this invention. It is a side view which shows the assembly of the base part and work floor part in the scaffold for installation work which concerns on Embodiment 8 of this invention. It is a rear view which shows the assembly of the base part and work floor part in the scaffold for installation work which concerns on Embodiment 8 of this invention. It is a top view which shows the raising / lowering mechanism part in the scaffold for installation work which concerns on Embodiment 8 of this invention. It is a side view which shows the assembly of the base part and work floor part in the scaffold for installation work which concerns on Embodiment 9 of this invention. It is a rear view which shows the assembly of the base part and work floor part in the scaffold for installation work which concerns on Embodiment 9 of this invention. It is a top view which shows the raising / lowering mechanism part in the scaffold for installation work concerning Embodiment 9 of this invention.

Embodiment 1 FIG.
1 is a perspective view showing a scaffold for installation work according to Embodiment 1 of the present invention, FIG. 2 is a side view showing a state in which the scaffold for installation work according to Embodiment 1 of the present invention is installed in a hoistway, and FIG. 3 is a cross-sectional view of the main part showing the periphery of the fixing portion of the installation work scaffold according to Embodiment 1 of the present invention, and FIG. 4 shows the configuration of the remote control fixing device in the installation work scaffold according to Embodiment 1 of the present invention. FIG. 5 is a top view for explaining, and FIG. 5 is a rear view for explaining the configuration of the remote control fixing device in the scaffold for installation work according to Embodiment 1 of the present invention. In each figure, the X direction is the frontage direction, the Y direction is the vertical direction, and the Z direction is the depth direction. Further, the back side means a direction away from the landing side in the Z direction.

  1 and 2, the installation work scaffold 100 is installed so as to be fixed to the landing 2 and the column 10 is fixed to the column 10 so that one end protrudes to the back side in the hoistway 1. A base portion 15, a work floor portion 25 installed on the base portion 15 so as to be movable up and down, and an elevating mechanism portion that moves the work floor portion 25 up and down.

  Each of the support columns 10 includes a pair of support columns 11 that are spaced apart in the X direction with the length direction as the Y direction, and a beam 12 that connects the upper ends of the pair of support columns 11 with the length direction as the X direction. And comprising. And the support | pillar part 10 fixes the lower end of a pair of support | pillar 11 to the floor of the platform 2 with an anchor bolt etc., and is standingly arranged by the entrance / exit 3 side of the platform 2. FIG.

  The base portion 15 includes four front and rear frames 16 whose length direction is the Z direction, four upper and lower frames 17 whose length direction is the Y direction, and four left and right frames whose length direction is the X direction. 18, and the end portions of the front and rear frame 16, the upper and lower frame 17, and the left and right frame 18 are connected to each other to produce a frame-like body constituted by 12 sides of a rectangular solid. Further, each of the pair of front and rear frames 16 that are separated in the Y direction is connected by a lever fulcrum support beam 19 having a length direction in the Y direction at a substantially intermediate position in the Z direction. Furthermore, the top plate 20 is provided on the upper surface of a frame-like body that is manufactured by connecting the ends of the front and rear frames 16, the upper and lower frames 17, and the left and right frames 18. The left and right frames 18 that connect the back sides of the pair of front and rear frames 16 positioned above overlap the left and right frames 18 that connect the back end portions of the pair of front and back frames 16 positioned below when viewed from the Y direction. It is shifted to the landing side so that it does not become.

  The work floor portion 25 is made of a rectangular flat work floor 26, each having a rectangular cross-section, and the length direction is defined as the Y direction, and leg portions 27 extending downward from the four corners of the work floor 26, respectively, in the Z direction. A front-rear connecting beam 28 that connects lower ends of the leg portions 27 that are spaced apart from each other. The width of the work floor 26 in the X direction is shorter than the gap between the front and rear frames 16 that are separated in the X direction of the base portion 15. Further, the interval between the leg portions 27 that are separated in the Z direction substantially matches the interval between the upper and lower frames 17 on the back side of the base portion 15 and the lever fulcrum support beam 19. Although not shown, a baseboard and a handrail are installed on the work floor 26.

  The guide portion 21 is formed in a cylindrical shape with a rectangular cross section through which the leg portion 27 can be inserted, or a shape in which one surface inside the cylindrical shape with the rectangular cross section is open, and as shown in FIGS. Is the Y direction, and is joined by welding or the like to the substantially intermediate position in the Z direction and the rear end of each of the opposing side surfaces of the pair of front and rear frames 16 positioned above the base portion 15. Pin insertion holes 22 are formed in two orthogonal surfaces of each guide portion 21. The four guide portions 21 are arranged such that the pin insertion holes 22 are opposed to the X direction and the remaining pin insertion holes 22 face the landing side.

  The work floor portion 25 is attached to the base portion 15 by inserting the four leg portions 27 into each of the guide portions 21. Therefore, the work floor portion 25 attached to the base portion 15 is guided by the guide portion 21 and is movable in the Y direction. A plurality of pin engagement holes 23 are formed at equal pitches in the Y direction on the outer surfaces in the X direction of the four leg portions 27. Further, although not shown, a plurality of pin engaging holes 23 are formed at equal pitches in the Y direction on each of the landing side surfaces of the four leg portions 27.

  The elevating mechanism portion is arranged in parallel with being spaced apart in the X direction, and a pair of rod members 31 held on the fulcrum support beam 19 and having a middle portion rotatable around a horizontal axis at a fulcrum 29, and a pair of A lever 30 is provided that includes a pair of connecting beams 32 that connect ends of the bar member 31 to each other. The connecting beam 32 on the landing side serves as a power point to be operated by the operator, and the end portions on the back side of the pair of rod members 31 serve as action points 33 for applying a load to the front and rear connecting beams 28 of the work floor 25. Moreover, the site | part to which the load of the front-rear connection beam 28 is applied becomes a load application part.

  Next, the fixing mechanism portion of the work floor portion 25 will be described with reference to FIGS.

  The fixing mechanism unit of the work floor unit 25 includes an automatic fixing device 35 and a remote operation fixing device 45.

  As shown in FIG. 3, the automatic fixing device 35 includes a holder 36 in which a plate is formed in a cylindrical shape with a bottom or a rectangular shape with one side open, a rear end portion protruding from a bottom portion of the holder 36, and a front end A cylindrical fixing pin 37 that is housed in the holding tool 36 so as to be able to protrude from the opening of the holding tool 36, and an inner peripheral surface of the holding tool 36 that is formed so as to protrude radially toward the distal end side of the fixing pin 37. And a spring 38 that is housed in the holder 36 and that biases the fixing pin 37 to protrude from the opening of the holder 36 via the flange 38. And a wire 40 connected to a rear end protruding from the bottom of the holder 36 of the fixing pin 37, and an inclined surface 41 formed by obliquely cutting the tip of the fixing pin 37.

  The automatic fixing device 35 configured in this manner is configured so that the distal end of the fixing pin 37 can be inserted into the pin insertion hole 22 and the inclined surface 39 faces downward so that the opening side of the holder 36 faces the guide portion 21. It is attached to the landing side surface by welding or other means. Therefore, at normal times, the fixing pin 37 is pressed by the urging force of the spring 39 and inserted into the pin insertion hole 22 and the pin engagement hole 23, and the leg portion 27 is in a fixed state. Further, by pulling the wire 40, the fixing pin 37 is pulled out from the pin insertion hole 22 and the pin engaging hole 23, and the fixing of the leg portion 27 is released. When the pulling of the wire 40 is stopped, the fixing pin 37 is inserted into the pin insertion hole 22 and the pin engagement hole 23 by the restoring force of the spring 39, and the leg portion 27 is fixed. In the automatic fixing device 35, when the tip of the fixing pin 37 is inserted into the pin engaging hole 23 by the biasing force of the spring 39, the base of the inclined surface 41 is the boundary between the pin inserting hole 22 and the pin engaging hole 23. It is comprised so that it may be located in.

  As shown in FIGS. 4 and 5, the remote operation fixing device 45 includes a fixture 46 attached to the center portion in the X direction of the back side surface of the left and right frame 18 positioned on the back side, and the axial direction in the Y direction. A drive shaft 47 that is pivotably attached through the fixture 46, a first link 48 having one end fixed to a downward projecting portion from the fixture 46 of the drive shaft 47, and the drive shaft 47 A second link 49 having a central portion fixed to an upward projecting portion from the fixture 46, and one end connected to the other end of the first link 48 so as to be rotatable around an axis whose axial direction is the Y direction; An operating rod 50 extending to the landing side, and a pair of fixing pins 51 attached to the opposing surfaces of the two guide portions 21 located on the back side so as to be movable in the X direction and insertable into the pin insertion hole 22; The end of the second link 49 and the fixing pin 51 are connected to each other. It includes a pair of third links 52, the.

In the remote operation fixing device 45 configured as described above, when the operating rod 50 is pushed inward in the Z direction, the pressing force of the operating rod 50 is transmitted to the drive shaft 47 via the first link 48, and the drive shaft 47 However, it rotates counterclockwise in FIG. As a result, the second link 49 rotates counterclockwise in FIG. 4, the third link 52 is pulled toward the fixture 46, and the fixing pin 51 is pulled from the pin insertion hole 22 and the pin engagement hole 23. The leg portion 27 is released from being pulled out.
When the operation rod 50 is pulled toward the landing in the Z direction, the pulling force of the operation rod 50 is transmitted to the drive shaft 47 via the first link 48, and the drive shaft 47 rotates clockwise in FIG. . As a result, the second link 49 rotates clockwise in FIG. 4, the third link 52 is pushed toward the guide portion 21, and the fixing pin 51 is inserted into the pin insertion hole 22 and the pin engagement hole 23. The leg 27 is fixed.

  In order to install the installation work scaffold 100 configured as described above, first, the column part 10, the base part 15, and the work floor part 25 that are separately assembled are transported to the site in the factory. At this time, the work floor portion 25 is in a state where the front and rear connecting beams 28 are not attached. Next, the four leg portions 27 of the work floor portion 25 are inserted into each of the guide portions 21, and the work floor portion 25 is attached to the base portion 15. Next, the lower ends of the legs 27 spaced apart in the Z direction are connected by the front and rear connecting beams 28 to assemble the work floor 25. Here, the four leg portions 27 are fixed to the base portion 15 by the automatic fixing device 35. Further, the two leg portions 27 on the back side are fixed to the base portion 15 by the remote operation fixing device 45. Further, the fixing pin 51 is inserted into the pin insertion hole 22 of the two guide portions 21 located on the landing side and the pin engaging hole 23 of the leg portion 27, and the two leg portions 27 on the landing side are fixed to the base portion 15. Is done.

  Next, the landing side of the frame-like body of the base portion 15 is fixed to the pair of support posts 11 with a mounting metal (not shown) or the like, and the base portion 15 is attached to the lower side of the support post portion 10. Next, the upper end of the diagonal support body 14 is fastened to the upper end side of the support column 11, and the lower end is fastened to the back side of the lower front and rear frame 16. And Thereby, the scaffold 100 for installation work is assembled.

  Next, a portion of the base portion 15 is protruded from the entrance 3 of the platform 2 into the hoistway 1 while pushing the support column 10 toward the wall surface of the platform 2. Next, the adjustment member 13 is sandwiched between the upper ends of the pair of support columns 11 and the wall surface of the landing 2 so that the support columns 11 are in a vertical state. Next, the lower ends of the pair of columns 11 are fixed to the floor of the landing 2 with anchor bolts or the like, and the column 10 is erected on the entrance / exit 3 side of the platform 2 to complete the installation of the installation work scaffold 100.

  In the installation work scaffold 100 installed in this manner, the base portion 15 is cantilevered by the support column portion 10, but the base portion 15 is connected to the support column portion 10 by the diagonal support body 14, so that the base portion 15 is firmly supported by the support 10. At this time, the load of the base portion 15 acts to rotate the column portion 10 clockwise around the lower end of the column portion 10 in FIG. The force for rotating the support column 10 clockwise is received by the wall surface of the landing 2 via the adjusting member 13 disposed between the upper end of the support column 11 and the wall surface of the landing 2. Therefore, the column portion 10 erected on the entrance / exit 3 side of the landing 2 is held in a vertical state.

  Next, when raising the position of the work floor 26, first, the operator is inserted into the pin insertion holes 22 of the two guide portions 21 and the pin engagement holes 23 of the leg portions 27 located on the landing side. The fixing pin 51 is pulled out, and the fixing of the two leg portions 27 on the landing side by the fixing pin 51 is released. Next, the operator pushes the operation rod 50 from the landing 2 to the back side, pulls out the fixing pin 51 from the pin insertion hole 22 and the pin engagement hole 23, and fixes the two legs 27 located at the back side by remote operation. The fixing by the device 45 is released. The four leg portions 27 are fixed by the automatic fixing device 35, and the work floor portion 25 does not descend.

  Next, the operator pushes down the connecting beam 32 on the landing side at the landing 2 and rotates the bar member 31 around the fulcrum 29 counterclockwise in FIG. As a result, the action point 33 of the lever 30 pushes up the front and rear connecting beams 28 and moves the work floor 25 upward. At this time, the peripheral wall portion of the pin engagement hole 23 formed in the leg portion 27 rises while sliding on the inclined surface 41 of the fixed pin 37 inserted in the pin engagement hole 23. Therefore, the fixing pin 37 moves backward toward the holder 36 against the biasing force of the spring 39 as the leg 27, that is, the pin engaging hole 23 rises, and finally comes out of the pin engaging hole 23. When the next pin engagement hole 23 rises to the position of the pin insertion hole 22, the fixing pin 37 is inserted into the pin engagement hole 23 by the restoring force of the spring 39. This operation is repeated to move the work floor 25 to a desired height position.

  Therefore, the operator inserts the fixing pin 51 into the pin insertion hole 22 of the two guide portions 21 and the pin engagement hole 23 of the leg portion 27 located on the landing side, and further pulls the operation rod 50 toward the landing side. The fixing pins 51 are inserted into the pin insertion holes 22 of the two guide portions 21 and the pin engagement holes 23 of the leg portions 27 located on the back side. Thereby, the work floor 25 is fixed at a desired height position. An operator can get on the top plate 20 from the landing 2 and further get on the work floor 26 to attach or remove a lifting beam or the like at the top of the hoistway 1.

  Next, when lowering the position of the work floor 26, first, the operator is inserted into the pin insertion holes 22 of the two guide portions 21 and the pin engagement holes 23 of the leg portions 27 located on the landing side. The fixing pin 51 is pulled out, and the fixing of the two leg portions 27 on the landing side by the fixing pin 51 is released. Next, the operator pushes the operation rod 50 from the landing 2 to the back side, pulls out the fixing pin 51 from the pin insertion hole 22 and the pin engagement hole 23, and fixes the two legs 27 located at the back side by remote operation. The fixing by the device 45 is released.

  Next, the operator pushes down the connecting beam 32 on the landing side at the landing 2 and presses the action point 33 of the lever 30 against the front and rear connecting beams 28. Therefore, the operator pulls the wire 40 from the landing 2 and pulls out the fixing pin 37 from the pin insertion hole 22 and the pin engaging hole 23 to release the fixing by the automatic fixing device 35. Next, the worker lifts the connecting beam 32 on the landing side little by little. As a result, the action point 33 is lowered and the work floor 25 is lowered by its own weight. When the work floor 26 moves to a desired height position, the wire 40 is stopped being pulled and the leg portion 27 is fixed by the automatic fixing device 35. Further, the fixing pin 51 is inserted into the pin insertion hole 22 of the two guide portions 21 and the pin engaging hole 23 of the leg portion 27 located on the landing side, and the operation rod 50 is further pulled to the landing side to be positioned on the back side. The fixing pin 51 is inserted into the pin insertion hole 22 of the two guide portions 21 and the pin engagement hole 23 of the leg portion 27. Thereby, the work floor 25 is fixed at a desired height position. An operator can get on the top board 20 from the landing 2 and further get on the work floor 26 to work, for example, at a position 2 m or more below the top of the hoistway 1.

According to the first embodiment, the installation work scaffold 100 includes a support column 10 that is fixed to the landing 2, a base unit 15 that is fixed to the support column 10 at one end and protrudes into the hoistway 1, and a base unit 15 And a work floor portion 25 attached to be movable up and down. Therefore, the operator can work in an appropriate posture by adjusting the height of the work floor 26 according to the work content. Further, since the height position of the work floor 25 can be adjusted after the installation work scaffold 100 is installed, the installation work scaffold 100 is disassembled and reassembled every time the height position of the work floor 25 is changed. This eliminates the need for elevator installation work. Further, additional parts for changing the height position of the work floor portion 25 are unnecessary, and the installation work scaffold 100 can be reduced in weight. Therefore, when the elevator is installed, the operator's transportation work load when the installation work scaffold 100 is transported to the top floor is reduced.
Moreover, since the lever 30 is used as the lifting mechanism of the work floor 25, the lifting work load on the work floor 25 of the operator is reduced.

  Here, when the lever 30 is used as the elevating mechanism, the action point 33 of the lever 30 moves on an arc centered on the fulcrum 29. Therefore, depending on the angle of the bar member 31 with respect to the horizontal, that is, the angle between the line connecting the fulcrum 29 and the action point 33 becomes horizontal, the force of the horizontal component in addition to the force of the vertical component works from the action point 33. The front and rear connecting beams 28 of the floor portion 25 are added. Since the guide portion 21 for guiding the leg portion 27 in the vertical direction exists, the leg portion 27 does not move in the horizontal direction, but the force of the horizontal component applied from the action point 33 is applied to the leg portion 27 that moves up and down. It acts as a resistance and becomes a factor such as catching of the leg 27 moving up and down.

  FIG. 6 is a schematic diagram showing the movable range of the elevating mechanism portion in the scaffold for installation work according to Embodiment 1 of the present invention. In FIG. 6, θ1 is an angle formed by the bar member 31 positioned at the upper limit of the movable range, and θ2 is an angle formed by the bar member 31 positioned at the lower limit of the movable range.

  If the movable range (θ1 + θ2) is constant, the maximum value of the force of the horizontal component applied to the front and rear connecting beams 28 from the action point 33 increases as the difference between θ1 and θ2 increases. That is, the maximum value of the force of the horizontal component applied to the front and rear connecting beams 28 from the action point 33 is minimum when θ1 and θ2 are equal. Therefore, from the viewpoint of reducing the force of the horizontal component that causes the leg 27 moving vertically, θ1 and θ2 are desirably set to satisfy θ2-10 ° ≦ θ1 ≦ θ2 + 10 °. , Θ1 = θ2 is particularly preferably set.

  FIG. 7 is a schematic diagram showing the relationship between the position of the action point of the lever and the position of the center of gravity of the work floor in the scaffold for installation work according to Embodiment 1 of the present invention. In FIG. 7, the position of the front / rear connecting beam 28 that coincides with the position of the center of gravity of the work floor 25 in the Z direction is shown as the center of gravity 34 for convenience.

  In FIG. 7, the moment corresponding to the distance in the Z direction between the action point 33 and the center of gravity 34 is generated in the work floor 25 as the action point 33 of the lever 30 is further away from the center of gravity 34 in the Z direction. As the moment acting on the work floor 25 increases, the smooth vertical movement of the work floor 25 is hindered. That is, reducing the distance in the Z direction between the center of gravity 34 and the action point 33 reduces the moment acting on the work floor 25 and allows the work floor 25 to move smoothly up and down. Therefore, it is desirable that the center of gravity 34 exists between the innermost position of the action point 33 of the lever 30 that moves within the movable range and the outermost landing side position with respect to the Z direction. It is particularly desirable to be in a central position with respect to the position. The innermost position of the action point 33 is the position of the action point 33 when the bar member 31 is horizontal. In addition, the most landing position of the action point 33 is the position of the action point 33 when the bar member 31 is in a state where the upper limit or lower limit angle is large.

  In the first embodiment, the fixing by the automatic fixing device 35, the fixing by the remote operation fixing device 45, and the fixing by the manual fixing pin 51 are used in combination, but for fixing the four legs. Only the automatic fixing device 35 may be used. Alternatively, the remote operation fixing device 45 may be used for fixing the leg portion 27 on the back side, and the manual fixing pin 51 may be used for fixing the leg portion 27 on the landing side. Further, the remote operation fixing device 45 may be used for fixing the leg portion 27 on the back side, and the automatic fixing device 35 may be used for fixing the leg portion 27 on the landing side.

Embodiment 2. FIG.
FIG. 8 is a schematic diagram of a main part showing the periphery of the lever action in the scaffold for installation work according to Embodiment 2 of the present invention, and FIG. 8 (a) shows the bar member positioned at the upper limit of the movable range. FIG. 8B shows a state where the bar member is positioned horizontally. In FIG. 8, reference numeral 42 is a vertical line passing through the position of the center of gravity 34.

In FIG. 8, the action point 33 of the lever 30 is connected to the position of the center of gravity 34 of the front-rear connecting beam 28 via a link 53. That is, the center of gravity 34 is a load application unit. The relationship between θ1 and θ2 is θ1 ≧ θ2.
Other configurations are the same as those in the first embodiment.

  In the second embodiment, in the state where the bar member 31 is positioned at the upper limit of the movable range, the angle θ1 ′ formed by the link 53 and the vertical line 42 passing through the position of the center of gravity 34 is smaller than θ1. Further, in the state where the bar member 31 is horizontal, the angle θ3 ′ formed by the link 53 and the vertical line 42 passing through the position of the center of gravity 34 is smaller than θ1.

Thus, by connecting the action point 33 of the lever 30 and the position of the center of gravity 34 of the front and rear connecting beams 28 by the link 53, the force of the horizontal line segment acting on the work floor 25 can be reduced, and the work floor 25 smooth vertical movements can be realized.
As the length of the link 53 is increased, the angle formed by the link 53 and the vertical line 42 is reduced, and the work floor 25 is easily moved up and down smoothly.

  In the second embodiment, the case of θ1 ≧ θ2 has been described. Even in the case of θ2 ≧ θ1, the work floor 25 can be moved up and down smoothly by providing the link 53.

Embodiment 3 FIG.
FIG. 9 is a side view showing an assembly of a base part and a work floor part in an installation work scaffold according to Embodiment 3 of the present invention.

In FIG. 9, the action point 33 of the lever 30 is connected to the position of the center of gravity 34 of the front-rear connecting beam 28 via a link 54. That is, the center of gravity 34 is a load application unit. The link 54 has a plurality of connection holes 55 in the length direction, and the distance between the action point 33 and the position of the center of gravity 34 of the front and rear connection beams 28 is changed by changing the connection holes 55 used for connection. It is possible.
Other configurations are the same as those in the first embodiment.

  In the third embodiment, the action point 33 of the lever 30 is connected to the position of the center of gravity 34 of the front-rear connecting beam 28 via the link 54, so the same effect as in the second embodiment can be obtained.

  Next, an effect obtained by changing the distance between the action point 33 and the position of the center of gravity 34 of the front and rear connecting beams 28 will be described.

  First, the height of the base portion 15 is A + B. However, A is the vertical length between the point of action 33 and the center of gravity 34 when the point of action 33 of the lever 30 located at the upper limit of the movable range contacts the top plate 20 of the base portion 15. Is the vertical length that the work floor 25 is movable when the lever 30 is moved within its movable range.

  In FIG. 9, the work floor 25 when the vertical length between the action point 33 and the center of gravity 34 is the minimum is indicated by a solid line, and when the vertical direction length between the action point 33 and the center of gravity 34 is the maximum. The work floor 25 is indicated by a dotted line. Thus, when the height of the base portion 15 is constant, when A becomes longer, B becomes smaller and the maximum reach height C of the work floor 26 becomes lower. Further, the maximum reach height C of the work floor 26 varies depending on the construction property.

  In view of these, for each construction property, B that can secure the required height C of the work floor 26 is calculated, and A is calculated from the height of the base portion 15 and the calculated B. The vertical length between the action point 33 and the center of gravity 34 when the action point 33 of the lever 30 positioned at the upper limit of the movable range contacts the top plate 20 of the base portion 15 is calculated as A. In addition, by selecting the connection hole 55 used for connection, it is possible to construct an installation work scaffold that can realize a smooth vertical movement of the work floor portion 25 while ensuring a necessary height of the work floor 26 to be reached. .

Embodiment 4 FIG.
10 is a side view showing an assembly of a base part and a work floor part in an installation work scaffold according to Embodiment 4 of the present invention, and FIG. 11 is a base part in an installation work scaffold according to Embodiment 4 of the present invention. It is a front view which shows the assembly of a work floor part.

10 and 11, the roller 56 can rotate around the axis having the axial direction as the X direction, that is, around the axis parallel to the axis of the fulcrum 29, outside the X direction of the back end of the bar member 31 Is attached. The roller 56 rolls on the lower surface of the front-rear connecting beam 28 during the operation of the lever 30 and becomes a load transmission portion at the action point 33 of the lever 30. And the lower surface of the front-rear connecting beam 28 becomes a load application portion.
Other configurations are the same as those in the first embodiment.

  In the fourth embodiment, during the operation of the lever 30, the roller 56 rolls on the lower surface of the front / rear connecting beam 28, and a load is applied to the front / rear connecting beam 28. Therefore, the horizontal component force acting on the work floor 25 is increased. It is possible to reduce, and a smooth vertical movement of the work floor 25 can be realized. Further, in the fourth embodiment, the movable range of the bar member 31 can be widened as compared with the second and third embodiments using the links 53 and 54.

Embodiment 5. FIG.
12 is a side view showing an assembly of a base part and a work floor part in an installation work scaffold according to Embodiment 5 of the present invention, and FIG. 13 is a base part in an installation work scaffold according to Embodiment 5 of the present invention. 14 is a front view showing the assembly of the working floor portion, and FIG. 14 is a perspective view of a principal part for explaining the state of connection with the legs of the working floor portion in the scaffold for installation work according to Embodiment 5 of the present invention. 15 is a side view of an essential part for explaining a state of connection with a leg portion of a lever work floor in a scaffold for installation work according to Embodiment 5 of the present invention.

  12 to 15, the front and rear frames 16 that are separated from each other in the Y direction are connected to each other by the support beam 24 at the same position in the Z direction as the landing portion 27 of the work floor 25. Further, a lever fulcrum support beam 19 connects the front and rear frames 16 spaced apart in the Y direction on the back side in the Z direction of the support beam 24. Furthermore, the action point 33 which is the back end of the bar member 31 is connected to the lower end of the back leg 27 via the link 53, and the front and rear connecting beams 28 are omitted. And the connection part with the link 53 of the leg part 27 becomes a load application part. The support beam 24 is the same as the upper and lower frames 17 constituting the base part 15.

The leg receiving member 57 is formed in a rectangular shape with one side opened by bending a steel plate, and is disposed so as to cover both side surfaces and bottom surfaces in the Z direction of the two leg portions 27 on the back side separated in the X direction. The two leg portions 27 are connected by welding or the like. A pair of link receiving members 58 are fixed in the leg receiving members 57 so as to face both the leg portions 27. Both ends of the link 53 are connected to the action point 33 of the lever 30 and the link receiving member 58 so as to be rotatable around an axis whose axial direction is the X direction. Both sides in the Z direction of the upper and lower frames 17 on the far side, which are spaced apart in the X direction, are the vertical guides 57a in which both sides of the leg receiving member 57 covering both side surfaces in the Z direction of the leg portion 27 protrude from the leg portion 27 in the X direction. It is arranged along the surface.
Other configurations are the same as those in the first embodiment.

  In the fifth embodiment, the action point 33 of the lever 30 is connected to the lower ends of the two legs 27 on the back side of the work floor 25 via the link 53, and the position of the lever fulcrum support beam 19 in the Z direction is the back. Has been shifted to the side. Thereby, compared with the said Embodiment 1, since the length between the fulcrum 29 of a lever 30 and a power point can be lengthened, the work floor part 25 can be raised / lowered with small force, and an operator's lifting work load Can be reduced.

  At this time, the load by the lever 30 is applied only to the back side of the work floor 25, but when the worker at the landing 2 presses the power point to raise and lower the work floor 25, the work that climbs the top plate 20 When a person applies force to the landing side of the work floor portion 25, the work floor portion 25 can be lifted and lowered in a balanced manner.

  In addition, the vertical guide 57a is disposed along both side surfaces in the Z direction of the two upper and lower frames 17 spaced apart in the X direction. Therefore, the leg portion 27 is guided by the upper and lower frames 17 and moves up and down in the length direction of the upper and lower frames 17 without being inclined with respect to the length direction of the upper and lower frames 17. Can be realized.

  In the fifth embodiment, the middle portion in the Z direction of the front and rear frames 16 that are separated in the Y direction is connected by the support beam 24 and the lever fulcrum support beam 19. Similarly, the lever fulcrum support beam 19 may be combined with the function of the support beam 24 and the support beam 24 may be omitted. In this case, the number of parts is reduced, and the weight of the installation work scaffold can be reduced.

Embodiment 6 FIG.
FIG. 16 is a perspective view of a main part for explaining a state of connection with a leg portion of a work floor in a scaffold for installation work according to Embodiment 6 of the present invention, and FIG. 17 is an installation according to Embodiment 6 of the present invention. It is a principal part side view explaining the connection state with the leg part of the lever and a work floor part in a working scaffold.

16 and 17, the extension leg 60 is detachably attached to the lower end of the back leg 27 separated in the X direction by a bolt or the like. A plurality of fixing holes 61 are formed at equal pitches in the vertical direction on the lower end side of the leg portion 27 and the Z-direction landing side surface of the extension leg portion 60.
The leg receiving member 57 ′ has a short bottom portion and is provided with vertical guides 57a on both sides of the bottom portion covering both side surfaces in the Z direction of the rear leg portion 27 spaced apart in the X direction. A pair of link receiving members 58 that connect the bottom portion and the vertical guide 57 a are fixed in the leg receiving member 57 ′ so as to face both the leg portions 27. The leg receiving member 57 ′ is mounted so as to cover both side portions in the Z direction of the rear leg portion 27 in which the vertical guide 57a is separated in the X direction, and is arranged to be movable in the Y direction. A pin insertion hole (not shown) is formed in a portion covering the leg portion 27 on the side of the landing side in the Z direction of the leg receiving member 57 ′. Then, the automatic fixing device 35 is attached to a portion covering the leg portion 27 on the side of the landing in the Z direction of the leg receiving member 57 ′, and the fixing pin 37 is inserted into the fixing hole 61 from the pin insertion hole, and the leg holder The member 57 ′ is fixed to the leg 27 or the extension leg 60. Here, for convenience, the automatic fixing device 35 is illustrated with only the fixing pin 37.
Other configurations are the same as those in the fifth embodiment.

  In the sixth embodiment, when the installation work scaffold is installed, the extension leg 60 is attached to the lower end of the rear leg 27. And after installing the scaffold for installation work, fixation of the leg part 27 by the remote control fixing device 45 is cancelled | released, and the bar member 31 is located in the upper limit of a movable range. Next, the leg portion 27 is fixed by the remote operation fixing device 45, and it is confirmed that the work floor portion 25 does not move up and down. Next, the fixing by the automatic fixing device 35 attached to the leg receiving member 57 'is released, and the leg receiving member 57' can be moved up and down. Next, the leg support member 57 ′ is moved to the lowest position, and the leg support member 57 ′ is fixed to the extension leg 60 by the automatic fixing device 35. Next, the fixing of the leg portion 27 by the remote operation fixing device 45 is released, the rod member 31 is positioned at the upper limit of the movable range, and then the leg portion 27 is fixed by the remote operation fixing device 45.

  Therefore, in the sixth embodiment, when the leg receiving member 57 ′ is fixed to the lower end of the rear leg 27, the bar member 31 is moved to the upper limit position of the movable range, thereby reaching the work floor 26. The height can be set to approximately twice the height of the base portion 15. Then, when the leg receiving member 57 ′ is fixed to the extension leg 60 attached to the lower end of the rear leg 27, the bar member 31 is moved to the upper limit position of the movable range, thereby The reach height of 26 can be further increased, and the workable height range of the operator can be expanded.

As described above, according to the sixth embodiment, it is possible to realize an installation work scaffold capable of setting the arrival height of the work floor 26 to be twice or more the height of the base portion 15.
Moreover, since the fixing position with respect to the leg part 27 of leg receiving member 57 'can be adjusted, the reach | attainment height of the work floor 26 can be adjusted arbitrarily.

In the sixth embodiment, the leg support member 57 ′ is fixed to the leg 27 or the extension leg 60 by the automatic fixing device 35. However, the leg support member 57 ′ and the leg 27 or the extension leg are fixed. The fixing means for the unit 60 is not limited to the automatic fixing device 35 as long as both can be detachably fixed.
In the sixth embodiment, the extension leg 60 is detachably attached to the lower end of the leg 27. However, the leg 27 may be a long leg integrated with the extension leg 60. Good.

Embodiment 7 FIG.
FIG. 18 is a side view showing an assembly of a base part and a work floor part in an installation work scaffold according to Embodiment 7 of the present invention, and FIG. 19 is a base part in the installation work scaffold according to Embodiment 7 of the present invention. FIG. 20 is a top view showing the lifting mechanism part in the scaffold for installation work according to Embodiment 7 of the present invention.

18 to 20, the trap 65 passes through the inside of the pair of bar members 31 of the elevating mechanism 30 and is installed on the landing side of the base portion 15 so that the operator can go up to the top plate 20. Yes.
Other configurations are the same as those in the fifth embodiment.

  According to the seventh embodiment, since the wrap 65 is installed on the landing side of the base portion 15, the operator can easily climb the wrap 65 and go up to the top plate 20, and can be installed easily. Is increased. At this time, if the connecting beam 32 on the landing side constituting the force point of the lever 30 is made detachable and the connecting beam 32 is attached only when the lever 30 is operated, the lever 30 is used when the operator uses the trap 65. Therefore, without removing the trap 65, it is possible to move the worker up and down the top plate 20 using the trap 65 and to move the work floor 25 up and down using the lever 30. .

Embodiment 8 FIG.
FIG. 21 is a side view showing an assembly of a base part and a work floor part in an installation work scaffold according to Embodiment 8 of the present invention, and FIG. 22 is a base part in the installation work scaffold according to Embodiment 8 of the present invention. FIG. 23 is a top view showing an elevating mechanism part in a scaffold for installation work according to Embodiment 8 of the present invention.

In FIG. 21 to FIG. 23, the elevating mechanism unit includes one bar member 31, a fulcrum 29 that supports the bar member 31 on the lever fulcrum support beam 19, and a force point that is detachably attached to the landing side of the bar member 31. And a lever 30 'composed of a handle 66 constituting the. An action point 33, which is an end portion on the far side of the bar member 31, is connected to a central portion in the X direction of the leg receiving member 57 via a link 53.
Other configurations are the same as those in the seventh embodiment.

  Also in the eighth embodiment, since the trap 65 is installed on the landing side of the base portion 15, the operator can easily climb the trap 65 and go up to the top plate 20 to improve the installation workability. It is done. Further, since the handle 66 constituting the leverage of the lever 30 ′ is detachably mounted on the bar member 31, if the handle 66 is mounted only during the operation of the lever 30 ′, the operator can The lever 30 'does not get in the way when used. Further, the trap 65 is configured to be detachable with a bolt or the like, and is removed when the lever is used, so that the trap 65 does not get in the way when the work floor 25 is raised and lowered.

  According to the eighth embodiment, there is only one bar member 31 constituting the lever 30 ', the number of parts is reduced, and the weight can be reduced.

Embodiment 9 FIG.
FIG. 24 is a side view showing an assembly of a base part and a work floor part in an installation work scaffold according to Embodiment 9 of the present invention, and FIG. 25 is a base part in the installation work scaffold according to Embodiment 9 of the present invention. FIG. 26 is a top view showing the lifting mechanism portion in the scaffold for installation work according to Embodiment 9 of the present invention.

24 to 26, the elevating mechanism section is provided on one rod member 31, a fulcrum 29 that supports the rod member 31 on the lever fulcrum support beam 19, and a landing side of the rod member 31, and constitutes a force point. The frame 67 includes a lever 30 ″. The frame 67 is configured to have a size surrounding the trap 65, and a horizontal bar 67a on the landing side is detachable. An action point 33 which is an end portion on the back side of the leg is connected to a center portion in the X direction of the leg receiving member 57 via a link 53.
Other configurations are the same as those in the seventh embodiment.

  Also in the ninth embodiment, since the trap 65 is installed on the landing side of the base portion 15, the operator can easily climb the trap 65 and go up to the top plate 20 to improve the installation workability. It is done. Further, since the horizontal bar 67a on the landing side of the frame 67 constituting the leverage of the lever 30 "is configured to be detachable, if the horizontal bar 67a is attached only during the operation of the lever 30", the work When the user uses the trap 65, the lever 30 "does not get in the way. Therefore, without removing the trap 65, the operator uses the trap 65 to go up and down the top plate 20 and use the lever 30". The up-and-down movement of the work floor portion 25 that has been made becomes possible.

  According to the ninth embodiment, the number of the parts 31 constituting the lever 30 ″ is one, the number of parts is reduced, and the weight can be reduced.

  DESCRIPTION OF SYMBOLS 1 Hoistway, 2 landings, 10 support | pillar part, 15 base part, 17 top and bottom frame, 19 lever fulcrum support beam, 25 work floor part, 27 leg part, 29 fulcrum, 30, 30 ', 30 "lever, 31 bar member, 32 connecting beam, 33 point of action, 35 automatic fixing device, 45 remote operation fixing device, 56 roller, 57 leg receiving member, 60 extension leg, 65 trap, 66 handle, 67 frame, 67a horizontal bar, 100 installation work Scaffolding.

Claims (14)

A column part fixedly attached to the landing,
A base portion that is fixed to the support column at one end and protrudes to the far side away from the landing in the hoistway;
A work floor portion that is attached to the projecting portion of the foundation portion into the hoistway so as to be lifted and lowered;
A fulcrum is pivotally supported by the base part and is arranged so as to extend from the landing side to the back side in the hoistway. The landing side end part is used as a power point for an operator to operate, and the back side end part is used. An elevating mechanism having a lever as an action point for applying a load to the work floor;
A fixing device for fixing the work floor part to the base part;
Elevator installation scaffolding equipped with   The fixing device allows an upward movement of the work floor portion, and automatically fixes the work floor portion to the base portion during the upward movement, and fixing and fixing the work floor portion to the base portion. The elevator installation work scaffold according to claim 1, further comprising at least one of a remote operation fixing device capable of operating release from the landing side.   The angle with respect to the horizontal when the height position of the action point is maximum is θ1, and the angle with respect to the horizontal when the height position of the action point is minimum is θ2. The elevator installation work scaffold according to claim 1 or 2, wherein θ2-10 ° ≤ θ1 ≤ θ2 + 10 °.   The position in the horizontal direction of the load application unit to which the load on the work floor is applied is the position of the action point where the position of the action point and the height position are maximum when the lever is horizontal. Or between the position of the action point when the lever is horizontal and the position of the action point when the height position is minimum. Elevator installation scaffolding.   The horizontal position of the load application part to which the said load of the said work floor part is applied exists on the vertical line which passes through the gravity center of the said work floor part, or its vicinity. Scaffolding for elevator installation work.   The elevator installation work according to any one of claims 1 to 4, wherein a horizontal position of the load application unit to which the load of the work floor is applied is a rear end of the work floor. Scaffolding.   The elevator installation work scaffold according to claim 5 or 6, wherein the action point and the load application unit are connected via a link.   The elevator installation work scaffold according to claim 7, wherein the link is configured such that a distance between the action point and the load application unit is variable. The work floor portion is disposed at the back end portion and spaced apart in the axial direction of the fulcrum, and each of the pair of leg portions whose length direction is the vertical direction and the pair of leg portions, respectively. A pair of extension legs detachably attached to the lower end, and a leg receiving member that connects between the pair of leg parts or between the pair of extension legs attached to the lower end of the pair of leg parts; Have
The elevator installation work scaffold according to claim 7, wherein the load application section is provided on the leg support member.   The working point is a roller that is attached to the rear end portion of the lever and rolls on the load application portion to which the load of the work floor is applied during the operation of the lever to apply the load. The elevator installation work scaffold according to any one of claims 1 to 4. The lever includes a pair of rod members that are spaced apart in the axial direction of the fulcrum, and a connecting beam that connects the landing side end portions of the pair of rod members and configures the force point, and the connecting beam includes It is detachable with respect to a pair of rod members,
The elevator installation work scaffold according to any one of claims 1 to 4, wherein a tarp is installed on the base portion so as to pass through a landing side between the pair of rod members. The lever includes one rod member, and a handle that is detachably attached to a landing side end portion of the rod member and constitutes the power point,
The elevator installation work scaffold according to any one of claims 1 to 4, wherein the wrapping is detachably installed on the platform side of the base portion. The lever includes one bar member and a frame body that is attached to a landing side end portion of the bar member and forms the power point, and a horizontal bar that forms a landing side end portion of the frame body. It is configured to be detachable,
The elevator work scaffolding according to any one of claims 1 to 4, wherein a trap is installed on the base portion so as to pass through the frame.   The elevator work scaffolding according to any one of claims 1 to 4, wherein the upper and lower frames constituting the base portion also serve as a lever fulcrum support beam for supporting the lever.

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