CN211695808U - High dielectric strength thermosetting insulating tube is dried and is used automatic feeding equipment - Google Patents

Abstract

The utility model relates to an automatic feeding device for drying a high-insulation-strength thermosetting insulating tube, which comprises a drying furnace, a feeding part, a vertical driving assembly and a control assembly; the feeding part comprises a support frame, a through hole arranged on the upper surface of the support frame, a horizontal driving assembly and a feeding frame; the vertical driving assembly comprises a workbench, a cylinder a and a pushing frame; this equipment will go up work or material rest and insulating tube automatically through horizontal drive subassembly earlier and carry to the drying area in through last work or material rest earlier insulating tube is concentrated to the cooperation vertical drive subassembly makes the insulating tube can be more abundant dry, this equipment mechanism is simple, convenient operation and should not damage, realized insulating tube automatic feeding to the drying furnace in, improve equipment's degree of automation, reduce workman's intensity of labour and operation danger, and improved the drying efficiency of insulating tube.

Description

High dielectric strength thermosetting insulating tube is dried and is used automatic feeding equipment

Technical Field

The utility model relates to an edge pipe stoving field especially relates to a high dielectric strength thermosetting insulating tube is dried and is used automatic feeding equipment.

Background

The insulating tube is mainly suitable for wiring insulation and mechanical protection of devices such as motors, electrical appliances, instruments, radios and the like, and can ensure long-term normal operation of power transmission and transformation equipment; the utility model provides an insulating tube adopts epoxy glass paper to wind into the insulating tube earlier, need put into the drying furnace with it and heat the stoving and make the insulating tube firm and improve its insulating properties after the insulating tube is rolled up into, present stoving to the insulating tube mainly adopts artificial mode, through the workman with insulating tube after the rolling one by one remove in the drying furnace then drying, this kind of mode has not only improved workman's intensity of labour, and need wait that the temperature in the drying furnace falls just can when taking out the insulating tube, the workman has certain dangerous and extravagant more time of operation.

The insulating tube gluing and drying device disclosed in the Chinese patent application No. CN201420088503.4 comprises a bracket body with a bracket, a plurality of boxes filled with insulating glue are fixed in the bracket of the frame body, a preheater is arranged at the upper part of each box, the upper part of the preheater is sequentially provided with a low-temperature heating drying furnace and a high-temperature heating drying furnace, the lower part of the box body is provided with a bracket, the bracket is provided with an S-shaped insulating tube through pipe device, the bottom of each box body is provided with a tube inlet disc, each tube inlet disc is provided with at least two tube inlet through holes communicated with the box body, an insulating tube woven by a weaving machine penetrates through the S-shaped insulating tube through pipe device and then enters the tube inlet through holes on the tube inlet discs, and penetrates through the pre-heater, the low-temperature heating drying furnace and the high-temperature heating drying furnace from the upper end of the tube inlet through hole and then enters a lower passage; the equipment is complex in structure and inconvenient to operate, automatic feeding cannot be achieved through the equipment, manual feeding of workers is still needed, and labor intensity and operation danger of the workers are greatly improved.

SUMMERY OF THE UTILITY MODEL

The utility model aims at prior art's weak point, concentrate the insulating tube through last work or material rest earlier and carry to the drying area through last work or material rest and horizontal drive subassembly is automatic again, and cooperate vertical drive assembly to make the insulating tube can be more abundant dry, this equipment mechanism is simple, convenient operation and should not damage, realized insulating tube automatic feeding to the drying furnace in, improve equipment's degree of automation, reduce workman's intensity of labour and operation danger, and improved the drying efficiency of insulating tube.

To the technical problem, the utility model discloses a technical scheme as follows:

the utility model provides a high dielectric strength thermosetting insulating tube is dried and is used automatic feeding equipment which characterized in that includes:

the drying furnace is internally provided with a drying area, and one end of the drying furnace is provided with a feeding hole communicated with the drying area;

the feeding part comprises a support frame, a plurality of through holes, a horizontal driving assembly and a feeding frame, wherein one end of the support frame is arranged in the drying area, the other end of the support frame is arranged outside the drying area, the plurality of through holes are symmetrically formed in the top of the support frame along the length direction of the support frame in a left-right mode, the horizontal driving assembly is arranged at the bottom of the support frame, and the feeding frame is arranged at the top of the support frame in a sliding mode;

the vertical driving assembly is positioned in the drying area and comprises a workbench arranged below the support frame, a cylinder a with a driving end vertically upwards arranged on the bottom surface of the workbench, and a pushing frame arranged at the driving end of the cylinder a and slidably arranged on the workbench.

Preferably, the horizontal driving assembly comprises mounting blocks, conveying wheels, a transmission belt a, transmission shafts and a driving motor, wherein the mounting blocks are arranged on the bottom surface of the supporting frame and correspond to the through holes in position and number, the transmission wheels are arranged on the side surfaces of the mounting blocks in a rotating fit mode, the transmission belt a is rotatably arranged on the plurality of conveying wheels, the transmission shafts are respectively arranged on the two conveying wheels in bilateral symmetry at two ends, and the driving motor drives the transmission shafts through the transmission belt b.

Preferably, the upper end of the conveying wheel is located in the through hole, and the height of the upper end of the conveying wheel in the vertical direction is higher than the upper surface of the supporting frame.

Preferably, a stop block is arranged at the end part of the support frame positioned at one end in the drying area, a positioning hole corresponding to the upper end part of the pushing frame is further formed in one side, positioned at the stop block, of the upper surface of the support frame, and sliding grooves a are further formed in the upper surface of the support frame in a bilateral symmetry mode.

Preferably, the bottom of the feeding frame is provided with a sliding block a corresponding to the sliding groove a, the bottom of the feeding frame is provided with a positioning groove matched with the positioning hole in position and size, and the sliding block a is arranged in the sliding groove a in a sliding fit manner.

Preferably, the bottom of the feeding frame is further provided with a plurality of vent holes.

Preferably, the bottom of the pushing frame is provided with a plurality of guide rods downwards, and the top of the workbench is provided with guide grooves downwards corresponding to the positions and the sizes of the guide rods.

Preferably, a control assembly is further arranged at the feed inlet of the drying furnace and comprises mounting plates, cylinders b and control doors, wherein the mounting plates are located on two sides of the feed inlet and are arranged on the drying furnace, the cylinders b are arranged on the top of the drying furnace, and the control doors are slidably mounted on the mounting plates.

Preferably, sliding grooves b are formed in the side face of the mounting plate in an up-down symmetrical mode, sliding blocks b corresponding to the sliding grooves b are arranged on the side face of the control door, and the sliding blocks b are arranged in the sliding grooves b in a sliding fit mode.

Preferably, a connecting plate is arranged at the top of the control door, the bottom of the connecting plate is connected with the control door, the side surface of the connecting plate is connected with the output end of the air cylinder b, and the output end of the air cylinder b is arranged outwards.

The utility model has the advantages that:

(1) the utility model discloses in concentrate the insulating tube through last work or material rest, the bottom of going up the work or material rest through the conveyer wheel drive among the horizontal transport subassembly will go up work or material rest and insulating tube and carry to the drying area in, then will go up the work or material rest through vertical drive assembly and upwards promote to make the insulating tube be in best stoving position, then close the control gate through control assembly is automatic and go up to dry.

(2) The utility model provides a go up the bottom of work or material rest and seted up a plurality of air vents, the effect of this air vent is that the work or material rest upwards promotes the back when vertical drive assembly, and the lower surface of the insulating tube that is located the work or material rest bottom also can dry through the air vent for the insulating tube can carry out more abundant stoving.

(3) The utility model discloses the bottom of well work or material rest of going up is provided with the constant head tank, makes the promotion frame more stable in the work or material rest of going up in the promotion through this constant head tank.

To sum up, the utility model discloses structural design is ingenious, has realized in insulating tube automatic feeding to the drying oven, improve equipment's degree of automation, reduce workman's intensity of labour and operation danger.

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 described below, and it is obvious that the drawings described below are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic diagram of a structure of an automatic feeding device for drying a high-insulation-strength thermosetting insulating tube according to an embodiment of the present invention;

fig. 2 is a schematic side view of a cross-sectional structure of an automatic feeding device for drying a high-insulation-strength thermosetting insulation pipe in the present invention;

FIG. 3 is a schematic structural view of the mounting block of the present invention;

FIG. 4 is a schematic structural view of the vertical driving assembly of the present invention;

fig. 5 is a schematic structural view of the middle feeding frame of the present invention;

fig. 6 is a schematic structural diagram of the middle control door of the present invention.

Detailed Description

The technical solution in the embodiment of the present invention is clearly and completely described below with reference to the accompanying drawings.

Example one

As shown in fig. 1 to 6, an automatic feeding device for drying a high insulation strength thermosetting insulation pipe comprises:

the drying device comprises a drying furnace 1, wherein a drying area 11 is arranged in the drying furnace 1, and a feeding hole 12 communicated with the drying area 11 is formed in one end of the drying furnace 1;

the feeding part 2 comprises a support frame 21, a plurality of through holes 22, a horizontal driving assembly 23 and a feeding frame 24, wherein one end of the support frame 21 is arranged in the drying area 11, the other end of the support frame 21 is arranged outside the drying area 11, the through holes 22 are symmetrically arranged at the top of the support frame 21 along the length direction of the support frame 21 in a left-right mode, the horizontal driving assembly 23 is arranged at the bottom of the support frame 21, and the feeding frame 24 is arranged at the top of the support frame 21 in a sliding mode;

the vertical driving assembly 3 is positioned in the drying zone 11 and comprises a workbench 31 arranged below the supporting frame 21, a cylinder a32 with a driving end vertically upwards arranged on the bottom surface of the workbench 31, and a pushing frame 33 arranged at the driving end of the cylinder a32 and slidably arranged on the workbench 31.

Further, as shown in fig. 1, 2 and 3, the horizontal driving assembly 23 includes mounting blocks 231 disposed on the bottom surface of the supporting frame 21 and corresponding to the positions and the number of the through holes 22, the mounting blocks 231 are disposed on one side of the through holes 22 and are rotatably fitted with the conveying wheels 232 disposed on the side surfaces of the mounting blocks 231, the bottom of the feeding frame 24 is driven by the rotation of the conveying wheels 232 to move the feeding frame 24, the driving belts a233 disposed on the conveying wheels 232 are rotated, the driving belts a233 are used for simultaneously driving the conveying wheels 232 to rotate synchronously, the driving shafts 234 having two ends disposed on the two bilaterally symmetric conveying wheels 232, and the driving motor 236 is used for driving the driving shafts 234 by the driving belts b 235.

Further, as shown in fig. 1 and 2, the upper end of the conveying wheel 232 is located in the through hole 22, and the height of the upper end of the conveying wheel 232 in the vertical direction is higher than the upper surface of the support frame 21, so that the bottom of the feeding frame 24 can be in contact with the upper end of the conveying wheel 232, and the feeding frame 24 can be driven to move simultaneously when the conveying wheel 232 rotates.

Further, as shown in fig. 1 and 2, a stopper 211 is disposed at an end of the support frame 21 located at one end of the drying region 11, the stopper 211 is used for limiting the position of the upper rack 24 so that the positioning groove 242 and the positioning hole 212 are exactly located on the same vertical axis, a positioning hole 212 corresponding to the upper end of the pushing frame 33 is further disposed on one side of the upper surface of the support frame 21 located at the stopper 211, the positioning hole 212 is used for facilitating the pushing frame 33 to pass through the upper surface of the support frame 21, and sliding grooves a213 are further symmetrically disposed on the upper surface of the support frame 21.

Further, as shown in fig. 3 and 5, a sliding block a241 corresponding to the sliding groove a213 is disposed at the bottom of the feeding frame 24, a positioning groove 242 adapted to the position and size of the positioning hole 212 is disposed at the bottom of the feeding frame 24, the sliding block a241 is disposed in the sliding groove a213 in a sliding fit manner, and the feeding frame 24 can be more stable when being conveyed by the conveying wheel 232 through the cooperation of the sliding block a241 and the sliding groove a 213.

Further, as shown in fig. 5, a plurality of vent holes 243 are further formed in the bottom of the feeding frame 24, and the vent holes 243 are used for drying the bottom of the insulating tube located at the bottom of the feeding frame 24.

Further, as shown in fig. 4, a plurality of guide bars 331 are downwardly disposed at the bottom of the pushing frame 33, a guide groove 311 corresponding to the position and size of the guide bar 331 is downwardly disposed at the top of the working table 31, and a cylinder a32 can reduce pressure and increase stability when the pushing frame 33 is driven by the sliding fit of the guide bar 331 and the guide groove 311, and the number of the guide bars 331 and the guide grooves 311 is preferably four.

Further, as shown in fig. 4, the feed inlet 12 of the drying oven 1 is further provided with a control assembly 4, the control assembly 4 comprises a mounting plate 41 which is located on the two sides of the feed inlet 12 and is arranged on the drying oven 1, a cylinder b42 which is arranged on the top of the drying oven 1 in a bilateral symmetry manner, and a control door 43 which is slidably mounted on the mounting plate 41, and the feed inlet 12 can be automatically opened and closed through the control assembly 4, so that the automation degree of the equipment is improved.

Further, as shown in fig. 6, sliding grooves b411 are symmetrically formed in the side surface of the mounting plate 41 in the up-down direction, a sliding block b431 corresponding to the sliding groove b411 is arranged on the side surface of the control door 43, and the sliding block b431 is arranged in the sliding groove b411 in a sliding fit manner.

Further, as shown in fig. 1 and 6, a connecting plate 432 is disposed on the top of the control door 43, the bottom of the connecting plate 432 is connected to the control door 43, the side of the connecting plate 432 is connected to the output end of the cylinder b42, the output end of the cylinder b42 is disposed outward, and the bottom of the control door 43 has a notch, the shape and the size of the notch correspond to the shape and the size of the cross section of the support frame 21, so that the control door 43 does not interfere with the support frame 21 when being closed and can also close the feed opening 12.

The working process is as follows: firstly, insulating tubes are intensively placed on a feeding frame 24 positioned at the end part of a supporting frame 21, then the equipment is started, a driving motor 236 supplies power to drive a conveying wheel 232 to rotate through a driving belt b235, a driving belt a233 and a transmission shaft 234, the upper feeding frame 24 arranged at the upper end of the conveying wheel 232 is driven to convey towards a drying area 11 through the rotation of the conveying wheel 232, after the feeding frame 24 and the insulating tubes are conveyed into the drying area 11, a cylinder a32 supplies power to drive a pushing frame 33 to move upwards along a workbench 31, the bottom of the feeding frame 24 is synchronously pushed through the pushing frame 33 so that the feeding frame 24 also moves upwards to an optimal drying position, then a cylinder b42 supplies power to drive a control door 43 to move along a mounting plate 41 to completely close a feeding hole 12, then after the drying is finished, the control door 43 is opened under the action of the cylinder b42, and the vertical driving component 3 is reset to an initial position, and then the feeding frame 24 and the dried insulating tube are conveyed to the outside through the horizontal driving assembly 23.

In the present invention, it is to be understood that: the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," and the like are used in an orientation or positional relationship indicated in the drawings for convenience and simplicity of description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are therefore not to be construed as limiting the invention. Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art can be made under the technical teaching of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (10)

1. The utility model provides a high dielectric strength thermosetting insulating tube is dried and is used automatic feeding equipment which characterized in that includes:

the drying device comprises a drying furnace (1), wherein a drying area (11) is arranged in the drying furnace (1), and a feeding hole (12) communicated with the drying area (11) is formed in one end of the drying furnace (1);

the feeding part (2) comprises a support frame (21) with one end arranged in the drying area (11) and the other end arranged outside the drying area (11), a plurality of through holes (22) which are arranged on the top of the support frame (21) along the length direction of the support frame (21) in a bilateral symmetry manner, a horizontal driving assembly (23) arranged at the bottom of the support frame (21), and a feeding frame (24) arranged on the top of the support frame (21) in a sliding manner;

the vertical driving assembly (3), the vertical driving assembly (3) is located in the drying area (11), and the vertical upward setting of workstation (31), the drive end of support frame (21) below is including setting up cylinder a (32) of workstation (31) bottom surface and setting are in the drive end and the slip setting of cylinder a (32) are in push frame (33) on workstation (31).

2. The automatic feeding device for drying the high-insulation-strength thermosetting insulating pipe according to claim 1, wherein the horizontal driving assembly (23) comprises mounting blocks (231) which are arranged on the bottom surface of the supporting frame (21) and correspond to the positions and the number of the through holes (22), conveying wheels (232) which are arranged on the side surfaces of the mounting blocks (231) in a rotating fit manner, transmission belts a (233) which are arranged on the plurality of conveying wheels (232) in a rotating manner, transmission shafts (234) which are respectively arranged on the two conveying wheels (232) in bilateral symmetry at two ends, and a driving motor (236) which drives the transmission shafts (234) through the transmission belts b (235).

3. The automatic feeding equipment for drying the high-insulation-strength thermosetting insulation pipe according to claim 2, wherein the upper end of the conveying wheel (232) is positioned in the through hole (22), and the height of the upper end of the conveying wheel (232) in the vertical direction is higher than the upper surface of the supporting frame (21).

4. The automatic feeding equipment for drying the high-insulation-strength thermosetting insulating tube according to claim 1, wherein a stopper (211) is arranged at one end of the support frame (21) in the drying zone (11), a positioning hole (212) corresponding to the upper end of the pushing frame (33) is further formed in one side, located at the stopper (211), of the upper surface of the support frame (21), and sliding grooves a (213) are further formed in the upper surface of the support frame (21) in a bilateral symmetry manner.

5. The automatic feeding equipment for drying the high-insulation-strength thermosetting insulating tube according to claim 4, wherein a sliding block a (241) corresponding to the sliding groove a (213) is arranged at the bottom of the feeding frame (24), a positioning groove (242) matched with the positioning hole (212) in position and size is arranged at the bottom of the feeding frame (24), and the sliding block a (241) is arranged in the sliding groove a (213) in a sliding fit manner.

6. The automatic feeding equipment for drying the high-insulation-strength thermosetting insulating pipe according to claim 5, wherein a plurality of vent holes (243) are further formed in the bottom of the feeding frame (24).

7. The automatic feeding equipment for drying the high-insulation-strength thermosetting insulation pipe according to claim 1, wherein a plurality of guide rods (331) are arranged at the bottom of the pushing frame (33) downwards, and guide grooves (311) corresponding to the positions and the sizes of the guide rods (331) are formed at the top of the workbench (31) downwards.

8. The automatic feeding equipment for drying the high-insulation-strength thermosetting insulating pipe according to claim 1, wherein a control assembly (4) is further arranged at a feeding hole (12) of the drying furnace (1), and the control assembly (4) comprises mounting plates (41) which are positioned at two sides of the feeding hole (12) and are arranged on the drying furnace (1), air cylinders b (42) which are arranged at the top of the drying furnace (1) in a bilateral symmetry manner, and a control door (43) which is slidably mounted on the mounting plates (41).

9. The automatic feeding equipment for drying the high-insulation-strength thermosetting insulating pipe according to claim 8, wherein sliding grooves b (411) are symmetrically formed in the side surface of the mounting plate (41) up and down, sliding blocks b (431) corresponding to the sliding grooves b (411) are arranged on the side surface of the control door (43), and the sliding blocks b (431) are arranged in the sliding grooves b (411) in a sliding fit mode.

10. The automatic feeding equipment for drying the high-insulation-strength thermosetting insulation pipe according to claim 8, wherein a connecting plate (432) is arranged at the top of the control door (43), the bottom of the connecting plate (432) is connected with the control door (43), the side surface of the connecting plate (432) is connected with the output end of the air cylinder b (42), and the output end of the air cylinder b (42) is arranged outwards.

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