CN112133575A

CN112133575A - Oiling closing device of condenser

Info

Publication number: CN112133575A
Application number: CN202010990854.4A
Authority: CN
Inventors: 晏林福
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-09-19
Filing date: 2020-09-19
Publication date: 2020-12-25

Abstract

The invention discloses an oil injection sealing device of a capacitor.A conveying and cooling device comprises a rectangular frame-shaped lifting conveying frame with left and right openings; a pair of horizontal supporting plates which are distributed up and down are respectively formed between the front side wall and the rear side wall of the lifting conveying frame; the pair of horizontal supporting plates uniformly divides the inner space of the lifting conveying frame into three parts, and conveying belts for conveying from left to right are respectively and rotatably arranged at the bottoms of the three spaces; the bottom of the horizontal supporting plate and the upper side wall of the lifting conveying frame are respectively provided with a plurality of uniformly distributed cold air nozzles; the lifting transmission frame is arranged in the vertical moving groove in a lifting way; a rectangular feeding hole which penetrates through the left and the right is formed at the bottom of the left upper supporting plate; a rectangular upper discharge hole penetrating left and right is formed on the right upper supporting plate; a rectangular lower discharging hole which penetrates through the left and the right is formed on the right lower supporting plate.

Description

Oiling closing device of condenser

Technical Field

The invention relates to the technical field of capacitor production, in particular to an oil injection sealing device of a capacitor.

Background

At present, in the condenser production process, be provided with the oil filler point on the shell top side of condenser usually to through the oil filler point to inside oiling, place the product in the other natural cooling that carries out of production line after waiting to fill oil, carry the condenser to seal welding device's workstation and seal the welding through the manual work in electrified container annotating the oil solidification back. In the production process, the natural cooling of the capacitor after oil injection usually needs two hours, and the capacitor is usually placed at one side of the production line manually, so that a large amount of space of a production workshop is occupied, and the mess of the production workshop of the capacitor is always loved; in the subsequent sealing welding process, materials need to be continuously carried up and down, the loading and unloading turnover period of the capacitor is prolonged, the labor intensity of workers is increased, and the production efficiency is low.

Disclosure of Invention

The invention aims to provide an oil filling and sealing device of a capacitor, aiming at the technical problem that the existing oil filling process of the capacitor is time-consuming and labor-consuming.

The technical scheme for solving the technical problems is as follows: an oil injection sealing device of a capacitor comprises a supporting workbench, a conveying cooling device and a sealing device; a plurality of supporting legs are arranged on the bottom surface of the supporting workbench; a vertical moving groove is formed at the right part of the supporting workbench; a left upper supporting plate and a right upper supporting plate are fixed on the upper end surface of the supporting workbench; the end surfaces of the left upper supporting plate and the right upper supporting plate, which are close to each other, are flush with the left side wall and the right side wall of the vertical moving groove respectively; a left lower supporting plate and a right lower supporting plate are fixed on the lower end surface of the supporting workbench; the end surfaces of the left lower supporting plate and the right lower supporting plate, which are close to each other, are flush with the left side wall and the right side wall of the vertical moving groove respectively; the conveying and cooling device comprises a rectangular frame-shaped lifting conveying frame with left and right openings; a pair of horizontal supporting plates which are distributed up and down are respectively formed between the front side wall and the rear side wall of the lifting conveying frame; the pair of horizontal supporting plates uniformly divides the inner space of the lifting conveying frame into three parts, and conveying belts for conveying from left to right are respectively and rotatably arranged at the bottoms of the three spaces; the bottom of the horizontal supporting plate and the upper side wall of the lifting conveying frame are respectively provided with a plurality of uniformly distributed cold air nozzles; the cold air spray head is connected with an external air supply device; the lifting transmission frame is arranged in the vertical moving groove in a lifting way, and the left width and the right width of the lifting transmission frame are the same as those of the vertical moving groove; a rectangular feeding hole which penetrates through the left and the right is formed at the bottom of the left upper supporting plate; a rectangular upper discharge hole penetrating left and right is formed on the right upper supporting plate; a rectangular lower discharging hole which penetrates through the left and the right is formed on the right lower supporting plate; a pair of sealing workbenches are formed on the right end surface of the right upper supporting plate; a sealing workbench is formed on the right end surface of the right lower supporting plate; the distance between the adjacent sealing work tables is the same; the upper end surface of the sealing workbench at the lowest side is flush with the lower side wall of the lower discharge hole; the upper end surface of the middle sealing workbench is flush with the lower side wall of the upper discharging hole; the sealing device comprises two groups of sealing head parts; the two groups of sealing heads respectively move left and right and are arranged on the lower end surfaces of a pair of sealing workbenches at the upper side.

Preferably, a pair of vertical guide rods which are arranged in bilateral symmetry are respectively fixed at the front end and the rear end of the lower end surface of the supporting workbench; the front and rear centers of the lower end surface of the supporting workbench are respectively pivoted with a vertical driving threaded rod; the vertical driving threaded rod is fixedly connected with an output shaft of a vertical driving motor on the lower side; the vertical driving motor is fixed on the ground; vertical driving plates are respectively formed at the lower ends of the front end face and the rear end face of the lifting transmission frame; the vertical driving plate is vertically sleeved on the pair of vertical guide rods on the corresponding side and is screwed on the vertical driving threaded rod on the corresponding side.

Preferably, a lower connecting plate is formed between the lower ends of the left lower supporting plate and the right lower supporting plate; an upper connecting plate is formed between the upper ends of the upper left supporting plate and the upper right supporting plate.

Preferably, the lower end face of the sealing workbench at the lowest end is provided with a plurality of auxiliary supporting legs.

Preferably, an upper avoidance groove is formed on the right end surface of the left upper supporting plate; the upper avoiding groove is over against the upper discharging hole; an upper left cylinder and a lower cylinder are fixed on the left end surface of the left upper supporting plate; the piston rods of the upper left and right cylinders penetrate through the left side wall of the upper avoidance groove in the left-right direction, and an upper push plate is fixed at the right end of the piston rods; the size of the upper push plate is the same as that of the upper avoidance groove; a lower avoidance groove is formed on the right end surface of the left lower supporting plate; the lower avoiding groove is opposite to the lower discharging hole; a lower left air cylinder and a lower right air cylinder are fixed on the left end surface of the left lower supporting plate; the left and right directions of a piston rod of the lower left and right air cylinders penetrate through the left side wall of the lower avoidance groove, and a lower push plate is fixed at the right end of the piston rod; the size of the lower push plate is the same as that of the lower avoidance groove.

Preferably, a pair of upper sealing tables are provided with left and right moving grooves on the lower end surfaces; a left driving threaded rod and a right driving threaded rod are pivoted between the left side wall and the right side wall of the left moving groove and the right moving groove; a left driving motor and a right driving motor are fixed on the right end surfaces of the pair of sealing workbenches on the upper side; the right end of the left and right driving threaded rod is fixedly connected with an output shaft of a left and right driving motor; the upper end of the sealing head is fixed with a left driving block and a right driving block; the left and right driving blocks are arranged in left and right moving grooves on the corresponding sides in a left and right moving mode and are in threaded connection with left and right driving threaded rods on the corresponding sides.

The invention has the beneficial effects that: the structure is simple, sufficient cooling time is provided by lifting the lifting conveying frame, and meanwhile, the processing conveying speed is not influenced.

Drawings

Fig. 1 is a schematic structural view of a cross section of the present invention.

In the figure, 10, a support table; 100. a vertical moving groove; 11. supporting legs; 12. a left upper support plate; 120. a feed port; 121. an upper avoidance groove; 13. a right upper support plate; 130. an upper discharge hole; 14. a left lower support plate; 140. a lower avoidance groove; 15. a right lower support plate; 150. a lower discharge hole; 16. a lower connecting plate; 17. an upper connecting plate; 18. a vertical guide bar; 19. a sealing workbench; 190. a groove is moved left and right; 191. auxiliary supporting legs; 20. a transfer cooling device; 21. a vertical drive motor; 22. a vertical drive threaded rod; 23. lifting the conveying frame; 24. a conveyor belt; 25. a horizontal support plate; 26. a cold air spray head; 27. an upper left cylinder and a lower right cylinder; 271. a push plate is arranged; 28. a lower left and right cylinder; 281. a lower push plate; 30. a sealing head; 31. a left and right driving block; 32. a left and right driving motor; 33. the threaded rod is driven left and right.

Detailed Description

As shown in fig. 1, the oil-filling and sealing device for the capacitor comprises a supporting workbench 10, a conveying and cooling device 20 and a sealing device 30; a plurality of supporting feet 11 are arranged on the bottom surface of the supporting workbench 10; a vertical moving groove 100 is formed at the right part of the support table 10; a left upper supporting plate 12 and a right upper supporting plate 13 are fixed on the upper end surface of the supporting workbench 10; the end surfaces of the left upper supporting plate 12 and the right upper supporting plate 13, which are close to each other, are flush with the left side wall and the right side wall of the vertical moving groove 100 respectively; a left lower supporting plate 14 and a right lower supporting plate 15 are fixed on the lower end surface of the supporting workbench 10; the end surfaces of the left lower support plate 14 and the right lower support plate 15 which are close to each other are respectively flush with the left side wall and the right side wall of the vertical moving groove 100; the conveying and cooling device 20 includes a rectangular frame-shaped lifting conveying frame 23 with left and right openings; a pair of horizontal supporting plates 25 which are distributed up and down are respectively formed between the front side wall and the rear side wall of the lifting transmission frame 23; the pair of horizontal supporting plates 25 uniformly divides the internal space of the lifting conveying frame 23 into three parts, and the bottoms of the three spaces are respectively and rotatably provided with conveying belts 24 for conveying from left to right; the bottom of the horizontal supporting plate 25 and the upper side wall of the lifting conveying frame 23 are respectively provided with a plurality of uniformly distributed cold air nozzles 26; the cold air spray head 26 is connected with an external air supply device; the lifting and conveying frame 23 is arranged in the vertical moving groove 100 in a lifting way, and the left and right width of the lifting and conveying frame 23 is the same as that of the vertical moving groove 100; a rectangular feeding hole 120 which penetrates through the left and the right is formed at the bottom of the left upper supporting plate 12; a rectangular upper discharging hole 130 penetrating left and right is formed on the right upper supporting plate 13; a rectangular lower discharging hole 150 penetrating left and right is formed on the right lower supporting plate 15; a pair of sealing worktables 19 are formed on the right end surface of the right upper supporting plate 13; a sealing workbench 19 is formed on the right end surface of the right lower supporting plate 15; the intervals between the adjacent sealing work tables 19 are the same; the upper end surface of the sealing workbench 19 at the lowest side is flush with the lower side wall of the lower discharging hole 150; the upper end surface of the middle sealing workbench 19 is flush with the lower side wall of the upper discharging hole 130; the sealing device comprises two groups of sealing head 30; the two sealing heads 30 are respectively arranged on the lower end surfaces of the pair of sealing workbenches 19 on the upper side in a left-right moving mode.

As shown in fig. 1, a pair of vertical guide rods 18 which are arranged in bilateral symmetry are respectively fixed at the front and rear ends of the lower end surface of the support workbench 10; the front and rear centers of the lower end surface of the support workbench 10 are respectively pivoted with a vertical driving threaded rod 22; the vertical driving threaded rod 22 is fixedly connected with an output shaft of the vertical driving motor 21 on the lower side; the vertical driving motor 21 is fixed on the ground; vertical driving plates are respectively formed at the lower ends of the front end surface and the rear end surface of the lifting transmission frame 23; the vertical drive plates are vertically sleeved on a pair of vertical guide rods 18 on the respective sides and are threadedly engaged on vertical drive threaded rods 22 on the respective sides.

As shown in fig. 1, a lower connecting plate 16 is formed between the lower ends of the left lower support plate 14 and the right lower support plate 15; an upper connecting plate 17 is formed between the upper ends of the left upper supporting plate 12 and the right upper supporting plate 13.

As shown in fig. 1, a plurality of auxiliary supporting legs 191 are provided on the lower end surface of the lowermost sealing table 19.

As shown in fig. 1, an upper avoidance groove 121 is formed on the right end surface of the left upper support plate 12; the upper avoiding groove 121 is opposite to the upper discharging hole 130; an upper left and right air cylinder 27 is fixed on the left end surface of the left upper supporting plate 12; the piston rod of the upper left and right air cylinder 27 passes through the left side wall of the upper avoidance groove 121 in the left-right direction, and the right end is fixed with an upper push plate 271; the size of the upper push plate 271 is the same as that of the upper avoidance groove 121; a lower avoidance groove 140 is formed on the right end surface of the left lower support plate 14; the lower avoidance groove 140 faces the lower discharge hole 150; a lower left cylinder 28 and a lower right cylinder 28 are fixed on the left end surface of the left lower supporting plate 14; the piston rod of the lower left and right cylinder 28 passes through the left side wall of the lower escape groove 140 in the left-right direction and the right end is fixed with a lower push plate 281; the lower push plate 281 has the same size as the lower escape groove 140.

As shown in fig. 1, left and right moving grooves 190 are formed on the lower end surfaces of the pair of upper closing tables 19; a left driving threaded rod 33 and a right driving threaded rod 33 are pivoted between the left side wall and the right side wall of the left moving groove 190 and the right side wall; a left and right driving motor 32 is fixed on the right end surface of the pair of sealing workbenches 19 on the upper side; the right end of the left and right driving threaded rod 33 is fixedly connected with the output shaft of the left and right driving motor 32; the upper end of the sealing head 30 is fixed with a left driving block 31 and a right driving block 31; the left and right driving blocks 31 are provided in the left and right movement grooves 190 of the respective sides to be moved in the left and right direction and are screwed to the left and right driving screw rods 33 of the respective sides.

The working principle of the oil injection sealing device of the capacitor is that;

in the initial state, the lifting conveying frame 23 is at the lowest end, and the upper surface of the uppermost conveying belt 24 is flush with the lower side wall of the feeding hole 120;

in operation, the oil-filled capacitor enters the uppermost conveyor belt 24 from the feed hole 120, the uppermost cold air nozzle 26 cools the capacitor on the uppermost conveyor belt 24, the conveying frame 23 is lifted upwards to make the upper surface of the middle conveyor belt 24 flush with the lower side wall of the feed hole 120, the oil-filled capacitor enters the middle conveyor belt 24 from the feed hole 120, the middle cold air nozzle 26 cools the capacitor on the middle conveyor belt 24, the conveying frame 23 is lifted upwards to make the upper surface of the lowermost conveyor belt 24 flush with the lower side wall of the feed hole 120, the oil-filled capacitor enters the lowermost conveyor belt 24 from the feed hole 120, the lowermost cold air nozzle 26 cools the capacitor on the lowermost conveyor belt 24, the conveying frame 23 is lifted downwards, and the capacitor on the uppermost conveyor belt 24 faces the upper discharge hole 130, then the uppermost conveyor belt 24 is started to push the capacitors on the conveyor belt 24 out of the upper discharge hole 130 to enter the upper end face of the middle sealing workbench 19, the upper sealing head 30 seals the capacitors on the upper end face of the middle sealing workbench 19, then the lifting conveying frame 23 descends, the capacitors on the middle conveyor belt 24 are over against the lower discharge hole 150, then the middle conveyor belt 24 is started to push the capacitors on the conveyor belt 24 out of the lower discharge hole 150 to enter the upper end face of the lowermost sealing workbench 19, meanwhile, the capacitors filled with oil enter the uppermost conveyor belt 24 from the feed holes 120, then the lower sealing 30 seals the capacitors on the upper end face of the lowermost sealing workbench head 19, then the lifting conveying frame 23 ascends, the capacitors on the lowermost conveyor belt 24 are over against the lower discharge hole 150, then the lowermost conveyor belt 24 is started to push the capacitors on the conveyor belt 24 out of the lower discharge hole 150 to enter the lowermost sealing workbench On the upper end face of the table 19, the capacitors filled with oil at the same time enter the middle conveyor belt 24 from the feed holes 120, and then the lower sealing head 30 seals the capacitors on the upper end face of the lowermost sealing table 19;

according to the above principle, the elevation transport frame 23 is elevated and lowered back and forth, thus providing sufficient cooling time while not affecting the processing transport speed.

The above description is only a preferred embodiment of the present invention, and for those skilled in the art, there are variations on the embodiment and the application scope according to the idea of the present invention, and the content of the present description should not be construed as a limitation to the present invention.

Claims

1. The utility model provides an oiling closing device of condenser which characterized in that: comprises a supporting workbench (10), a conveying and cooling device (20) and a sealing device (30); a plurality of supporting feet (11) are arranged on the bottom surface of the supporting workbench (10); a vertical moving groove (100) is formed at the right part of the supporting workbench (10); a left upper supporting plate (12) and a right upper supporting plate (13) are fixed on the upper end surface of the supporting workbench (10); the end surfaces of the left upper supporting plate (12) and the right upper supporting plate (13) which are close to each other are respectively flush with the left side wall and the right side wall of the vertical moving groove (100); a left lower supporting plate (14) and a right lower supporting plate (15) are fixed on the lower end surface of the supporting workbench (10); the end surfaces of the left lower supporting plate (14) and the right lower supporting plate (15) which are close to each other are respectively flush with the left side wall and the right side wall of the vertical moving groove (100); the conveying and cooling device (20) comprises a rectangular frame-shaped lifting conveying frame (23) with left and right openings; a pair of horizontal supporting plates (25) which are distributed up and down are respectively formed between the front side wall and the rear side wall of the lifting conveying frame (23); the internal space of the lifting conveying frame (23) is uniformly divided into three parts by a pair of horizontal supporting plates (25), and conveying belts (24) for conveying from left to right are respectively and rotatably arranged at the bottoms of the three spaces; a plurality of uniformly distributed cold air spray heads (26) are respectively arranged on the bottom of the horizontal supporting plate (25) and the upper side wall of the lifting conveying frame (23); the cold air spray head (26) is connected with an external air supply device; the lifting conveying frame (23) is arranged in the vertical moving groove (100) in a lifting mode, and the left width and the right width of the lifting conveying frame (23) are the same as those of the vertical moving groove (100); a rectangular feeding hole (120) which penetrates through the left and the right is formed at the bottom of the left upper supporting plate (12); a rectangular upper discharging hole (130) which penetrates through the left and the right is formed on the right upper supporting plate (13); a rectangular lower discharging hole (150) which penetrates through the right and left is formed on the right lower supporting plate (15); a pair of sealing workbenches (19) are formed on the right end surface of the right upper supporting plate (13); a sealing workbench (19) is formed on the right end surface of the right lower supporting plate (15); the distance between the adjacent sealing work tables (19) is the same; the upper end surface of the sealing workbench (19) at the lowest side is flush with the lower side wall of the lower discharging hole (150); the upper end surface of the middle sealing workbench (19) is flush with the lower side wall of the upper discharging hole (130); the sealing device comprises two groups of sealing head (30); the two groups of sealing heads (30) are respectively arranged on the lower end surfaces of a pair of sealing workbenches (19) at the upper side in a left-right moving mode.

2. The oil-filled sealing device for capacitors of claim 1, wherein: a pair of vertical guide rods (18) which are arranged symmetrically left and right are respectively fixed at the front end and the rear end of the lower end surface of the supporting workbench (10); the front and rear end centers of the lower end surface of the supporting workbench (10) are respectively pivoted with a vertical driving threaded rod (22); the vertical driving threaded rod (22) is fixedly connected with an output shaft of a vertical driving motor (21) on the lower side; the vertical driving motor (21) is fixed on the ground; vertical driving plates are respectively formed at the lower ends of the front end surface and the rear end surface of the lifting transmission frame (23); the vertical driving plates are vertically sleeved on a pair of vertical guide rods (18) on the corresponding side and are in threaded connection with vertical driving threaded rods (22) on the corresponding side.

3. The oil-filled sealing device for capacitors of claim 1, wherein: a lower connecting plate (16) is formed between the lower ends of the left lower supporting plate (14) and the right lower supporting plate (15); an upper connecting plate (17) is formed between the upper ends of the left upper supporting plate (12) and the right upper supporting plate (13).

4. The oil-filled sealing device for capacitors of claim 1, wherein: the lower end face of the sealing workbench (19) at the lowest end is provided with a plurality of auxiliary supporting legs (191).

5. The oil-filled sealing device for capacitors of claim 1, wherein: an upper avoidance groove (121) is formed on the right end surface of the left upper supporting plate (12); the upper avoiding groove (121) is right opposite to the upper discharging hole (130); an upper left cylinder (27) and a lower left cylinder (27) are fixed on the left end surface of the left upper support plate (12); the piston rod of the upper left and right air cylinder (27) passes through the left side wall of the upper avoidance groove (121) in the left and right directions, and the right end of the piston rod is fixed with an upper push plate (271); the size of the upper push plate (271) is the same as that of the upper avoidance groove (121); a lower avoidance groove (140) is formed on the right end surface of the left lower supporting plate (14); the lower avoiding groove (140) is opposite to the lower discharging hole (150); a lower left cylinder (28) and a lower right cylinder (28) are fixed on the left end surface of the left lower supporting plate (14); the piston rod of the lower left and right air cylinder (28) passes through the left side wall of the lower avoidance groove (140) in the left-right direction, and the right end of the piston rod is fixed with a lower push plate (281); the size of the lower push plate (281) is the same as that of the lower avoidance groove (140).

6. The oil-filled sealing device for capacitors of claim 1, wherein: a left-right moving groove (190) is formed on the lower end surface of the pair of sealing workbenches (19) on the upper side; a left driving threaded rod (33) and a right driving threaded rod (33) are pivoted between the left side wall and the right side wall of the left-right moving groove (190); a left and a right driving motors (32) are fixed on the right end surfaces of the pair of sealing workbenches (19) on the upper side; the right end of the left and right driving threaded rod (33) is fixedly connected with an output shaft of a left and right driving motor (32); a left driving block and a right driving block (31) are fixed at the upper end of the sealing head (30); the left and right driving blocks (31) are arranged in left and right moving grooves (190) on the corresponding sides in a left and right moving mode and are in threaded connection with left and right driving threaded rods (33) on the corresponding sides.