CN113246350A - High-efficient curing device for glass steel sleeve pipe production - Google Patents

Abstract

The invention discloses a curing device for producing a high-efficiency glass fiber reinforced plastic sleeve, which comprises a curing and forming unit, a curing unit and a curing unit, wherein the curing unit comprises a conveying belt, a pre-forming curing box arranged at the top of the conveying belt, and a deep-forming curing box arranged at the top of the conveying belt and positioned on the right side of the pre-forming curing box; the centre gripping unit set up in the surface of transmission band, including place the board, set up in place the coupling assembling at board top, set up in inboard centre gripping subassembly of coupling assembling, set up in the protection component of coupling assembling both sides. When the glass fiber reinforced plastic sleeve is used, the sleeve curing and forming unit carries out curing and forming operation on the glass fiber reinforced plastic sleeve, the glass fiber reinforced plastic sleeve is clamped by matching the driving assembly, the first transmission assembly, the second transmission assembly and the clamping assembly, and the glass fiber reinforced plastic sleeve rotates in the curing and forming process, so that the surface of the glass fiber reinforced plastic sleeve is heated more uniformly, and the curing and forming efficiency and the qualification rate are improved.

Description

High-efficient curing device for glass steel sleeve pipe production

Technical Field

The invention relates to the technical field of production and forming of a glass reinforced plastic sleeve, in particular to a curing device for efficient production of the glass reinforced plastic sleeve.

Background

The glass fiber reinforced plastic dry type transformer bushing is a device for one or more conductors to penetrate through a wall or a box body and the like to play a role in insulation and support, and comprises a gas impregnated bushing, an oil impregnated paper bushing, an adhesive impregnated fiber bushing and the like, wherein the adhesive impregnated fiber is made of resin impregnated fiber rolls for main insulation, a plurality of anti-corrosion corrugated pipes are required to be arranged on the surface of the glass fiber reinforced plastic bushing in the manufacturing and forming process to improve the anti-corrosion performance of the formed glass fiber reinforced plastic bushing, a curing and forming device is required to improve the curing effect and improve the forming efficiency, when the curing and forming device in the prior art is used, the glass fiber reinforced plastic bushing to be formed cannot rotate in the glass fiber reinforced plastic bushing, so that the surface of the glass fiber reinforced plastic bushing is heated unevenly in the curing and forming process, the forming qualification rate is influenced, and the clamping effect of the bushing before the curing and forming is not good enough, the conditions such as damage are easy to occur in the process of curing and forming, and the qualification rate of curing and forming is further influenced.

Disclosure of Invention

This section is for the purpose of summarizing some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. In this section, as well as in the abstract and the title of the invention of this application, simplifications or omissions may be made to avoid obscuring the purpose of the section, the abstract and the title, and such simplifications or omissions are not intended to limit the scope of the invention.

The present invention has been made in view of the above and/or the problems occurring in the conventional curing apparatus for producing a high-efficiency glass reinforced plastic sleeve.

Therefore, the invention aims to solve the problems that the curing and forming device in the prior art is inconvenient to clamp the glass fiber reinforced plastic sleeve and is not uniformly heated enough, and the qualification rate of fixed forming is influenced.

In order to solve the technical problems, the invention provides the following technical scheme: the curing device for producing the high-efficiency glass fiber reinforced plastic sleeve comprises a curing and forming unit, a curing and forming unit and a curing unit, wherein the curing and forming unit comprises a conveying belt, a pre-forming curing box arranged at the top of the conveying belt, and a deep-forming curing box arranged at the top of the conveying belt and positioned on the right side of the pre-forming curing box; the centre gripping unit, set up in the surface of transmission band, including place the board, set up in place the coupling assembling at board top, set up in inboard centre gripping subassembly of coupling assembling, set up in the protective component of coupling assembling both sides, set up in the inside first drive assembly of protective component, set up in the inside second drive assembly of coupling assembling, and set up in the drive assembly of protective component one side.

As a preferred scheme of the curing device for producing the high-efficiency glass fiber reinforced plastic sleeve, the curing device comprises the following components: the coupling assembling including set up in inside through-hole, set up in the centre gripping chamber at top, and set up in the shifting chute of centre gripping intracavity wall.

As a preferred scheme of the curing device for producing the high-efficiency glass fiber reinforced plastic sleeve, the curing device comprises the following components: the centre gripping subassembly including set up in centre gripping intracavity side's connection pad, set up in the centre gripping frame of connection pad one side, set up in the connection pad with flexible guide between the centre gripping frame, set up in the tightening spring of connection pad one side, and set up in the connecting rod of connection pad opposite side, the one end of connecting rod extends to the inside of protection component.

As a preferred scheme of the curing device for producing the high-efficiency glass fiber reinforced plastic sleeve, the curing device comprises the following components: the clamping frame comprises a movable rubber plate arranged inside, a first tensioning spring arranged inside and a convex block arranged on the inner wall, wherein the first tensioning spring is arranged between the movable rubber plate and the clamping frame.

As a preferred scheme of the curing device for producing the high-efficiency glass fiber reinforced plastic sleeve, the curing device comprises the following components: the protection assembly comprises a protection box and a protection top cover.

As a preferred scheme of the curing device for producing the high-efficiency glass fiber reinforced plastic sleeve, the curing device comprises the following components: the first transmission assembly comprises a transmission gear arranged on the inner wall of the protective box, a connecting plate arranged at one end of the connecting rod, a fixed box arranged on one side of the connecting plate, a fixed rod arranged inside the fixed box, a driven gear arranged at one end of the fixed rod and matched with the transmission gear, and a moving member arranged on the surface of the fixed box.

As a preferred scheme of the curing device for producing the high-efficiency glass fiber reinforced plastic sleeve, the curing device comprises the following components: the moving member includes the shifting ring, set up in the fixed plate at shifting ring top, set up in the movable rod at protection top cap middle part, set up in the briquetting on movable rod top, set up in the second tensioning spring of briquetting bottom, set up in the spacing frame of movable rod bottom, set up in shifting ring side and with connecting plate complex third tensioning spring, and set up in the gag lever post of dead lever side, the shifting ring including set up in the side and with gag lever post complex spacing groove, the fixed plate including set up in the top and with spacing frame complex chute.

As a preferred scheme of the curing device for producing the high-efficiency glass fiber reinforced plastic sleeve, the curing device comprises the following components: the second transmission assembly comprises a transmission rod arranged in the through hole, driving gears arranged at two ends of the transmission rod and matched with the transmission gear, a traction piece arranged on the surface of the transmission rod and positioned in the through hole, and an electromagnetic ring arranged in the through hole and matched with the traction piece.

As a preferred scheme of the curing device for producing the high-efficiency glass fiber reinforced plastic sleeve, the curing device comprises the following components: the traction piece comprises two groups of external threads arranged on the surface of the transmission rod, a threaded ring arranged on the surface of the transmission rod and matched with the external threads, a traction rod arranged at the top of the threaded ring, and a limiting block arranged on the side surface of the traction rod and positioned on the inner wall of the clamping cavity, and the clamping frame further comprises a traction groove arranged on the side surface and matched with the traction rod.

As a preferred scheme of the curing device for producing the high-efficiency glass fiber reinforced plastic sleeve, the curing device comprises the following components: the drive assembly comprises a drive box arranged on the side face of the protection box, a movable top cover arranged at the top of the drive box, and a servo motor arranged in the drive box and matched with the transmission rod.

The invention has the beneficial effects that: when the glass fiber reinforced plastic sleeve is used, the sleeve curing and forming unit carries out curing and forming operation on the glass fiber reinforced plastic sleeve, the glass fiber reinforced plastic sleeve is clamped by matching the driving assembly, the first transmission assembly, the second transmission assembly and the clamping assembly, and the glass fiber reinforced plastic sleeve rotates in the curing and forming process, so that the surface of the glass fiber reinforced plastic sleeve is heated more uniformly, and the curing and forming efficiency and the qualification rate are improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise. Wherein:

FIG. 1 is a schematic diagram showing the entire structure of a curing apparatus for producing a high-efficiency glass fiber reinforced plastic sleeve.

FIG. 2 is a view showing a structure of a holding unit of a curing apparatus for producing a high-efficiency glass fiber reinforced plastic sleeve.

FIG. 3 is a schematic diagram of a connection assembly of a curing apparatus for producing a high-efficiency glass fiber reinforced plastic sleeve.

FIG. 4 is a view showing a structure of a clamping unit of the curing apparatus for producing a high-efficiency glass fiber reinforced plastic sleeve.

FIG. 5 is a view showing a structure of a holding frame of a curing apparatus for producing a high-efficiency glass fiber reinforced plastic sleeve.

FIG. 6 is a view showing the structure of the shield assembly of the curing apparatus for producing a high-efficiency glass fiber reinforced plastic sleeve.

FIG. 7 is a connection structure diagram of the connection assembly and the first transmission assembly of the curing device for producing the high-efficiency glass fiber reinforced plastic sleeve.

FIG. 8 is a connection structure diagram of the first transmission assembly of the curing apparatus for producing high efficiency glass fiber reinforced plastic sleeve.

FIG. 9 is a schematic diagram showing the structure of a moving part of the curing apparatus for producing a high-efficiency GRP pipe.

FIG. 10 is a connection structure diagram of the clamping assembly and the second transmission assembly of the curing device for producing the high-efficiency glass fiber reinforced plastic sleeve.

FIG. 11 is a sectional view of the connection between the second transmission assembly and the connection assembly of the curing device for producing the high-efficiency glass fiber reinforced plastic sleeve.

FIG. 12 is a schematic diagram showing a driving unit of a curing apparatus for producing a high-efficiency glass fiber reinforced plastic sleeve.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways than those specifically described and will be readily apparent to those of ordinary skill in the art without departing from the spirit of the present invention, and therefore the present invention is not limited to the specific embodiments disclosed below.

Furthermore, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

Referring to fig. 1 and 2, a first embodiment of the present invention provides a curing device for producing a high-efficiency glass reinforced plastic sleeve, which includes a curing and molding unit 100 and a clamping unit 200, wherein the glass reinforced plastic sleeve is clamped and rotated by the clamping unit 200 during the curing and molding process of the glass reinforced plastic sleeve, so that the surface of the glass reinforced plastic sleeve is heated more uniformly, and the curing and molding efficiency and the yield are improved.

Specifically, the curing and forming unit 100 comprises a transmission belt 101, a pre-forming curing box 102 arranged at the top of the transmission belt 101, and a deep-forming curing box 103 arranged at the top of the transmission belt 101 and positioned on the right side of the pre-forming curing box 102, a glass steel sleeve to be cured and formed is transported to the inside of the pre-forming curing box 102 and the deep-forming curing box 103 through the transmission belt 101, pre-curing and forming are performed on the glass steel sleeve through the pre-forming curing box 102, deep-curing and forming are performed through the deep-forming curing box 103, and therefore the curing and forming efficiency of the glass steel sleeve is greatly improved.

Preferably, the clamping unit 200 is arranged on the surface of the conveying belt 101, and comprises a placing plate 201, a connecting assembly 202 arranged on the top of the placing plate 201, a clamping assembly 203 arranged inside the connecting assembly 202, protecting assemblies 204 arranged on both sides of the connecting assembly 202, a first transmission assembly 205 arranged inside the protecting assemblies 204, a second transmission assembly 206 arranged inside the connecting assembly 202, and a driving assembly 207 arranged on one side of the protecting assemblies 204, wherein the glass fiber reinforced plastic sleeve to be cured and molded is placed inside the two clamping assemblies 203, the sleeve is clamped inside the clamping assembly 203 through the matching among the driving assembly 207, the first transmission assembly 205 and the second transmission assembly 206, so that the clamping is more stable in the curing and molding process, and meanwhile, the clamping assembly 203 is driven to rotate in the curing and molding process, so that the surface of the glass fiber reinforced plastic sleeve is heated more uniformly, further improving the efficiency and the qualification rate of the fixed molding.

In use, the glass fibre reinforced plastic sleeve to be cured is placed inside the two clamping assemblies 203, the casing is clamped inside the clamping assembly 203 through the cooperation among the driving assembly 207, the first transmission assembly 205 and the second transmission assembly 206, so that the clamping is more stable during the curing and forming process, meanwhile, the clamping assembly 203 is driven to rotate in the curing and forming process, so that the surface of the glass fiber reinforced plastic sleeve is heated more uniformly, the efficiency and the qualification rate of the fixed forming are further improved, then the clamping assembly 203 is arranged on the placing plate 201, the glass fiber reinforced plastic sleeve to be cured and molded is transported to the interior of the pre-forming curing box 102 and the deep-forming curing box 103 through the conveying belt 101, the pre-curing and forming are carried out through the pre-forming curing box 102, and then the deep curing and forming are carried out through the deep forming curing box 103, so that the curing and forming efficiency of the glass fiber reinforced plastic sleeve is greatly improved.

Example 2

Referring to fig. 2 to 9, a second embodiment of the present invention is based on the above embodiment.

Specifically, coupling assembling 202 is including setting up in inside through-hole 202a, setting up in the centre gripping chamber 202b at the top to and set up in the shifting chute 202c of centre gripping chamber 202b inner wall, and the setting of centre gripping chamber 202b is used for treating the fashioned glass steel sleeve of curing to carry out the centre gripping fixed, avoids its condition such as skew to take place at the fashioned in-process of curing, influences the fashioned efficiency of curing.

Preferably, the clamping assembly 203 comprises a connecting disc 203a arranged on the inner side of the clamping cavity 202b, a clamping frame 203b arranged on one side of the connecting disc 203a, a telescopic guide 203c arranged between the connecting disc 203a and the clamping frame 203b, a compression spring 203d arranged on one side of the connecting disc 203a, and a connecting rod 203e arranged on the other side of the connecting disc 203a, one end of the connecting rod 203e extends into the protection assembly 204, when the glass fiber reinforced plastic sleeve to be cured and molded needs to be clamped, the glass fiber reinforced plastic sleeve is placed between the two clamping frames 203b, the two clamping frames 203b are driven to move inwards through the matching between the driving assembly 207 and the second transmission assembly 206, the glass fiber reinforced plastic sleeve can be clamped, and at the moment, the glass fiber reinforced plastic sleeve is limited through the telescopic guide 203c, so that the glass fiber reinforced plastic sleeve is more stable and convenient to move leftwards for clamping.

Preferably, the clamping frame 203b comprises a movable rubber plate 203b-a arranged inside, a first tension spring 203b-b arranged inside, and a lug 203b-c arranged on the inner wall, the first tension spring 203b-b is arranged between the movable rubber plate 203b-a and the clamping frame 203b, and the first tension spring 203b-b and the movable rubber plate 203b-a play a role in buffering, so that the glass fiber reinforced plastic sleeve to be cured and molded is buffered in the clamping process, and the glass fiber reinforced plastic sleeve is prevented from being damaged by being extruded by the two groups of clamping frames 203 b.

Preferably, the protection assembly 204 includes a protection box 204a and a protection top cover 204b, and the first transmission assembly 205 can be protected by the protection box 204a and the protection top cover 204b, so as to prevent the first transmission assembly from being damaged by external force during use.

Preferably, the first transmission assembly 205 includes a transmission gear 205a disposed on the inner wall of the protection box 204a, a connection plate 205b disposed at one end of the connection rod 203e, a fixed box 205c disposed at one side of the connection plate 205b, a fixed rod 205d disposed inside the fixed box 205c, a driven gear 205e disposed at one end of the fixed rod 205d and matched with the transmission gear 205a, and a moving member 205f disposed on the surface of the fixed box 205c, the second transmission assembly 206 is driven by the driving assembly 207 to rotate, so as to drive the two sets of clamping frames 203b to perform clamping operation, the second transmission assembly 206 drives the transmission gear 205a to rotate, the transmission gear 205a drives the driven gear 205e to rotate, and the driven gear 205e, the fixed rod 205d, the fixed box 205c and the connection plate 205b drive the clamping frame 203b to rotate, so that the clamping frame 203b can simultaneously achieve clamping and rotating effects, the efficiency and the qualification rate of curing molding are greatly improved.

When the glass fiber reinforced plastic sleeve to be cured and molded is required to be clamped, the glass fiber reinforced plastic sleeve to be cured and molded is placed between the two clamping frames 203b, the two clamping frames 203b are driven to move inwards through the matching between the driving assembly 207 and the second transmission assembly 206, so that the glass fiber reinforced plastic sleeve can be clamped, the glass fiber reinforced plastic sleeve is limited by the telescopic guide piece 203c at the moment, so that the glass fiber reinforced plastic sleeve is more stable and convenient to move leftwards and rightwards for clamping, meanwhile, the buffering effect is achieved through the arrangement of the first tensioning spring 203b-b and the movable rubber plate 203b-a, the glass fiber reinforced plastic sleeve to be cured and molded is buffered in the clamping process, the glass fiber reinforced plastic sleeve is prevented from being extruded by the two groups of clamping frames 203b to be damaged, at the moment, the second transmission assembly 206 is driven to rotate by the driving assembly 207, so that the two groups of clamping frames 203b can be driven to be clamped, and the second transmission assembly 206 drives the transmission gear 205a to rotate, the driven gear 205e is driven to rotate by the transmission gear 205a, namely the clamping frame 203b is driven to rotate by the driven gear 205e, the fixed rod 205d, the fixed box 205c and the connecting plate 205b, so that the clamping frame 203b can simultaneously achieve the effects of clamping and rotating, and the efficiency and the qualification rate of curing molding are greatly improved.

Example 3

Referring to FIGS. 8-12, a third embodiment of the present invention is based on the first two embodiments.

Specifically, the moving member 205f includes a moving ring 205f-a, a fixed plate 205f-b disposed on the top of the moving ring 205f-a, a movable rod 205f-c disposed in the middle of the protective top cover 204b, a pressing block 205f-d disposed on the top of the movable rod 205f-c, a second tension spring 205f-e disposed on the bottom of the pressing block 205f-d, a limiting frame 205f-f disposed on the bottom of the movable rod 205f-c, a third tension spring 205f-g disposed on the side of the moving ring 205f-a and engaged with the connecting plate 205b, and a limiting rod 205f-h disposed on the side of the fixed rod 205d, the moving ring 205f-a includes a limiting groove M disposed on the side and engaged with the limiting rod 205f-h, the fixed plate 205f-b includes a chute N disposed on the top and engaged with the limiting frame 205f-f, wherein, the limiting frames 205f-f and the chutes N are arranged in two groups, one chute N is provided with a groove matched with the limiting frames 205f-f for limiting the limiting frames 205f-f, when the glass fiber reinforced plastic sleeve needs to be clamped and the clamping frame 203b does not need to rotate, one pressing block 205f-d is pressed, the limiting frames 205f-f are driven to move downwards along the chute N by the pressing block 205f-d and the movable rod 205f-c and are buckled in the groove, namely, the fixed rod 205d and the driven gear 205e are driven to move inwards by the movable ring 205f-a and the limiting rods 205f-h, the driven gear 205e is separated from the transmission gear 205a, wherein the limiting rods 205f-h are in a T shape or a wedge shape, and the limiting groove M corresponds to the limiting rods 205f-h, so as to ensure that the limiting rods 205f-h cannot be separated from the inside of the limiting groove M in the using process, thereby enabling the limiting rods 205f-h to pull the moving ring 205f-a to move, meanwhile, when the limiting rods 205f-h rotate along with the fixed rod 205d, the limiting rods 205f-h can slide in the limiting groove M while rotating, and the moving ring 205f-a is prevented from being driven to rotate, at the moment, the clamping frame 203b can carry out clamping operation under the matching of the driving assembly 207 and the second rotating assembly 206, and the driven gear 205e is separated from the transmission gear 205a so as not to rotate, when the glass steel sleeve needs to be clamped, and when the clamping frame 203b needs to rotate, the other pressing block 205f-d is pressed, so that the other limiting frame 205f-f without the groove moves downwards along the chute N, at the moment, the upper limiting frame 205f-f is pulled upwards through the second tensioning springs 205f-e The clamping frame 203b is separated from the chute N, and then the third tension spring 205f-g pushes the moving ring 205f-a, the fixed rod 205d and the driven gear 205e to move outwards until the driven gear 205e is meshed with the transmission gear 205a, at this time, the clamping frame 203b can simultaneously perform clamping and rotating operations through the cooperation of the driving assembly 207 and the second rotating assembly 206.

Preferably, the second transmission assembly 206 includes a transmission rod 206a disposed inside the through hole 202a, a driving gear 206b disposed at both ends of the transmission rod 206a and engaged with the transmission gear 205a, a pulling member 206c disposed on the surface of the transmission rod 206a and located inside the through hole 202a, and an electromagnetic ring 206d disposed inside the through hole 202a and engaged with the pulling member 206c, when two sets of clamping frames 203b are required to clamp the glass fiber reinforced plastic sleeve to be cured, the driving rod 206a is driven to rotate by the driving assembly 207, the pulling member 206c is driven by the transmission rod 206a to drive the clamping frames 203b to move inward, when the clamping frames move to the position of the electromagnetic ring 206d, the electromagnetic ring 206d is charged to have strong magnetism, the pulling member 206c can be adsorbed, the clamping stability is improved, when the glass fiber reinforced plastic sleeve needs to be disassembled, the electromagnetic ring 206d is powered off, the pulling piece 206c is separated from the electromagnetic ring 206d, the spring 203d is contracted to pull the clamping frame 203b and the pulling piece 206c to move outwards, the threaded ring 206c-b is matched with the external thread 206c-a, so that the resetting operation of the clamping frame 203b is conveniently completed, the pulling piece 206c can be driven to drive the clamping frame 203b to move outwards through the matching of the driving assembly 207 and the driving rod 206a, and the glass fiber reinforced plastic sleeve which is subjected to curing molding can be taken down from the clamping frame 203 b.

Preferably, the pulling member 206c includes two sets of external threads 206c-a disposed on the surface of the driving rod 206a, a threaded ring 206c-b disposed on the surface of the driving rod 206a and engaged with the external threads 206c-a, a pulling rod 206c-c disposed on top of the threaded ring 206c-b, and limit blocks 206c-d arranged at the side surfaces of the pulling rods 206c-c and positioned at the inner wall of the clamping cavity 202b, the clamping frame 203b further comprises pulling grooves 203b-d arranged at the side surfaces and matched with the pulling rods 206c-c, the two groups of external threads 206c-a are arranged in opposite directions, i.e. the two sets of threaded rings 206c-b and the tow bars 206c-c can move simultaneously inboard or outboard as the drive bar 206a rotates, the clamping frame 203b can then perform clamping and disassembling functions through the cooperation of the pulling rods 206c-c and the pulling grooves 203 b-d.

Preferably, the driving assembly 207 comprises a driving box 207a arranged on the side surface of the protection box 204a, a movable top cover 207b arranged on the top of the driving box 207a, and a servo motor 207c arranged inside the driving box 207a and matched with the transmission rod 206a, the servo motor 207c can conveniently drive the traction rod 206c-c to rotate forwards and reversely, namely, the installation, the disassembly and the rotation of the glass fiber reinforced plastic sleeve to be cured and molded can be completed through a single driving source, and the energy consumption and the manufacturing cost are greatly reduced.

When the glass fiber reinforced plastic sleeve is used, the glass fiber reinforced plastic sleeve to be cured and molded is placed between the two clamping frames 203b, the servo motor 207c drives the transmission rod 206a to rotate, when the transmission rod 206a rotates, the two groups of threaded rings 206c-b and the pulling rods 206c-c move inwards at the same time, then the clamping frames 203b move inwards through the matching of the pulling rods 206c-c and the pulling grooves 203b-d, when the transmission rod 206a moves to the position of the electromagnetic ring 206d, the electromagnetic ring 206d is charged to have strong magnetism, the threaded rings 206c-b can be adsorbed, the clamping stability is improved, the glass fiber reinforced plastic sleeve can be clamped, at the moment, the glass fiber reinforced plastic sleeve is limited through the telescopic guide piece 203c, the glass fiber reinforced plastic sleeve is more stable and convenient to move leftwards and rightwards to clamp, and rightwards, and stably plays a role in buffering through the arrangement of the first tensioning springs 203b-b and the movable rubber plates 203b-a, the glass fiber reinforced plastic sleeve to be cured and molded is buffered in the clamping process, the glass fiber reinforced plastic sleeve to be cured and molded is prevented from being damaged by being extruded by two groups of clamping frames 203b, then the clamping assembly 203 is installed on the placing plate 201, the glass fiber reinforced plastic sleeve to be cured and molded is conveyed to the interior of the pre-forming curing box 102 and the deep forming curing box 103 through the conveying belt 101, the pre-forming curing box 102 is used for pre-curing and molding, and the deep forming curing box 103 is used for deep curing and molding, so that the curing and molding efficiency of the glass fiber reinforced plastic sleeve is greatly improved, meanwhile, the transmission rod 206a drives the transmission gear 205a to rotate, the transmission gear 205a drives the driven gear 205e to rotate, the clamping frames 203b are driven to rotate through the driven gear 205e, the fixing rod 205d, the fixing box 205c and the connecting plate 205b, and the clamping frames, when the glass fiber reinforced plastic sleeve needs to be clamped and the clamping frame 203b does not need to rotate, one of the pressing blocks 205f-d is pressed, the limiting frame 205f-f is driven to move downwards along the chute N through the pressing blocks 205f-d and the movable rods 205f-c and is buckled in the groove, the fixed rod 205d and the driven gear 205e can be driven to move inwards through the moving ring 205f-a and the limiting rods 205f-h, so that the driven gear 205e is separated from the transmission gear 205a, the clamping frame 203b can carry out clamping operation under the matching of the driving assembly 207 and the second rotating assembly 206, the driven gear 205e is separated from the transmission gear 205a and cannot rotate, when the glass fiber reinforced plastic sleeve needs to be clamped and the clamping frame 203b needs to rotate, pressing another pressing block 205f-d to make another limiting frame 205f-f without a groove move downwards along the chute N, at this time, pulling the previous limiting frame 205f-f upwards through a second tensioning spring 205f-e to separate the limiting frame from the chute N, pushing a moving ring 205f-a, a fixing rod 205d and a driven gear 205e outwards through a third tensioning spring 205f-g until the driven gear 205e is meshed with a transmission gear 205a, at this time, through the cooperation of a driving assembly 207 and a second rotating assembly 206, enabling the clamping frame 203b to simultaneously carry out clamping and rotating operations, after the solidification molding is completed, powering off an electromagnetic ring 206d to separate a pulling piece 206c from the electromagnetic ring 206d, at this time, a reverse rotation servo motor 207c can drive the pulling piece 206c to drive the clamping frame 203b to move outwards through the cooperation with the transmission rod 206a, the glass fiber reinforced plastic sleeve which is cured and molded can be taken down from the clamping frame 203b, and the operation of curing and molding is completed.

It should be noted that the above-mentioned embodiments are only for illustrating the technical solutions of the present invention and not for limiting, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, which should be covered by the claims of the present invention.

Claims (10)

1. The utility model provides a solidification equipment is used in production of high-efficient glass steel casing pipe which characterized in that: comprises the steps of (a) preparing a mixture of a plurality of raw materials,

the curing and forming unit (100) comprises a conveying belt (101), a pre-forming curing box (102) arranged at the top of the conveying belt (101), and a deep-forming curing box (103) arranged at the top of the conveying belt (101) and positioned at the right side of the pre-forming curing box (102); and the number of the first and second groups,

the clamping unit (200) is arranged on the surface of the conveying belt (101) and comprises a placing plate (201), a connecting assembly (202) arranged on the top of the placing plate (201), a clamping assembly (203) arranged on the inner side of the connecting assembly (202), protection assemblies (204) arranged on two sides of the connecting assembly (202), a first transmission assembly (205) arranged in the protection assemblies (204), a second transmission assembly (206) arranged in the connecting assembly (202), and a driving assembly (207) arranged on one side of the protection assemblies (204).

2. The curing device for producing the high-efficiency glass reinforced plastic sleeve as claimed in claim 1, wherein: the connecting assembly (202) comprises a through hole (202 a) arranged inside, a clamping cavity (202 b) arranged at the top, and a moving groove (202 c) arranged on the inner wall of the clamping cavity (202 b).

3. The curing device for producing the high-efficiency glass reinforced plastic sleeve as claimed in claim 2, wherein: the centre gripping subassembly (203) including set up in connection pad (203 a) of centre gripping chamber (202 b) inboard, set up in centre gripping frame (203 b) of connection pad (203 a) one side, set up in connection pad (203 a) with flexible guide (203 c) between centre gripping frame (203 b), set up in compact spring (203 d) of connection pad (203 a) one side, and set up in connecting rod (203 e) of connection pad (203 a) opposite side, the one end of connecting rod (203 e) extends to the inside of protection subassembly (204).

4. The curing device for producing the high-efficiency glass reinforced plastic sleeve as claimed in claim 3, wherein: the clamping frame (203 b) comprises a movable rubber plate (203 b-a) arranged inside, a first tensioning spring (203 b-b) arranged inside and a convex block (203 b-c) arranged on the inner wall, wherein the first tensioning spring (203 b-b) is arranged between the movable rubber plate (203 b-a) and the clamping frame (203 b).

5. The curing apparatus for producing a high efficiency glass reinforced plastic sleeve according to claim 3 or 4, wherein: the guard assembly (204) includes a guard box (204 a), and a guard roof (204 b).

6. The curing device for producing the high-efficiency glass reinforced plastic sleeve as claimed in claim 5, wherein: the first transmission assembly (205) comprises a transmission gear (205 a) arranged on the inner wall of the protective box (204 a), a connecting plate (205 b) arranged at one end of the connecting rod (203 e), a fixed box (205 c) arranged on one side of the connecting plate (205 b), a fixed rod (205 d) arranged inside the fixed box (205 c), a driven gear (205 e) arranged at one end of the fixed rod (205 d) and matched with the transmission gear (205 a), and a moving member (205 f) arranged on the surface of the fixed box (205 c).

7. The curing device for producing the high-efficiency glass reinforced plastic sleeve according to claim 6, wherein: the moving piece (205 f) comprises a moving ring (205 f-a), a fixed plate (205 f-b) arranged at the top of the moving ring (205 f-a), a movable rod (205 f-c) arranged in the middle of the protective top cover (204 b), a pressing block (205 f-d) arranged at the top end of the movable rod (205 f-c), a second tensioning spring (205 f-e) arranged at the bottom of the pressing block (205 f-d), a limiting frame (205 f-f) arranged at the bottom end of the movable rod (205 f-c), a third tensioning spring (205 f-g) arranged on the side surface of the moving ring (205 f-a) and matched with the connecting plate (205 b), and a limiting rod (205 f-h) arranged on the side surface of the fixed rod (205 d), wherein the moving ring (205 f-a) comprises a limiting rod (205 f-a) arranged on the side surface and matched with the limiting rod (205 f-h) The fixing plate (205 f-b) comprises an inclined groove (N) which is arranged at the top and matched with the limiting frame (205 f-f).

8. The curing apparatus for producing a high efficiency glass reinforced plastic sleeve according to claim 6 or 7, wherein: the second transmission assembly (206) comprises a transmission rod (206 a) arranged in the through hole (202 a), a driving gear (206 b) arranged at two ends of the transmission rod (206 a) and matched with the transmission gear (205 a), a pulling piece (206 c) arranged on the surface of the transmission rod (206 a) and positioned in the through hole (202 a), and an electromagnetic ring (206 d) arranged in the through hole (202 a) and matched with the pulling piece (206 c).

9. The curing device for producing the high-efficiency glass reinforced plastic sleeve according to claim 8, wherein: the pulling piece (206 c) comprises two groups of external threads (206 c-a) arranged on the surface of the transmission rod (206 a), a threaded ring (206 c-b) arranged on the surface of the transmission rod (206 a) and matched with the external threads (206 c-a), a pulling rod (206 c-c) arranged at the top of the threaded ring (206 c-b), and a limiting block (206 c-d) arranged on the side surface of the pulling rod (206 c-c) and positioned on the inner wall of the clamping cavity (202 b), and the clamping frame (203 b) further comprises a pulling groove (203 b-d) arranged on the side surface and matched with the pulling rod (206 c-c).

10. The curing device for producing the high-efficiency glass reinforced plastic sleeve as claimed in claim 9, wherein: the driving assembly (207) comprises a driving box (207 a) arranged on the side face of the protection box (204 a), a movable top cover (207 b) arranged on the top of the driving box (207 a), and a servo motor (207 c) arranged inside the driving box (207 a) and matched with the driving rod (206 a).

Images