CN118082067A - Dry forming equipment is used in geomembrane production - Google Patents

Abstract

The invention belongs to the technical field of geomembrane production, and discloses drying and forming equipment for geomembrane production, which has the technical points that: including the workstation, workstation surface fixed mounting has the riser, be provided with geomembrane body between two sets of risers, two sets of risers are provided with flattening mechanism jointly, flattening mechanism is including hot-pressing roller and rotating assembly, two sets of riser top fixed mounting have the roof jointly, roof surface mounting has the air heater, the air heater has the blowing pipe through the pipe connection, be provided with positioning mechanism between two sets of risers, positioning mechanism is including supporting component and reciprocal translation subassembly, be provided with the blast mechanism with geomembrane body mutually supporting between two sets of risers, blast mechanism is including direction subassembly and blast subassembly, the current geomembrane is in the removal in-process, the hot-blast contact time that the membrane body surface and hot-blast pipe blown out is shorter, the drying mode of blowing is comparatively single, lead to the relatively poor problem of dry shaping effect of geomembrane.

Description

Dry forming equipment is used in geomembrane production

Technical Field

The invention relates to the technical field of geomembrane production, in particular to drying and forming equipment for geomembrane production.

Background

The geomembrane is a waterproof barrier material with high molecular polymer as basic raw material. The method mainly comprises the following steps: low density polyethylene geomembranes, high density polyethylene geomembranes, and EVA geomembranes. The geomembrane has excellent environmental stress cracking resistance, excellent chemical corrosion resistance, a larger service temperature range and longer service life, and is widely applied to construction of construction sites.

In the production of geomembranes, it is necessary to dry-mold the geomembrane. Currently, the just produced geomembrane is usually dried by blowing on both sides of the geomembrane.

When the existing drying equipment is used, the hot air pipe is usually and directly fixedly arranged on the equipment, the hot air contact time between the surface of the geomembrane and the hot air blown out by the hot air pipe is shorter in the moving process of the geomembrane, and the drying mode of the hot air is single, so that the drying and forming effects of the geomembrane are poorer.

Disclosure of Invention

The invention aims to provide a drying and forming device for producing a geomembrane, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions:

The utility model provides a dry former for geomembrane production, which comprises a workbench, workstation surface fixed mounting has two sets of relatively distributed risers, be provided with the geomembrane body between two sets of risers, two sets of risers are provided with the mechanism of flattening mutually supporting with the geomembrane body jointly, the mechanism of flattening is including hot press roller and rotating assembly, the hot press roller is provided with two sets of and is located geomembrane body upper and lower both sides respectively, rotating assembly is located between two sets of risers and is connected with the hot press roller, rotating assembly is used for controlling two sets of hot press roller and rotates along opposite direction, two sets of riser tops are fixed mounting jointly has the roof, roof surface and workstation diapire are fixed mounting respectively the air heater, the air heater is provided with the blowing pipe through the pipe connection, be provided with the positioning mechanism mutually supporting with the blowing pipe between two sets of risers, the positioning mechanism comprises a supporting component and a reciprocating translation component, the supporting component is positioned between two groups of risers and is connected with the blowing pipes, the supporting component is used for controlling the two groups of blowing pipes to be respectively positioned at the upper side and the lower side of the geomembrane body, the reciprocating translation component is positioned on the side walls of the risers and is connected with the supporting component, the reciprocating translation component controls the blowing pipes to reciprocate between the two groups of risers along the direction parallel to the geomembrane body in a manner of being mutually matched with the supporting component, a blowing mechanism which is mutually matched with the geomembrane body is arranged between the two groups of risers, the blowing mechanism comprises a guiding component and a blowing component, the guiding component is positioned between the two groups of risers and is in contact with the geomembrane body, the guiding component is used for changing the advancing track of the geomembrane body, the blowing component is positioned between the two groups of risers and is connected with the reciprocating translation component, the blowing component is used for blowing the two sides of the geomembrane body in a mode of being matched with the guiding component.

As a further scheme of the invention: the rotating assembly comprises two groups of rotating rods which are rotatably arranged between the two groups of vertical plates, the hot pressing roller is fixedly arranged on the surface of the rotating rods, one end of each rotating rod extends to the outer sides of the vertical plates and is fixedly connected with a transmission fluted disc, the two groups of transmission fluted discs are meshed with each other, and the end part of one group of rotating rods is connected with a first motor.

As a further scheme of the invention: the support assembly comprises slide ways which are arranged on the surfaces of two groups of vertical plates, the slide ways are provided with two rows and are respectively arranged on the upper side and the lower side of the vertical plates, the two groups of slide ways which are distributed on the surfaces of the two groups of vertical plates are connected with bearing posts in a sliding mode along the horizontal direction, the blowing pipe is fixedly arranged on the side wall surface of the bearing posts, which faces the geomembrane body, and the bearing posts are connected with the reciprocating translation assembly.

As a further scheme of the invention: the reciprocating translation assembly comprises two groups of vertical plates, two side walls of the two groups of vertical plates are respectively rotatably mounted, a control plate is fixedly mounted on the surface of the rotating shaft, the control plate is of a strip-shaped structure, first guide grooves are respectively formed in the upper end and the lower end of the control plate, first guide posts are fixedly mounted at the end parts of the bearing posts, the first guide posts are inserted into the first guide grooves, fixing plates are respectively rotatably mounted on the surfaces of the two groups of vertical plates, second guide grooves located on the outer sides of the fixing plates are formed in the surfaces of the control plate, second guide posts are fixedly mounted at the eccentric positions of the surfaces of the fixing plates, the second guide posts are inserted into the second guide grooves, transmission shafts are jointly rotatably mounted on the two groups of vertical plates, gear rings are fixedly mounted on the surfaces of the fixing plates, fixing fluted discs are in meshed connection with the gear rings, and one ends of the transmission shafts extend to the outer sides of the vertical plates and are connected with second motors.

As a further scheme of the invention: the guide assembly comprises first guide rods rotatably arranged between two groups of vertical plates, the first guide rods are provided with two groups, two groups of second guide rods are rotatably arranged between the two groups of vertical plates, the two groups of second guide rods are positioned between the two groups of first guide rods, the two groups of second guide rods are respectively positioned on the upper side and the lower side of the first guide rods, and the geomembrane body sequentially penetrates through the surfaces of the first guide rods and the second guide rods from left to right.

As a further scheme of the invention: the blowing assembly comprises rotating rods which are rotatably arranged between two groups of vertical plates, the rotating rods are provided with two groups and are respectively positioned at two sides of the geomembrane body, the rotating rods are positioned at the bending part of the geomembrane body, a plurality of groups of fan blades which are distributed in parallel are arranged on the surface of the rotating rods, synchronous fluted discs are respectively and fixedly arranged on the surfaces of the rotating rods and the transmission shaft, and the synchronous fluted discs are jointly connected with synchronous belts.

As still further aspects of the invention: and a limiting rod distributed along the horizontal direction is fixedly arranged in the slideway and is in sliding connection with the bearing column.

Compared with the prior art, the invention has the beneficial effects that: by arranging the supporting component and the reciprocating translation component to be matched with each other, the contact area and the contact time between hot air blown by the blowing pipe and the surface of the geomembrane body can be effectively increased, and the drying and forming effects of the geomembrane body are effectively improved; through setting up direction subassembly and the subassembly mutually supporting of blowing, can carry out dry treatment of blowing many times to the geomembrane body, further improve the drying effect. The problem of present geomembrane at the removal in-process, the hot-blast contact time that the membranous surface and hot-blast tuber pipe blow out is shorter, and the drying mode of blowing is comparatively single, leads to the drying shaping effect of geomembrane relatively poor is solved.

Drawings

Fig. 1 is a schematic perspective view of a dry forming device for geomembrane production according to an embodiment of the present invention.

Fig. 2 is a schematic diagram of a carrying column and its structure in a drying and forming apparatus for geomembrane production according to an embodiment of the present invention.

Fig. 3 is a schematic diagram of a geomembrane body and a connection structure thereof in a drying and forming apparatus for geomembrane production according to an embodiment of the present invention.

Fig. 4 is a schematic plan view of a dry forming apparatus for geomembrane production according to an embodiment of the present invention.

Fig. 5 is a schematic diagram of a control board and a connection structure thereof in a drying and forming device for geomembrane production according to an embodiment of the present invention.

Wherein: 1-workbench, 2-riser, 3-flattening mechanism, 31-hot press roller, 32-rotating component, 321-rotating rod, 322-transmission fluted disc, 323-first motor, 4-roof, 5-air heater, 6-blowing pipe, 7-positioning mechanism, 71-supporting component, 711-slide, 712-bearing column, 72-reciprocating translation component, 721-rotating shaft, 722-control panel, 723-first guide groove, 724-first guide column, 725-fixed disc, 726-second guide groove, 727-second guide column, 728-transmission shaft, 729-gear ring, 720-fixed fluted disc, 7211-second motor, 8-blowing mechanism, 81-guide component, 811-first guide rod, 812-second guide rod, 82-blowing component, 821-rotating rod, 822-fan blade, 823-synchronous fluted disc, 824-synchronous belt, 9-geomembrane body, 10-limiting rod.

Detailed Description

It should be noted that, without conflict, the embodiments of the present invention and features of the embodiments may be combined with each other.

Specific implementations of the invention are described in detail below in connection with specific embodiments.

As shown in fig. 1,2 and 4, a structure diagram of a drying and forming device for geomembrane production is provided for an embodiment of the present invention, which includes a workbench 1, two sets of opposite vertical plates 2 are fixedly installed on the surface of the workbench 1, a geomembrane body 9 is disposed between the two sets of vertical plates 2, the two sets of vertical plates 2 are jointly provided with a flattening mechanism 3 matched with the geomembrane body 9, the flattening mechanism 3 includes a hot press roller 31 and a rotating assembly 32, the hot press roller 31 is provided with two sets of hot press rollers and is respectively located on the upper side and the lower side of the geomembrane body 9, the rotating assembly 32 is located between the two sets of vertical plates 2 and is connected with the hot press roller 31, the rotating assembly 32 is used for controlling the two sets of hot press rollers 31 to rotate along opposite directions, top ends of the two sets of vertical plates 2 are jointly and fixedly installed with a top plate 4, the surface of the top plate 4 and bottom wall of the workbench 1 are respectively fixedly installed with a hot air heater 5, the hot air heater 5 is connected with a blowing pipe 6 through a conduit, a positioning mechanism 7 matched with the blowpipes 6 is arranged between the two groups of risers 2, the positioning mechanism 7 comprises a supporting component 71 and a reciprocating translation component 72, the supporting component 71 is positioned between the two groups of risers 2 and connected with the blowpipes 6, the supporting component 71 is used for controlling the two groups of blowpipes 6 to be respectively positioned at the upper side and the lower side of the geomembrane body 9, the reciprocating translation component 72 is positioned at the side wall of the risers 2 and connected with the supporting component 71, the reciprocating translation component 72 controls the blowpipes 6 to reciprocate between the two groups of risers 2 along the direction parallel to the geomembrane body 9 in a mode of being matched with the supporting component 71, a blowing mechanism 8 matched with the geomembrane body 9 is arranged between the two groups of risers 2, the blowing mechanism 8 comprises a guiding component 81 and a blowing component 82, the guiding component 81 is positioned between the two groups of risers 2 and contacted with the geomembrane body 9, the guiding component 81 is used for changing the advancing track of the geomembrane body 9, the blowing component 82 is located between the two groups of risers 2 and connected with the reciprocating translation component 72, and the blowing component 82 blows to two sides of the geomembrane body 9 in a manner of mutually matching with the guiding component 81.

When the geomembrane body 9 is rolled up after production, the geomembrane body 9 passes through between two groups of risers 2, the geomembrane body 9 is in the process of going, rotating assembly 32 controls two groups of hot pressing rollers 31 to rotate along opposite directions, two groups of hot pressing rollers 31 can carry out even hot pressing leveling treatment on the geomembrane body 9, the geomembrane body 9 after hot pressing continuously moves forward, the hot air blower 5 generates hot air and conveys the hot air into the blowing pipe 6, the blowing pipe 6 uniformly blows the hot air to the surface of the geomembrane body 9, the reciprocating translation assembly 72 and the supporting assembly 71 are mutually matched, the two groups of blowing pipes 6 are controlled to reciprocate along the horizontal direction on the upper side and the lower side of the geomembrane body 9 respectively, the hot air blown by the blowing pipe 6 can continuously carry out drying treatment on the surface of the geomembrane body 9, the contact time between the surface of the geomembrane body 9 and the geomembrane body is effectively improved, and then the drying effect of the geomembrane body 9 is improved, when the geomembrane body 9 after preliminary drying by the blowing pipe 6 continues to move forward, the moving of the geomembrane body 9, the guide assembly 81 changes the moving track of the geomembrane body 9, the moving along the vertical track of the blowing pipe 6 uniformly blows the hot air to the surface of the geomembrane body 9, the moving along the vertical track, the moving along the horizontal track, the horizontal track of the surface of the blowing assembly, the two sides of the geomembrane 9 can be contacted with the surface, and the surface of the geomembrane 9 can be further contacted with the surface, and the surface of the geomembrane 9, and the surface.

As shown in fig. 1, 4 and 5, as a preferred embodiment of the present invention, the rotating assembly 32 includes two sets of rotating rods 321 rotatably installed between two sets of risers 2, the heat pressing roller 31 is fixedly installed on the surface of the rotating rods 321, one end of each rotating rod 321 extends to the outside of each riser 2 and is fixedly connected with a driving fluted disc 322, the two sets of driving fluted discs 322 are meshed with each other, and the end of one set of rotating rods 321 is connected with a first motor 323.

The first motor 323 drives a set of dwang 321 to rotate and then drives the synchronous rotation of transmission fluted disc 322, and two sets of transmission fluted disc 322 meshing transmission, and then drives two sets of dwang 321 and follow opposite direction synchronous rotation, and dwang 321 drives the synchronous rotation of hot pressing roller 31, and geomembrane body 9 when two sets of hot pressing roller 31 are worn between, and hot pressing roller 31 can carry out even hot pressing flattening to geomembrane body 9.

As shown in fig. 1, 2, 4 and 5, as a preferred embodiment of the present invention, the supporting assembly 71 includes two rows of slides 711 provided on the surfaces of two sets of risers 2, the slides 711 are respectively disposed on the upper and lower sides of the risers 2, the two sets of slides 711 distributed on the surfaces of the two sets of risers 2 are slidably connected together in a horizontal direction to form a bearing post 712, the blowpipe 6 is fixedly mounted on the side wall surface of the bearing post 712 facing the geomembrane body 9, and the bearing post 712 is connected with the reciprocating translation assembly 72.

The geomembrane body 9 after hot pressing continuously moves, the bearing columns 712 on the upper side and the lower side of the geomembrane body 9 are controlled by the reciprocating translation assembly 72 to reciprocate in the slide ways 711, the bearing columns 712 drive the blowing pipes 6 to synchronously move, the contact time between hot air blown by the blowing pipes 6 and the surface of the geomembrane body 9 can be effectively prolonged, and the drying and forming effects of the geomembrane body 9 can be effectively improved.

As shown in fig. 1,2, 4, and 5, as a preferred embodiment of the present invention, the reciprocating translational assembly 72 includes a rotating shaft 721 rotatably mounted on two opposite side walls of the two sets of risers 2, a control board 722 is fixedly mounted on the surface of the rotating shaft 721, the control board 722 is in a strip structure, a first guide groove 723 is respectively formed on the upper and lower ends of the control board 722, a first guide post 724 is fixedly mounted on an end portion of the bearing post 712, the first guide post 724 is inserted into the first guide groove 723, a fixed disk 725 is rotatably mounted on the surface of the two sets of risers 2, a second guide groove 726 is formed on the surface of the control board 722 and is located outside the fixed disk 725, a second guide post 727 is fixedly mounted on the eccentric position of the surface of the fixed disk 725, the second guide post 727 is inserted into the second guide groove 726, a transmission shaft 728 is rotatably mounted on the surface of the two sets of risers 2, a gear ring 729 is fixedly mounted on the surface of the transmission shaft 728, a fixed fluted disc 720 is meshed with the gear ring 729 is fixedly mounted on the surface of the transmission shaft 728, and one end of the transmission shaft 728 extends to the outside of the riser 2 and is connected with the second motor 7211.

When in use, the second motor 7211 drives the transmission shaft 728 to rotate, and then drives the fixed fluted disc 720 to synchronously rotate, the fixed fluted disc 720 and the gear ring 729 are meshed for transmission, and then the fixed disc 725 is driven to rotate on the surface of the vertical plate 2, the fixed disc 725 drives the second guide post 727 to rotate, the second guide post 727 is matched with the second guide groove 726, and then the control plate 722 is driven to swing back and forth around the rotation shaft 721 outside the vertical plate 2, and the first guide groove 723 at the end of the control plate 722 is matched with the first guide post 724, so that the bearing post 712 can be pushed to reciprocate in the slide way 711.

As shown in fig. 1, 3 and 4, as a preferred embodiment of the present invention, the guide assembly 81 includes first guide bars 811 rotatably installed between two sets of risers 2, the first guide bars 811 are provided with two sets, two sets of second guide bars 812 are rotatably installed between the two sets of risers 2, the two sets of second guide bars 812 are located between the two sets of first guide bars 811, the two sets of second guide bars 812 are located on the upper and lower sides of the first guide bars 811, and the geomembrane body 9 passes through the surfaces of the first guide bars 811 and the second guide bars 812 from left to right in sequence.

When the geomembrane body 9 moves from left to right, the geomembrane body 9 sequentially passes through the surfaces of the first guide rod 811, the second guide rod 812 and the first guide rod 811, the two groups of first guide rods 811 and the two groups of second guide rods 812 can position the geomembrane body 9, so that the geomembrane body 9 moves along a fold line-shaped track, the air blowing component 82 can perform efficient air drying treatment on the surface of the geomembrane body 9 at the fold line, the contact area and the contact time between the fold line-shaped geomembrane body 9 and air flowing at a high speed can be effectively increased by the aid of the geomembrane body 9, and the drying and forming effects of the geomembrane body 9 are further improved.

As shown in fig. 1,2, 3 and 4, as a preferred embodiment of the present invention, the blowing component 82 includes two sets of rotating rods 821 rotatably installed between the two sets of risers 2, the rotating rods 821 are provided with two sets of rotating rods 821 and are respectively located at two sides of the geomembrane body 9, the rotating rods 821 are located at the bending position of the geomembrane body 9, the surfaces of the rotating rods 821 are provided with a plurality of sets of fan blades 822 distributed in parallel, the surfaces of the rotating rods 821 and the transmission shaft 728 are respectively fixedly installed with a synchronous fluted disc 823, and the plurality of sets of synchronous fluted discs 823 are commonly connected with a synchronous belt 824.

The transmission shaft 728 drives the synchronous fluted disc 823 to rotate, the synchronous fluted disc 823 of multiunit and hold-in range 824 mutually support, and then can drive rotary rod 821 and rotate at geomembrane body 9 broken line department, and rotary rod 821 drives flabellum 822 synchronous rotation, and flabellum 822 can accelerate the air flow speed of geomembrane body 9 broken line department, further improves the dry shaping effect of geomembrane body 9.

As shown in fig. 1 and 2, in a preferred embodiment of the present invention, the slide 711 is fixedly provided with a stop lever 10 distributed along a horizontal direction, and the stop lever 10 is slidably connected with the bearing post 712. The bearing column 712 slides on the surface of the limit rod 10, and the limit rod 10 can effectively improve the stability of the bearing column 712 when moving in the slide way 711.

The working principle of the invention is as follows: when the geomembrane body 9 is rolled after production, the geomembrane body 9 passes through between two groups of risers 2, and in the running process, the first motor 323 drives a group of rotating rods 321 to rotate so as to drive the transmission fluted disc 322 to synchronously rotate, and the two groups of transmission fluted discs 322 are meshed to drive the two groups of rotating rods 321 to synchronously rotate along opposite directions, and the rotating rods 321 drive the hot pressing rollers 31 to synchronously rotate, so that when the geomembrane body 9 passes through between the two groups of hot pressing rollers 31, the hot pressing rollers 31 can uniformly perform hot pressing leveling treatment on the geomembrane body 9.

The geomembrane body 9 after hot pressing continuously moves, the hot air blower 5 generates hot air and conveys the hot air into the blowing pipe 6, the blowing pipe 6 uniformly blows the hot air to the surface of the geomembrane body 9, the second motor 7211 drives the transmission shaft 728 to rotate so as to drive the fixed fluted disc 720 to synchronously rotate, the fixed fluted disc 720 and the gear ring 729 are in meshed transmission, the fixed fluted disc 725 is driven to rotate on the surface of the vertical plate 2, the fixed fluted disc 725 drives the second guide post 727 to rotate, the second guide post 727 and the second guide groove 726 are mutually matched, the control plate 722 is driven to reciprocate outside the vertical plate 2 by taking the rotating shaft 721 as the center of a circle, and the first guide groove 723 at the end part of the control plate 722 is mutually matched with the first guide post 724 so as to push the bearing post 712 to reciprocate in the slide 711. The bearing column 712 drives the blowing pipe 6 to synchronously move, so that the contact time between hot air blown by the blowing pipe 6 and the surface of the geomembrane body 9 can be effectively prolonged, and the drying and forming effects of the geomembrane body 9 can be effectively improved.

When the geomembrane body 9 moves from left to right, the geomembrane body 9 sequentially passes through the surfaces of the first guide rod 811, the second guide rod 812 and the first guide rod 811, the two groups of first guide rods 811 and the two groups of second guide rods 812 can position the geomembrane body 9, the geomembrane body 9 moves along a fold line-shaped track, the transmission shaft 728 drives the synchronous fluted disc 823 to rotate, the synchronous fluted disc 823 and the synchronous belt 824 are matched with each other, the rotary rod 821 can be driven to rotate at the fold line of the geomembrane body 9, the rotary rod 821 drives the fan blades 822 to synchronously rotate, the fan blades 822 can accelerate the air flow speed at the fold line of the geomembrane body 9, and the drying and forming effects of the geomembrane body 9 are further improved.

While the preferred embodiments of the present invention have been described in detail, the present invention is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present invention within the knowledge of those skilled in the art.

Claims (7)

1. The drying and forming equipment for geomembrane production comprises a workbench, wherein two groups of relatively distributed vertical plates are fixedly arranged on the surface of the workbench, a geomembrane body is arranged between the two groups of vertical plates, the drying and forming equipment is characterized in that the two groups of vertical plates are jointly provided with a flattening mechanism mutually matched with the geomembrane body, the flattening mechanism comprises a hot press roller and a rotating assembly, the hot press roller is provided with two groups and is respectively positioned on the upper side and the lower side of the geomembrane body, the rotating assembly is positioned between the two groups of vertical plates and is connected with the hot press roller, the rotating assembly is used for controlling the two groups of hot press rollers to rotate along opposite directions, top plates are fixedly arranged on the top ends of the two groups of vertical plates together, a hot air blower is fixedly arranged on the surface of the top plates and the bottom wall of the workbench respectively, the hot air blower is connected with a blowing pipe through a guide pipe, a positioning mechanism mutually matched with the blowing pipe is arranged between the two groups of vertical plates, the positioning mechanism comprises a supporting component and a reciprocating translation component, the supporting component is positioned between two groups of risers and is connected with the blowing pipes, the supporting component is used for controlling the two groups of blowing pipes to be respectively positioned at the upper side and the lower side of the geomembrane body, the reciprocating translation component is positioned on the side walls of the risers and is connected with the supporting component, the reciprocating translation component controls the blowing pipes to reciprocate between the two groups of risers along the direction parallel to the geomembrane body in a manner of being mutually matched with the supporting component, a blowing mechanism which is mutually matched with the geomembrane body is arranged between the two groups of risers, the blowing mechanism comprises a guiding component and a blowing component, the guiding component is positioned between the two groups of risers and is in contact with the geomembrane body, the guiding component is used for changing the advancing track of the geomembrane body, the blowing component is positioned between the two groups of risers and is connected with the reciprocating translation component, the blowing component is used for blowing the two sides of the geomembrane body in a mode of being matched with the guiding component.

2. The drying and molding device for geomembrane production according to claim 1, wherein the rotating assembly comprises two sets of rotating rods rotatably mounted between two sets of risers, the heat pressing roller is fixedly mounted on the surface of the rotating rods, one end of each rotating rod extends to the outer side of each riser and is fixedly connected with a transmission fluted disc, the two sets of transmission fluted discs are meshed with each other, and the end part of one set of rotating rods is connected with the first motor.

3. The drying and forming device for geomembrane production according to claim 1, wherein the supporting assembly comprises slide ways arranged on the surfaces of two groups of vertical plates, the slide ways are provided with two rows and are respectively arranged on the upper side and the lower side of the vertical plates, the two groups of slide ways which are oppositely distributed on the surfaces of the two groups of vertical plates are connected with bearing columns in a sliding manner along the horizontal direction, the blowing pipe is fixedly arranged on the side wall surface of the bearing column, which faces the geomembrane body, and the bearing columns are connected with the reciprocating translation assembly.

4. The drying and forming device for geomembrane production according to claim 3, wherein the reciprocating translation assembly comprises two groups of vertical plates, two side walls of the two groups of vertical plates are opposite to each other, a control plate is fixedly arranged on the surface of the rotary shaft and is of a strip-shaped structure, first guide grooves are respectively formed in the upper end and the lower end of the control plate, first guide posts are fixedly arranged at the end parts of the bearing posts and are inserted into the first guide grooves, fixing plates are respectively and rotatably arranged on the surfaces of the two groups of vertical plates, second guide grooves positioned on the outer sides of the fixing plates are formed in the surfaces of the control plate, second guide posts are fixedly arranged at the eccentric positions of the surfaces of the fixing plates and are inserted into the second guide grooves, a transmission shaft is jointly and rotatably arranged on the surfaces of the two groups of vertical plates, a gear ring is fixedly arranged on the surfaces of the fixing plates, a fixing fluted disc meshed with the gear ring is fixedly arranged on the surfaces of the transmission shaft, and one end of the transmission shaft extends to the outer sides of the vertical plates and is connected with a second motor.

5. The drying and forming device for geomembrane production according to claim 4, wherein the guide assembly comprises first guide rods rotatably installed between two sets of vertical plates, the first guide rods are provided with two sets of second guide rods rotatably installed between the two sets of vertical plates, the two sets of second guide rods are located between the two sets of first guide rods, the two sets of second guide rods are located on the upper side and the lower side of the first guide rods respectively, and the geomembrane body penetrates through the surfaces of the first guide rods and the second guide rods from left to right in sequence.

6. The drying and forming device for geomembrane production according to claim 4, wherein the blowing component comprises rotating rods rotatably installed between two sets of vertical plates, the rotating rods are provided with two sets of rotating rods and are respectively positioned at two sides of the geomembrane body, the rotating rods are positioned at the bending positions of the geomembrane body, a plurality of groups of fan blades distributed in parallel are arranged on the surfaces of the rotating rods, synchronous fluted discs are fixedly installed on the surfaces of the rotating rods and the transmission shafts respectively, and the synchronous fluted discs are commonly connected with synchronous belts.

7. A geomembrane production drying and forming device according to claim 3, wherein the slide way is fixedly provided with limiting rods distributed along the horizontal direction, and the limiting rods are in sliding connection with the bearing columns.