CN212399915U - Annular production line for concrete prefabricated parts - Google Patents

Abstract

The utility model relates to a concrete prefabricated part annular production line, which comprises a flexible curing kiln, a transverse track, a longitudinal track, a movable mould platform, a ferry vehicle and a flexible distributing machine, wherein the transverse track comprises a first track, a second track, a third track and a fourth track which are sequentially arranged in parallel; the flexible curing kiln is composed of a high-position curing kiln, a low-position curing kiln and a pre-curing kiln, wherein the high-position curing kiln, the low-position curing kiln and the pre-curing kiln are parallel to the transverse track, the low-position curing kiln is located between the high-position curing kiln and the pre-curing kiln, the high-position curing kiln is used for curing large-size components and is arranged on the first track in a crossing mode, the low-position curing kiln is used for curing small-size components and is arranged on the second track in a crossing mode, and the pre-curing kiln is used for pre-curing the small. The utility model discloses can carry out two-way annular circulation operation simultaneously, be fit for the production of many grades, big concrete member in batches, the commonality is strong, can effectively improve equipment rate of utilization, increases production efficiency simultaneously.

Description

Annular production line for concrete prefabricated parts

Technical Field

The utility model relates to an assembly type precast concrete building element's production technology specifically is a precast concrete component annular production line.

Background

At the present stage, the production of municipal prefabricated components (including curbstones, frame slope protection retaining walls, prefabricated inspection wells, well covers, stairs, prefabricated rainwater wells and the like) is usually independent mold production, the maintenance mode mainly adopts natural maintenance and simple maintenance, the optimal production frequency is one mold per day, operators need to frequently walk and flow in the whole component workshop, the labor intensity is high, and the efficiency is low. In order to improve efficiency and reduce labor intensity, it is necessary to develop a highly automated production line suitable for municipal prefabricated parts.

At present, for the production line of concrete prefabricated products, a laminated slab production line and a comprehensive wallboard production line are typical. The laminated slab production line is dedicated to producing laminated slabs (commonly called floor slabs); the comprehensive wallboard production line can produce components such as laminated boards, inner walls, outer walls (sandwich wallboards) and the like, but is limited by the material distribution height of a material distributor and the heights of inlets and outlets of a pre-curing kiln and a curing kiln, and the existing production line cannot produce components with too high height such as bay windows and the like. In addition, both the laminated slab production line and the comprehensive production line mainly adopt counterclockwise single circulation, are suitable for producing single varieties, and easily cause product process conflicts on the production line in a single direction when the types of products are more, so that the two production lines have obvious defects.

Disclosure of Invention

The utility model aims at providing a concrete prefabricated component annular production line has combination formula maintenance kiln, the cloth machine of flexible characteristic through the development design to carry out reasonable overall arrangement to the production line, thereby establish a production line that is fit for many grades, big concrete component in batches, the production line has higher commonality, can improve production efficiency by a wide margin.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

an annular production line for precast concrete components comprises a flexible curing kiln, a transverse rail, a longitudinal rail, a movable mould platform, a ferry vehicle and a flexible distributing machine, wherein the transverse rail comprises a first rail, a second rail, a third rail and a fourth rail which are sequentially arranged in parallel, and the lengths of the first rail, the second rail, the third rail and the fourth rail are equal;

the flexible curing kiln consists of a high-position curing kiln, a low-position curing kiln and a pre-curing kiln which are parallel to the transverse track, the low-position curing kiln is positioned between the high-position curing kiln and the pre-curing kiln, the high-position curing kiln for curing the large-sized component spans on the first track, the low-position curing kiln for curing the small-sized component spans on the second track, and the pre-curing kiln for pre-curing the small-sized component spans on the third track;

the transverse tracks also comprise fifth tracks arranged at the right end of the first track at intervals and sixth tracks arranged at the tail ends of the fourth tracks at intervals;

the flexible material distributing machine is arranged at the left end of the sixth rail in a spanning mode, and a first pouring area is arranged below the flexible material distributing machine and used for pouring small and medium-sized components;

the longitudinal rails comprise a rail A, a rail B and a rail C which are arranged in parallel, the rail A is positioned at the left ends of the first rail, the second rail, the third rail and the fourth rail, the rail B is positioned at the right ends of the first rail, the second rail, the third rail and the fourth rail, and the rail C is positioned at the right ends of the fifth rail and the sixth rail;

the ferry vehicle runs on the longitudinal rail, the movable mould platform runs on the transverse rail, and the movable mould platform is switched on the transverse rail through the ferry vehicle;

the high-position curing kiln comprises heat-insulating wall boards, heat-insulating partition boards, lifting devices and sealing devices, wherein the horizontally arranged heat-insulating partition boards are positioned between the heat-insulating wall boards which are arranged in parallel and form a tunnel kiln body together with the heat-insulating wall boards on two sides; the heat preservation baffle be the rectangle flat board, its width is less than the interval between the heat preservation wallboard of both sides, heat preservation baffle bilateral symmetry is equipped with the guiding hole and moves on elevating gear through the guiding hole.

The lifting device of the high-position curing kiln comprises supporting columns, cross rods, a winch, a steel wire rope and a fixed pulley block, wherein the supporting columns are symmetrically arranged on two sides of a first track in the high-position curing kiln, the cross rods used for keeping the supporting columns stable are arranged above the supporting columns, the heat-insulating partition plate is in sliding connection with the supporting columns through guide holes on two sides of the heat-insulating partition plate, the winch is arranged on the heat-insulating partition plate, the steel wire rope A is clockwise wound at one end of a rotating shaft of the winch, the steel wire rope B is anticlockwise wound at the other end of the rotating shaft of the winch, and the other end of the steel wire rope A, B; the fixed pulley group comprises a fixed pulley A arranged on the cross rod and a fixed pulley B arranged on the heat insulation partition board.

The sealing device of the high-position curing kiln comprises L-shaped sliding sealing plates and a driving mechanism, wherein the L-shaped sliding sealing plates are arranged on two sides of the upper surface of the heat-insulation partition plate, each L-shaped sliding sealing plate comprises a transverse plate and a vertical plate, the vertical plates are fixedly connected to one ends of the transverse plates, and the transverse plates are equidistantly provided with the driving mechanisms connected with the heat-insulation partition plate; the driving mechanism comprises a pushing connecting rod, a V-shaped connecting rod, an electric telescopic rod and a buffering compression spring, one end of the electric telescopic rod is hinged to the middle of the heat-insulation partition plate, the other end of the electric telescopic rod is hinged to one end of the V-shaped connecting rod, the bottom of the V-shaped connecting rod is hinged to the heat-insulation partition plate, the other end of the V-shaped connecting rod is hinged to the pushing connecting rod, the buffering compression spring is arranged between the pushing connecting rod and the V-shaped connecting rod, the other end of the pushing connecting rod is hinged to the middle of the upper end face of a transverse plate of the L-shaped sliding sealing plate, the lower end face of the transverse plate of the L-shaped.

The flexible material distributor comprises a rack, an X-axis translation vehicle, a Y-axis translation vehicle and a material box, wherein the rack is composed of two groups of vertical columns which are arranged in parallel along the transverse direction and an X-direction track 601 which is arranged at the top ends of the vertical columns; the feeding box is composed of a fixed box body, a movable box body and a Z-axis driving mechanism, the whole fixed box body is of a rectangular box body structure with an upper opening and a lower opening, the upper end of the rectangular box body structure penetrates through the Y-axis translation vehicle and is fixedly connected with the Y-axis translation vehicle, the lower end of the rectangular box body structure penetrates through the vehicle body of the X-axis translation vehicle and is slidably connected with the upper portion of the movable box body, a feeding port is formed in the lower portion of the movable box body, the Z-axis driving mechanism is symmetrically arranged on two sides of the outer portion of the fixed box body, the upper.

The upper part of the movable box body is of a rectangular box body structure matched with the fixed box body, the lower part of the movable box body is of a funnel-shaped structure with two parallel side surfaces, a stirring device is further arranged in the movable box body, and a motor used for driving the stirring device is arranged outside the movable box body.

The left side of the track A is provided with an empty area A for placing large prefabricated components, and the right side of the track C is provided with an empty area C for placing small and medium-sized components.

And a second pouring area is arranged in the area of the fourth track and is used for pouring the large-scale component.

A circulation area A is arranged between the left end outlet of the flexible curing kiln and the track A, and a circulation area C is arranged between the track B and the track C.

The utility model has the advantages that: the utility model discloses structural configuration is reasonable, can carry out two-way annular circulation operation simultaneously, is fit for the production of many grades, big concrete member in batches, and the commonality is strong, and wherein high-order maintenance kiln can trun into location maintenance kiln according to actual demand and use, can effectively improve equipment rate of utilization, increases production efficiency simultaneously.

Drawings

Fig. 1 is a top view of the overall structure of the present invention.

Fig. 2 is a schematic diagram of the left cycle of the present invention.

Fig. 3 is a right side circulation diagram of the present invention.

Fig. 4 is a schematic cross-sectional view of the flexible curing kiln of the present invention.

FIG. 5 is a partial top view of the high-level curing kiln of the present invention.

FIG. 6 is a schematic sectional view of the elevating device of the high-level curing kiln.

FIG. 7 is a schematic sectional view of a sealing device of the high-level curing kiln.

Fig. 8 is a schematic view of the overall structure of the flexible distributing machine.

Fig. 9 is a partial top view of the flexible distributor.

In the figure, 101, a first track, 102, a second track, 103, a third track, 104, a fourth track, 105, a fifth track, 106 and a sixth track;

201. track a, 202, track B, 203, track C;

3. the high-position maintenance kiln comprises a high-position maintenance kiln 301, heat-insulation wall boards 302, heat-insulation partition boards 303, support columns 304, cross rods 305, a winch 306, steel wire ropes A and 307, steel wire ropes B and 308, fixed pulleys A and 309, fixed pulleys B and 310, an L-shaped sliding sealing plate 311, a pushing connecting rod 312, a V-shaped connecting rod 313, an electric telescopic rod 314, a buffering compression spring 321, transverse plates 321 and 322 and a vertical plate;

4. a low-level curing kiln 5, a pre-curing kiln,

601. the device comprises an X-direction track, 602, a stand column, 603, an X-axis translation vehicle, 631, a Y-direction track, 604, a Y-axis translation vehicle, 605, a material box, 651, a fixed box body, 652, a movable box body, 653, a Z-axis driving mechanism, 654, a feeding port, 655, a stirring device, 656 and a motor;

7. the method comprises the following steps of moving a mold platform, 8, a ferry vehicle, 9, vacant areas A, 10, vacant areas C, 11, a second pouring area, 12, flowing areas A, 13, flowing areas C, 14 and a crown block.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1, an annular production line for precast concrete members comprises a flexible curing kiln, a transverse rail, a longitudinal rail, a movable mold table, a ferry vehicle and a flexible distributing machine, wherein the transverse rail comprises a first rail 101, a second rail 102, a third rail 103 and a fourth rail 104 which are sequentially arranged in parallel, and the lengths of the first rail 101, the second rail 102, the third rail 103 and the fourth rail 104 are equal;

as shown in fig. 1 and 4, the flexible curing kiln is composed of a high-position curing kiln 3, a low-position curing kiln 4 and a pre-curing kiln 5 which are parallel to the transverse rail, the low-position curing kiln 4 is positioned between the high-position curing kiln 3 and the pre-curing kiln 5, the high-position curing kiln 3 for curing large-sized components is arranged on the first rail 101 in a spanning mode, the low-position curing kiln 4 for curing small-sized components is arranged on the second rail 102 in a spanning mode, and the pre-curing kiln 5 for pre-curing the small-sized components is arranged on the third rail 103 in a spanning mode;

as shown in fig. 1, the transverse tracks further include a fifth track 105 disposed at the right end of the first track 101 at intervals, and a sixth track 106 disposed at the end of the fourth track 104 at intervals;

as shown in fig. 1, the flexible material distributing machine is arranged at the left end of the sixth rail 106 in a spanning manner, and a first pouring area is arranged below the flexible material distributing machine for pouring small and medium-sized components;

as shown in fig. 1, the longitudinal rails include a rail a201, a rail B202 and a rail C203 which are arranged in parallel, the rail a201 is located at the left end of the first rail 101, the second rail 102, the third rail 103 and the fourth rail 104, the rail B202 is located at the right end of the first rail 101, the second rail 102, the third rail 103 and the fourth rail 104, and the rail C203 is located at the right end of the fifth rail 105 and the sixth rail 106;

as shown in fig. 1, the ferry vehicle 8 runs on a longitudinal track, the movable mold table 7 runs on a transverse track, and the movable mold table 7 is switched on the transverse track through the ferry vehicle 8;

as shown in fig. 5, 6 and 7, the high-position curing kiln 3 includes heat-insulating wall boards 301, heat-insulating partition boards 302, a lifting device and a sealing device, the horizontally arranged heat-insulating partition boards 302 are located between the heat-insulating wall boards 301 arranged in parallel and form a tunnel kiln body with the heat-insulating wall boards 301 at two sides, the lifting device is arranged in the kiln body, the heat-insulating partition boards 302 are arranged between the heat-insulating wall boards 301 at two sides in a lifting manner through the lifting device, and the openable sealing devices are arranged between the heat-insulating partition boards 302 and the heat-insulating wall boards 301 at two sides; the heat preservation baffle 302 be the rectangle flat board, its width is less than the interval between the heat preservation wallboard 301 of both sides, heat preservation baffle 302 bilateral symmetry is equipped with the guiding hole and moves on elevating gear through the guiding hole.

As shown in fig. 5, 6 and 7, the lifting device of the high-level curing kiln 3 comprises support columns 303, cross bars 304, a winch 305, a steel wire rope and a fixed pulley block, wherein the support columns 303 are symmetrically arranged at two sides of the first track 101 in the high-level curing kiln, the cross bars 304 for keeping the support columns 303 stable are arranged above the support columns 303, the heat-insulating partition plate 302 is slidably connected with the support columns 303 through guide holes at two sides of the heat-insulating partition plate 302, the winch 305 is arranged on the heat-insulating partition plate 302, the steel wire rope a306 is clockwise wound at one end of a rotating shaft of the winch 305, the steel wire rope B307 is counterclockwise wound at the other end of the rotating shaft of the winch 305, and the other ends of the steel wire rope a306 and the steel wire rope; the fixed pulley group comprises a fixed pulley A308 arranged on the cross bar 304 and a fixed pulley B309 arranged on the heat insulation partition 302.

As shown in fig. 5, 6 and 7, the sealing device of the high-level curing kiln 3 comprises L-shaped sliding sealing plates 310 and driving mechanisms, the L-shaped sliding sealing plates 310 are arranged on two sides of the upper surface of the heat-insulating partition plate 302, the L-shaped sliding sealing plates 310 comprise transverse plates 321 and vertical plates 322, the vertical plates 322 are fixedly connected to one ends of the transverse plates 321, and the transverse plates 321 are equidistantly provided with the driving mechanisms connected with the heat-insulating partition plate 302; the driving mechanism comprises a pushing connecting rod 311, a V-shaped connecting rod 312, an electric telescopic rod 313 and a buffering compression spring 314, one end of the electric telescopic rod 313 is hinged to the middle of the heat-insulating partition plate 302, the other end of the electric telescopic rod is hinged to one end of the V-shaped connecting rod 312, the bottom of the V-shaped connecting rod 312 is hinged to the heat-insulating partition plate 302, the other end of the V-shaped connecting rod 312 is hinged to the pushing connecting rod 311, the buffering compression spring 314 is arranged between the pushing connecting rod 311 and the V-shaped connecting rod 312, the other end of the pushing connecting rod 311 is hinged to the middle of the upper end face of the transverse plate 321 of the L-shaped sliding sealing plate 310, the lower end face of the transverse plate 321 of the L-shaped sliding sealing plate 310 is.

As shown in fig. 1, 8 and 9, the flexible material distributing machine includes a frame, an X-axis translational vehicle 603, a Y-axis translational vehicle 604 and a material box 605, the frame is composed of upright posts 602 arranged at two sides of a sixth rail 106 in parallel and an X-axis rail 601 arranged at the top ends of the upright posts 602, a vehicle body of the X-axis translational vehicle 603 is a rectangular frame structure, parallel Y-axis rails 631 are arranged on the vehicle body, the X-axis translational vehicle 603 runs on the X-axis rails 601 of the frame, and the Y-axis translational vehicle 604 runs on the Y-axis rails 631 of the X-axis translational vehicle 603; the material box 605 is composed of a fixed box body 651, a movable box body 652 and a Z-axis driving mechanism 653, the fixed box body 651 is integrally of a rectangular box body structure with an upper opening and a lower opening, the upper end of the fixed box body 651 penetrates through the Y-axis translation vehicle 604 and is fixedly connected with the Y-axis translation vehicle 604, the lower end of the fixed box body passes through the vehicle body of the X-axis translation vehicle 603 and is in sliding connection with the upper part of the movable box body 652, the lower part of the movable box body 652 is provided with a feeding port 654, the Z-axis driving mechanisms 653 are symmetrically arranged on two sides of the outer part of the fixed box body 651, the upper end of.

As shown in fig. 8 and 9, the upper portion of the movable box 652 is a rectangular box structure adapted to the fixed box 651, the lower portion of the movable box 652 is a funnel structure with two parallel sides, a stirring device 655 is further disposed in the movable box 652, and a motor 656 for driving the stirring device 655 is disposed outside the movable box 652.

As shown in fig. 1, the left side of the track a201 is provided with an empty area a9 for placing large prefabricated components, and the right side of the track C is provided with an empty area C10 for placing small and medium-sized components.

As shown in fig. 1, the fourth track 104 is provided with a second casting area 11 in an area thereof for casting a large member. Here, since the height of the component to be cast is greater than the feeding height of the flexible concrete feeder, the overhead traveling crane or the crane is used for hoisting the feeding hopper for casting and feeding, and the manual operation is mainly performed.

As shown in FIG. 1, a circulation zone A12 is arranged between the outlet at the left end of the flexible curing kiln and the track A201, and a circulation zone C13 is arranged between the track B202 and the track C203.

The utility model discloses a whole operation still includes general equipment such as overhead traveling crane 14, is not being repeated at the time one by one.

The principle of the utility model is as follows:

1. the production of the left large member is in a counterclockwise circulation, as shown by an arrow in fig. 2, and the specific process flow is as follows:

the components are steamed and cured in the high-position curing kiln 3 for 5 to 8 hours (the main factor of curing time of the prefabricated components is according to the thickness of the components and the mix proportion of concrete), and then taken out of the kiln, and the components are conveyed to one of four vacant areas A9 on the left side of the production line by a movable mold platform 7 communicated with the components by using a ferry vehicle 8 on a track A201;

after the movable mould table 7 is in place, removing the mould, demoulding, cleaning the mould, coating a demoulding agent, assembling the mould, arranging the ribs and installing the embedded parts, and completing the whole process from removing the mould to pouring in 3 hours;

the movable mould table 8 is transported to the fourth track 104 by the ferry vehicle 8 and moves rightwards, and the reinspection check before pouring is carried out;

after the re-inspection is finished, the concrete flows to the right, and pouring and vibrating operation is carried out in a second pouring area;

after pouring and vibrating, moving the movable mould platform 7 to the track B202, and conveying the movable mould platform 7 into the high-level curing kiln 3 for curing by using a ferry vehicle 8 on the track B202; the time consumption is different according to the size and the volume of the component, and the maintenance time is 8 hours by taking a prefabricated catch basin as an example.

2. The production of the small and medium-sized components on the right side is clockwise circulation, as shown by the arrow in fig. 3, the specific process flow is as follows:

the component is taken out of the kiln after being steamed and cured for 5 to 6 hours in the low-position curing kiln 4, and the component is communicated with the movable mould platform 7 and is transported to one of two vacant areas C10 on the right side of the production line by using a ferry vehicle 8 on a track B202;

after the movable mould table 7 is in place, removing the mould, demoulding, cleaning the mould, coating a demoulding agent, assembling the mould, arranging the ribs and installing the embedded parts, and completing the whole process from removing the mould to pouring in 2 hours;

the movable mould table 7 is rotated to the fourth track 104 by using the ferry vehicle 8 on the track C203, and is moved leftwards, and the reinspection check before pouring is carried out;

after the re-inspection is finished, the materials are continuously circulated leftwards and enter a first pouring area below the flexible material distributor to be poured and vibrated;

after pouring and vibrating, the movable mould platform 7 is operated to the left end of the fourth track 104, and the materials are sent into the pre-curing kiln 5 by the ferry vehicle 8 on the track B for pre-curing.

After precuring is finished, the movable mould platform is moved leftwards, the calendaring and surface collecting operation is carried out in the flowing area A, after finishing, the transverse ferry vehicle 8 on the track A201 is used for rotating to the low-level curing kiln 4, and the low-level curing kiln 4 is sequentially fed for curing; according to different component structures, beats are different, and taking the ecological slope protection as an example, the maintenance time is 5 hours.

In a specific embodiment of the present invention, the flexible curing kiln is a combined high-low kiln, as shown in fig. 4, the structure of the flexible curing kiln is a steel structure integrated kiln, and in order to realize energy saving and universality, three longitudinal curing kilns are isolated by using heat insulation boards with the thickness of 100 mm; sending the components (such as a water falling well) with the height of more than 1.5m into the high-level curing kiln; the low-level curing kiln produces components with height less than 1.5m, such as stairs; the precuring kiln can be used for accelerating the initial setting of the concrete on the outer surface of the member with the thickness less than 1.5 m.

The three kilns can set the temperature and the humidity according to the actual conditions to realize the switching of the curing and pre-curing functions; wherein, the curing temperature control range is as follows: 50-65 ℃, humidity control range: 90% -100% and a precuring temperature control range: 30-40 ℃.

The heat-insulating partition board of the high-level curing kiln is used as a ceiling, automatic lifting can be realized, the curing space is reduced, and energy consumption is reduced under the condition of ensuring the curing effect.

The flexible material distributor is also one of key devices of the invention, and in order to meet the material distribution requirements of municipal components, the maximum lifting stroke distance of the mould table is 0.85 m; the conventional cloth with the height of 500mm at most is lifted to 850mm by lifting the frame of the cloth machine and arranging a liftable material box.

By using the technical scheme provided by the invention, 1 mould per day can be changed into 2-3 moulds per day according to different products, and the work efficiency is greatly improved.

In an embodiment of the present invention, the annular production line configuration device is as shown in table one:

table one:

according to the technical scheme provided by the utility model, medium-power project Luoyang fabricated building science and technology Limited receives the customer order in 3 months of 2020, and 1400 ecological revetments are required to be delivered in 20 days, and only 40 ecological revetments can be produced every day by using 40 sets of moulds according to the conventional production scheme in the past; after the invention is applied, 80 ecological revetments are produced in daily life by changing the curing height of the high-level curing kiln and using the high-level curing kiln and the low-level curing kiln, thereby becoming a classic case for cost reduction and efficiency improvement.

The part of the utility model not detailed is prior art.

Claims (8)

1. An annular production line for precast concrete components comprises a flexible curing kiln, a transverse rail, a longitudinal rail, a movable mould platform, a ferry vehicle and a flexible distributing machine, wherein the transverse rail comprises a first rail (101), a second rail (102), a third rail (103) and a fourth rail (104) which are sequentially arranged in parallel, and the lengths of the first rail (101), the second rail (102), the third rail (103) and the fourth rail (104) are equal; the method is characterized in that:

the flexible curing kiln consists of a high-position curing kiln (3), a low-position curing kiln (4) and a pre-curing kiln (5), wherein the high-position curing kiln (3), the low-position curing kiln (4) and the pre-curing kiln (5) are parallel to the transverse track, the high-position curing kiln (3) for curing large-sized components is arranged on the first track (101) in a crossing manner, the low-position curing kiln (4) for curing small-sized components is arranged on the second track (102) in a crossing manner, and the pre-curing kiln (5) for pre-curing small-sized components is arranged on the third track (103) in a crossing manner;

the transverse tracks also comprise fifth tracks (105) arranged at the right end of the first track (101) at intervals and sixth tracks (106) arranged at the tail ends of the fourth tracks (104) at intervals;

the flexible material distributing machine is arranged at the left end of the sixth track (106) in a spanning mode, and a first pouring area is arranged below the flexible material distributing machine and used for pouring small and medium-sized components;

the longitudinal rails comprise a rail A (201), a rail B (202) and a rail C (203) which are arranged in parallel, the rail A (201) is positioned at the left ends of the first rail (101), the second rail (102), the third rail (103) and the fourth rail (104), the rail B (202) is positioned at the right ends of the first rail (101), the second rail (102), the third rail (103) and the fourth rail (104), and the rail C (203) is positioned at the right ends of the fifth rail (105) and the sixth rail (106);

the ferry vehicle (8) runs on the longitudinal track, the movable mould platform (7) runs on the transverse track, and the movable mould platform (7) is switched on the transverse track through the ferry vehicle (8);

the high-position curing kiln (3) comprises heat-insulating wall boards (301), heat-insulating partition boards (302), a lifting device and sealing devices, wherein the horizontally arranged heat-insulating partition boards (302) are positioned between the heat-insulating wall boards (301) which are arranged in parallel and form a tunnel kiln body together with the heat-insulating wall boards (301) on the two sides, the lifting device is arranged in the kiln body, the heat-insulating partition boards (302) are arranged between the heat-insulating wall boards (301) on the two sides in a lifting manner through the lifting device, and the openable sealing devices are arranged between the heat-insulating partition boards (302) and the heat-insulating wall boards (301) on the two; the heat preservation baffle (302) be the rectangle flat board, its width is less than the interval between both sides heat preservation wallboard (301), heat preservation baffle (302) bilateral symmetry is equipped with the guiding hole and moves on elevating gear through the guiding hole.

2. The endless production line for precast concrete members according to claim 1, wherein: the lifting device of the high-position curing kiln (3) is composed of supporting columns (303), cross rods (304), a winch (305), steel wire ropes and a fixed pulley block, the supporting columns (303) are symmetrically arranged on two sides of a first rail (101) in the high-position curing kiln, the cross rods (304) used for keeping the supporting columns (303) stable are arranged above the supporting columns (303), the heat-insulating partition plate (302) is in sliding connection with the supporting columns (303) through guide holes on two sides of the heat-insulating partition plate (302), the winch (305) is arranged on the heat-insulating partition plate (302), one end of a rotating shaft of the winch (305) is clockwise wound with the steel wire ropes A (306), the other end of the rotating shaft of the winch (305) is anticlockwise wound with the steel wire ropes B (307), and the other ends of the steel wire ropes A (306) and the steel wire; the fixed pulley group comprises a fixed pulley A (308) arranged on the cross rod (304) and a fixed pulley B (309) arranged on the heat-insulating partition board (302).

3. The endless production line for precast concrete members according to claim 1, wherein: the sealing device of the high-position curing kiln (3) is composed of L-shaped sliding sealing plates (310) and a driving mechanism, the L-shaped sliding sealing plates (310) are arranged on two sides of the upper surface of the heat-insulating partition plate (302), the L-shaped sliding sealing plates (310) are composed of transverse plates (321) and vertical plates (322), the vertical plates (322) are fixedly connected to one ends of the transverse plates (321), and the transverse plates (321) are equidistantly provided with the driving mechanism connected with the heat-insulating partition plate (302); the driving mechanism comprises a pushing connecting rod (311), a V-shaped connecting rod (312), an electric telescopic rod (313) and a buffering compression spring (314), one end of the electric telescopic rod (313) is hinged to the middle of the heat-insulating partition plate (302), the other end of the electric telescopic rod is hinged to one end of the V-shaped connecting rod (312), the bottom of the V-shaped connecting rod (312) is hinged to the heat-insulating partition plate (302), the other end of the V-shaped connecting rod (312) is hinged to the pushing connecting rod (311), the buffering compression spring (314) is arranged between the pushing connecting rod (311) and the V-shaped connecting rod (312), the other end of the pushing connecting rod (311) is hinged to the middle of the upper end face of the transverse plate (321) of the L-shaped sliding sealing plate (310), and the, the lower end surface of the transverse plate (321) and the upper end surface of the heat-insulating partition plate (302) form a seal, and the side end surface of the vertical plate (322) and the heat-insulating wall plate (301) form a seal.

4. The endless production line for precast concrete members according to claim 1, wherein: the flexible material distributing machine comprises a rack, an X-axis translation vehicle (603), a Y-axis translation vehicle (604) and a material box (605), wherein the rack is composed of upright columns (602) arranged on two sides of a sixth rail (106) in parallel and an X-direction rail (601) arranged at the top end of the upright column (602), a vehicle body of the X-axis translation vehicle (603) is of a rectangular frame structure, parallel Y-direction rails (631) are arranged on the vehicle body of the X-axis translation vehicle, the X-axis translation vehicle (603) runs on the X-direction rails (601) of the rack, and the Y-axis translation vehicle (604) runs on the Y-direction rails (631) of the X-axis translation vehicle (603); the feeding box (605) is composed of a fixed box body (651), a movable box body (652) and a Z-axis driving mechanism (653), the whole fixed box body (651) is of a rectangular box body structure with an upper opening and a lower opening, the upper end of the fixed box body (651) penetrates through the Y-axis translation vehicle (604) and is fixedly connected with the Y-axis translation vehicle (604), the lower end of the fixed box body (651) penetrates through the vehicle body of the X-axis translation vehicle (603) and is in sliding connection with the upper portion of the movable box body (652), a feeding port (654) is formed in the lower portion of the movable box body (652), the Z-axis driving mechanism (653) is symmetrically arranged on two outer sides of the fixed box body (651), the upper end of the Z-axis driving mechanism (653).

5. The endless production line for concrete precast elements according to claim 4, wherein: the upper part of the movable box body (652) is a rectangular box body structure matched with the fixed box body (651), the lower part of the movable box body (652) is a funnel-shaped structure with two parallel side surfaces, a stirring device (655) is further arranged in the movable box body (652), and a motor (656) for driving the stirring device (655) is arranged outside the movable box body (652).

6. The endless production line for precast concrete members according to claim 1, wherein: the left side of the track A (201) is provided with an empty area A (9) for placing large prefabricated components, and the right side of the track C (203) is provided with an empty area C (10) for placing small and medium-sized components.

7. The endless production line for precast concrete members according to claim 1, wherein: and a second pouring area (11) is arranged in the area of the fourth track (104) and is used for pouring large-scale components.

8. The endless production line for precast concrete members according to claim 1, wherein: a circulation area A (12) is arranged between the left end outlet of the flexible curing kiln and the track A (201), and a circulation area C (13) is arranged between the track B (202) and the track C (203).

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