CN115467536A - Construction device and construction method for building outer wall heat insulation layer - Google Patents

Abstract

The invention discloses a construction device and a construction method for a heat-insulating layer of an outer wall of a building, and the construction device comprises a main underframe, a support frame, an unlocking mechanism and a material conveying mechanism, wherein the left side and the right side of the main underframe are respectively and movably provided with an auxiliary underframe capable of being adjusted in a sliding manner, a horizontal frame body in the support frame is lapped and fixedly connected to the side wall of a pipe body part in the auxiliary underframe through bolts, the unlocking mechanism is arranged on the upper side wall of the horizontal frame body in the support frame, and the material conveying mechanism is movably inserted into a frame cavity of a U-shaped limiting frame. According to the construction device and the construction method for the heat-insulating layer of the building outer wall, continuous conveying and feeding are achieved through the construction device, the construction device is different from loading and transportation of a traditional hanging basket, heat-insulating layer plates do not need to be stacked in the hanging basket, repeated lifting and dropping of the hanging basket are also not needed to load the heat-insulating layer plates, the construction efficiency is greatly improved, automatic locking after the heat-insulating layer plates are loaded and convenient material taking after the heat-insulating layer plates are transported are achieved, and the construction efficiency is further improved.

Description

Construction device and construction method for building outer wall heat insulation layer

Technical Field

The invention relates to the technical field related to heat insulation layer construction, in particular to a construction device and a construction method for a heat insulation layer of an outer wall of a building.

Background

The application of the building outer wall heat-insulating layer can not only play a role in heat insulation for a building body, but also play a role in well protecting the building wall body, so that the service life of the building body is guaranteed, and when the building outer wall heat-insulating layer is constructed, operations such as leveling pretreatment, pasting of a heat-insulating layer plate, reinforcing of the heat-insulating layer plate, coating of a mortar surface layer and the like of the building wall surface are required to be sequentially carried out;

the heat-insulation layer plate is used as a prefabricated plate and is an important component in a building external wall heat-insulation system, when the heat-insulation layer plate is pasted, the heat-insulation layer plate needs to be continuously carried and loaded, the hanging basket is used as a construction platform, and the adhesive is used for pasting the high-rise building wall surface layer by layer.

To the building outer wall heat preservation layer construction that uses under the prior art background with heat preservation plywood conveyer, still there is certain shortcoming, for example:

1. in the process of pasting construction of the heat-insulation laminates, in the existing heat-insulation laminate transportation mode, a certain number of heat-insulation laminates are loaded by a hanging basket at one time and transported to a pasting position for pasting operation, and as the hanging basket carries a limited number of heat-insulation laminates, the hanging basket needs to be lifted and lowered continuously for loading the heat-insulation laminates, and the complicated transportation mode is repeated, so that the workload of constructors is increased, and the construction efficiency is seriously influenced;

2. the heat-insulation layer plates are conveyed through the hanging basket, and the heat-insulation layer plates need to be stacked in the hanging basket, so that the narrow hanging basket space is limited by the heat-insulation layer plates, and after the heat-insulation layer plates occupy the hanging basket space, the construction operation of constructors is influenced, and further potential safety hazards in the construction process are caused;

therefore, we propose a construction device and a construction method for a building external wall insulation layer, so as to solve the problems mentioned above.

Disclosure of Invention

The invention aims to provide a construction device and a construction method for a heat-insulating layer of an outer wall of a building, and aims to solve the problems that a hanging basket provided by the background technology is repeated and tedious in transportation, the workload of constructors is increased, the construction efficiency is influenced, and in addition, a heat-insulating layer plate is piled in the hanging basket, the construction operation is influenced, and potential safety hazards are caused.

In order to achieve the purpose, the invention provides the following technical scheme: a construction device for a heat-insulating layer of an exterior wall of a building comprises:

(1) The middle part of the front section of the main underframe is fixedly provided with a winch through a bolt, a left reel steel wire rope, a middle reel steel wire rope and a right reel steel wire rope in the winch are all arranged on the main underframe in a vertically upward state under the assistance of a guide sheave, the left side and the right side of the main underframe are respectively and movably provided with an auxiliary underframe capable of being adjusted in a sliding mode, a fixing bolt for locking is arranged at the sliding connection part of the auxiliary underframe and the main underframe, and the lower side wall of the front end of a pipe body part in the auxiliary underframe and the lower side wall of the rear end of the pipe body part in the auxiliary underframe are respectively and fixedly provided with a trundle through bolts;

further comprising:

the support frame is characterized in that a horizontal frame body in the support frame is lapped and fixedly connected to the side wall of a tube body part in the auxiliary bottom frame through bolts, a U-shaped limiting frame of an integrated structure is vertically arranged at the upper end of a vertical frame body in the support frame, and a bearing frame of the integrated structure is vertically arranged at the lower end of the vertical frame body in the support frame;

the lower end of the inclined side wall in the upper material plate frame is fixedly connected to the longitudinal pipe frame part of the main bottom frame through a bolt;

the unlocking mechanism is arranged on the upper side wall of a horizontal frame body in the supporting frame and comprises a shell, an unlocking piece, a first movable column, a second movable column, a first gear, a connecting pipe and a linkage rod, wherein the lower side wall of the shell is fixedly connected to the horizontal frame body of the supporting frame through bolts, a placing groove part of the shell and a frame cavity of the bearing frame are arranged in a corresponding state, the unlocking piece is connected in a cavity of the rear section of the shell in a sliding mode, the front section of the unlocking piece is arranged in an upward inclined state, the first movable column is connected above the cavity of the front section of the shell in a sliding mode, the second movable column is connected below the cavity of the front section of the shell in a sliding mode, the first gear is arranged in a gap between the second movable column and the first movable column, the connecting pipe is movably inserted in a pipe cavity of a pipe shell in the shell of the shell, the rear end of the connecting pipe is fixedly connected with a lug in the unlocking piece through bolts, the linkage rod capable of sliding in a telescopic mode is movably inserted in the pipe cavity of the connecting pipe, and the front end of the linkage rod is fixedly connected with a lug in the first movable column through bolts;

the inner wall of the groove at the rear section of the second movable column is provided with a driving rack in an integrated structure, the rack-shaped side wall of the second movable column is meshed and connected with the lower side of the first gear, the upper side of the first gear is meshed and connected with the rack-shaped side wall of the first movable column, the first gear is fixedly connected to the output end of the first motor through a bolt, and the first motor is fixedly installed on the side wall of the shell through a bolt;

the linkage pipe middle ring cover is arranged in the shell, a groove cavity of the linkage pipe middle ring cover is connected with a locking piece in a sliding mode, a hemispherical head end of the locking piece and a through hole part of the shell are located on the same horizontal central axis, and a first spring is arranged at the joint of the locking piece and the linkage pipe middle ring cover;

the connecting part of the linkage rod and the linkage pipe is provided with a second spring, and the front end rod body of the linkage rod is connected with the cylindrical tail end head of the locking piece in a clamping manner;

the conveying mechanism is movably inserted into a frame cavity of the U-shaped limiting frame and comprises a T-shaped connecting frame, a steel wire rope walking device, a first U-shaped angle frame, a round pipe seat, a main rod frame, an auxiliary rod frame, a round rod seat, a second U-shaped angle frame and a turnover gear, wherein the steel wire rope walking device is fixedly installed on a frame body in the middle of the T-shaped connecting frame and is arranged on a middle reel steel wire rope of the winch, the first U-shaped angle frame capable of being adjusted in a sliding mode is movably installed on a left rod body and a right rod body of the T-shaped connecting frame, a fixing bolt for locking is installed at the sliding connection position of the first U-shaped angle frame and a middle rod body of the T-shaped connecting frame, and the round pipe seat is fixedly connected to the middle portion of a side frame plate in the first U-shaped angle frame through a bolt;

the pipe body of the round pipe seat is movably provided with a main rod frame capable of being adjusted in a sliding mode, a fixing bolt used for locking is arranged at the sliding connection position of the round pipe seat and the main rod frame, the upper end of the main rod frame is vertically provided with a long round rod part in an integrated structure, and the end part of the long round rod part in the main rod frame is arranged in a wide structure;

an auxiliary rod frame capable of sliding in a telescopic mode is movably inserted into a pipe cavity of the lower section of the main rod frame, a third spring is installed at the joint of the auxiliary rod frame and the main rod frame, and a short round rod part of an integrated structure is vertically arranged on a rod body of the lower section of the auxiliary rod frame;

the lower end of the auxiliary rod frame is connected with the rod body of the rod seat in a rotating mode, a torsion spring is installed at the rotating connection position of the rod seat and the auxiliary rod frame, the rod seat is fixedly connected to the middle of the side frame plate of the second U-shaped corner frame through a bolt, and the end portion of the rod body of the rod seat is fixedly connected with a turnover gear through a bolt.

Preferably, a first connecting plate capable of being adjusted in a sliding mode is movably mounted on a front frame plate of the U-shaped limiting frame, a fixing bolt used for locking is mounted at the sliding connection position of the first connecting plate and the U-shaped limiting frame, a second connecting plate capable of being adjusted in a sliding mode is movably mounted on a rear frame plate of the U-shaped limiting frame, the fixing bolt used for locking is also mounted at the sliding connection position of the second connecting plate and the U-shaped limiting frame, and a supporting plate part of an integrated structure is vertically arranged in the middle of the second connecting plate in a bending mode.

Preferably, the lateral wall all is circular arc chamfer structural status setting about the recess opening part in the second activity post, and the width dimension of recess is greater than the thickness dimension of upset gear in the second activity post to the maximum interval size between short round rod portion is less than the degree of depth size of placing the slot part in the casing in upset gear and the auxiliary rod frame, and the diameter dimension of upset gear is less than the width dimension of placing the slot part in the casing moreover.

Preferably, the steel wire rope walking device comprises a walking device shell, an electric wire winding disc, a conductive disc, a first walking wheel, a second motor and a second gear, guide pipes are vertically and fixedly mounted at the upper end and the lower end of the walking device shell, the end part of the lower guide pipe in the walking device shell is of a conical structure, the electric wire winding disc is arranged in a box cavity of a right shell part in the walking device shell, the conductive disc for power transmission is arranged on the left side of the electric wire winding disc, the conductive disc is fixedly mounted on the right shell part of the walking device shell through a bolt, the first walking wheel and the second walking wheel which can rotate are sequentially mounted in a shell cavity of the walking device shell from top to bottom, guide grooved wheels are arranged below the second walking wheel and above the first walking wheel, the second motor is fixedly mounted on the side wall of the left shell part in the walking device shell through a bolt, and the second gear is fixedly connected to the output end of the second motor.

Preferably, the guide pipe is movably inserted into a through positioning hole of a supporting plate part in the second connecting plate, the supporting plate part of the second connecting plate is arranged in a fit state with the lower side of the walking device shell, the guide pipe is movably sleeved on a middle winding drum steel wire rope of the winch, the middle winding drum steel wire rope of the winch sequentially winds a lower guide sheave, a second travelling wheel, a first travelling wheel and an upper guide sheave of the walking device shell from bottom to top, and the left winding drum steel wire rope and the right winding drum steel wire rope in the winch are respectively inserted through a long round rod part through groove of the left main rod frame and a long round rod part through groove of the right main rod frame in an auxiliary mode through the guide sheaves;

the end part of a middle reel steel wire rope of the winch is fixedly arranged in the middle of the fixing frame, a left reel steel wire rope and a right reel steel wire rope of the winch are fixedly arranged at the left end and the right end of the fixing frame respectively, and the left reel steel wire rope, the middle reel steel wire rope and the right reel steel wire rope of the winch are arranged in a parallel state.

Preferably, the second gear is arranged at a gap between the first traveling wheel and the second traveling wheel, the upper side of the second gear is connected with the gear part of the first traveling wheel in a meshing manner, and the lower side of the second gear is connected with the gear part of the second traveling wheel in a meshing manner;

the right side wall of the second travelling wheel is fixedly connected with the wire winding disc through a bolt, and the wire winding disc is driven by the second travelling wheel to form a rotating structure on the conductive disc.

Preferably, the long round rod part of the main rod frame is connected with the funnel groove of the support frame in a clamping mode, and the wide-head side wall of the long round rod part in the main rod frame is attached to and abutted against the side wall of the vertical frame body of the support frame.

The invention provides another technical scheme for providing a construction method of a building outer wall heat-insulating layer construction device, which comprises the following steps:

step 1: according to the specification and the size of the heat-insulation layer plate, the whole frame body and the material conveying mechanism in the construction device are sequentially adjusted;

and 2, step: carrying out position arrangement of the construction device;

and 3, step 3: the unlocking mechanism drives the second U-shaped angle frame to move downwards and turn over, so that unlocking operation is realized;

and 4, step 4: after the heat-insulation laminated plate is fed, the second U-shaped corner frame is driven by the unlocking mechanism again to reset, move upwards and reset and turn over, so that the heat-insulation laminated plate is clamped and locked;

and 5: the steel wire rope walking device drives the material conveying mechanism to carry out material conveying operation on the heat-insulation laminate.

Compared with the prior art, the invention has the beneficial effects that: according to the construction device and the construction method for the heat-insulating layer of the building outer wall, continuous conveying and feeding are realized through the construction device, the construction device is different from the traditional hanging basket in loading and transportation, heat-insulating layer plates do not need to be stacked in the hanging basket, repeated lifting and dropping of the hanging basket are also not needed to load the heat-insulating layer plates, the construction efficiency is greatly improved, automatic locking after the heat-insulating layer plates are loaded and convenient material taking after the heat-insulating layer plates are transported are realized, and the construction efficiency is further improved;

1. the construction device is provided with a winch and a material conveying mechanism, a steel wire rope walking device is arranged on a middle reel steel wire rope of the winch, a left reel steel wire rope and a right reel steel wire rope in the winch respectively pass through a long round rod part through groove of a left main rod frame and a long round rod part through groove of a right main rod frame in an auxiliary insertion mode through a guide sheave, the material conveying mechanism is driven by the steel wire rope walking device to carry a heat-insulation layer plate to climb on the middle reel steel wire rope of the winch, continuous conveying of the heat-insulation layer plate is achieved through the construction device, loading and conveying of the heat-insulation layer plate are different from loading and conveying of a traditional hanging basket, the heat-insulation layer plate does not need to be stacked in the hanging basket, the hanging basket space is occupied, repeated lifting and descending of the hanging basket are not needed to load the heat-insulation layer plate, construction efficiency is greatly improved, workload of constructors is relieved, potential safety hazards in the construction process are eliminated, in addition, unwinding work is carried out along with lifting of the steel wire rope in the hanging basket, the high-rise building, use requirements are met, and flexibility of the construction device is improved;

2. the device is provided with an unlocking piece and a steel wire rope walking device, when the first movable column and the second movable column reset and slide, the first movable column drives the linkage rod to reset and contract on the linkage pipe, a driving rack in the second movable column drives the overturning gear to rotate reversely, after the first movable column and the second movable column continuously reset and slide, the driving rack in the second movable column loses contact with the overturning gear, the overturning gear drives the second U-shaped angle frame to complete overturning and resetting, the linkage pipe and the linkage rod are locked together again through the locking piece, the unlocking piece resets and slides and loses contact with the short round rod part of the auxiliary rod frame, so that the auxiliary rod frame drives the second U-shaped angle frame to reset and move upwards, the overturning motion and the upwards moving motion of the second U-shaped angle frame are completed in sequence through the linkage structure, the automatic locking after the feeding of the heat-insulating laminated plate is realized, meanwhile, the automatic unlocking is realized through the unlocking mechanism, the problem of quick feeding is solved, the operation mode is optimized, and the construction efficiency is further improved;

3. the construction device is provided with a main rod frame and an auxiliary rod frame, the heat preservation layer plate is pressed downwards, the heat preservation layer plate presses the second U-shaped angle frame to move downwards, the auxiliary rod frame is made to slide and extend out of the main rod frame, the heat preservation layer plate is separated from the first U-shaped angle frame and is not limited, the second U-shaped angle frame is assisted by the round rod seat to form a rotating structure on the auxiliary rod frame, the turnover heat preservation layer plate is stirred, the second U-shaped angle frame is made to turn over on the auxiliary rod frame, the heat preservation layer plate can be conveniently taken after being transported in a drawing mode, in addition, the elastic deformation resetting of the third spring and the torsion spring is utilized, the automatic resetting after the downward movement and the turnover movement of the second U-shaped angle frame is realized, the secondary material conveying of the construction device is ensured, and the construction efficiency is further ensured.

Drawings

FIG. 1 is a schematic front perspective view of the present invention;

FIG. 2 is a schematic view of a front perspective structure of the connection between the main chassis and the winch according to the present invention;

FIG. 3 is a schematic side view of a three-dimensional structure of the connection between the main chassis and the upper material plate frame;

FIG. 4 is a schematic view of the connection between the U-shaped limiting frame and the first connecting plate in an orthographic perspective view;

FIG. 5 is a schematic view of a front perspective structure of the connection of the support frame and the unlocking mechanism of the present invention;

FIG. 6 is a schematic view of a front cut-away perspective structure of the unlocking mechanism of the present invention;

FIG. 7 is a schematic view of a front sectional perspective view of the second movable column and the first gear according to the present invention;

FIG. 8 is a schematic diagram of a side-view cross-sectional three-dimensional structure of the linkage pipe and the linkage rod according to the present invention;

FIG. 9 is an exploded side view of the linkage and the locking member of the present invention;

FIG. 10 is a front perspective view of the feeding mechanism of the present invention;

FIG. 11 is a schematic view of a side-view three-dimensional structure of the T-shaped connecting frame and the steel wire rope walking device;

FIG. 12 is a schematic view of a front perspective structure of the main bar frame and the sub-bar frame according to the present invention;

FIG. 13 is a schematic view of a front sectional perspective structure of the main bar frame and the sub-bar frame according to the present invention;

FIG. 14 is an exploded side view perspective view of the wire rope traveling device according to the present invention;

fig. 15 is a schematic side-view cross-sectional three-dimensional structure of the wire rope walking device of the present invention.

In the figure: 1. a main chassis; 2. a winch; 3. a sub chassis; 4. a caster wheel; 5. a support frame; 6. a U-shaped limiting frame; 7. a bearing frame; 8. a feeding plate frame; 9. an unlocking mechanism; 10. a housing; 11. unlocking the lock; 12. a first movable column; 13. a second movable column; 14. a first gear; 15. a linkage pipe; 16. a linkage rod; 17. a first motor; 18. a locking member; 19. a first spring; 20. a second spring; 21. a material conveying mechanism; 22. a T-shaped connecting frame; 23. a wire rope walker; 24. a first "U" -shaped corner frame; 25. a round tube seat; 26. a main bar frame; 27. a sub-bar frame; 28. a third spring; 29. a rod seat; 30. a torsion spring; 31. a second "U" -shaped corner frame; 32. turning over a gear; 33. a first connecting plate; 34. a second connecting plate; 35. a walker housing; 36. a guide tube; 37. a wire winding disc; 38. a conductive plate; 39. a first traveling wheel; 40. a second road wheel; 41. a second motor; 42. a second gear; 43. a fixing frame.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-15, the present invention provides a technical solution: a construction device for a heat-insulating layer of an outer wall of a building comprises a main underframe 1, and further comprises a support frame 5, an unlocking mechanism 9 and a material conveying mechanism 21.

The building outer wall heat-insulating layer construction device is particularly a conveying device for heat-insulating layer plates in the building outer wall heat-insulating layer construction process, wherein the specification and the size of various heat-insulating layer plates are different, the length and width size difference is large, the thickness size difference is small, before the building outer wall heat-insulating layer construction device is used, the building outer wall heat-insulating layer construction device needs to be adjusted according to the size and the size of the heat-insulating layer plates, and the specific adjusting steps are that the material conveying mechanism 21 is firstly adjusted, and then the whole frame body in the construction device is adjusted;

as shown in fig. 1, 2, 4, 10 and 11, the first U-shaped corner frame 24, the main rod frame 26, the auxiliary rod frame 27 and the second U-shaped corner frame 31 are combined to form a group of clamping mechanisms for the heat preservation laminate, the clamping mechanisms are arranged on the T-shaped connecting frame 22 in a mirror image manner, when the adjustment operation of the material conveying mechanism 21 is performed, firstly, the length sizes of the two groups of clamping mechanisms are respectively adjusted, because the main rod frame 26 and the circular tube seat 25 are movably connected in a penetrating manner, and the fixing bolt in the circular tube seat 25 is in threaded connection with the tube wall thereof, the fixing bolt at the sliding connection position of the circular tube seat 25 and the main rod frame 26 is loosened by screwing, after the locking is lost, the circular tube seat 25 is pushed to slide on the main rod frame 26, the circular tube seat 25 is fixedly connected to the middle of the side frame plate in the first U-shaped corner frame 24 through a bolt to form an integrated structure, the circular tube seat 25 slides while driving the first U-shaped corner frame 24 to synchronously move, the first U-shaped corner frame 24 and the second U-shaped corner frame 24 in the clamping mechanism are inserted into the inner corner space of the fixing bolt, the two U-shaped corner frames 24 are inserted into the clamping mechanisms, the upper and the two U-shaped corner clamping mechanisms, the two U-shaped corner frames 21, the two U-corner clamping mechanisms are inserted into the two U-shaped corner fixing bolts to adjust the length sizes of the heat preservation laminate, and the two U-corner frames, and the two clamping mechanisms 21;

then the space between the two groups of clamping mechanisms is adjusted, as the side edge of the back frame plate in the first U-shaped corner frame 24 is bent and provided with a sleeve part, the sleeve part of the first U-shaped corner frame 24 is movably sleeved on the rod body of the T-shaped connecting frame 22 after the first U-shaped corner frame 24 is arranged, and the fixing bolt in the first U-shaped corner frame 24 is in threaded connection with the side wall of the sleeve part, the fixing bolt at the sliding connection part of the rod body in the first U-shaped corner frame 24 and the T-shaped connecting frame 22 is unscrewed, and after the locking is lost, the first U-shaped corner frame 24 is pushed to enable the sleeve part to slide on the rod body of the T-shaped connecting frame 22, the left and right first U-shaped angle frames 24 on the T-shaped connecting frame 22 slide in opposite directions at equal intervals, the distance between the left and right first U-shaped angle frames 24 is adjusted, the left and right corners of the side edge of the heat-insulation layer plate are respectively inserted into the frame cavities of the left and right first U-shaped angle frames 24, after the material conveying mechanism 21 is adjusted, the distance between the two groups of clamping mechanisms is matched with the width of the heat-insulation layer plate, the fixing bolts are screwed again, the fixing bolts in the first U-shaped angle frames 24 penetrate through the side wall of the sleeve part of the fixing bolts and abut against the rod body of the T-shaped connecting frame 22, and the re-locking after the distance between the two groups of clamping mechanisms is adjusted is completed;

because the width dimension of the frame cavity in the second U-shaped corner frame 31 is equal to the width dimension of the frame cavity in the first U-shaped corner frame 24 and is larger than the thickness dimension of the largest specification of the heat preservation laminate, when the heat preservation laminate with smaller thickness dimension is dealt with, the limiting pieces with the same dimension are respectively arranged in the frame cavities of the first U-shaped corner frame 24 and the second U-shaped corner frame 31, the width dimension of the frame cavity is reduced by the limiting pieces, so that the size of the frame cavity is matched with the thickness dimension of the heat preservation laminate, and the mounting mode is the prior art, and the description is not described in the attached drawings of the specification;

according to the size adjusted by the material conveying mechanism 21, the adjusting operation of the whole frame body in the construction device is carried out, the auxiliary bottom frame 3 is composed of a pipe body part which is longitudinally arranged and a plurality of square column parts which are transversely arranged, the plurality of square column parts in the auxiliary bottom frame 3 are all welded on the pipe body part to form an integrated structure, the main bottom frame 1 is composed of a longitudinal pipe frame part and a plurality of transverse pipe frame parts, the longitudinal pipe frame part and the transverse pipe frame part in the main bottom frame 1 are welded together to form an integrated structure, each square column part in the auxiliary bottom frame 3 and each transverse pipe frame part in the main bottom frame 1 are arranged in a one-to-one correspondence mode, the square column parts are movably inserted in the pipe cavities of the transverse pipe frame parts of the main bottom frame 1 after the auxiliary bottom frame 3 is arranged, and the side walls of the pipe body parts in the auxiliary bottom frame 3 are fixedly connected with the horizontal frame bodies in the supporting frame 5 through bolts, an integrated structure is formed, and because the U-shaped limiting frame 6 is arranged in the supporting frame 5 and is in a vertical state at the upper end of the vertical frame body, the front frame plate and the rear frame plate in the U-shaped limiting frame 6 are both arranged in a square tubular structure by utilizing the bending technology, the first connecting plate 33 is arranged at the gap between the left U-shaped limiting frame 6 and the right U-shaped limiting frame 6, the left section of the first connecting plate 33 is movably inserted in the tube cavity of the front frame plate of the left U-shaped limiting frame 6 after the first connecting plate 33 is arranged, the right section of the first connecting plate is movably inserted in the tube cavity of the front frame plate of the right U-shaped limiting frame 6, the first connecting plate 33 and the second connecting plate 34 are correspondingly arranged in the front and the rear direction and are also arranged at the gap between the left U-shaped limiting frame 6 and the right section of the second connecting plate 34 is movably inserted in the tube cavity of the rear frame plate of the left U-shaped limiting frame 6 after the second connecting plate is arranged, the right section of the second connecting plate is movably inserted in the tube cavity of the rear frame plate of the right U-shaped limiting frame 6, the fixing bolts at the sliding connection part of the auxiliary underframe 3 and the main underframe 1, the fixing bolt at the sliding connection part of the first connecting plate 33 and the U-shaped limiting frame 6 and the fixing bolt at the sliding connection part of the second connecting plate 34 and the U-shaped limiting frame 6 are sequentially screwed and loosened, after the locking is lost, the square column part of the auxiliary underframe 3 is pushed to slide in the transverse pipe frame part of the main underframe 1, and the front and the back frame plates of the U-shaped limit frames 6 slide on the first connecting plate 33 and the second connecting plate 34 respectively, the left and the right auxiliary bottom frames 3 on the main bottom frame 1 slide equidistantly in opposite directions, the adjustment between the left and the right auxiliary bottom frames 3, the adjustment between the left and the right support frames 5 and the adjustment between the left and the right U-shaped limit frames 6 are respectively carried out, the adjusted material conveying mechanism 21 is inserted between the left and the right U-shaped limit frames 6, the long round rod part of the left main rod frame 26 and the long round rod part of the right main rod frame 26 are respectively clamped in the funnel groove of the left support frame 5 and the funnel groove of the right support frame 5, the wide-head side wall of the middle long circular rod part of the left main rod frame 26 and the wide-head side wall of the middle long circular rod part of the right main rod frame 26 are respectively attached to and abutted against the vertical frame side wall of the left support frame 5 and the vertical frame side wall of the right support frame 5, fixing bolts are screwed in sequence again, the fixing bolts in the auxiliary bottom frame 3 penetrate through the adjusting grooves of the transverse pipe frame parts in the main bottom frame 1 and are connected to the square column parts of the auxiliary bottom frame, the fixing bolts in the first connecting plate 33 penetrate through the adjusting grooves of the front frame plate in the U-shaped limiting frame 6 and are connected to the side walls of the auxiliary bottom frame, the fixing bolts in the second connecting plate 34 penetrate through the adjusting grooves of the rear frame plate in the U-shaped limiting frame 6 and are connected to the side walls of the auxiliary bottom frame in a threaded mode, and the whole frame in the construction device is locked again after adjustment;

according to the attached drawings 1 and 2, the middle part of the rear section of the longitudinal pipe frame part in the main chassis 1 and the left and right side walls thereof are rotatably connected with guide sheaves, the side wall of the rear section of the pipe body part in the auxiliary chassis 3 is also rotatably connected with the guide sheaves, the winch 2 is in a three-drum type and is sequentially divided into a left drum, a middle drum and a right drum from left to right, after the winch 2 is arranged, the drum steel wire rope is inserted into the pipe cavity of the longitudinal pipe frame part in the main chassis 1 and is longitudinally bent along the middle guide sheave on the main chassis 1 to be vertically upwards, the left drum steel wire rope is firstly inserted into the pipe cavity of the longitudinal pipe frame part in the main chassis 1 and is transversely bent along the left guide sheave on the main chassis 1 and then inserted into the pipe body part of the left auxiliary chassis 3 and is longitudinally bent along the guide sheave in the left auxiliary chassis 3 to be vertically upwards, the arrangement mode of a right reel steel wire rope is the same as that of a left reel steel wire rope, the right reel steel wire rope is vertically and upwards arranged through auxiliary longitudinal bending of a right guide sheave on a main underframe 1 and a guide sheave in a right auxiliary underframe 3, after the construction device for the building outer wall heat insulation layer is adjusted, the distance between the left reel steel wire rope on the left auxiliary underframe 3 and the right reel steel wire rope on the right auxiliary underframe 3 is changed, a fixing frame 43 with matched size is selected, the end part of a middle reel steel wire rope is fixedly arranged in the middle of the fixing frame 43, the left reel steel wire rope and the right reel steel wire rope are respectively and fixedly arranged at the left end and the right end of the fixing frame 43, and the left reel steel wire rope, the middle reel steel wire rope and the right reel steel wire rope are arranged in parallel to each other;

when the building outer wall heat insulation layer construction device is used, the construction device is placed firstly, as shown in attached drawings 1 and 2, a control box is installed on a transverse pipe frame portion of a main chassis 1, the control box mainly comprises a control main board and an external control switch, the control box is the prior art, detailed description is not provided in the attached drawings of the specification, a winch 2 is fixedly installed in the middle of the front section of the main chassis 1 through bolts, the winch 2 is in circuit connection with the control box through electric wires, a fixing frame 43 is fixedly installed on a hanging basket, the connection mode is the prior art, detailed description is not provided in the attached drawings of the specification, the winch 2 is started to run through the control box in the lifting process of the hanging basket, the left reel steel wire rope, the middle reel steel wire rope and the right reel steel wire rope in the winch 2 are unreeled synchronously through a guide sheave, and the truckles 4 are fixedly installed on the lower side wall of the front end and the lower side wall of the lower end of a pipe body portion in an auxiliary chassis 3, and the lower side wall of the rear end of the pipe body, the truckles 4 can rotate universally, the truckles 4 are provided with a locking structure, and after the hanging basket is moved to a specified position, the hanging basket is moved through the auxiliary of the reel steel wire rope, the construction device, the hanging basket 4, the hanging basket is set in a vertical state;

then, the feeding operation of the insulation laminate is performed, as shown in fig. 6, fig. 7, fig. 8 and fig. 9, the unlocking mechanisms 9 and the supporting frame 5 are arranged in a mirror image manner, the unlocking operation of the two groups of clamping mechanisms in the material conveying mechanism 21 is respectively performed through the left unlocking mechanism 9 and the right unlocking mechanism 9, because the left side wall and the right side wall of the first movable column 12 are respectively provided with a plurality of rollers, the rollers are movably clamped in the upper strip-shaped chute at the front section of the shell 10 after the first movable column 12 is arranged, so that the first movable column 12 is movably positioned above the cavity at the front section of the shell 10, the left side wall and the right side wall of the second movable column 13 are also provided with a plurality of rollers, the rollers are movably clamped in the lower strip-shaped chute at the front section of the shell 10 after the second movable column 13 is arranged, so that the second movable column 13 is movably positioned below the cavity at the front section of the shell 10, and the unlocking mechanisms 9 are fixedly connected to the horizontal frame body of the supporting frame 5 after the second movable column 13 is arranged, and because the lower side wall of the first movable column 12 and the upper side wall of the front section of the second movable column 13 are both in a rack-shaped structure, the first gear 14 is arranged at the gap between the second movable column 13 and the first movable column 12, the lower side of the first gear 14 is meshed and connected with the rack-shaped side wall of the second movable column 13, the upper side of the first gear 14 is meshed and connected with the rack-shaped side wall of the first movable column 12, the first gear 14 is fixedly connected with the output end of the first motor 17, the first motor 17 is fixedly arranged on the side wall of the shell 10 and is in circuit connection with the control box through an electric wire, the first motor 17 is started to operate through the control box, the first gear 14 is driven to rotate, the first movable column 12 and the second movable column 13 slide in opposite directions in the cavity of the shell 10, the front end and the rear end of the shell 10 are both plugged and fixedly connected with end covers through bolts, for blocking, preventing the first movable column 12 and the second movable column 13 from sliding excessively;

because the side wall of the shell 10 is provided with the tube shell part with an integrated structure, and the side wall of the first movable column 12 is vertically provided with the convex block with an integrated structure, wherein the convex block movably penetrates through the upper strip-shaped sliding groove at the front section of the shell 10 to be inserted into the tube cavity of the tube shell part in the shell 10 and is fixedly connected with the front end of the linkage rod 16, the first movable column 12 drives the linkage rod 16 to synchronously slide in the tube shell part of the shell 10 while sliding, and because the locking piece 18 is in a cylindrical structure close to the tail end of the linkage rod 16, the cylindrical tail end head of the locking piece 18 movably penetrates through the ring cover of the linkage tube 15 after being arranged to extend into the ring cavity and is connected with the front end rod body of the linkage rod 16 in a clamping manner, so that the linkage rod 16 and the linkage tube 15 are locked together, the linkage tube 15 is movably positioned in the tube cavity of the tube shell part in the shell 10 after being arranged, and the linkage rod 16 drives the linkage tube 15 to synchronously slide in the tube shell part of the shell 10;

because the side wall of the unlocking piece 11 is vertically provided with a convex block with an integrated structure, wherein the convex block movably penetrates through a strip-shaped chute at the rear section of the shell 10 to be inserted into a tube cavity of a tube shell part in the shell 10 and is fixedly connected with the rear end of the linkage tube 15, and because the left side wall and the right side wall of the unlocking piece 11 are respectively provided with a plurality of idler wheels, after the unlocking piece 11 is arranged, the idler wheels are movably clamped in the strip-shaped chute at the rear section of the shell 10, so that the unlocking piece 11 is movably positioned in a cavity at the rear section of the shell 10, and the linkage tube 15 slides and simultaneously drives the unlocking piece 11 to synchronously slide in the cavity at the rear section of the shell 10;

as shown in fig. 1, 5, 6, 10, 12 and 13 of the accompanying drawings, the round bar base 29 is vertically disposed at the lower end of the sub-bar frame 27 and rotatably connected to the lower end of the sub-bar frame 27, and the end of the round bar base 29 is fixedly connected to the turning gear 32, the short round bar portion of the sub-bar frame 27 is vertically disposed on the lower rod portion of the sub-bar frame 27, the turning gear 32 is disposed right below the short round bar portion of the sub-bar frame 27 and is on the same vertical central axis with the short round bar portion of the sub-bar frame 27, since the middle portion of the housing 10 is opened with a placement slot portion, which is disposed corresponding to the frame cavity of the carrying frame 7, the maximum distance between the turning gear 32 and the short round rod part in the auxiliary rod frame 27 is smaller than the depth of the groove part in the shell 10, the diameter of the turning gear 32 is smaller than the width of the groove part in the shell 10, and the funnel groove is arranged at the upper end of the vertical frame body in the support frame 5, the long round rod part in the main rod frame 26 is vertically arranged at the upper end of the main rod frame 26, the material conveying mechanism 21 is movably inserted in the frame cavity of the U-shaped limiting frame 6, so that the short round rod part in the auxiliary rod frame 27 and the turning gear 32 are arranged in the groove part in the shell 10, and the long round rod part in the main rod frame 26 is clamped in the funnel groove in the support frame 5;

because the pipe orifice of the lower end of the main rod frame 26 is inserted and fixedly connected with a ring cover through a bolt, the upper-section rod body of the auxiliary rod frame 27 is connected with the ring cover of the main rod frame 26 in a movable penetrating manner and is inserted in the pipe cavity of the lower section of the main rod frame 26 in a movable state, the upper end of the rod body of the auxiliary rod frame 27 is fixedly connected with a positioning ring through a bolt, the third spring 28 is arranged at the joint of the auxiliary rod frame 27 and the main rod frame 26 and is sleeved on the upper-section rod body of the auxiliary rod frame 27 in a movable state, one end of the third spring 28 is abutted against the ring cover of the main rod frame 26, the other end of the third spring 28 is abutted against the positioning ring of the auxiliary rod frame 27, and after the auxiliary rod frame 27 is arranged, the bolt on the positioning ring is inserted in a strip-shaped chute on the pipe wall of the main rod frame 26 in a movable state, so that the auxiliary rod frame 27 is movably positioned on the main rod frame 26, the front section of the unlocking piece 11 is arranged in an upward inclined state, after the unlocking piece 11 slides, the short round rod part of the auxiliary rod frame 27 presses the auxiliary rod frame down through the inclined end, the inclined side wall of the short rod part of the auxiliary rod frame 11, the elastic support frame 26 slides to limit the vertical deformation of the main rod frame 26, and the elastic support frame 26 slides to enable the elastic support frame 26 to extend out, the main rod frame 26, and the elastic support frame 26 to extend upwards;

because the rear section of the second movable column 13 is arranged in a concave structural state, the left side wall and the right side wall of the opening of the groove in the second movable column 13 are both arranged in a circular arc chamfer structure, the second movable column 13 is arranged below the placing groove part of the shell 10 after sliding, and because the width dimension of the groove in the second movable column 13 is larger than the thickness dimension of the turnover gear 32, the turnover gear 32 is inserted in the groove of the second movable column 13 in a movable state after synchronously moving downwards along with the auxiliary rod frame 27;

referring to fig. 1, 3, 5, 6, 8, 10 and 13, a through hole is opened on the shell wall of the shell in the shell 10, the through hole of the shell 10 and the hemispherical head of the locking element 18 are on the same horizontal central axis, when the linkage tube 15 drives the unlocking element 11 to slide to a specified position, the short circular rod part in the secondary rod frame 27 slides down to the specified position under the pressure of the unlocking element 11, so that the turnover gear 32 is movably positioned in the groove of the second movable column 13, and the locking element 18 corresponds to the through hole of the shell 10, because the head of the locking element 18 departing from the linkage rod 16 is in a hemispherical structure, the locking element 18 is positioned in the groove cavity of the annular cover in the linkage tube 15, the hemispherical head end movably penetrates through a hole groove on the side wall of the linkage pipe 15 to extend to the outside, and because the first spring 19 is arranged at the joint of the locking piece 18 and a ring cover in the linkage pipe 15 and is sleeved on the locking piece 18 in a movable state, one end of the first spring 19 abuts against a middle ring body of the locking piece 18, the other end of the first spring 19 abuts against the wall of the ring cover groove of the linkage pipe 15, the locking piece 18 loses spacing after corresponding to the through hole part of the shell 10, and is reset by utilizing the elastic deformation of the first spring 19, so that the hemispherical head end of the locking piece 18 is inserted into the through hole part of the shell 10, and the cylindrical tail end of the locking piece 18 is not clamped with the front end rod body of the linkage rod 16;

because the front end of the linkage pipe 15 is inserted and fixedly connected with a ring cover through a bolt, after the linkage rod 16 is arranged, the rod body of the linkage rod is connected with the ring cover of the linkage pipe 15 in a movable penetrating mode and is inserted in the pipe cavity of the linkage pipe 15 in a movable state, and because the second spring 20 is arranged at the joint of the linkage rod 16 and the linkage pipe 15 and is sleeved on the rod body of the linkage rod 16 in a movable state, one end of the second spring 20 is propped against the ring cover of the linkage pipe 15, and the other end of the second spring 20 is propped against the end ring body of the linkage rod 16, when the unlocking piece 11 slides at a specified position, the unlocking piece 11 is limited by the strip-shaped sliding groove at the rear section of the shell 10 to stop sliding, so as to limit the movement of the linkage pipe 15, and when the first movable column 12 continuously slides, the linkage rod 16 is driven to slide and extend on the linkage pipe 15, so that the second spring 20 is elastically deformed under stress;

because the driving rack is arranged on the inner wall of the groove at the rear section of the second movable column 13, the driving rack is matched with the turning gear 32, and because the torsion spring 30 is arranged at the rotary joint of the rod body in the rod seat 29 and the auxiliary rod frame 27 and is sleeved on the rod body of the rod seat 29 in a movable state, one end of the torsion spring 30 is hooked on the rod body of the rod seat 29, the other end of the torsion spring 30 is hooked on the groove wall at the lower end of the auxiliary rod frame 27, while the first movable column 12 continuously slides, the second movable column 13 synchronously and continuously slides, so that the driving rack is meshed with the turning gear 32, the turning gear 32 is driven by the driving rack, the rod seat 29 rotates at the lower end of the auxiliary rod frame 27, and the torsion spring 30 is elastically deformed under the stress;

because the round rod seat 29 is fixedly connected with the middle part of the side frame plate of the second U-shaped angle frame 31 to form an integrated structure, the bearing frame 7 is arranged in the support frame 5 in a vertical state vertical to the lower end of the frame body, the material conveying mechanism 21 is movably inserted in the frame cavity of the U-shaped limit frame 6, the second U-shaped angle frame 31 and the bearing frame 7 are correspondingly arranged, and after the auxiliary rod frame 27 slides downwards and extends out, the second U-shaped angle frame 31 is movably inserted in the frame cavity of the bearing frame 7;

because the upper section of the front frame plate in the bearing frame 7 is arranged in a forward inclined state, the lower section of the rear frame plate is arranged in a backward inclined state, the inclined wall of the front frame plate in the bearing frame 7 has the same inclination angle as the inclined wall of the rear frame plate, and the rear section of the feeding frame 8 is arranged in an inclined state, the inclined side wall of the inclined side wall and the inclined side wall of the front frame plate in the bearing frame 7 are positioned on the same plane, a gap is reserved between the inclined side wall and the inclined side wall, the inclination angle of the inclined side wall is the same as the inclination angle of the inclined side wall of the front frame plate in the bearing frame 7, and after the round rod seat 29 rotates, the second U-shaped corner frame 31 is driven to turn over in the frame cavity of the bearing frame 7, so that the front frame plate of the second U-shaped corner frame 31 is attached to the inclined side wall of the front frame plate in the bearing frame 7, the arc-shaped curled edge of the front frame plate in the second U-shaped corner frame 31 is inserted to the gap between the inclined side wall of the front frame plate in the feeding frame 7 and the inclined side wall in the feeding frame 8, and the rear frame plate in the bearing frame 7 is attached to the inclined side wall of the rear frame 7;

because the feeding plate frame 8 is arranged at the front side of the bearing frame 7 and the lower end of the inclined side wall of the feeding plate frame is fixedly connected to the longitudinal pipe frame part of the main chassis 1 through bolts, the front section of the feeding plate frame 8 is arranged in a horizontal state, and because the side edges of the front and rear frame plates and the side edges of the side frame plates in the second U-shaped angle frame 31 are both arranged in an arc-shaped hemming structure state, and the length size of the rear frame plate is larger than that of the front frame plate, the heat-insulating laminate is inserted into the frame cavity of the second U-shaped angle frame 31 along the inclined side wall of the feeding plate frame 8, so that the left corner and the right corner of the lower side edge of the feeding plate frame 8 are respectively clamped in the left and right second U-shaped angle frames 31, the feeding operation of the heat-insulating laminate is completed, and in addition, the horizontal plate surface of the feeding plate frame 8 is used as a placing platform for temporarily placing the heat-insulating laminate;

then, the operation of re-locking the thermal insulation laminate after feeding is performed, according to the above description, as shown in fig. 1, fig. 5, fig. 6, fig. 8, fig. 9 and fig. 13, the first motor 17 drives the first gear 14 to rotate reversely, when the first movable column 12 is reset and slid, the linkage rod 16 is contracted and slid on the linkage pipe 15 by the elastic deformation reset of the second spring 20, when the second movable column 13 is reset and slid, the driving rack drives the reverse gear 32 to rotate reversely, and the second movable column 13 is reset and slid by the elastic deformation of the torsion spring 30, the circular rod seat 29 drives the second U-shaped angle frame 31 to reset and rotate on the sub-rod frame 27, and the second U-shaped angle frame 31 drives the thermal insulation laminate to reset and flip in the frame cavity of the bearing frame 7, because the depth dimension of the frame cavity in the first U-shaped angle frame 24 is smaller than the sliding distance dimension of the sub-rod frame 27, the thermal insulation laminate is supported by the rear frame plate of the second U-shaped angle frame 31, the upper side corresponds to the frame cavity of the first U-shaped angle frame 24, after the second movable column 13 continuously resets and slides, the driving rack loses contact with the turnover gear 32, the turnover gear 32 is movably arranged in the groove of the second movable column 13, after the first movable column 12 continuously resets and slides, the linkage rod 16 is completely contracted into the linkage pipe 15, the linkage pipe 15 is pushed to reset and slide in the pipe shell part of the shell 10, the hemispherical head end of the locking piece 18 is separated from the through hole part of the shell 10, the cylindrical tail end of the locking piece 18 is newly clamped on the front end rod body of the linkage rod 16, after the linkage pipe 15 resets and slides, the unlocking piece 11 is driven to synchronously reset and slide, after the unlocking piece 11 loses contact with the short round rod part of the auxiliary rod frame 27, the elastic deformation of the third spring 28 resets, the auxiliary rod frame 27 is contracted and slides on the main rod frame 26, and drives the second U-shaped angle frame 31 and the heat preservation laminate to move upwards, because the side edge of the front frame plate and the side edge of the side frame plate in the first U-shaped angle frame 24 are both arranged in an arc-shaped curling structure state, under the assistance of arc-shaped curling, the left corner and the right corner of the upper side edge of the heat-insulating layer plate are respectively clamped in the left first U-shaped angle frame 24 and the right first U-shaped angle frame 24, and the relocking of the heat-insulating layer plate after feeding is completed;

finally, a material conveying operation of the insulation laminate is carried out, according to the above, as shown in fig. 1, fig. 2, fig. 10, fig. 11, fig. 13, fig. 14 and fig. 15, a steel wire rope walking device 23 is arranged on a middle reel steel wire rope of the winch 2, wherein a walking device housing 35 is fixedly connected to a middle frame body of the T-shaped connecting frame 22 through bolts, and the walking device housing 35 is provided with a left shell part and a right shell part in half, since a first walking wheel 39 and a second walking wheel 40 which can rotate are sequentially installed in a shell cavity of the walking device housing 35 from top to bottom, and the first walking wheel 39 is formed by combining a walking sheave and a shaft body, a left side wall of the walking sheave in the first walking wheel 39 is provided with a gear part which is concentric with the first walking wheel 39, after the first walking wheel 39 is arranged, the shaft body thereof is fixedly connected to the walking device housing 35 through bolts, and a second walking wheel 40 is similarly formed by combining a walking sheave and a walking sheave, a walking wheel 40 which is vertically arranged on the walking wheel housing, and a walking device housing 35, and a second walking wheel 35 which is vertically arranged on the same central axis, and a walking guide line, and a walking device housing 35 are vertically arranged on the same walking wheel 35, and a walking device housing which is arranged on the same specification, and a walking wheel 35, and a walking device housing which is vertically arranged on the same axis, and a walking wheel 35, and a walking device housing which is vertically arranged on the same walking wheel 35, and a walking device housing which is vertically arranged on the same walking wheel 35, a middle reel steel wire rope of the winch 2 penetrates into a shell cavity of the walking device shell 35 from a tube cavity of the lower guide tube 36, and then sequentially winds a lower guide sheave of the walking device shell 35, a second walking wheel 40, a first walking wheel 39 and an upper guide sheave of the walking device shell 35 from bottom to top and penetrates out from a tube cavity of the upper guide tube 36;

because the second gear 42 is fixed on the output end of the second motor 41, and is placed in the gap between the first traveling wheel 39 and the second traveling wheel 40, its upper side is meshed with the gear portion of the first traveling wheel 39, its lower side is meshed with the gear portion of the second traveling wheel 40, and the second motor 41 is fixedly mounted on the side wall of the left shell portion of the traveling device shell 35, and because the wire winding disk 37 is movably sleeved on the shaft body of the second traveling wheel 40, and is placed in the box cavity of the right shell portion of the traveling device shell 35, and is fixed on the right side wall of the second traveling wheel 40, and the conductive ring is arranged on the left side of the wire winding disk 37, one end of the wire in the wire winding disk 37 is in circuit connection with the conductive ring, and the other end of the wire in the wire winding disk 37 is inserted through the slotted hole of the traveling device shell 35 to form circuit connection with the control box, the conductive disc 38 is covered outside the conductive ring in the wire winding disc 37 after being placed, and is fixedly installed on the right shell part of the traveling device shell 35, the conductive disc 38 is internally provided with an electric brush, the electric brush is matched with the conductive ring to conduct current, which is described in detail in the attached drawings of the specification, and the second motor 41 is in circuit connection with the conductive disc 38 through a wire, the second motor 41 is driven by a control box, the first traveling wheel 39 and the second traveling wheel 40 are driven by a second gear 42 to rotate synchronously, the steel wire rope traveling device 23 is driven to ascend on a middle winding drum steel wire rope of the winding machine 2 by virtue of friction force among the first traveling wheel 39, the second traveling wheel 40 and the steel wire rope, the second traveling wheel 40 rotates and simultaneously drives the wire winding disc 37 to rotate synchronously, and the wire is unwound in the ascending process of the steel wire rope traveling device 23;

because the wide-head through groove of the long round rod part in the main rod frame 26 is connected with the guide sheave in a rotating way, and the left reel steel wire rope and the right reel steel wire rope in the winch 2 respectively pass through the long round rod part through groove of the left main rod frame 26 and the long round rod part through groove of the right main rod frame 26 through the guide sheave assistance, the stable lifting of the material conveying mechanism 21 is ensured through the assistance of the left reel steel wire rope and the right reel steel wire rope, and because the frame cavity of the bearing frame 7 and the frame cavity of the U-shaped limiting frame 6 are arranged up and down correspondingly, the side edge of the rear frame plate in the bearing frame 7 is arranged in an arc-shaped curling structural state, the upper and lower side walls of the front frame plate in the U-shaped limiting frame 6 and the upper and lower side walls of the rear frame plate are arranged in a semicircular structural state, and the supporting plate part of the second connecting plate 34 is arranged in a vertical bending state in the middle part, a through positioning hole is formed in the center of the lower guide pipe 36, when the material conveying mechanism 21 is landed and recovered, the end of the lower guide pipe 36 is in a conical structure, the lower guide pipe 36 is movably inserted into the through positioning hole of the middle supporting plate part of the second connecting plate 34, and then the left reel steel wire rope and the right reel steel wire rope are combined to ensure that the material conveying mechanism 21 is accurately put into a frame cavity of the U-shaped limiting frame 6 after being recovered, after the material conveying mechanism 21 is completely recovered, the supporting plate part of the second connecting plate 34 is attached to the lower side of the walking device shell 35, the wide-head side wall of the long circular rod part in the left main rod frame 26 and the wide-head side wall of the long circular rod part in the right main rod frame 26 are respectively attached to and abutted against the vertical frame side wall of the left supporting frame 5 and the vertical frame side wall of the right supporting frame 5, and accurate positioning after the material conveying mechanism 21 is recovered is further ensured;

according to the attached drawings 10 and 13, after the material feeding mechanism 21 finishes feeding, the wire rope walking device 23 is fixed on the middle reel wire rope of the winch 2 by using friction force, and when the material taking operation is performed, according to the above, the heat preservation laminate is manually pressed downwards, the auxiliary rod frame 27 slides downwards and extends out on the main rod frame 26, and drives the second U-shaped angle frame 31 to move downwards, the upper side edge of the heat preservation laminate loses contact with the first U-shaped angle frame 24, the heat preservation laminate is turned over, the second U-shaped angle frame 31 is turned over on the auxiliary rod frame 27 by the aid of the round rod seat 29, the heat preservation laminate is correspondingly lost with the first U-shaped angle frame 24, the heat preservation laminate is pulled out to finish material taking, and the return shrinkage of the auxiliary rod frame 27 and the return turning over of the second U-shaped angle frame 31 are sequentially completed by the elastic deformation return of the third spring 28 and the torsion spring 30;

the working principle is summarized as follows: after the adjustment and placement of the building outer wall heat insulation layer construction device are completed, firstly, the unlocking operation of the clamping mechanism in the material conveying mechanism 21 is carried out through the unlocking mechanism 9, the first gear 14 drives the first movable column 12 and the second movable column 13 to slide, when the first movable column 12 slides with the second movable column 13, the concave end of the second movable column 13 slides to the lower part of the placement groove part of the shell 10, the unlocking piece 11 presses the short round rod part of the auxiliary rod frame 27 downwards through the linkage of the linkage pipe 15 and the linkage rod 16, the auxiliary rod frame 27 slides and extends on the main rod frame 26 to drive the second U-shaped angle frame 31 to be movably inserted into the frame cavity of the bearing frame 7 and drive the turnover gear 32 to be movably inserted into the groove of the second movable column 13, and after the first movable column 12 and the second movable column 13 continuously slide, the locking piece 18 loses the clamping with the linkage rod 16, the linkage rod 16 slides out of the linkage pipe 15, the second movable column 13 drives the overturning gear 32 through the driving rack to overturn the second U-shaped angle frame 31 after moving downwards, after the second movable column is inserted into the heat preservation layer plate, the first gear 14 drives the first movable column 12 and the second movable column 13 to reset and slide, the overturning gear 32 resets and rotates, after the auxiliary rod frame 27 resets and contracts and slides, the second U-shaped angle frame 31 is reset, overturned, reset and moved upwards, so that the heat preservation layer plate is automatically clamped between the second U-shaped angle frame 31 and the first U-shaped angle frame 24, then the material conveying mechanism 21 is driven by the steel wire rope walking device 23 and assisted by the left winding drum steel wire rope and the right winding drum steel wire rope in the winding machine 2 to climb on the middle winding drum steel wire rope of the winding machine 2 for material conveying, and finally the heat preservation layer plate is pressed and overturned downwards to enable the second U-shaped angle frame 31 to move downwards and overturn, the second U-shaped corner frame 31 and the first U-shaped corner frame 24 lose the clamping of the heat preservation laminate and complete material taking;

this is the whole working process of the construction device for the heat-insulating layer of the outer wall of the building, and the content which is not described in detail in the specification belongs to the prior art which is well known to those skilled in the art.

The standard parts used in the invention can be purchased from the market, the special-shaped parts can be customized according to the description of the specification and the accompanying drawings, the specific connection mode of each part adopts conventional means such as bolts, rivets, welding and the like mature in the prior art, the machines, the parts and equipment adopt conventional models in the prior art, and the circuit connection adopts the conventional connection mode in the prior art, so that the detailed description is omitted.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.

Claims (8)

1. A construction device for a heat-insulating layer of an exterior wall of a building comprises:

the middle of the front section of the main chassis (1) is fixedly provided with a winch (2) through bolts, a left reel steel wire rope, a middle reel steel wire rope and a right reel steel wire rope in the winch (2) are arranged on the main chassis (1) in a vertically upward state under the assistance of guide sheaves, auxiliary chassis (3) capable of being adjusted in a sliding mode are movably arranged on the left side and the right side of the main chassis (1), a fixing bolt for locking is arranged at the sliding connection position of the auxiliary chassis (3) and the main chassis (1), and a caster (4) is fixedly arranged on the lower side wall of the front end and the lower side wall of the rear end of a pipe body part in the auxiliary chassis (3) through bolts;

it is characterized by also comprising:

the support frame (5), the horizontal frame body in the support frame (5) is lapped and fixedly connected to the side wall of the pipe body part in the auxiliary underframe (3) through bolts, the upper end of the vertical frame body in the support frame (5) is vertically provided with a U-shaped limiting frame (6) with an integrated structure, and the lower end of the vertical frame body in the support frame (5) is vertically provided with a bearing frame (7) with an integrated structure;

an upper material plate frame (8) is arranged on the front side of the bearing frame (7), the inclined side wall of the rear section of the upper material plate frame (8) and the inclined side wall of the front frame plate in the bearing frame (7) are positioned on the same plane, and the lower end of the inclined side wall in the upper material plate frame (8) is fixedly connected to the longitudinal pipe frame part of the main chassis (1) through bolts;

the unlocking mechanism (9) is arranged on the upper side wall of a horizontal frame body in the support frame (5), the unlocking mechanism (9) comprises a shell (10), an unlocking piece (11), a first movable column (12), a second movable column (13), a first gear (14), a linkage pipe (15) and a linkage rod (16), the lower side wall of the shell (10) is fixedly connected to the horizontal frame body of the support frame (5) through bolts, a placing groove part of the shell (10) is arranged corresponding to a frame cavity of the bearing frame (7), the unlocking piece (11) is connected in a cavity of the rear section of the shell (10) in a sliding mode, the front section of the unlocking piece (11) is arranged in an upward inclined mode, a first movable column (12) is connected above the cavity of the front section of the shell (10) in a sliding mode, a second movable column (13) is connected below the cavity of the front section of the shell (10) in a sliding mode, a first gear (14) is arranged at a gap between the second movable column (13) and the first movable column (12), a movable shell part of the shell (10) is connected with the linkage pipe cavity of the middle pipe shell (15) through a telescopic pipe, and the linkage pipe (15) is inserted into the linkage pipe cavity of the linkage pipe, and the linkage pipe (16) is inserted into the linkage pipe cavity of the linkage pipe, and the linkage pipe (11), the front end of the linkage rod (16) is fixedly connected with a convex block in the first movable column (12) through a bolt;

a driving rack of an integrated structure is arranged on the inner wall of a groove at the rear section of the second movable column (13), the rack-shaped side wall of the second movable column (13) is meshed and connected with the lower side of the first gear (14), the upper side of the first gear (14) is meshed and connected with the rack-shaped side wall of the first movable column (12), the first gear (14) is fixedly connected to the output end of the first motor (17) through a bolt, and the first motor (17) is fixedly mounted on the side wall of the shell (10) through a bolt;

a locking piece (18) is connected in a groove cavity of the ring cover in the linkage pipe (15) in a sliding mode, a hemispherical head end of the locking piece (18) and a through hole part of the shell (10) are located on the same horizontal central axis, and a first spring (19) is installed at the connecting position of the locking piece (18) and the ring cover in the linkage pipe (15);

a second spring (20) is arranged at the joint of the linkage rod (16) and the linkage pipe (15), and the rod body at the front end of the linkage rod (16) is connected with the cylindrical tail end of the locking piece (18) in a clamping manner;

the device comprises a material conveying mechanism (21), wherein the material conveying mechanism (21) is movably inserted into a frame cavity of a U-shaped limiting frame (6), the material conveying mechanism (21) comprises a T-shaped connecting frame (22), a steel wire rope walking device (23), a first U-shaped angle frame (24), a circular pipe seat (25), a main rod frame (26), an auxiliary rod frame (27), a circular rod seat (29), a second U-shaped angle frame (31) and a turnover gear (32), the steel wire rope walking device (23) is fixedly installed on a frame body in the middle of the T-shaped connecting frame (22), the steel wire rope walking device (23) is installed on a middle reel steel wire rope of a winch (2), a first U-shaped angle frame (24) capable of being adjusted in a sliding mode is movably installed on a left rod body and a right rod body of the T-shaped connecting frame (22), a fixing bolt used for locking is installed at the sliding connection position of the rod body in the first U-shaped angle frame (24) and the T-shaped connecting frame (22), and a middle of the first U-shaped angle frame (25) is connected with a middle of the U-shaped angle frame (24) through a bolt plate (25);

a main rod frame (26) capable of being adjusted in a sliding mode is movably mounted in a tube cavity of the circular tube seat (25), a fixing bolt used for locking is mounted at the sliding connection position of the circular tube seat (25) and the main rod frame (26), an integrated long round rod part is vertically arranged at the upper end of the main rod frame (26), and the end part of the long round rod part in the main rod frame (26) is arranged in a wide structure;

an auxiliary rod frame (27) capable of sliding in a telescopic mode is movably inserted into a tube cavity of the lower section of the main rod frame (26), a third spring (28) is installed at the joint of the auxiliary rod frame (27) and the main rod frame (26), and a short round rod part of an integrated structure is vertically arranged on the rod body of the lower section of the auxiliary rod frame (27);

the lower end of the auxiliary rod frame (27) is rotationally connected with the rod body of the round rod seat (29), a torsion spring (30) is installed at the rotational connection position of the round rod seat (29) and the auxiliary rod frame (27), the round rod seat (29) is fixedly connected to the middle of the side frame plate of the second U-shaped angle frame (31) through a bolt, and the end part of the rod body of the round rod seat (29) is fixedly connected with a turnover gear (32) through a bolt.

2. The construction device of the heat-insulating layer of the external wall of the building as claimed in claim 1, wherein: the movable mounting has first connecting plate (33) that can slide adjusting on the preceding deckle board of "U" shape spacing frame (6), and the sliding connection department of first connecting plate (33) and "U" shape spacing frame (6) installs the gim peg that is used for the locking, movable mounting has second connecting plate (34) that can slide adjusting on the back deckle board of "U" shape spacing frame (6), and sliding connection department of second connecting plate (34) and "U" shape spacing frame (6) installs the gim peg that is used for the locking equally to the middle part of second connecting plate (34) is bent perpendicularly and is provided with the tray portion of integral structure.

3. The construction device of the heat-insulating layer of the external wall of the building as claimed in claim 1, wherein: the lateral wall all is circular arc chamfer structural condition setting about recess opening part in second activity post (13), and the width dimension of recess is greater than the thickness dimension of upset gear (32) in second activity post (13) to the biggest interval size between short round rod portion is less than the degree of depth size of placing the slot part in casing (10) in upset gear (32) and sub-lever frame (27), and the diameter size of upset gear (32) is less than the width dimension of placing the slot part in casing (10).

4. The construction device of the heat-insulating layer of the external wall of the building as claimed in claim 1, wherein: wire rope walking ware (23) are including walking ware shell (35), electric wire rolling dish (37), conducting disc (38), first walking wheel (39), second walking wheel (40), second motor (41) and second gear (42), the equal perpendicular fixed mounting in upper and lower both ends of walking ware shell (35) has stand pipe (36), and the tip of stand pipe (36) under in walking ware shell (35) is the circular cone column structure, the box intracavity of right side shell portion has electric wire rolling dish (37) in walking ware shell (35), and the left side of electric wire rolling dish (37) is provided with conducting disc (38) that are used for power transmission to conducting disc (38) are through bolt fixed mounting on the right side shell portion of walking ware shell (35), the shell intracavity of walking ware shell (35) is last to install first walking wheel (39) and second walking wheel (40) that can rotate in proper order from last down, and the below of second walking wheel (40) and the top of first walking wheel (39) all are provided with the direction, install second walking wheel (41) and go up motor side wall through second fixed mounting in walking ware shell (35), and motor output motor side wall (41).

5. The construction device of the heat-insulating layer of the external wall of the building as claimed in claim 4, wherein: the guide pipe (36) is movably inserted into a through positioning hole of a middle supporting plate part of the second connecting plate (34), the supporting plate part of the second connecting plate (34) is attached to the lower side of the walking device shell (35), the guide pipe (36) is movably sleeved on a middle winding drum steel wire rope of the winch (2), the middle winding drum steel wire rope of the winch (2) sequentially winds a lower guide sheave of the walking device shell (35), a second walking wheel (40), a first walking wheel (39) and an upper guide sheave of the walking device shell (35) from bottom to top, and a left winding drum steel wire rope and a right winding drum steel wire rope in the winch (2) respectively pass through a long round rod part through groove of the left main rod frame (26) and a long round through groove of the right main rod frame (26) in an auxiliary penetrating manner through the guide sheaves;

the end part of a middle reel steel wire rope of the winch (2) is fixedly arranged in the middle of the fixing frame (43), a left reel steel wire rope and a right reel steel wire rope of the winch (2) are respectively and fixedly arranged at the left end and the right end of the fixing frame (43), and the left reel steel wire rope, the middle reel steel wire rope and the right reel steel wire rope of the winch (2) are arranged in a parallel state.

6. The construction device of the heat-insulating layer of the external wall of the building as claimed in claim 4, wherein: the second gear (42) is arranged at the gap between the first travelling wheel (39) and the second travelling wheel (40), the upper side of the second gear (42) is connected with the gear part of the first travelling wheel (39) in a meshing manner, and the lower side of the second gear (42) is connected with the gear part of the second travelling wheel (40) in a meshing manner;

the right side wall of the second travelling wheel (40) is fixedly connected with the wire winding disc (37) through a bolt, and the wire winding disc (37) is driven by the second travelling wheel (40) to form a rotating structure on the conductive disc (38).

7. The construction device of the heat-insulating layer of the external wall of the building as claimed in claim 1, wherein: the long round rod part of the main rod frame (26) is connected with the funnel groove of the support frame (5) in a clamping mode, and the wide-head side wall of the long round rod part in the main rod frame (26) is attached to and abutted against the vertical frame side wall of the support frame (5).

8. A construction method of the construction device of the heat insulating layer of the external wall of the building as claimed in claim 1, characterized in that: the construction method comprises the following steps:

step 1: according to the specification and the size of the heat-insulation layer plate, the whole frame body and the material conveying mechanism (21) in the construction device are sequentially adjusted;

step 2: placing the construction device;

and step 3: the unlocking mechanism (9) drives the second U-shaped angle frame (31) to move downwards and turn over, so that unlocking operation is realized;

and 4, step 4: after the heat preservation laminate is fed, the unlocking mechanism (9) drives the second U-shaped angle frame (31) to reset, move upwards, reset and turn over again, so that the heat preservation laminate is clamped and locked;

and 5: the steel wire rope walking device (23) drives the material conveying mechanism (21) to carry out material conveying operation of the heat insulation laminate.

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