CN114232913B

CN114232913B - Large-gradient roof tile hanging construction system

Info

Publication number: CN114232913B
Application number: CN202111331353.6A
Authority: CN
Inventors: 周春雨; 程飞; 王亚坤; 刘明浩; 修天翔; 毕磊; 郭小伟; 赵焕明; 咸林; 王振宇; 刘振东
Original assignee: First Construction Co Ltd of China Construction Eighth Engineering Division Co Ltd
Current assignee: First Construction Co Ltd of China Construction Eighth Engineering Division Co Ltd
Priority date: 2021-11-11
Filing date: 2021-11-11
Publication date: 2023-06-16
Anticipated expiration: 2041-11-11
Also published as: CN114232913A

Abstract

The invention provides a large-gradient roof tile hanging construction system, belongs to the technical field of building construction, and effectively solves the problems of high difficulty, low efficiency and difficult guarantee of safety of large-gradient roof tile hanging construction. The technical scheme includes that set up perpendicularly in the protection frame that returns the eaves top, roofing top is provided with the operation panel that is parallel to each other with the roofing, and the inboard sliding connection of operation panel has dress tile case and operating pedal, is provided with automatic tile mechanism that goes out on the dress tile case, and the both sides of operation panel all are provided with the backup pad. The beneficial effects of the invention are as follows: the high-efficiency, convenient and safe roof tile hanging construction system with the large gradient is provided.

Description

Large-gradient roof tile hanging construction system

Technical Field

The invention relates to the technical field of building construction, in particular to a large-gradient roof tile hanging construction system.

Background

Along with the continuous development of the construction industry, the construction layers of the pitched roof are endless, the gradient of the roof is gradually increased along with the changeable modeling, the roofs of the buildings generally have the characteristics of steep gradient, large span, large construction difficulty of inclined operation surfaces, low efficiency, high danger and the like, great difficulty is brought to the construction operation of hanging tiles, the uppermost layer of overhanging scaffolds are reserved as the external protection of the construction of the pitched roof when the construction is performed on the high-rise pitched roof at present, gaps exist between the outer frames and the roof during the construction of the pitched roof, unsafe factors are increased, and the construction safety protection of the eave area of the pitched roof is extremely difficult.

Therefore, how to solve the above technical problems is a subject of the present invention.

Disclosure of Invention

In order to solve the defects in the prior art, the invention provides an efficient, convenient and safe large-gradient roof tile hanging construction system.

The technical scheme adopted for solving the technical problems is as follows: the invention provides a large-gradient roof tile hanging construction system, which comprises a protection frame vertically arranged at the top of an upper return eave, wherein an operation frame parallel to the roof is arranged above the roof, and the inner side of the operation frame is connected with a tile loading box and an operation pedal in a sliding manner;

a tile discharging mechanism is arranged on the tile loading box;

both sides of the operation frame are provided with support plates.

The protection frame comprises a plurality of planting bars which are uniformly and fixedly connected to the top of the upper return eave and are vertically arranged, a vertically arranged adapter rod is fixedly connected to one side of each planting bar above the upper return eave, and a vertical rod which is vertically upwards arranged is fixedly connected to one side of each adapter rod;

a horizontally arranged sweeping rod is fixedly connected between the inner sides of the switching rods;

the vertical rods are uniformly and fixedly connected with a plurality of horizontal rods which are horizontally arranged from bottom to top.

The operation frame comprises a pair of sliding rods which are parallel to each other and are symmetrically arranged, and a plurality of connecting rods are uniformly and fixedly connected between the bottom sides of the sliding rods;

hooks are arranged at the tops of the pair of sliding rods, and each hook is hung and matched with a sliding rod horizontally arranged along the top of the ridge in a sliding manner;

the lower sides of the bottoms of the pair of sliding rods are coaxially and horizontally provided with threaded sleeves, the threaded sleeves are internally and in threaded fit with screws, two ends of each screw are rotatably connected to the top of the upper return eave, and one end of each screw is coaxially and fixedly connected with an output shaft of the translation motor;

the opposite sides of the pair of sliding rods are symmetrically provided with sliding grooves from bottom to top, both sides of the supporting plate are in sliding connection with the sliding grooves, the top of the front side of the supporting plate is fixedly connected with the tile containing box with the top being in an opening shape, and the rear side of the supporting plate is fixedly connected with the operating pedal;

an electric winch is arranged between the bottoms of the sliding rods, a traction rope is arranged on the electric winch, and the traction end of the traction rope extends upwards from the bottom side of the supporting plate and bypasses a first rope wheel arranged at the top of the sliding rods to be downwards and fixedly connected to the front side of the supporting plate.

A partition plate is arranged in the tile loading box to divide the tile loading box into a left storage area and a right storage area, a lifting plate is slidably connected in each storage area, and each lifting plate is connected with the tile discharging mechanism;

a push plate is arranged at the position, close to the top, of the tile loading box, and the size of the push plate is matched with the size of a through placing hole formed in the upper side of the partition plate;

corresponding the push plate is provided with penetrating tile outlet holes matched with tiles on the left side and the right side of the tile loading box, and the push plate is connected with the tile outlet mechanism.

The tile discharging mechanism comprises racks which are fixedly connected with two ends of the push plate and are mutually perpendicular to the push plate through connecting columns, the two racks are close to the outer wall of the tile loading box from the outer side of the tile loading box, and the two connecting columns are connected in sliding holes symmetrically formed in the upper side of the tile loading box in a sliding mode;

the lower side of each rack is provided with a gear meshed with the rack and rotationally connected to the outer wall of the tile loading box, one gear is fixedly connected with an output shaft of a pushing motor in a coaxial manner, and the pushing motor is fixedly connected to the tile loading box through a mounting seat;

connecting plates are fixedly connected to the front side and the rear side of each lifting plate, and each connecting plate extends to the outer side of the tile loading box through a through groove formed in the tile loading box from top to bottom and is in sliding fit with the through groove;

one end of a pull rope is fixedly connected to the top of each connecting plate, and the other end of the pull rope is wound to a rope disc after passing through a second rope wheel arranged on the upper side of the tile loading box and a third rope wheel arranged on the front side of the supporting plate.

Each rope disc is coaxially inserted and matched with a rotary disc, and each rotary disc is rotatably connected to the outer wall of the tile loading box;

each turntable is uniformly provided with a plurality of outward arc-shaped spring pieces along the circumferential direction, the spring pieces on the same side of each rack are hinged with inward arc-shaped poking pieces, and the outer side of each poking piece is provided with a baffle for limiting outward turning;

and each limiting column is uniformly matched with the corresponding spring piece on the turntable in a clamping way.

Connecting shafts are uniformly arranged on two sides of the operating frame, and the outer sides of the connecting shafts are sleeved on the inner sides of the supporting plates and are in running fit;

the support plate with the connecting axle sleeve establishes the end with connecting axle sliding fit, connecting axle top both sides fixedly connected with two cardboard of handling frame mutually perpendicular, two the interval of cardboard with the thickness cooperation of support plate.

Control terminals are arranged on two sides of the tile loading box, and the control terminals are electrically connected with the tile discharging mechanism, the translation motor and the driving piece of the electric winch.

The top surfaces of the operating pedal and the supporting plate are provided with raised anti-slip edges;

the bottom of the operating frame is provided with rollers.

The invention is practically used: firstly, an operator ties a safety rope on a protection frame for subsequent work, after the tower crane transports tiles to a roof, the operator stacks the tiles into left and right storage areas of a tile loading box respectively in sequence, stands on an operation pedal, holds the tile loading box by hand to start an electric winch to pull the worker and the tile loading box together along the operation frame to the high position of a sloping roof for tile hanging, tile hanging construction can be simultaneously carried out on two sides of the tile loading box, the two side workers open the support plate according to the height and fix the support plate through the clamping plate so as to facilitate the worker to pedal for construction, the worker pushes the tiles in the storage area on the same side to one side by starting a tile outlet mechanism, the worker takes out the tiles for tile hanging, the tile hanging height can be realized by adjusting the height of the tile loading box through the electric winch, and then a translation motor is started when the transverse movement is needed, and under the cooperation of a threaded sleeve and a screw, the operation frame is enabled to transversely move so as to carry out tile hanging on an unworked area through the auxiliary effect of a roller.

The tile discharging mechanism comprises a gear, a rack, a tile discharging hole, a pulling piece, a spring piece, a rotating disc, a rope disc, a lifting plate, a limiting post, a spring piece, a push plate, a fixing rope disc, a push plate, a rope disc, a lifting plate, a rope disc, a limiting post, a push plate and a limiting post.

The connection of the limit post and the tile loading box adopts an easy-to-insert structure, when the tile loading box needs to be reloaded with tiles, the connection of the limit post and the tile loading box is released, and the rope disc rotates under the gravity action of the lifting plate until the lifting plate falls back to the bottom of the tile loading box.

The beneficial effects of the invention are as follows:

1. the invention ensures stronger safety of the heavy-gradient roof tile hanging, and the special guard rail is arranged on the upper return eave, so that the safety of constructors is further ensured, and in the tile hanging process, the support plate effectively supports the constructors in an auxiliary way, thereby being safe and convenient for construction;

2. according to the invention, the construction efficiency of the heavy-gradient roof is improved, the lifting and the moving of the tiles on the roof can be automatically completed, workers do not need to frequently and reciprocally take the tiles, and the tile loading box is divided into two storage areas, so that tile covering construction can be performed on two sides at the same time;

3. the invention obviously reduces the labor intensity and construction difficulty of workers while improving the construction efficiency, and the workers are not only free from carrying tile loads to move on the roof, but also are effectively assisted in the moving and stable construction process.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is an enlarged schematic view of the region a of fig. 1.

FIG. 3 is a schematic view of the positioning structure of the operation frame and the tile loading box according to the present invention.

Fig. 4 is an enlarged schematic view of the area a of fig. 3.

Fig. 5 is an enlarged schematic view of region B of fig. 3.

Fig. 6 is an enlarged schematic view of region C of fig. 5.

Fig. 7 is a schematic structural view of the shipping state of the tile-containing box.

Fig. 8 is a schematic diagram of a tile-out state structure of the tile-loading box.

Fig. 9 is an enlarged schematic view of the region a of fig. 8.

Wherein, the reference numerals are as follows: 1. an upper eave; 2. a protective frame; 201. planting ribs; 202. a transfer rod; 203. a vertical rod; 204. a sweeping rod; 205. a horizontal bar; 3. roof covering; 4. an operation rack; 401. a slide bar; 402. a connecting rod; 403. a hook; 404. a thread sleeve; 405. a screw; 406. a translation motor; 407. a chute; 408. a supporting plate; 409. an electric winch; 410. a traction rope; 411. a first sheave; 412. a connecting shaft; 413. a clamping plate; 414. a roller; 5. loading a tile box; 501. a partition plate; 502. a storage area; 503. a lifting plate; 504. a push plate; 506. a connecting plate; 507. a through groove; 508. a tile outlet hole; 509. a mounting base; 510. placing the hole; 6. operating the pedal; 7. a tile discharging mechanism; 701. a rack; 702. a gear; 703. a pushing motor; 704. a pull rope; 705. a second sheave; 706. a third sheave; 707. rope reel; 708. a turntable; 709. a spring piece; 710. a pulling piece; 711. a baffle; 712. a limit column; 8. a support plate; 9. a slide bar; 10. a tile; 11. and controlling the terminal.

Detailed Description

In order to clearly illustrate the technical characteristics of the scheme, the scheme is explained below through a specific embodiment.

Referring to fig. 1 to 9, the invention relates to a construction system for hanging tiles on a large-gradient roof, which comprises a protection frame 2 vertically arranged at the top of an upper return eave 1, an operation frame 4 parallel to the roof is arranged above the roof 3, a tile loading box 5 and an operation pedal 6 are connected to the inner side of the operation frame 4 in a sliding manner, a tile discharging mechanism 7 is arranged on the tile loading box 5, and support plates 8 are arranged on two sides of the operation frame 4.

The both sides of handling frame 4 are even to be provided with connecting axle 412, and the inboard and running fit of backup pad 8 are all located to every connecting axle 412 outside cover, and backup pad 8 establishes end and connecting axle 412 sliding fit with the connecting axle 412 cover, and connecting axle 412 top both sides fixedly connected with and handling frame 4 mutually perpendicular's two cardboard 413, the interval of two cardboard 413 and the thickness fit of backup pad 8. The top surfaces of the operating pedal 6 and the supporting plate 8 are provided with raised anti-slip edges, and the bottom of the operating frame 4 is provided with rollers 414.

The protection frame 2 includes a plurality of planting muscle 201 of even fixed connection in last eave 1 top and vertical setting, and every planting muscle 201 is located the equal fixedly connected with vertical pole 202 that sets up in one side of last eave 1 top, and the pole setting 203 of the vertical upward setting of one side equal fixedly connected with of every pole 202, the pole 204 of sweeping the floor of fixedly connected with level setting between the pole 202 inboard, the horizontal pole 205 of a plurality of level settings of by the even fixedly connected with of supreme down between the pole setting 203.

The handling frame 4 includes a pair of slide bar 401 that are parallel to each other and symmetry set up, even fixedly connected with a plurality of connecting rods 402 between a pair of slide bar 401 bottom side, the top of a pair of slide bar 401 all is provided with couple 403, every couple 403 all articulates and sliding fit with slide bar 9 that sets up along ridge top level, the bottom downside of a pair of slide bar 401 all coaxial level is provided with thread bush 404, thread bush 404 internal thread complex has screw 405, the both ends rotation of screw 405 is connected in last eave 1 top, wherein one end and translation motor 406's coaxial fixed connection of output shaft. The opposite sides of a pair of sliding rods 401 are symmetrically provided with sliding grooves 407 from bottom to top, two sides of a supporting plate 408 are both in sliding connection with the sliding grooves 407, the top of the front side of the supporting plate 408 is fixedly connected with a tile loading box 5 with an open top, the rear side of the supporting plate 408 is fixedly connected with an operating pedal 6, an electric winch 409 is arranged between the bottoms of the sliding rods 401, a traction rope 410 is arranged on the electric winch 409, and the traction end of the traction rope 410 extends upwards from the bottom side of the supporting plate 408 and bypasses a first rope pulley 411 arranged at the top of the sliding rod 401 to be downwards fixedly connected with the front side of the supporting plate 408.

The tile containing box 5 is internally provided with a partition plate 501 which is used for dividing the tile containing box 5 into a left storage area 502 and a right storage area 502, lifting plates 503 are slidably connected in each storage area 502, each lifting plate 503 is connected with a tile discharging mechanism 7, a push plate 504 is arranged at a position, close to the top, of the tile containing box 5, the size of the push plate 504 is matched with the size of a through placing hole 510 formed in the upper side of the partition plate 501, through tile discharging holes 508 matched with tiles 10 are formed in the left side and the right side of the tile containing box 5, corresponding to the push plate 504, of the push plate 504, and the push plate 504 is connected with the tile discharging mechanism 7. Control terminals 10 are provided on both sides of the tile-holding box 5, and the control terminals 10 are electrically connected to the tile-discharging mechanism 7 and the translational motor 406, and the driving member of the electric capstan 409.

The tile discharging mechanism 7 comprises racks 701 fixedly connected with two ends of a push plate 504 and mutually perpendicular to the racks 701 through connecting columns, the two racks 701 are all pressed close to the outer wall of the tile containing box 5 from the outer side of the tile containing box 5, the two connecting columns are all connected in sliding holes 505 symmetrically formed in the upper side of the tile containing box 5 in a sliding mode, gears 702 meshed with the racks are arranged on the lower side of each rack 701 and are rotationally connected to the outer wall of the tile containing box 5, one gear 702 is fixedly connected with an output shaft of a pushing motor 703, the pushing motor 703 is fixedly connected to the tile containing box 5 through a mounting seat 509, connecting plates 506 are fixedly connected to the front side and the rear side of each lifting plate 503, each connecting plate 506 extends to the outer side of the tile containing box 5 through a through groove 507 formed from top to bottom and is in sliding fit with the through groove 507, one end of each connecting plate 506 is fixedly connected with a pull rope 704, and the other end of each pull rope 704 is respectively wound to a rope disc 707 after passing through a second rope wheel 705 arranged on the upper side of the tile containing box 5 and a third rope wheel 706 arranged on the front side of the tile containing box 408. Each rope pulley 707 is coaxially inserted and matched with a rotary table 708, each rotary table 708 is rotationally connected to the outer wall of the tile containing box 5, each rotary table 708 is uniformly provided with a plurality of outward arc-shaped spring plates 709 along the circumferential direction, the two ends of each rack 701 corresponding to the spring plates 709 on the same side are hinged with inward arc-shaped shifting sheets 710, the outer side of each shifting sheet 710 is provided with a blocking sheet 711 for limiting outward turning, each rotary table 708 is correspondingly provided with a limiting column 712 fixedly connected to the outer wall of the tile containing box 5, and each limiting column 712 is uniformly matched with the corresponding spring plate 709 on the rotary table 708 in a clamping manner.

The invention is practically used: firstly, an operator carries out subsequent work after tying safety ropes on a protection frame 2, after a tower crane conveys tiles 10 to a roof, the worker stacks the tiles 10 into left and right storage areas 502 of a tile loading box 5 respectively in sequence, stands on an operation pedal 6 to hold the tile loading box 5, starts an electric winch 409 to pull the worker and the tile loading box 5 together along the operation frame 4 to the high position of a sloping roof 3, and carries out tile hanging construction, the workers on two sides of the tile loading box 5 can simultaneously carry out tile hanging construction, the workers on two sides open a support plate 8 according to the height, the workers can conveniently step on the tiles by the aid of a clamping plate 413, the workers push out the tiles 10 in the storage areas on the same side to one side of the workers through starting a tile outlet mechanism 7, tile hanging can be achieved through adjusting the height of the tile loading box 5 by the electric winch 409, when the workers need to carry out lateral movement, the translation motor 406 is started under the cooperation of a threaded sleeve 404 and a screw 405, and the operation frame 4 is made to carry out lateral movement through the auxiliary effect of a roller 414 so as to carry out tile hanging construction on an unworked area.

The working process of the tile discharging mechanism 7 is that a gear 702 is driven to rotate towards one side of an operation end by a pushing motor 703, the gear 702 drives a rack 701 to move, the rack 701 drives a push plate 504 to push a topmost tile 10 to move outwards, the tile is conveniently taken out by workers through a tile discharging hole 508, when the rack 701 extends outwards, a poking piece 710 at the end of the tile is inwards turned when being contacted with a spring piece 709, when the rack 701 is recovered, the poking piece 710 is clamped with the spring piece 709 to move to drive a turntable 708 to rotate to a certain extent, the turntable 708 rotates and drives a rope disc 707 to rotate, the pull rope 704 is recovered, namely, the lifting plate 503 is pulled upwards from two sides, the tile 10 of the next layer is lifted to the first layer, the next pushed-out position is met, after the rope disc 707 rotates a certain angle, a limit post 712 is clamped with the spring piece 709 from the inner side, the turntable 708 is not rotated, so that the rope disc 707 is fixed, the rotating position of the tile 10 is lifted, when the push plate 504 is recovered, a small amount of tilt occurs from the bottom of the tile 504, and when the push plate 504 is completely recovered, and after the push plate 504 is completely recovered into the placing hole 510, the tile 10 is immediately flattened.

It should be further noted that, the connection between the limiting post 712 and the tile loading box 5 adopts an easy-to-insert structure, when the tile loading box 5 needs to be reloaded with tiles 10, the connection between the limiting post 712 and the tile loading box 5 is released, and the rope pulley 707 rotates under the gravity action of the lifting plate 503 until the lifting plate 503 falls back to the bottom of the tile loading box 5.

The foregoing description of the preferred embodiments of the invention is not intended to limit the invention to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and scope of the invention are intended to be included within the scope of the invention.

Claims

1. The construction system for hanging tiles on the high-gradient roof is characterized by comprising a protection frame (2) vertically arranged at the top of an upper return eave (1), an operation frame (4) parallel to the roof is arranged above the roof (3), and a tile loading box (5) and an operation pedal (6) are connected to the inner side of the operation frame (4) in a sliding manner;

a tile discharging mechanism (7) is arranged on the tile loading box (5);

support plates (8) are arranged on two sides of the operation frame (4);

the operation frame (4) comprises a pair of sliding rods (401) which are parallel to each other and are symmetrically arranged, and a plurality of connecting rods (402) are uniformly and fixedly connected between the bottom sides of the sliding rods (401);

the tops of the pair of sliding rods (401) are respectively provided with a hook (403), and each hook (403) is hung and matched with a sliding rod (9) horizontally arranged along the top of a ridge in a sliding way;

a thread sleeve (404) is coaxially and horizontally arranged on the lower side of the bottom of the sliding rod (401), a screw rod (405) is in threaded fit with the thread sleeve (404), two ends of the screw rod (405) are rotatably connected to the top of the upper return eave (1), and one end of the screw rod is coaxially and fixedly connected with an output shaft of the translation motor (406);

a sliding groove (407) is symmetrically formed in opposite sides of the pair of sliding rods (401) from bottom to top, two sides of a supporting plate (408) are both connected in the sliding groove (407) in a sliding mode, the top of the front side of the supporting plate (408) is fixedly connected with a tile containing box (5) with an open top, and the rear side of the supporting plate (408) is fixedly connected with an operating pedal (6);

an electric winch (409) is arranged between the bottoms of the pair of sliding rods (401), a traction rope (410) is arranged on the electric winch (409), and the traction end of the traction rope (410) extends upwards from the bottom side of the supporting plate (408) and is fixedly connected to the front side of the supporting plate (408) downwards after bypassing a first rope wheel (411) arranged at the top of the sliding rods (401);

a partition board (501) is arranged in the tile containing box (5) to divide the tile containing box (5) into a left storage area (502) and a right storage area (502), lifting plates (503) are connected in each storage area (502) in a sliding manner, and each lifting plate (503) is connected with the tile discharging mechanism (7);

a push plate (504) is arranged at the position, close to the top, of the tile containing box (5), and the size of the push plate (504) is matched with the size of a through placing hole (510) formed in the upper side of the partition plate (501);

corresponding to the push plate (504), a tile outlet hole (508) which penetrates through and is matched with the tile (10) is formed in the left side and the right side of the tile loading box (5), and the push plate (504) is connected with the tile outlet mechanism (7);

the tile discharging mechanism (7) comprises racks (701) which are fixedly connected with two ends of the push plate (504) and are mutually perpendicular to the push plate through connecting columns, the two racks (701) are both close to the outer wall of the tile containing box (5) from the outer side of the tile containing box (5), and the two connecting columns are both connected in sliding holes (505) symmetrically formed in the upper side of the tile containing box (5) in a sliding manner;

the lower side of each rack (701) is provided with a gear (702) meshed with the rack and rotationally connected to the outer wall of the tile loading box (5), one gear (702) is fixedly connected with the output shaft of a pushing motor (703) in a coaxial way, and the pushing motor (703) is fixedly connected to the tile loading box (5) through a mounting seat (509);

connecting plates (506) are fixedly connected to the front side and the rear side of each lifting plate (503), and each connecting plate (506) extends to the outer side of the tile loading box (5) from top to bottom through a through groove (507) formed in the tile loading box (5) and is in sliding fit with the through groove (507);

one end of a pull rope (704) is fixedly connected to the top of each connecting plate (506), and the other end of the pull rope (704) is wound to a rope disc (707) after passing through a second rope wheel (705) arranged on the upper side of the tile loading box (5) and a third rope wheel (706) arranged on the front side of the supporting plate (408) respectively;

each rope reel (707) is coaxially inserted and matched with a rotary table (708), and each rotary table (708) is rotatably connected to the outer wall of the tile containing box (5);

each turntable (708) is uniformly provided with a plurality of outward arc-shaped spring pieces (709) along the circumferential direction, and both ends of each rack (701) corresponding to the spring pieces (709) on the same side are hinged with inward arc-shaped spring pieces

A poking piece (710), wherein a baffle piece (711) for limiting the outward turning of the poking piece (710) is arranged on the outer side of each poking piece (710);

and a limiting column (712) fixedly connected to the outer wall of the tile loading box (5) is arranged corresponding to each rotary table (708), and each limiting column (712) is matched with the corresponding spring piece (709) on the rotary table (708) in a clamping way.

2. The heavy-gradient roof tile hanging construction system according to claim 1, wherein the protection frame (2) comprises a plurality of planting bars (201) which are uniformly and fixedly connected to the top of the upper return eave (1) and are vertically arranged, each planting bar (201) is fixedly connected with a vertically arranged switching rod (202) on one side above the upper return eave (1), and a vertical upright rod (203) which is vertically upwards arranged is fixedly connected on one side of each switching rod (202);

a horizontally arranged sweeping rod (204) is fixedly connected between the inner sides of the switching rods (202);

a plurality of horizontal rods (205) which are horizontally arranged are uniformly and fixedly connected between the vertical rods (203) from bottom to top.

3. The heavy-gradient roof tile hanging construction system according to claim 1, wherein connecting shafts (412) are uniformly arranged on two sides of the operating frame (4), and the outer side of each connecting shaft (412) is sleeved on the inner side of the supporting plate (8) and is in running fit;

the support plate (8) and the connecting shaft (412) are sleeved with the connecting shaft (412) in a sliding fit mode, two clamping plates (413) perpendicular to the operating frame (4) are fixedly connected to two sides of the top of the connecting shaft (412), and the distance between the two clamping plates (413) is matched with the thickness of the support plate (8).

4. The heavy grade roofing tile hanging construction system according to claim 1, wherein control terminals (10) are arranged on two sides of the tile holding box (5), and the control terminals (10) are electrically connected with the tile discharging mechanism (7), the translation motor (406) and the driving piece of the electric winch (409).

5. The heavy grade roofing tile hanging construction system according to claim 1, wherein the top surfaces of the operating pedal (6) and the supporting plate (8) are provided with raised anti-slip edges;

the bottom of the operating frame (4) is provided with a roller (414).