KR20090047104A - Device for lifting temporary stand - Google Patents

Abstract

According to an aspect of the present invention, there is provided a lifting apparatus for elevating a temporary platform including a profile provided on a side facing a structure outer wall and having a plurality of locking portions at predetermined intervals, wherein a slot having a circular arc shape having a predetermined length perpendicular to the lifting direction is provided. A pair of left and right guide frames provided, a support frame provided to face each other while supporting the guide frame, and installed between the support frames, and the profile is rotated upwards in contact with the engaging portion when the profile is entered upwards The left and right ones which are engaged with the locking portion when entering downward and are rotated by a predetermined length along the latch for lifting the profile while supporting the lower portion of the locking portion, and the arc-shaped slot provided in the guide frame. A pair of guide arms, the guide frame and the A first connecting pin that connects an ad arm and rotates along an arc of a slot formed in the guide frame and connected to the guide arm through a first connecting pin that forms a rotation axis when the guide arm rotates; It includes two connecting pins, the guide arm relates to a hypothesis lifting device that is rotated in accordance with the movement of the second connecting pin with the first connecting pin as the rotation axis. According to the present invention, the temporary stand can be safely and easily lifted to a desired height position.

 Elevating device, profile, hydraulic cylinder, slot, anchor unit

Description

Temporary lifting device {Device for lifting temporary stand}

The present invention relates to a lifting device, and more particularly, to a temporary lifting device for lifting the construction of the construction site or the loading dock to a variety of temporary or working scaffolding to the desired height position.

An elevating device is indispensably used to elevate a large load of temporary construction materials or construction materials to a desired height at a construction site, or to transport a heavy load temporary construction table to a predetermined height at a loading dock.

For example, formwork is installed on the outer wall of the structure at the time of construction of the building structure, in which case a temporary acting as a kind of scaffold for the work is installed on the outer wall of the structure in order to perform smooth work on the outer wall of the structure. These constructions continue to be further installed as the number of floors of the structure increases. In the past, ascending constructions were lifted up entirely by cranes when constructing high-rise building structures. However, there is a problem that the use of the crane increases the time and expense required for the work, which causes a problem to the public travel. Accordingly, the applicant of the present invention performs the lifting step of the temporary lifting rod without using a crane by the lifting base material stepped up and down the profile in the Republic of Korea Patent No. 0743520 (name: temporary lifting device and temporary lifting method using the same). I've presented a technique to make it possible.

The registered patent has a main point of elevating the profile step by step while the lifting base is engaged to the engaging projection formed at a predetermined interval along the vertical direction to the profile of the temporary table. In particular, the lifting material is selectively engaged with any one of the protruding projections while moving forward or backward along the lifting direction through the configuration of the hydraulic cylinder and the hook. Therefore, it is possible to raise and lower the temporary stage step by step safely and easily.

On the other hand, the applicant of the present invention, following the lifting device disclosed in the registered patent feels the need for a technology that can lift the hypothesis more safely and easily and led to the development of the present invention.

The technical problem to be achieved by the present invention is to provide a simplified construction platform lifting device while being able to lift and move the construction platform safely and easily at the construction site, the loading dock and handling various construction sites.

According to an aspect of the present invention, there is provided a lifting apparatus for elevating a temporary platform including a profile provided on a side facing a structure outer wall and having a plurality of locking portions at predetermined intervals, wherein a slot having a circular arc shape having a predetermined length perpendicular to the lifting direction is provided. A pair of left and right guide frames provided, a support frame provided to face each other while supporting the guide frame, and installed between the support frames, and the profile is rotated upwards in contact with the engaging portion when the profile is entered upwards The left and right ones which are engaged with the locking portion when entering downward and are rotated by a predetermined length along the latch for lifting the profile while supporting the lower portion of the locking portion, and the arc-shaped slot provided in the guide frame. A pair of guide arms, the guide frame and the A first connecting pin that connects an ad arm and rotates along an arc of a slot formed in the guide frame and connected to the guide arm through a first connecting pin that forms a rotation axis when the guide arm rotates; It includes two connecting pins, the guide arm provides a hypothesis lifting device that is rotated in accordance with the movement of the second connecting pin with the first connecting pin as the rotation axis.

In addition, the present invention is a lifting device for elevating the temporary platform including a profile provided on the side facing the outer wall of the structure, comprising a profile having a plurality of engaging portions in the vertical length direction, and a pair of upper and lower One of which is fixed to the structure and is provided with a latch that can be engaged with the engaging portion, at least one of the upper and lower pairs of the lifting operation means for lifting the profile while supporting the lower portion of the locking portion, and the upper and lower lifting operation means A lift drive means coupled to the lift drive means for providing a lift drive force, the lift drive means comprising: a pair of left and right guide frames provided with a slot having an arc shape of a predetermined length perpendicular to the lift direction; A support frame provided to face each other while facing the guide frame and supporting the guide frame; Installed between the frame and the profile is in contact with the locking portion when the profile is upwardly moved upwards, the profile is engaged with the locking portion when the profile is downwardly entered and the latch for lifting the profile while supporting the lower portion of the locking portion, the guide A pair of left and right guide arms which are opened or closed by being rotated by a predetermined length along an arc-shaped slot provided in the frame, and connecting the guide frame and the guard arm to form a rotation axis when the guide arm is rotated. And a second connecting pin connected to the guide arm through a slot of the guide frame and rotating along an arc of a slot formed in the guide frame, wherein the guide arm rotates the first connecting pin. Temporary platform platform to be rotated in accordance with the movement of the second connecting pin It provides.

The guide frame may include a pair of left and right upper guide frames having slots formed thereon, and a pair of left and right lower guide frames spaced apart from and disposed below the upper guide frame.

The guide arm may include a pair of left and right upper guide arms partially overlapped with the upper or lower portion of the upper guide frame, and a pair of left and right lower guide arms partially overlapped with the upper or lower portion of the lower guide frame. It may include a support frame for connecting between the upper guide arm and the lower guide arm.

The first connecting pin penetrates the upper and lower guide frames to connect the upper guard arm and the lower guide arm and forms a rotation axis when the upper and lower guide arms rotate, and the second connecting pin is the upper And a connection between the upper guide arm and the lower guide arm through the slots of the lower guide frame and rotationally moving along the arcs of the slots formed in the upper and lower guide frames.

The guide arm may be provided with a guide channel that partially surrounds the web of the profile.

A curved seating groove may be formed at a corresponding portion of the latching portion supported by the latching portion so as to stably support the lower portion of the latching portion.

One end of the latch, the curved projection is provided to match the curved shape of the seating groove, the seating groove of the locking portion may be formed with a radius of curvature larger than the radius of curvature.

The latch is installed between the support frame by a rotation support pin, and the latch may be rotated downward by the center of gravity of the latch.

The anti-rotation plate further includes a rotation preventing plate that supports the other end of the latch when the one end of the latch supports the lower end of the latch, thereby restricting the latch from rotating downward clockwise by a predetermined angle. The portion of the clasp contacting the anti-rotation plate made of a plate shape may be formed in a vertical plane.

Further comprising an anchor unit is installed on the slab slab of the structure, the support frame is connected to the fixing part for fixing to the structure, the fixing part enters the anchor unit partially overlap each other and insert the overlapping portion It can be detachably coupled to the anchor unit by a fastening bolt penetrating.

The anchor unit is formed with a ditch and has at least one slot made of through grooves of a predetermined length on both sides of the ditch, and one end of the fixing part is formed into a hexagonal pillar structure to be inserted into the ditch of the anchor unit and inserted into the anchor unit. At least two fastening bolts may be fastened to the hexagonal columns through the slots to be coupled.

On one end of the anchor unit, a screw driver connected to the fixing unit is provided, and as the screw driver rotates, the fixing unit may linearly move forward and backward along the slot provided in the anchor unit.

The profile is made of an H-beam, and the locking portion may be formed at one flange of the H-beam.

According to the present invention, since the guide arm of the elevating operation means can be easily opened or closed, the task of installing or dismantling the profile on the elevating operation means is simple and easy.

It can be used to elevate the temporary platform in connection with the profile installed on the outer wall of the building structure, or it can be used to load and elevate heavy loads by connecting the loading box.

Various construction works can be safely and easily lifted to a desired position at a construction site or an unloading site, so that work can be smoothly progressed. In particular, the present invention can be usefully applied in the actual field because the mechanical configuration is much simpler than the conventional lifting device, and the operation is convenient.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the following embodiments are provided to those skilled in the art to fully understand the present invention, and may be modified in various forms, and the scope of the present invention is limited to the embodiments described below. It doesn't happen. Like numbers refer to like elements in the figures.

1 is a perspective view showing a state in which the temporary lifting device according to a preferred embodiment of the present invention is bound to a profile. 2 and 3 are a perspective view and an exploded perspective view showing a temporary lifting device according to a preferred embodiment of the present invention. Figure 4 is a side view showing a state in which the temporary lifting device according to a preferred embodiment of the present invention bound to the profile. 5 is an assembled perspective view of the lifting operation means disclosed in the present embodiment, Figure 6 is a perspective view showing an open state of the guide arm of the lifting operation means. FIG. 7 is an exploded perspective view of the lifting operation means, FIG. 8 is a plan view of the lifting operation means, and FIG. 9 is a side cross-sectional view cut along the line AA ′ of FIG. 8. 10 is a perspective view showing a state in which the first lifting operation means is coupled to the fixed portion, and FIG. 11 is a perspective view showing an opening state of the guide arm of the first lifting operation means. 12 is an exploded perspective view of the first lift operation means coupled to the fixed portion, Figure 13 is a plan view of the first lift operation means coupled to the fixed portion, Figure 14 is a cross-sectional view taken along the line AA 'of FIG. Side cross section view.

1 to 14, the temporary lifting device has a lifting operation means (200, 300) and the lifting drive means (400).

Lifting operation means (200,300) consists of a pair of upper and lower, for convenience, the lower one is called the first lifting operation means 200, the upper one is called the second lifting operation means (300). Any one of the first elevating operation means 200 and the second elevating operation means 300 is installed on the outer wall or the slab of the building structure to be fixed. Hereinafter, a case where the first lifting operation means 200 is fixed to the structure 10 such as concrete will be described as an example.

When the profile 100 moves up and down, the elevator 100 lifts and lowers without interference of the latches 210 and 310 provided in the lifting operation means 200 and 300, and stops by stopping the latches 210 and 310 at a predetermined height, which will be described in detail later. do.

The elevating driving means 400 is coupled between the first elevating operation means 200 and the second elevating operation means 300 to provide the driving force necessary for the elevating operation means 200 and 300 to elevate. Specific examples of the elevating driving means 400 may include a hydraulic actuator that can exert a large force and has excellent buffering performance and control performance. 2 and 3 illustrate a hydraulic actuator including a hydraulic cylinder 410 and a piston rod 420 that operate by receiving a working fluid from a hydraulic source (not shown).

As described above, the first elevating operation means 200, the second elevating operation means 300, and the elevating driving means 400 have the profile 100 installed in the assembled state as shown in FIG. 1.

Profile 100 is a structural member having a locking portion 140 for each lifting section, which is disclosed as an H-beam in this embodiment. The profile 100 is connected to the temporary platform or the load is loaded with a temporary, and is installed in the lifting operation means (200,300) in the state of lifting the lifting operation means (200,300) as the lifting shaft while lifting the hypothesis . Engaging portions 140 are provided on one side flange 120 of the flanges 120 and 130 of the web 110 constituting the H-beam by means of welding or the like, and each locking portion 140 has a temporary lift. A predetermined interval is formed at predetermined intervals. The locking portion 140 is engaged with the latches 210 and 310 of the lifting operation means 200 and 300 which will be described later. For example, the catching part 140 has a beak shape of a bird, and the upper part 142 is formed in an obliquely inclined oblique shape in a downward direction, and the lower part 144 has a recessed groove having a curved shape concave inward. In correspondence with the lower end 144 of the part 140, the relative portions of the latches 210 and 310 are also formed in a convex curved shape. The profile 100 configured as described above is installed on the lifting operation means 200 and 300 installed in a structure (eg, an outer wall or a plate-shaped slab of a structure on which a construction work temporary work platform is installed).

Next, a specific embodiment of the above-described lifting operation means 200 and 300 will be described in detail.

The first lifting operation means 200 includes an upper guide frame 220 and a lower guide frame 230 and a support frame 240 connecting them, and the upper guide frame 220 and the lower guide frame 230. And the support frame 240 is provided in a pair of left and right on the basis of the latch (210).

A latch 210 is installed between the pair of support frames 240, and the latch 210 is between the support frames 240 by a rotation support pin 260 passing through the support frame 240. It is possible to rotate. One end of the latch 210 is formed, for example, curved projections 212 to be engaged with the locking portion 140 of the profile 100. A curved mounting recess 144 is formed at a corresponding portion of the catching portion 140 engaged with the catch 210. At this time, the mounting groove 144 of the locking portion 140 is preferably made of a radius of curvature larger than the radius of curvature of the locking projection 212. By this structure, the latch 210 is coupled to the locking portion 140 in a stable state. The latch 210 is rotated relative to the locking portion 140 of the profile 100 when the profile 100 is raised, and when the lifting stops, the locking protrusion 212 is caught by the locking portion 140 of the profile 100. do.

The support frame 240 is provided with a rotation preventing plate 280 to prevent the rotation of the latch 210. The anti-rotation plate 280 serves to prevent the latch 210 from rotating more than a predetermined angle in the clockwise rotation direction as shown in FIGS. 9 and 14. The anti-rotation pin 280 is formed in a plate shape of a square cross-section, the anti-rotation plate 280 by being installed in the support frame 240 is in contact with one side 211 of the clasp 210 is no longer a clasp 210 Is prevented from rotating in the clockwise rotation direction. When the locking projection 212 of the latch 210 is caught by the locking portion 140 of the profile 100 in the first lifting operation means 200 installed in the profile 100, the anti-rotation plate 280 is a latch ( Since acting on the 210, the first lifting operation means 200 is maintained in a state fixed to the profile (100).

The detent 210 is provided to rotate about the rotation support pin 260 by its center of gravity, whereby the inclined surface 211 of the detent 210 always rotates when the detent 210 is rotated by an external force. It is restored to the original in the direction in contact with the prevention plate (280). Accordingly, the locking protrusion 210 of the latch 210 maintains a state capable of being always engaged with the seating groove 144 of the locking portion 140 when there is no external force. By the center of gravity of the latch 210, the latch 210 is always trying to rotate downward toward the latch 140, but the anti-rotation plate 280 supports the one end 211 of the latch 210 by the latch ( 210 is limited to rotate down clockwise more than a certain angle.

Thus, the clasp 210 is rotated upward by contacting the catch portion 140 when the profile 100 is upwardly entered, and the profile 100 is mutually engaged with the catch portion 140 when the profile 100 is downwardly entered and thus below the catch portion 140. Support.

On the other hand, an elastic member (not shown) may be installed around the rotation support pin 260. In this case, the elastic member exerts an elastic force such that when the latch 210 is rotated by an external force, the inclined surface 211 of the latch 210 always recovers in the direction of contact with the anti-rotation plate 280. This elastic member may be applied to a conventional torsion spring, it is stable to be provided one by one on both sides of the latch (210). In addition, one end of each elastic member may be fixed to the latch 210, the other end may be fixed to the support frame 240.

The configuration of the guide frame 220, 230, the support frame 240 and the latch 210 is the same also in the case of the second lifting operation means (300).

The first lifting operation means 200 is formed with guide arms 222 and 232 coupled to the profile 100, respectively. The guide arms 222 and 232 partially surround both sides of the flange 120 on which the locking portion 140 of the profile 100 is provided, thereby allowing the profile 100 to be smoothly lifted and lowered. The guide arms 222 and 232 have an upper guide arm 222 and a lower guide arm 232 and a supporting frame 234 connecting them, the upper guide arm 222, the lower guide arm 232 and Support frame 234 is provided in a pair of left and right relative to the latch (210). Guide arms 222 and 232 may further include guide channels 236 for guiding web 110 of profile 100. The guide channel 236 is inserted between the flange 120 and the flange 130 to serve to guide the web 110. The configuration of the guide arms 222 and 232 is the same also in the case of the second lifting operation means 300.

One end portion of the guide arms 222 and 232 overlaps with the upper guide frame 220 and the lower guide frame 230 so as to be engaged with each other. One end of the upper guide arm 222 is installed to be positioned above the upper guide frame 220, and one end of the lower guide arm 232 is installed to be positioned below the lower guide frame 230.

The upper guide frame 220 and the lower guide frame 230 are provided with a slot 238 which is a moving path of the guide arms 222 and 232. The guide arms 222 and 232 are opened or closed by sliding along a slot 238 of a predetermined length consisting of a through groove perpendicularly to the lifting direction. The slot 238 has a structure in which the guide arms 222 and 232 can be rotated while drawing an arc by a predetermined length, and grooves are formed in the upper guide frame 220 and the lower guide frame 230. The upper guide arm 222 and the lower guide arm 232 have a first connecting pin 244 penetrating the fixing holes 252 of the upper and lower guide frames 220 and 230 and a second connecting pin 246 penetrating the slot 238. Is connected via). The first connection pin 244 is inserted through the through hole 250 of the guide arms 222 and 232 and the fixing hole 252 of the guide frames 220 and 230, and the guide arms 222 and 232 may be opened. When it forms a rotation axis. When the guide arms 222 and 232 move along the slot 238, the first connecting pin 244 forms a rotation axis and the second connecting pin 246 rotates while drawing an arc by a predetermined length about the rotation axis. When the guide arms 222 and 232 are closed, the fixing pins 242 are inserted to penetrate the slots 238 of the upper and lower guide frames 220 and 230 to fix the guide arms 222 and 232 so as not to move. A first end jaw 254 is formed in the guide arms 222 and 232. When the fixing pin 242 is inserted through the slot 238, the first step 254 is engaged with the fixing pin 242. Arms 222 and 232 are immovably fixed. At this time, the position where the fixing pin 242 is inserted is one end of the slot 238.

When the profile 100 is installed in the first lifting operation means 200, the guide arms 222 and 232 of the first lifting operation means 200 are moved along the slots, as shown in FIGS. 6 and 11. Open to lose. In order to mount the profile 100 on the first lifting operation means 200, the fixing pin 242 holding the guide arms 222 and 232 so as not to move is removed, and the first connecting pin 244 is connected to the second shaft by the rotation shaft. The pin 246 is slid and rotated along the slot 238, and then the fixing pins 242 of the guide arms 222 and 232 are inserted into the slots 238 to fix the guide arms 222 and 232. A second step 256 is formed in the guide arms 222 and 232, and when the fixing pin 242 is inserted to pass through the slot 238, the second step 256 is engaged with the fixing pin 242. (222,232) is immobilized. At this time, the position of the slot 238 into which the fixing pin 242 is inserted is the position where the second connection pin 246 was located when the guide arms 222 and 232 were closed. That is, the other end of the slot 238 opposite to one end of the slot 238 into which the fixing pin 242 is inserted to fix the guide arms 222 and 232 to be closed. The guide arms 222 and 232 are moved along the slot 238 so that the fixing pin 242 is inserted into the slot 238 where the second connecting pin 246 was located when the guide arms 222 and 232 were closed. When the second connection pin 246 is blocked by the fixing pin 242, the path restored to its original position is no longer moved and fixed.

In this state, one side flange 120 of the profile 100 is inserted in the lifting operation means 200 and 300.

When one side flange 120 of the profile 100 is inserted, the guide arms 222 and 232 of the elevating operation means 200 and 300 partially cross both sides of the one flange 120 provided with the engaging portion 140 of the profile 100. The profile 100 is installed on the lifting operation means 200 and 300 by closing the guide arms 222 and 232 to wrap. That is, the guide pins 222 and 232 are removed from the fixing pin 242 fixed to the movement, the first connecting pin 244 is rotated along the slot 238 by using the second connecting pin 246 as the rotation axis. After sliding, the fixing pins 242 are inserted to penetrate the slots 238 of the upper and lower guide frames 220 and 230 so that the guide arms 222 and 232 are immovably fixed. When the fixing pin 242 is inserted through the slot 238, the first step 254 is engaged with the fixing pin 242 so that the guide arms 222 and 232 are not moved.

The configuration of the first lift operation means 200 described above may be equally applied to the second lift operation means 300.

The first lifting operation means 200 is coupled to and supported by the fixing part 500. The fixed part 500 is provided with a pair of support frames 512, and a lower end portion of the lift drive means 400 to connect the lift drive means 400 between the pair of support frames 512. The through hole 510 to be inserted is formed. In addition, the upper side of the pair of support frame 512 through the left and right through holes in which the coupling pin is inserted to secure the lower end of the lifting drive means 400 inserted into the through hole 510 with a coupling pin (not shown) ( 514 is formed. Accordingly, the first lifting operation means 200 has left and right through holes 514 above the support frame 512 in a state where the lower end of the lifting driving means 400 is inserted into the through hole 510 of the fixing part 500. As the coupling pin is inserted into the lift driving means 400.

The fixing part 500 is coupled to the anchor unit 600 installed on the plate-shaped slab of the structure 10. The fixing part 500 is partially detachably coupled to the anchor unit 600 by fastening bolts 516 and 516 'which partially enter the anchor unit 600 and overlap each other and penetrate the overlapping part. That is, the anchor unit 600 is a groove 602 is formed, one end of the fixing portion 500 is inserted into the groove 602 of the anchor unit 600. One end of the fixing part 500 has a hexagonal column structure, and at least two bolt fasteners 518 and 518 'are provided at both sides of the hexagonal column to be inserted and coupled to the anchor unit 600.

Anchors 602 are formed in the anchor unit 600, and at least one slot 604 and 604 ′ is provided at both sides of the trench 602. Slots 604 and 604 'are provided with grooves of a predetermined length on both sides of the groove 602. When one end of the fixing part 500 is inserted into the groove 602 of the anchor unit 600, the bolt is fastened to the bolt fasteners 518 and 518 ′ through the holes of the slots 604 and 604 ′ and the anchor unit 600 and the anchor unit 600. Coupling the fixing part 500. Slots 604 and 604 'of the anchor unit 600 provide a path through which the fixing part 500 is linearly moved horizontally. The skew screw driver 610 is provided on one end of the anchor unit 600. The screw driver 610 is connected to the fixing part 500, and as the screw driver 610 rotates, the fixing part 500 moves forward and backward along the slots 604 and 604 'to linearly move. The fixing part 500 can be moved back and forth by the driving of the screw driver 610, and since the first lifting operation means 200 is fastened to the fixing part 500, the fixing part 500 moves back and forth linearly. 1 elevating operation means 200 is also moved back and forth linearly.

Front and rear linear movement of the first lifting operation means 200 is necessary to control the play when the profile 100 is raised or lowered. In addition, since the fixed part 500 and the first lifting operation means 200 can move back and forth linearly, even if the appearance of the structure to be built is changed, there is an advantage of raising or lowering the hypothesis accordingly. By adjusting the relative position of the fixing part 500 with the screw driver 610, even if the outer wall of the structure is inclined, it can be lifted while adjusting the inclination of the profile 100 accordingly. For example, with respect to the outer wall of the structure having a "＼" shape inclination, the fixing portion 500 coupled with the first lifting operation means 200 in the lower portion to be protruded out using a screw driver 610, The fixing part 500 coupled with the first lifting operation means 200 in the upper portion is adjusted to enter in by using the screw driver 610, thereby raising the temporary hypothesis by inclining the profile 100 in a "＼" shape. You can.

On the other hand, in the case of the second lifting operation means 300, the through hole between the support frame 340 to the left and right through holes 370 under the support frame 340 in a state where the upper end of the lifting driving means 400 is inserted. The coupling pin is inserted into the lifting driving means 400. The configuration of the second lifting operation means 300 may also be applied to the first lifting operation means 200. That is, a through hole through which the upper end portion of the elevating driving means 400 can be inserted between the pair of supporting frames 240 of the first elevating operation means 200, and the coupling pin is also provided on the lower side of the supporting frame 240. The left and right through holes which can be inserted are formed, so that the first lifting operation means 200 can be compatible with the second lifting operation means.

Next, the lifting operation of the lifting device according to the present invention will be described based on the configuration of the above-described embodiment.

15 and 16 are views showing a lifting operation process of the lifting apparatus according to the embodiment of the present invention, for convenience of cutting the profile and the side of the lifting operation means is shown. Referring to these drawings, look at the operation sequence of the lifting device made when raising the temporary table to a predetermined height as follows.

The upper end of the first lifting operation means 200 is fixed to the anchor unit 600 installed on the plate-shaped slab of the structure 10 by the fixing part 500, the first lifting operation means 200 and the second lifting operation Both means 300 are opposed to profile 100. In this case, it is assumed that the profile 100 is placed on the ground, for example. Clamps 210 and 310 of the first elevating operation means 200 and the second elevating operation means 300 are supported by the center of gravity of the locking projections 212 and 312 at one end thereof to support the lower portion of the locking portion 140 of the profile 100. It is rotated in a form that can be, and the anti-rotation plate 280 supports the one end 211 of the latch 210 to restrict the latch 210 is rotated downward in a clockwise direction over a predetermined angle. The locking projections 212 and 312 of the latches 210 and 310 are always forced to be in close contact with the profile 100 by the center of gravity. The first lifting operation means 200 has a locking protrusion 212 provided at one end of the latch 210 is coupled to the locking portion 140 of the profile 100. Likewise, the second lifting operation means 300 also has a locking projection 312 provided at one end of the latch 310 is coupled to the other locking portion 140 of the profile 100.

In this state, the lifting driving means 400 that connects the first lifting operation means 200 and the second lifting operation means 300 is operated. The hydraulic cylinder 410 and the piston rod 420 of the lifting driving means 400 are sufficiently relaxed to raise the second lifting operating means 300. That is, when the working fluid is supplied from the hydraulic source (not shown) to the hydraulic cylinder 410 of the elevating driving means 400 illustrated as the hydraulic actuator in this embodiment, the hydraulic cylinder 410 and the piston rod 420 are relaxed. As the second lifting operation means 300 is raised. At this time, since the latch 310 of the second lifting operation means 300 is to be rotated in the clockwise rotation direction by the center of gravity thereof, the locking protrusion 312 of the latch 310 is always the locking portion of the profile 100 ( The profile 100 is raised in close contact with the 140. As the second lifting operation means 300 rises, the profile 100 rises. At this time, since the latch 210 of the first elevating operation means 200 can always rotate freely in the direction opposite to the clockwise rotation about the rotation support pin 260, when the profile 100 is raised, Even if the upper end portion 142 of the locking portion 140 rises and collides with each other, the upper edge portion 142 of the locking portion 140 rises without interference of the latch 210 provided in the first lifting operation means 200.

In the state where the second elevating operation means 300 and the profile 100 are raised to a predetermined height by the elevating driving means 400, the first elevating operation means 200 is caught by the engaging portion 140 located at the corresponding height. In order to be coupled, the piston rod 420 is relaxed and retracted so that the locking portion 140 of the profile 100 is located slightly above the position to stop (the latching position of the first lifting operation means). Then, the locking protrusion 212 of the latch 210 of the first lifting operation means 200 is caught by the seating groove 144 of the locking portion 140, so that the profile 100 is applied to the first lifting operation means 200. It is fixed.

When the profile 100 is fixed by the first lifting operation means 200, the piston rod 420 of the lifting driving means 400 is contracted so that the second lifting operation means 300 is lowered. At this time, the profile 100 is fixed by the first lifting operation means (200). When the second lifting operation means 300 is lowered, the latch 310 is freely rotated in a counterclockwise direction about the rotation support pin 260, so that even when it hits the engaging portion 140 of the profile 100. The second lifting operation means 300 can be lowered without interference.

In order to allow the second lifting operation means 300 to be engaged with the locking portion 140 positioned at the corresponding height in a state where the second lifting operation means 300 is lowered to a predetermined height, the locking portion of the profile 100 is engaged. Shrink the piston rod 420 so that the latch 310 of the second lift operation means 300 is positioned slightly below the position of 140, and then relax again so that the latch 310 of the second lift operation means 300 is To be seated in the mounting groove 144 of the locking portion 140 of the profile (100).

As described above, the elevating apparatus according to the present invention may raise the profile 100 to a position having a desired height by repeating the above-described process. As the profile 100 rises together as the second lifting operation means 300 rises, the profile 100 can be raised by a desired height step by step.

Next, FIG. 17 is a view showing a lowering operation process of the elevating apparatus according to the embodiment of the present invention, for convenience of cutting the profile and the side of the elevating operation means. Referring to these drawings, look at the operation sequence of the lifting device is made when the hypothesis is lowered to a predetermined height as follows.

The locking protrusions 212 and 312 at one end provided at the latches 210 and 310 of the first lifting operation means 200 and the second lifting operation means 300 are respectively moved by the locking portions 140 of the profile 100. It is not fixed but showing a fixed appearance.

By slightly lowering the hydraulic cylinder 410 and the piston rod 420 of the lifting driving means 400, the latch 210 of the first lifting operating means 200 is spaced apart from the locking portion 142 of the profile 100. . At this time, the latch 210 is spaced apart so that it can rotate in the counterclockwise rotation direction on the drawing without being interrupted by the latch 140.

Subsequently, the latch 210 of the first lifting operation means 200 is rotated in a counterclockwise rotation direction. Then, when the hydraulic cylinder 410 and the piston rod 420 of the lifting driving means 400 are contracted, the profile 100 can be lowered without being bound by the latch 210 of the first lifting operating means 200. .

Subsequently, when the hydraulic cylinder 410 and the piston rod 420 are retracted, the locking portion 142 of the profile 100 initially caught on the latch 210 of the first lifting operation means 200 is latched 210. Passed through, the locking portion 140 of the profile 100 initially caught on the first lifting operation means 200 is lowered below the first lifting operation means 200. When the locking portion 140 of the profile 140 firstly caught by the first lifting operation means 200 passes completely through the first lifting operation means 200, the latch 210 of the first lifting operation means 200 weighs. It rotates in the clockwise rotation direction by the center and the anti-rotation plate 280 is in contact with one side 211 of the clasp 210 is prevented from rotating the clasp 210 anymore. Then, when the profile 100 is lowered by the piston rod 420, the locking protrusion 212 of the latch 210 maintains a state of being in close contact with the profile 100.

When the profile 100 completes the descending to a predetermined height, the lower end locking projection 212 of the latch 210 of the first lifting operation means 200 is engaged with the locking portion 140 of the corresponding height. (100) is stopped.

When the profile 100 is fixed by the first elevating operation means 200, the hydraulic cylinder 410 and the piston rod 420 of the elevating driving means 400 are slightly contracted so that the latch of the second elevating operation means 300 is reduced. The 310 is spaced apart from the locking portion 140 of the profile 100. At this time, the latch 310 is spaced apart so that it can rotate in the counterclockwise rotation direction on the drawing without receiving the obstacle 140.

Subsequently, the latch 310 of the second lifting operation means 300 is rotated in the counterclockwise rotation direction. Then, when the piston rod 420 of the elevating driving means 400 is raised, the second elevating operation means 300 can rise without being bound by the locking portion 140 of the profile 100.

The piston rod 420 of the lifting driving means 400 is relaxed so that the second lifting operating means 300 is raised. At this time, the profile 100 is fixed by the first lifting operation means (200).

In the state in which the second lifting operation means 300 is raised to a predetermined height, the latch of the second lifting operation means 300 is engaged so that the second lifting operation means 300 is engaged with the locking portion 140 positioned at the corresponding height. 310 to be seated in the mounting groove 144 of the locking portion 140 of the profile (100).

As described above, the elevating device according to the present invention is to be lowered to the position of the desired height by repeating the above-described process, accordingly it is possible to lower the means of loading the temporary or connected load connected to the profile 100 to a predetermined height. .

As mentioned above, although preferred embodiment of this invention was described in detail, this invention is not limited to the said embodiment, A various deformation | transformation by a person of ordinary skill in the art within the scope of the technical idea of this invention is carried out. This is possible.

1 is a perspective view showing a state in which the temporary lifting device according to a preferred embodiment of the present invention is bound to a profile.

Figure 2 is a perspective view showing a temporary lifting device according to a preferred embodiment of the present invention.

3 is an exploded perspective view showing a temporary lifting device according to a preferred embodiment of the present invention.

Figure 4 is a side view showing a state in which the temporary lifting device according to a preferred embodiment of the present invention bound to the profile.

5 is an assembled perspective view of the lifting operation means disclosed in this embodiment.

6 is a perspective view showing an open state of the guide arm of the lifting operation means.

7 is an exploded perspective view of the lifting operation means.

8 is a plan view of the lifting operation means.

9 is a side cross-sectional view taken along the line AA ′ of FIG. 8.

10 is a perspective view showing a state in which the first lift operation means is coupled to the fixed portion.

11 is a perspective view showing an open state of the guide arm of the first lift operation means.

12 is an exploded perspective view of the first lift operation means coupled to the fixed portion.

13 is a plan view of the first lift operation means coupled to the fixed portion.

14 is a side cross-sectional view cut along the line AA ′ of FIG. 13.

15 and 16 are views showing a lifting operation process of the lifting device according to an embodiment of the present invention.

17 is a view showing a lowering operation of the lifting device according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: Structure 100: Profile

200,300: lifting operation means 210,310: latch

220,230: guide frame 222,232: guide arm

238: slot 240: support frame

400: lifting driving means 500: fixed part

600: anchor unit

Claims (14)

In the elevating device for elevating the temporary platform including a profile installed on the side facing the outer wall of the structure and provided with a plurality of engaging portions at regular intervals, A pair of left and right guide frames each having a slot having an arc shape having a predetermined length perpendicular to the lifting direction; A support frame provided to face each other while facing each other while supporting the guide frame; It is installed between the support frame, the profile is in contact with the locking portion when the upward entry, and is rotated upward, the profile is mutually engaged with the locking portion when entering the downward, for lifting the profile while supporting the lower portion of the locking portion Braces; A pair of left and right guide arms rotated by a predetermined length along an arc-shaped slot provided in the guide frame and opened or closed; A first connecting pin connecting the guide frame and the guard arm to form a rotation axis when the guide arm rotates; And A second connecting pin penetrating the slot of the guide frame and connected to the guide arm and rotating along a circular arc of the slot formed in the guide frame, The guide arm is a hypothesis lifting device characterized in that the rotational movement in accordance with the movement of the second connecting pin using the first connecting pin as the rotation axis. In the elevating device for elevating the temporary platform including a profile installed on the side facing the outer wall of the structure, A profile having a plurality of engaging portions along the vertical length direction; Elevating operation to raise and lower the profile while any one of the upper and lower pairs is fixed to the structure, one of which is fixed to the structure, is provided with a latch that can be engaged with the engaging portion at least one of the upper and lower pairs supporting the lower portion of the engaging portion Way; And It includes a lifting driving means coupled between the lifting operation means of the up and down to provide the lifting driving force to the lifting operation means, The lifting operation means, A pair of left and right guide frames each having a slot having an arc shape having a predetermined length perpendicular to the lifting direction; A support frame provided to face each other while facing each other while supporting the guide frame; It is installed between the support frame, the profile is in contact with the locking portion when the upward entry, and is rotated upward, the profile is mutually engaged with the locking portion when entering the downward, for lifting the profile while supporting the lower portion of the locking portion Braces; A pair of left and right guide arms rotated by a predetermined length along an arc-shaped slot provided in the guide frame and opened or closed; A first connecting pin connecting the guide frame and the guard arm to form a rotation axis when the guide arm rotates; And A second connecting pin penetrating the slot of the guide frame and connected to the guide arm and rotating along a circular arc of the slot formed in the guide frame, The guide arm is a hypothesis lifting device characterized in that the rotational movement in accordance with the movement of the second connecting pin using the first connecting pin as the rotation axis. The method of claim 1 or 2, wherein the guide frame, A pair of left and right upper guide frames having slots formed therein; And Temporary lifting device including a pair of left and right lower guide frame spaced apart from the upper guide frame, the slot is formed. The method of claim 3, wherein the guide arm, A pair of left and right upper guide arms installed to partially overlap the upper or lower portion of the upper guide frame; A pair of left and right lower guide arms installed to partially overlap the upper or lower portion of the lower guide frame; And And a support frame for connecting between the upper guide arm and the lower guide arm. The method of claim 4, wherein the first connecting pin penetrates the upper and lower guide frames to connect the upper guard arm and the lower guide arm and forms a rotation axis when the upper and lower guide arms rotate. 2 connecting pins pass through the slots of the upper and lower guide frame to connect the upper guide arm and the lower guide arm, the hypothesis lifting, characterized in that the rotational movement along the arc of the slot formed in the upper and lower guide frame Device. The method according to claim 1 or 2, wherein the guide arm, And a guide channel partially covering the web of the profile. The method according to claim 1 or 2, And a seating groove of a curved surface is formed in a corresponding portion of the latching portion on which the latching portion is supported so that the latch can be stably supported below the locking portion. The method of claim 7, wherein one end of the latch, The hooking protrusion of the curved shape is provided to match the curved shape of the seating groove, the seating groove lifting device is characterized in that formed with a radius of curvature larger than the radius of curvature. The method of claim 1 or 2, wherein the latch, It is installed between the support frame with a rotating support pin, by the center of gravity of the latch, the latch is a hypothesis lifting device characterized in that it rotates downward toward the latch. The anti-rotation plate according to claim 1 or 2, further comprising an anti-rotation plate for supporting the other end of the latch when one end of the latch supports the lower portion of the latch so as to restrict the latch from rotating downward clockwise by a predetermined angle. , The anti-rotation plate is made of a plate-shaped square cross section, the corresponding portion of the latch contacting the anti-rotation plate is a hypothesis lifting device, characterized in that formed in a vertical plane. According to claim 1 or 2, further comprising an anchor unit which is installed on the slab slab of the structure, The support frame is connected to a fixing part for fixing to the structure, and the fixing part enters and detachably attaches to the anchor unit by a fastening bolt which partially enters the anchor unit and overlaps each other and inserts the overlapping part. Temporary lifting device characterized in that the. According to claim 1, wherein the anchor unit is formed with a ditch and at least one slot formed of through grooves of a predetermined length on both sides of the ditch, one end of the fixing portion is made of a hexagonal pillar structure inserted into the ditch of the anchor unit And, at least two fastening bolts penetrate the slots to be inserted into the anchor unit and fastened to the hexagonal column. According to claim 12, One end of the anchor unit is provided with a screw driver connected to the fixing portion, and as the screw driver rotates the fixed portion is moved back and forth along the slot provided in the anchor unit to move linearly Temporary lifting device, characterized in that. The method according to claim 1 or 2, The profile is made of an H-beam, the locking portion is a temporary lifting device, characterized in that formed on one flange of the H-beam.

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