CN218442913U - Cooling device for graphite electrode production - Google Patents

Abstract

The utility model provides a cooling device for graphite electrode production, which relates to the technical field of cooling devices and comprises a bracket component and a stirring mechanism, wherein the inner side of the top of the bracket component is provided with a cooling part, and the cooling part is provided with the stirring mechanism in rotary connection; the utility model discloses mainly be the utilization is under the drive power of motor output, make the rotary rod cooperation go up triple trapezoidal flower pole can the efficient carry out abundant stirring with the raw materials of cooling part's inside, and install built-in motor in the inboard of rotary rod, it drives meshing gear and carries out transmission output with the gear shaft to have motor output power, it lets the vibrating arm carry out the efficient vibration to the inside raw materials of cooling part to make the gear shaft drive the eccentric wheel like this, make the surface area of raw materials carry out abundant exposure through stirring and vibration, let the quick giving off of heat of raw materials let the cooling part take away the heat, thereby the consumption of cooling water has been reduced, and the cost is reduced.

Description

Cool material device is used in graphite electrode production

Technical Field

The utility model relates to a cold material technical field especially relates to a graphite electrode production is with cold material device.

Background

The material cooling device is also called as material cooling machine and cooling machine, it is a special equipment used in carbon and chemical industry, the material produced by kneading machine is fed into material cooling machine to make kneading and cooling, the cooled material is mainly the kneaded material used for producing carbon rod in battery or various anode carbon blocks used in smelting metal, it is made up by uniformly heating and kneading molten Zheqing and carbon powder granules, and its viscosity is relatively large.

Present cool material device need consume too much cooling water source at the in-process of cooling of putting in the use, causes the waste of resource and the lifting scheduling problem of cost easily, consequently, the utility model provides a graphite electrode production is with cool material device is with solving the problem that exists among the prior art.

SUMMERY OF THE UTILITY MODEL

To the above problem, the utility model provides a graphite electrode production is with cold material device, this graphite electrode production is with cold material device mainly utilizes under the drive power of motor output, make the triple trapezoidal flower pole can the efficient carry out abundant stirring with the raw materials of cooling part's inside on the rotary rod cooperation, and install built-in motor in the inboard of rotary rod, it drives the meshing gear and carries out transmission output with the gear shaft to be the motor output power, it enables the gear shaft to drive the eccentric wheel like this and lets the vibrating arm carry out the efficient vibration to the inside raw materials of cooling part, make the surface area of raw materials carry out abundant exposure through stirring and vibration, let the quick giving off of heat of raw materials let cooling part take away the heat, thereby the consumption of cooling water has been reduced, and the cost is reduced.

For realizing the purpose of the utility model, the utility model discloses a following technical scheme realizes: a cooling device for graphite electrode production comprises a support assembly and a stirring mechanism, wherein a cooling part is arranged on the inner side of the top of the support assembly, the stirring mechanism in rotary connection is arranged on the cooling part, and a discharging assembly is arranged above one side of the support assembly and is in plug-in connection with the cooling part;

rabbling mechanism includes first motor, rotary rod, flower rod, second motor, rotation axis, master gear, gear shaft, eccentric wheel and vibrating arm, first motor sets up the top side of cooling part, the output of first motor runs through the cooling part is connected with the rotary rod, just the avris annular of rotary rod distributes and has the flower rod, the inside of rotary rod is provided with the second motor, just the output of second motor is connected with the rotation axis of installation master gear, the master gear is connected with the one end meshing of gear shaft, the input of gear shaft is connected with the eccentric wheel, the outside of eccentric wheel is provided with the vibrating arm of installing in the rotary rod both sides.

The improved structure is characterized in that the flower rod is of a three-trapezoid re-pasting structure, the main gear is in meshing transmission connection with the gear shaft, and the eccentric gear and the vibrating rod are symmetrically distributed on the central axis of the rotating rod.

The improved structure of the bolt support is characterized in that the support component comprises a base, a high-lift frame and a bolt sleeve seat, the high-lift frame is arranged above the periphery of the base, and the bolt sleeve seat is arranged on the top side of the high-lift frame.

The improved bolt sleeve is characterized in that the cooling part comprises an outer shell, a water inlet, an annular copper pipe, a circular fin, a water outlet, an inner shell, a top cover, a feeding port and a discharging port, the outer shell is arranged above the inner side of the bolt sleeve seat, the water inlet is formed in one end of the outer shell and penetrates through the outer shell to be connected with the annular copper pipe, the circular fin is arranged on the outer side of the annular copper pipe, and the end portion of the annular copper pipe penetrates through the outer shell to be connected with the water outlet.

The improved structure is characterized in that an inner shell is arranged on the inner side of the annular copper pipe, a top cover is arranged at the top end of the outer shell, feeding ports are formed in the upper portions of two sides of the top cover, and a discharging port is formed in the bottom side of the outer shell.

The discharging assembly comprises a cylinder, a rotary guide rod, a third motor, a rotary rod and a plug, the cylinder is arranged above one end of the base, the output end of the cylinder is connected with the rotary guide rod, the third motor is arranged at one end of the rotary guide rod, the output end of the third motor is connected with the rotary rod, and one side of the rotary rod is inserted into the discharging port through the plug.

The utility model has the advantages that:

the utility model discloses mainly be the utilization is under the drive power of motor output, make the rotary rod cooperation go up triple trapezoidal flower pole can the efficient carry out abundant stirring with the raw materials of cooling part's inside, and install built-in motor in the inboard of rotary rod, it drives meshing gear and carries out transmission output with the gear shaft to have motor output power, it lets the vibrating arm carry out the efficient vibration to the inside raw materials of cooling part to make the gear shaft drive the eccentric wheel like this, make the surface area of raw materials carry out abundant exposure through stirring and vibration, let the quick giving off of heat of raw materials let the cooling part take away the heat, thereby the consumption of cooling water has been reduced, and the cost is reduced.

Drawings

Fig. 1 is a schematic perspective view of the present invention;

fig. 2 is a schematic bottom perspective view of the present invention;

FIG. 3 is a schematic sectional perspective view of the cooling member of the present invention;

fig. 4 is a schematic view of the three-dimensional structure of the stirring mechanism of the present invention;

fig. 5 is a schematic view of the internal structure of the stirring mechanism of the present invention.

Wherein: 1. a bracket assembly; 101. a base; 102. a high-lift frame; 103. a bolt sleeve seat; 2. a cooling member; 201. a housing; 202. a water inlet; 203. an annular copper tube; 204. a round fin; 205. a water outlet; 206. an inner shell; 207. a top cover; 208. a feeding port; 209. a discharge port; 3. a stirring mechanism; 301. a first motor; 302. rotating the rod; 303. a flower rod; 304. a second motor; 305. a rotating shaft; 306. a main gear; 307. a gear shaft; 308. an eccentric wheel; 309. a vibrating rod; 4. a discharge assembly; 401. a cylinder; 402. rotating the guide rod; 403. a third motor; 404. rotating the rod; 405. and (4) plugging.

Detailed Description

In order to deepen the understanding of the present invention, the following embodiments will be combined to make the present invention do further details, and the present embodiment is only used for explaining the present invention, and does not constitute the limitation of the protection scope of the present invention.

According to fig. 1-5, the embodiment provides a cooling device for graphite electrode production, which includes a support assembly 1 and a stirring mechanism 3, wherein a cooling component 2 is disposed on an inner side of a top of the support assembly 1, the stirring mechanism 3 is rotatably connected to the cooling component 2, and a discharging assembly 4 is disposed above one side of the support assembly 1 and is connected to the cooling component 2 in an inserting manner;

the stirring mechanism 3 comprises a first motor 301, a rotating rod 302, a flower rod 303, a second motor 304, a rotating shaft 305, a main gear 306, a gear shaft 307, an eccentric 308 and a vibrating rod 309, wherein the first motor 301 is arranged on the top side of the cooling component 2, the output end of the first motor 301 penetrates through the cooling component 2 to be connected with the rotating rod 302, the flower rod 303 is annularly distributed on the side of the rotating rod 302, the second motor 304 is arranged inside the rotating rod 302, the rotating shaft 305 for installing the main gear 306 is connected with the output end of the second motor 304, the main gear 306 is meshed with one end of the gear shaft 307, the eccentric 308 is connected with the input end of the gear shaft 307, and the vibrating rods 309 arranged on the two sides of the rotating rod 302 are arranged outside the eccentric 308.

The spline shaft 303 is in a three-trapezoid re-attaching structure, the main gear 306 is in meshing transmission connection with the gear shaft 307, and the eccentric wheel 308 and the vibrating rod 309 are symmetrically distributed around the central axis of the rotating rod 302.

In this embodiment, after a large amount of raw materials enter the inner shell 206, the first motor 301 is started to output power to rotate the rotating rod 302, so that the flower rod 303 outside the rotating rod 302 can perform circular motion under the rotation of the rotating rod 302, because the flower rod 303 is in a three-trapezoid re-attaching structure, the efficiency and the degree of filling of stirring can be improved when the raw materials are stirred, so that the surface area of the raw materials can be exposed as much as possible, and then the second motor 304 is started to output power to drive the main gear 306 outside the rotating shaft 305 to rotate at a high speed, so that the main gear 306 drives the gear shaft 307 and the eccentric wheel 308 to rotate, so that the vibration force generated by the eccentric wheel 308 can be transmitted to the raw materials inside the inner shell 206 through the vibrating rod 309, so that the stirred raw materials are vibrated, and the surface area of the raw materials is more fully exposed.

The bracket assembly 1 comprises a base 101, a raised frame 102 and a bolt sleeve seat 103, wherein the raised frame 102 is arranged above the periphery of the base 101, and the bolt sleeve seat 103 is arranged on the top side of the raised frame 102.

In this embodiment, the base 101 has a large area, so that the elevated frame 102 can be stably supported, and the top side of the elevated frame 102 supports and sleeves the housing 201 by the bolt sleeve seat 103.

The cooling part 2 comprises an outer shell 201, a water inlet 202, an annular copper pipe 203, a circular fin 204, a water outlet 205, an inner shell 206, a top cover 207, a feeding port 208 and a discharging port 209, wherein the outer shell 201 is arranged above the inner side of the bolt sleeve seat 103, the water inlet 202 is arranged at one end of the outer shell 201, the water inlet 202 penetrates through the outer shell 201 and is connected with the annular copper pipe 203, the circular fin 204 is arranged on the outer side of the annular copper pipe 203, and the end part of the annular copper pipe 203 penetrates through the outer shell 201 and is connected with the water outlet 205.

In this embodiment, when the surface area of raw materials fully exposes through the processing of rabbling mechanism 3, through utilizing the water inlet 202 output cooling water body of shell 201 one side, make during cooling water passes through water inlet 202 and gets into annular copper pipe 203, annular copper pipe 203 like this under the cooperation with round fin 204, can make the water among the annular copper pipe 203 with the abundant a large amount of absorption of heat among the inner shell 206, make the raw materials among the inner shell 206 carry out cooling, final cooling water body discharges through the delivery port 205 of shell 201 opposite side and releases heat.

An inner shell 206 is arranged on the inner side of the annular copper pipe 203, a top cover 207 is arranged at the top end of the outer shell 201, a feeding port 208 is arranged above two sides of the top cover 207, and a discharging port 209 is arranged on the bottom side of the outer shell 201.

In this embodiment, the raw material to be processed is first put into the apparatus through the material inlet 208 above the two sides of the top cover 207, so that the raw material enters the inner shell 206 inside the ring-shaped copper tube 203, and after the plug 405 leaves the material outlet 209, the cooled raw material is output from the apparatus through the material outlet 209 at the bottom side of the outer shell 201 in cooperation with the stirring mechanism 3 to complete the final processing.

Discharging component 4 includes cylinder 401, rotatory guide arm 402, third motor 403, rotatory stick 404 and plug 405, and cylinder 401 sets up the one end top at base 101, and the output of cylinder 401 is connected with rotatory guide arm 402, and the one end of rotatory guide arm 402 is provided with third motor 403, and the output of third motor 403 is connected with rotatory stick 404, and one side of rotatory stick 404 is passed through plug 405 and is pegged graft in discharge gate 209.

In this embodiment, when the temperature reduction of the raw material in the inner shell 206 is completed, the starting cylinder 401 outputs power to make the rotating guide rod 402 descend, so that the third motor 403 outputs power to drive the rotating rod 404 to effectively rotate under the driving of the rotating guide rod 402, and the plug 405 leaves the discharge hole 209.

The working principle of the cooling device for producing the graphite electrode is as follows: firstly, raw materials to be processed are put into the equipment through the feeding ports 208 on the two sides of the top cover 207, so that the raw materials enter the inner shell 206 on the inner side of the annular copper tube 203, after a large amount of raw materials enter the inner shell 206, the first motor 301 is started to output power to enable the rotating rod 302 to rotate, so that the flower rod 303 on the outer side of the rotating rod 302 can make circular motion under the rotation of the rotating rod 302, because the flower rod 303 is in a three-trapezoid re-attaching structure, the stirring efficiency and the stirring degree can be improved during stirring the raw materials, the surface area of the raw materials can be exposed as much as possible, then the main gear 306 on the outer side of the rotating shaft 305 is driven to rotate at high speed by starting the second motor 304 to output power, so that the main gear 306 drives the gear shaft 307 and the eccentric wheel 308 to rotate, and the vibration force generated by the eccentric wheel 308 can be transmitted to the raw materials in the inner shell 206 through the vibration rod 309, the stirred raw material is vibrated, the surface area of the raw material is more fully exposed, when the surface area of the raw material is fully exposed through the processing of the stirring mechanism 3, the cooling water is output by utilizing the water inlet 202 on one side of the outer shell 201, the cooling water enters the annular copper pipe 203 through the water inlet 202, so that the annular copper pipe 203 is matched with the round fin 204, the water in the annular copper pipe 203 can fully and greatly absorb the heat in the inner shell 206, the raw material in the inner shell 206 is cooled, and finally the cooling water is discharged through the water outlet 205 on the other side of the outer shell 201 to release heat, when the cooling treatment of the raw material in the inner shell 206 is completed, the air cylinder 401 is started to output power to enable the rotary guide rod 402 to descend, so that the third motor 403 outputs power to drive the rotary rod 404 to effectively rotate under the driving of the rotary guide rod 402, the plug 405 is removed from the outlet 209 and, in conjunction with the stirring mechanism 3, the cooled material is discharged through the outlet 209 at the bottom side of the housing 201 and out of the apparatus to complete the final process.

The foregoing illustrates and describes the general principles, features and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides a graphite electrode production is with cold material device, includes bracket component (1) and rabbling mechanism (3), its characterized in that: a cooling part (2) is arranged on the inner side of the top of the support assembly (1), a stirring mechanism (3) in rotary connection is arranged on the cooling part (2), and a discharging assembly (4) is arranged above one side of the support assembly (1) and is in plug-in connection with the cooling part (2);

rabbling mechanism (3) include first motor (301), rotary rod (302), flower pole (303), second motor (304), rotation axis (305), main gear (306), gear shaft (307), eccentric wheel (308) and vibration pole (309), first motor (301) set up the top side of cooling part (2), the output of first motor (301) runs through cooling part (2) are connected with rotary rod (302), just the avris ring of rotary rod (302) distributes and has flower pole (303), the inside of rotary rod (302) is provided with second motor (304), just the output of second motor (304) is connected with rotation axis (305) of installation main gear (306), main gear (306) are connected with the one end meshing of gear shaft (307), the input of gear shaft (307) is connected with eccentric wheel (308), the outside of eccentric wheel (308) is provided with vibration pole (309) of installing in rotary rod (302) both sides.

2. The cooling device for producing the graphite electrode according to claim 1, wherein: the pole (303) are three trapezoids and paste the structure again, be connected for the meshing transmission between master gear (306) and gear shaft (307), eccentric wheel (308) and vibrating arm (309) are with the axis symmetric distribution of rotary rod (302).

3. The cooling device for producing the graphite electrode according to claim 1, wherein: the support assembly (1) comprises a base (101), a high-lift frame (102) and a bolt sleeve seat (103), wherein the high-lift frame (102) is arranged above the periphery of the base (101), and the bolt sleeve seat (103) is arranged on the top side of the high-lift frame (102).

4. The cooling device for producing the graphite electrode according to claim 3, wherein: cooling unit (2) include shell (201), water inlet (202), annular copper pipe (203), circular fin (204), delivery port (205), inner shell (206), top cap (207), pan feeding mouth (208) and discharge gate (209), shell (201) sets up the inboard top of bolt cover seat (103), the one end of shell (201) is provided with water inlet (202), just water inlet (202) run through shell (201) is connected with annular copper pipe (203), the outside of annular copper pipe (203) is provided with circular fin (204), the tip of annular copper pipe (203) runs through shell (201) is connected with delivery port (205).

5. The cooling device for producing the graphite electrode according to claim 4, wherein: the inner side of the annular copper pipe (203) is provided with an inner shell (206), the top end of the outer shell (201) is provided with a top cover (207), feed openings (208) are formed in the upper portions of the two sides of the top cover (207), and a discharge opening (209) is formed in the bottom side of the outer shell (201).

6. The cooling device for producing the graphite electrode according to claim 3, wherein: ejection of compact subassembly (4) include cylinder (401), rotatory guide arm (402), third motor (403), rotatory stick (404) and plug (405), cylinder (401) set up the one end top of base (101), the output of cylinder (401) is connected with rotatory guide arm (402), just the one end of rotatory guide arm (402) is provided with third motor (403), the output of third motor (403) is connected with rotatory stick (404), just one side of rotatory stick (404) is passed through plug (405) and is pegged graft in discharge gate (209).

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