CN209777356U

CN209777356U - Titanium electrode discharging device

Info

Publication number: CN209777356U
Application number: CN201920299250.8U
Authority: CN
Inventors: 周志江; 罗新生; 熊永坤
Original assignee: Hefei Tiantai Electromechanical Equipment Engineering Co Ltd
Current assignee: Hefei Tiantai Electromechanical Equipment Engineering Co Ltd
Priority date: 2019-03-07
Filing date: 2019-03-07
Publication date: 2019-12-13
Anticipated expiration: 2029-03-07

Abstract

The utility model discloses a titanium electrode discharging device, which relates to the technical field of titanium electrode transportation, and adopts the technical scheme that the device comprises a frame arranged at the tail end of a transportation line, a roller rotationally connected to the frame, a driving mechanism arranged on the frame, and an auxiliary discharging mechanism arranged at one end of the roller far away from the transportation line; two baffles are symmetrically arranged in the roller, and the shape of the inner cavity of the roller is the same as that of the titanium electrode group; the driving mechanism comprises a driving assembly arranged on the rack and used for driving the roller to rotate and two groups of first guiding assemblies respectively arranged on two sides of the top of the rack and used for guiding the roller. The utility model provides a higher problem of operating personnel intensity of labour, reached the effect that reduces operating personnel intensity of labour.

Description

titanium electrode discharging device

Technical Field

the utility model relates to a titanium electrode transportation technical field, more specifically the saying so, it relates to a titanium electrode discharging device.

Background

The sponge titanium is sponge metallic titanium produced by a metallothermic reduction method and is a main raw material for preparing industrial titanium alloy. The production of titanium sponge is a basic link in the titanium industry, and is a raw material of titanium materials, titanium powder and other titanium components. Titanium tetrachloride is obtained from ilmenite, which is then placed in a sealed stainless steel tank and filled with argon gas to react with magnesium metal, thus obtaining titanium sponge. Such porous "titanium sponges" are not directly usable and must be melted in an electric furnace to form a liquid and then cast into titanium electrodes.

as shown in FIG. 1, a large titanium electrode mass 1 is composed of two titanium electrode blocks 11; however, in the prior art, when producing titanium electrode mass, the operator generally removes the titanium electrode block on the conveying line and then combines the two titanium electrode blocks, which makes the labor intensity of the operator large.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art exists, the utility model aims to provide a titanium electrode discharging device can merge two titanium electrode pieces into together, can reduce operating personnel's intensity of labour like this.

In order to achieve the above purpose, the utility model provides a following technical scheme: a titanium electrode discharging device comprises a rack arranged at the tail end of a conveying line, a roller rotatably connected to the rack, a driving mechanism arranged on the rack, and an auxiliary discharging mechanism arranged at one end, far away from the conveying line, of the roller; two baffles are symmetrically arranged in the roller, and the shape of the inner cavity of the roller is the same as that of the titanium electrode group; the driving mechanism comprises a driving assembly arranged on the rack and used for driving the roller to rotate and two groups of first guiding assemblies respectively arranged on two sides of the top of the rack and used for guiding the roller.

by adopting the technical scheme, the first titanium electrode block enters the roller from the conveying line, then the driving assembly drives the roller to rotate 180 degrees, at the moment, the first titanium electrode block rotates 180 degrees along with the roller under the action of the two baffles, then the second sponge block enters the roller and is combined with the first sponge block, then the driving assembly drives the roller to rotate 90 degrees, the roller rotates to drive the first titanium electrode block and the second titanium electrode block which are combined together to rotate together, so that the third titanium electrode block on the conveying line pushes the first titanium electrode block and the second titanium electrode block which are combined together to the auxiliary discharging mechanism together, finally the driving assembly drives the roller to rotate 90 degrees to reset the roller, at the moment, the third titanium electrode block in the roller is the same as the initial state of the first titanium electrode block entering the roller under the action of self gravity … …, and so on the auxiliary discharging mechanism, a plurality of first titanium electrode blocks combined together are formed Welding the first titanium electrode block and the second titanium electrode block by an operator to form a titanium electrode group; the titanium electrode group is formed in the above mode, so that the times of conveying the titanium electrode block by an operator can be reduced, and the labor intensity of the operator can be reduced.

the utility model discloses further set up to: the driving assembly comprises a driving motor arranged in the rack, a driving gear sleeved and fixed on an output shaft of the driving motor and a driven gear sleeved and fixed at one end of the roller; the driving gear and the driven gear are meshed with each other; a controller is arranged in the rack and electrically connected with the driving motor.

By adopting the technical scheme, the driving motor is started through the controller, the output shaft of the driving motor drives the driving gear to rotate, the driving gear rotates to drive the driven gear to rotate, and the driven gear rotates to drive the roller to rotate; the driving assembly drives the roller to rotate, so that the roller can rotate more stably.

the utility model discloses further set up to: each group of first guide assemblies comprises a rotating roller which is rotatably connected to the top of the rack and two first friction wheels which are respectively sleeved and fixed at two ends of the rotating roller; two second friction wheels are arranged on the roller; the two first friction wheels are respectively abutted with the two second friction wheels.

Through adopting above-mentioned technical scheme, the cylinder rotates and drives the rotation of second friction pulley, and the rotation of second friction pulley drives first friction pulley and rotates, and first friction pulley plays the guide effect to second friction pulley to this can reduce the cylinder and rotate the possibility that the in-process takes place to deviate.

The utility model discloses further set up to: the rack is provided with a second guide assembly for guiding the roller, the second guide assembly comprises a fixed frame arranged at the top of the rack and a third friction wheel rotatably connected to the fixed frame, and the third friction wheel is abutted to the second friction wheel close to the fixed frame.

Through adopting above-mentioned technical scheme, the cylinder rotates and drives the rotation of second friction pulley, and the rotation of second friction pulley drives the rotation of third friction pulley, and third friction pulley plays the guide effect to second friction pulley to this can further reduce the cylinder and rotate the possibility that the in-process takes place to deviate.

The utility model discloses further set up to: the roller is characterized in that two groups of symmetrical third guide assemblies are arranged in the roller, each group of third guide assemblies comprises a fixed plate fixedly connected to the inner side wall of the roller and a first guide roller rotatably connected to one end of the fixed plate and horizontally arranged.

Through adopting above-mentioned technical scheme, through setting up first guide roll, the titanium electrode piece in with the cylinder is released to the titanium electrode piece on the transportation line of being convenient for to can reduce the friction of the titanium electrode piece in the cylinder and cylinder inner wall, therefore can play certain guard action to titanium electrode piece and cylinder.

The utility model discloses further set up to: the auxiliary discharging mechanism comprises a discharging frame arranged at one end, far away from the conveying line, of the roller, a fourth guiding assembly arranged at the top of the discharging frame and two groups of fifth guiding assemblies respectively arranged on two sides of the top of the discharging frame.

Through adopting above-mentioned technical scheme, the titanium electrode piece removes through the mode that a promotion another piece on the play work or material rest, can make the titanium electrode piece remove along the length direction of play work or material rest through setting up fourth guide subassembly, can reduce the possibility that the titanium electrode piece takes place to deviate to the both sides of going out the work or material rest through setting up fifth guide subassembly.

The utility model discloses further set up to: the fourth direction subassembly includes rotates in proper order along the direction of transportation of material and connects in a plurality of second guide rolls of play work or material rest top and level setting.

Through adopting above-mentioned technical scheme, can lead to the titanium electrode piece on the one hand, on the other hand can alleviate the friction of titanium electrode piece and play work or material rest.

The utility model discloses further set up to: every group the fifth guide assembly includes along the direction of transportation of material rotate in proper order connect in a plurality of third guide rolls of play work or material rest top and vertical setting.

Through adopting above-mentioned technical scheme, can lead to the titanium electrode piece on the one hand, on the other hand can reduce the possibility that the titanium electrode piece takes place to drop from the both sides of play work or material rest.

To sum up, the utility model discloses compare and have following beneficial effect in prior art:

1. The first titanium electrode block enters the roller from the conveying line, then the driving component drives the roller to rotate 180 degrees, at the moment, under the action of the two baffles, the first titanium electrode block rotates 180 degrees together with the roller, next, the second sponge block enters the roller and is combined with the first sponge block, then the driving component drives the roller to rotate 90 degrees, the roller rotates to drive the first titanium electrode block and the second titanium electrode block which are combined together to rotate together, so that the third titanium electrode block on the conveying line pushes the first titanium electrode block and the second titanium electrode block which are combined together to the auxiliary discharging mechanism together, finally, the driving component drives the roller to rotate 90 degrees to reset the roller, at the moment, the third titanium electrode block in the roller is the same as the initial state of the first titanium electrode block entering the roller under the action of self gravity … …, and so on the auxiliary discharging mechanism, a plurality of first titanium electrode blocks and second titanium electrode blocks which are combined together are formed Welding the first titanium electrode block and the second titanium electrode block by an operator to form a titanium electrode group; the titanium electrode group is formed in the above way, so that the times of carrying the titanium electrode block by an operator can be reduced, and the labor intensity of the operator can be reduced;

2. The roller rotates to drive the second friction wheel to rotate, the second friction wheel rotates to drive the first friction wheel to rotate, and the first friction wheel plays a role in guiding the second friction wheel, so that the possibility of deviation of the roller in the rotating process can be reduced;

3. The titanium electrode block moves on the discharging frame in a mode that one block pushes the other block, the titanium electrode block can move along the length direction of the discharging frame by arranging the fourth guide assembly, and the possibility that the titanium electrode block deviates from the two sides of the discharging frame can be reduced by arranging the fifth guide assembly.

Drawings

FIG. 1 is a schematic structural diagram of a titanium electrode mass;

FIG. 2 is a schematic view of the overall structure of the embodiment;

FIG. 3 is a schematic view showing the structure of the driving mechanism in the embodiment;

Fig. 4 is a partially enlarged view of a portion a in fig. 3.

In the figure: 1. titanium electrode clusters; 11. a titanium electrode block; 2. a transport line; 3. a frame; 4. a drum; 41. a baffle plate; 5. a drive mechanism; 51. a drive assembly; 511. a drive motor; 512. a driving gear; 513. a driven gear; 514. a controller; 52. a first guide assembly; 521. rotating the roller; 522. a first friction wheel; 523. a second friction wheel; 53. a second guide assembly; 531. a fixed mount; 532. a third friction wheel; 6. a third guide assembly; 61. a fixing plate; 62. a first guide roller; 7. an auxiliary discharging mechanism; 71. a discharging frame; 72. a fourth guide assembly; 721. a second guide roller; 73. a fifth guide assembly; 731. and a third guide roller.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings. In which like parts are designated by like reference numerals. It should be noted that the terms "front," "back," "left," "right," "upper" and "lower" used in the following description refer to directions in the drawings, and the terms "bottom" and "top," "inner" and "outer" refer to directions toward and away from, respectively, the geometric center of a particular component.

Example (b): a titanium electrode discharging device, as shown in fig. 2 and 3, comprising a frame 3 arranged at the tail end of a conveying line 2, a roller 4 rotatably connected to the frame 3, a driving mechanism 5 arranged on the frame 3, and an auxiliary discharging mechanism 7 arranged at one end of the roller 4 far away from the conveying line 2; two baffles 41 are symmetrically arranged in the roller 4, and the shape of the inner cavity of the roller 4 is the same as that of the titanium electrode group 1; the driving mechanism 5 includes a driving assembly 51 mounted on the frame 3 for driving the roller 4 to rotate, and two sets of first guiding assemblies 52 respectively mounted on two sides of the top of the frame 3 for guiding the roller 4. A first titanium electrode block 11 enters the roller 4 from the conveying line 2, then the driving component 51 drives the roller 4 to rotate 180 degrees, at the moment, the first titanium electrode block 11 rotates 180 degrees along with the roller 4 under the action of the two baffles 41, then a second sponge block enters the roller 4 and is combined with the first sponge block, then the roller 4 is driven to rotate 90 degrees by the driving component 51, the roller 4 rotates to drive the first titanium electrode block 11 and the second titanium electrode block 11 which are combined together to rotate together, so that the third titanium electrode block 11 on the conveying line 2 pushes the first titanium electrode block 11 and the second titanium electrode block 11 which are combined together to the auxiliary discharging mechanism 7 together, and finally the roller 4 is driven to rotate 90 degrees by the driving component 51 to reset the roller 4, at the moment, the third titanium electrode block 11 in the roller 4 is the same as the initial state … … of the first titanium electrode block 11 entering the roller 4 under the action of self gravity, and so on the auxiliary discharging mechanism A plurality of first titanium electrode blocks 11 and second titanium electrode blocks 11 which are combined together are formed on the mechanism 7, and then the first titanium electrode blocks 11 and the second titanium electrode blocks 11 are welded by an operator to form a titanium electrode group 1; by forming the titanium electrode cluster 1 in the above manner, the number of times the operator carries the titanium electrode block 11 can be reduced, and thus the labor intensity of the operator can be reduced.

As shown in fig. 3, the driving assembly 51 includes a driving motor 511 installed in the frame 3, a driving gear 512 sleeved on and fixed to an output shaft of the driving motor 511, and a driven gear 513 sleeved on and fixed to one end of the drum 4; the driving gear 512 and the driven gear 513 are meshed with each other; a controller 514 is arranged in the frame 3, the controller 514 is electrically connected with the driving motor 511, and the controller 514 can be a single chip microcomputer. The driving motor 511 is started through the controller 514, an output shaft of the driving motor 511 drives the driving gear 512 to rotate, the driving gear 512 rotates to drive the driven gear 513 to rotate, and the driven gear 513 rotates to drive the roller 4 to rotate; the roller 4 is driven to rotate by the driving assembly 51, so that the roller 4 can rotate more stably.

As shown in fig. 3, each set of the first guiding assemblies 52 includes a rotating roller 521 rotatably connected to the top of the frame 3 and two first friction wheels 522 respectively sleeved and fixed at two ends of the rotating roller 521; two second friction wheels 523 are arranged on the roller 4; the two first friction wheels 522 abut against the two second friction wheels 523, respectively. The roller 4 rotates to drive the second friction wheel 523 to rotate, the second friction wheel 523 rotates to drive the first friction wheel 522 to rotate, and the first friction wheel 522 plays a guiding role in the second friction wheel 523, so that the possibility of deviation of the roller 4 in the rotating process can be reduced.

as shown in fig. 3, the frame 3 is provided with a second guide assembly 53 for guiding the drum 4, the second guide assembly 53 includes a fixed frame 531 mounted on the top of the frame 3 and a third friction wheel 532 rotatably connected to the fixed frame 531, and the third friction wheel 532 abuts against a second friction wheel 523 adjacent to the fixed frame 531. The roller 4 rotates to drive the second friction wheel 523 to rotate, the second friction wheel 523 rotates to drive the third friction wheel 532 to rotate, and the third friction wheel 532 plays a guiding role in guiding the second friction wheel 523, so that the possibility of deviation of the roller 4 in the rotating process can be further reduced.

As shown in fig. 2 and 4, two sets of symmetrical third guiding assemblies 6 are disposed in the drum 4, each set of third guiding assemblies 6 includes a fixed plate 61 fixedly connected to the inner side wall of the drum 4 and a first guiding roller 62 rotatably connected to one end of the fixed plate 61 and horizontally disposed; the thickness of the fixing plate 61 is larger than the width of the baffle plate 41, so that the titanium electrode block 11 can enter the roller 4 conveniently. Through setting up first guide roll 62, be convenient for titanium electrode piece 11 on the transport line 2 to push out titanium electrode piece 11 in the cylinder 4 to can reduce the friction of titanium electrode piece 11 in the cylinder 4 and cylinder 4 inner wall, therefore can play certain guard action to titanium electrode piece 11 and cylinder 4.

As shown in fig. 2, the auxiliary discharging mechanism 7 includes a discharging frame 71 disposed at one end of the drum 4 far from the transport line 2, a fourth guiding assembly 72 disposed at the top of the discharging frame 71, and two sets of fifth guiding assemblies 73 disposed at two sides of the top of the discharging frame 71 respectively; the fourth guide assembly 72 includes a plurality of second guide rollers 721 which are sequentially and rotatably connected to the top of the discharging frame 71 along the material transporting direction and are horizontally disposed; each set of fifth guiding assemblies 73 comprises a plurality of third guiding rollers 731 which are sequentially and rotatably connected to the top of the discharging frame 71 and vertically arranged along the conveying direction of the material. The titanium electrode block 11 moves on the discharging frame 71 in a mode of pushing the other block, the titanium electrode block 11 can move along the length direction of the discharging frame 71 by arranging the fourth guide assembly 72, and the possibility that the titanium electrode block 11 deviates to the two sides of the discharging frame 71 can be reduced by arranging the fifth guide assembly 73.

The working principle of the titanium electrode discharging device is as follows:

A first titanium electrode block 11 enters a roller 4 from a conveying line 2, then a driving motor 511 is started, an output shaft of the driving motor 511 drives a driving gear 512 to rotate, the driving gear 512 rotates to drive a driven gear 513 to rotate, the driven gear 513 rotates to drive the roller 4 to rotate 180 degrees, at the moment, the first titanium electrode block 11 rotates 180 degrees along with the roller 4 under the action of two baffles 41, then a second sponge block enters the roller 4 and is combined with the first sponge block, then the roller 4 is driven to rotate 90 degrees through a driving assembly 51, the roller 4 rotates to drive the first titanium electrode block 11 and the second titanium electrode block 11 which are combined together to rotate together, so that the first titanium electrode block 11 and the second titanium electrode block 11 which are combined together on the conveying line 2 are pushed onto a discharging frame 71 together, and finally the roller 4 is driven to rotate 90 degrees through the driving assembly 51 to reset the roller 4, at the moment, the third titanium electrode block 11 in the roller 4 is in the same initial state … … as the first titanium electrode block 11 enters the roller 4 under the action of self gravity, and so on, a plurality of first titanium electrode blocks 11 and second titanium electrode blocks 11 which are combined together are formed on the discharging frame 71, and then the first titanium electrode blocks 11 and the second titanium electrode blocks 11 are welded by an operator to form a titanium electrode group 1; by forming the titanium electrode cluster 1 in the above manner, the number of times the operator carries the titanium electrode block 11 can be reduced, and thus the labor intensity of the operator can be reduced.

It is above only the utility model discloses a preferred embodiment, the utility model discloses a scope of protection does not only confine above-mentioned embodiment, the all belongs to the utility model discloses a technical scheme under the thinking all belongs to the utility model discloses a scope of protection. It should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims

1. The utility model provides a titanium electrode discharging device which characterized in that: comprises a frame (3) arranged at the tail end of a conveying line (2), a roller (4) rotationally connected to the frame (3), a driving mechanism (5) arranged on the frame (3), and an auxiliary discharging mechanism (7) arranged at one end of the roller (4) far away from the conveying line (2); two baffles (41) are symmetrically arranged in the roller (4), and the shape of the inner cavity of the roller (4) is the same as that of the titanium electrode group (1); the driving mechanism (5) comprises a driving assembly (51) which is arranged on the rack (3) and used for driving the roller (4) to rotate and two groups of first guiding assemblies (52) which are respectively arranged on two sides of the top of the rack (3) and used for guiding the roller (4).

2. The titanium electrode discharging device according to claim 1, wherein: the driving assembly (51) comprises a driving motor (511) arranged in the rack (3), a driving gear (512) sleeved and fixed on an output shaft of the driving motor (511) and a driven gear (513) sleeved and fixed at one end of the roller (4); the driving gear (512) and the driven gear (513) are meshed with each other; a controller (514) is arranged in the rack (3), and the controller (514) is electrically connected with the driving motor (511).

3. The titanium electrode discharging device according to claim 1, wherein: each group of first guide assemblies (52) comprises a rotating roller (521) which is rotatably connected to the top of the frame (3) and two first friction wheels (522) which are respectively sleeved and fixed at two ends of the rotating roller (521); two second friction wheels (523) are arranged on the roller (4); the two first friction wheels (522) are respectively abutted against the two second friction wheels (523).

4. The titanium electrode discharging device according to claim 3, wherein: the roller guide device is characterized in that a second guide assembly (53) used for guiding the roller (4) is arranged on the rack (3), the second guide assembly (53) comprises a fixed frame (531) arranged at the top of the rack (3) and a third friction wheel (532) rotatably connected to the fixed frame (531), and the third friction wheel (532) is abutted to the second friction wheel (523) close to the fixed frame (531).

5. The titanium electrode discharging device according to claim 1, wherein: the roller is characterized in that two groups of mutually symmetrical third guide assemblies (6) are arranged in the roller (4), and each group of the third guide assemblies (6) comprises a fixed plate (61) fixedly connected to the inner side wall of the roller (4) and a first guide roller (62) rotatably connected to one end of the fixed plate (61) and horizontally arranged.

6. The titanium electrode discharging device according to claim 1, wherein: the auxiliary discharging mechanism (7) comprises a discharging frame (71) arranged at one end, far away from the conveying line (2), of the roller (4), a fourth guiding assembly (72) arranged at the top of the discharging frame (71) and two groups of fifth guiding assemblies (73) respectively arranged at two sides of the top of the discharging frame (71).

7. The titanium electrode discharging device according to claim 6, wherein: the fourth guide assembly (72) comprises a plurality of second guide rollers (721) which are sequentially and rotatably connected to the top of the discharging frame (71) in the material conveying direction and are horizontally arranged.

8. The titanium electrode discharging device according to claim 7, wherein: every group fifth guide assembly (73) include along the direction of transportation of material rotate in proper order connect in a plurality of third guide roll (731) of ejection of compact frame (71) top and vertical setting.