CN114812199A

CN114812199A - Electrode control system of hot stove in ferrosilicon ore deposit

Info

Publication number: CN114812199A
Application number: CN202210122727.1A
Authority: CN
Inventors: 房建鑫; 房守忠
Original assignee: Ningxia Sanyuan Zhongtai Metallurgy Co ltd
Current assignee: Ningxia Sanyuan Zhongtai Metallurgy Co ltd
Priority date: 2022-06-22
Filing date: 2022-06-22
Publication date: 2022-07-29
Anticipated expiration: 2042-06-22
Also published as: CN114812199B

Abstract

The application relates to an electrode control system of a ferrosilicon ore heating furnace, which relates to the technical field of metallurgical industry and comprises a mounting seat, a first moving assembly, a second moving assembly and an adjusting assembly, wherein the mounting seat is provided with a plurality of first moving grooves at intervals along the length direction of the mounting seat, the mounting seat is provided with a second moving groove along the width direction of the mounting seat, and the second moving groove is positioned at the same end of the plurality of first moving grooves; the first moving piece comprises a first moving block and a first driving part, the first moving block slides along the first moving groove, and the first driving part is connected with the first moving block and used for driving the first moving block to slide in the first moving groove; the second moving assembly comprises a second moving block and a second driving part, the second moving block can slide along the first moving groove and can slide along the second moving groove, and the second driving part is detachably connected with the second moving block. The temperature control system has the effect of reducing the temperature of the control system.

Description

Electrode control system of hot stove of ferrosilicon ore

Technical Field

The application relates to the technical field of metallurgical industry, in particular to an electrode control system of a ferrosilicon ore heating furnace.

Background

The hot stove in ore deposit mainly used smelts the ore, when using hot stove in ore deposit to mineral substance such as ferrosilicon smelt, through adding raw materials such as ferrosilicon in the hot stove in ore deposit, rise the temperature in the hot stove in ore deposit to smelt material such as ferrosilicon.

Among the correlation technique, hot stove in ore deposit is including heating system, and heating system is provided with control system, is provided with a plurality of electroplates among the control system and is used for monitoring and controlling the temperature in the hot stove in ore deposit, is provided with a plurality of electrodes on the electroplate, because temperature change is more in the hot stove in ore deposit, and control system is comparatively frequent to be used, can make the electroplate temperature rise, and the electrode temperature rises thereupon to lead to the control system high temperature.

Disclosure of Invention

In order to reduce the temperature of the control system, the application provides an electrode control system of a ferrosilicon ore heating furnace.

The application provides an electrode control system of hot stove in ferrosilicon ore adopts following technical scheme:

an electrode control system of a ferrosilicon ore heating furnace comprises a mounting seat, a first moving assembly, a second moving assembly and an adjusting assembly, wherein the mounting seat is provided with a plurality of first moving grooves at intervals along the length direction of the mounting seat, the mounting seat is provided with a second moving groove along the width direction of the mounting seat, the second moving groove is positioned at the same end of the plurality of first moving grooves, and openings are formed in the upper surfaces, close to the mounting seat, of the first moving grooves and the second moving grooves; the first moving component comprises a first moving block and a first driving part, the first moving block slides along the first moving groove, and the first driving part is connected with the first moving block and used for driving the first moving block to slide in the first moving groove; the second moving assembly comprises a second moving block and a second driving part, the second moving block can slide along the first moving groove and can slide along the second moving groove, the second driving part is detachably connected with the second moving block, and the second driving part is used for driving the second moving block to slide along the first moving groove; the adjusting assembly is arranged at one end, close to the second moving groove, of the mounting seat and comprises a first adjusting piece and a second adjusting piece, the first adjusting piece is connected with one end, close to the second moving groove, of the mounting seat, the first adjusting piece is used for driving the second moving block to slide along the second moving groove, and the second adjusting piece is used for pushing the second moving block into the first moving groove and enabling the second moving block to be clamped with the second driving part; and the end of the first moving block, which is far away from the mounting seat, and the end of the second moving block, which is far away from the mounting seat, are both provided with cooling components, and the cooling components are used for cooling the electrodes.

By adopting the technical scheme, the mounting base is arranged in the control system and is close to the electrodes on the electroplate, the first moving block can cool the electrodes in different areas along the first moving groove under the action of the first driving part, the second moving block sequentially selects one of the positions close to the electrodes with higher temperature, the electrodes sequentially enter the first moving groove under the coordination of the second driving part and the adjusting assembly, and the electrodes are cooled simultaneously by being matched with the cooling assembly in the first moving groove; when the second moving piece enters the first moving groove, the first adjusting piece is started, the second moving block is pushed to the position, capable of entering the first moving groove, of the second moving block by the first adjusting piece, the second adjusting piece is started, the second moving block is pushed to the first moving groove by the second adjusting piece, the second moving block and the second driving part can be clamped, the second driving part drives the second moving block to slide along the first moving groove, and the cooling assembly above the second moving block cools the electrode, so that the temperature of the control system is reduced.

Optionally, the first driving part includes a screw rod and a first driving part, a fixing plate is arranged at one end of the first moving groove close to the second moving groove, the side wall of the fixing plate close to the second moving groove is flush with the side wall of the second moving groove close to the fixing plate, the height of the fixing plate is half of the depth of the first moving groove, one end of the screw rod is rotatably connected with one end of the mounting seat far away from the second moving groove, the other end of the screw rod penetrates through the first moving block and is rotatably connected with the fixing plate, the axis of the screw rod is the same as the length direction of the first moving groove, and the first driving part is connected with the screw rod and is used for driving the screw rod to rotate.

Optionally, the second driving component includes a second driving mechanism and a connecting piece, a sliding groove is formed in a side wall, close to the first moving groove, of the mounting seat, the connecting piece slides along the sliding groove, the sliding direction of the connecting piece is the same as that of the first moving block, clamping grooves are formed in side walls, far away from the first moving groove, of the connecting piece, clamping blocks are connected to the second moving block, and the clamping blocks are clamped with the clamping grooves; the connecting piece is connected with a second driving mechanism, and the second driving mechanism is used for driving the connecting piece to slide along the first moving groove.

Optionally, the second driving mechanism includes two belt pulleys and a second driving member, one belt pulley is rotatably connected to one end of the mounting seat far away from the second moving groove in the first moving groove, the other belt pulley is rotatably connected to one end of the mounting seat near the second moving groove in the first moving groove, a conveying belt is sleeved on the two belt pulleys, the connecting member is connected with the conveying belt, the second driving member is connected with one of the belt pulleys, the second driving member is used for driving the belt pulley to rotate, and the conveying direction of the conveying belt is the same as the sliding direction of the first moving block.

Optionally, the adjusting assembly further includes a third adjusting member, the third adjusting member is disposed below the second moving block, an output end of the third adjusting member is connected to the second moving block, and the third adjusting member is configured to drive the second moving block to lift along the second moving groove.

Optionally, a limiting block is arranged on one side, away from the first moving groove, of the second moving block, a limiting part is arranged at one end, close to the limiting block, of the mounting base, and when the upper surface of the limiting block abuts against one surface, close to the limiting block, of the limiting block, one surface, close to the second moving groove, of the second moving block can slide along one surface, away from the bottom surface of the first moving groove, of the fixed plate.

Optionally, the first adjusting part includes two first adjusting drives symmetrically disposed at two ends of the second moving block, and output ends of the two first adjusting drives can be abutted to side walls of the second moving block.

Optionally, the second adjusting part includes a second adjusting drive and an electromagnetic part, an output end of the second adjusting drive faces the second moving block, and the electromagnetic part is disposed between the output end of the second adjusting drive and the second moving block.

Optionally, a temperature sensor and a controller are arranged on the mounting seat, and the temperature sensor is electrically connected with the controller.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the electrode cooling device is characterized in that the electrode cooling device is provided with a mounting seat, a first moving assembly, a second moving assembly and an adjusting assembly, wherein the mounting seat is provided with a plurality of first moving grooves and a second moving groove, the first moving assemblies are arranged in the first moving grooves, the cooling assembly arranged on the first moving assembly can cool an electrode along with the movement of the first moving assembly, the cooling assembly arranged on the second moving assembly can selectively enter one of the first moving grooves according to the position of the electrode to increase the cooling area, and the adjusting assembly is used for adjusting the second moving assembly to enter one of the first moving grooves to cool the electrode, so that the temperature of a control system is reduced, and the energy consumption and waste caused by the arrangement of a plurality of first moving parts and cooling assemblies in the same first moving groove are reduced;

2. the second moving block is provided with a limiting block, and the mounting seat is provided with a limiting block corresponding to the limiting block, so that when the second moving block is pushed and lifted by the third adjusting part, the height of the second moving block can be conveniently positioned, and the second adjusting part can conveniently push the second moving block into the first moving groove.

Drawings

Fig. 1 is a schematic structural diagram of an electrode control system of a ferrosilicon furnace according to an embodiment of the present application.

Fig. 2 is a perspective sectional view of an electrode control system of a ferrosilicon furnace according to an embodiment of the present application.

FIG. 3 is a partial perspective sectional view of an electrode control system of a ferrosilicon furnace according to an embodiment of the present application.

FIG. 4 is a partial schematic view of a concealed mount of an electrode control system of a ferrosilicon furnace according to an embodiment of the present application.

Description of reference numerals: 1. a mounting seat; 11. a first moving slot; 12. a second moving slot; 13. a chute; 14. a stopper; 2. a first moving assembly; 21. a first moving block; 22. a first drive member; 221. a screw; 222. a first driving member; 223. a fixing plate; 3. a second moving assembly; 31. a second moving block; 311. a clamping block; 312. a limiting block; 32. a second drive member; 321. a second drive mechanism; 3211. a belt pulley; 3212. a second driving member; 3213. a conveyor belt; 322. a connecting member; 3221. a card slot; 4. an adjustment assembly; 41. a first adjustment member; 411. a first adjustment drive; 42. a second adjustment member; 421. a second adjustment drive; 422. an electromagnetic member; 43. a third adjustment member; 5. a cooling assembly; 6. a temperature sensor; 7. and a controller.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

The embodiment of the application discloses an electrode control system of a ferrosilicon ore heating furnace.

Referring to fig. 1, an electrode control system of a ferrosilicon ore heating furnace comprises a mounting base 1, a first moving assembly 2, a second moving assembly 3 and an adjusting assembly 4, wherein the mounting base 1 is rectangular, the mounting base 1 is provided with five first moving grooves 11 at intervals along the length direction thereof, the mounting base 1 is provided with a second moving groove 12 near one end of the mounting base where the five first moving grooves 11 are the same, the second moving groove 12 is communicated with the five first moving grooves 11, and the upper surfaces of the first moving grooves 11 and the second moving groove 12 near the mounting base 1 are provided with openings. The first moving assembly 2 is positioned in the first moving groove 11 and can slide along the first moving groove 11, the second moving assembly 3 is positioned in the second moving groove 12, and the second moving assembly 3 can slide in the second moving groove 12 and can also slide in the first moving groove 11; the adjusting assembly 4 is used for controlling the second moving assembly 3 to enter the first moving groove 11 or to be separated from the first moving groove 11, the cooling assembly 5 is connected above the first moving assembly 2 and the second moving assembly 3, and the cooling assembly 5 is used for cooling the electrode.

Referring to fig. 1 to 3, the first moving assembly 2 includes a first moving block 21 and a first driving part 22, the first moving block 21 slides along the first moving groove 11, the first driving part 22 includes a screw 221 and a first driving part 222, a fixing plate 223 is welded at one end of the first moving groove 11 close to the second moving groove 12, a side wall of the fixing plate 223 close to the second moving groove 12 is flush with a side wall of the second moving groove 12 close to the fixing plate 223, the height of the fixing plate 223 is half of the depth of the first moving groove 11, and the height of the fixing plate 223 is defined to facilitate the second moving assembly 3 to enter the first moving groove 11; one end of the screw 221 is rotatably connected with one end, far away from the second moving groove 12, of the mounting base 1 through a bearing, the other end of the screw penetrates through the first moving block 21 and is rotatably connected with the fixing plate 223 through a bearing, the axis of the screw 221 is the same as the length direction of the first moving groove 11, the first driving piece 222 is connected with the screw 221 through a coupler, the first driving piece 222 is a servo motor, when the first driving piece 222 is started, the first driving piece 222 drives the screw 221 to rotate, the screw 221 drives the first moving block 21 to slide along the first moving groove 11, the cooling assembly 5 is fixedly connected with one end, far away from the mounting base 1, of the first moving block 21 through a bolt, and the cooling assembly 5 can be driven to move together while the first moving block 21 moves.

Referring to fig. 2 to 3, the second moving assembly 3 includes a second moving block 31 and second driving parts 32, two second driving parts 32 are disposed on each first moving groove 11, and the second driving parts 32 are symmetrically disposed on both sides of the first moving groove 11 along the sliding direction of the first moving block 21. The second driving part 32 comprises a second driving mechanism 321 and a connecting part 322, the side wall of the mounting seat 1 close to the first moving groove 11 is provided with a sliding groove 13, the connecting part 322 can slide along the sliding groove 13, the sliding direction of the connecting part 322 is the same as that of the first moving block 21, the connecting part 322 is a rectangular block, the side wall of the connecting part 322 far away from the first moving groove 11 is provided with a clamping groove 3221, the second moving block 31 is connected with a clamping block 311, the clamping block 311 is elastically clamped with the clamping groove 3221, and one end of the connecting part 322 far away from the second moving groove 12 is welded with a stopping block, when the second moving block 31 is pushed into the connecting part 322, the second moving block 31 is limited.

Referring to fig. 3 and 4, the second driving mechanism 321 includes two belt pulleys 3211 and a second driving member 3212, one belt pulley 3211 is rotatably connected to the mounting base 1 through a rotating shaft, the other belt pulley 3211 is rotatably connected to the mounting base 1 through a rotating shaft, the two belt pulleys 3211 are located at two ends of one first moving groove 11, a transmission belt 3213 is sleeved on the two belt pulleys 3211, and a transmission direction of the transmission belt is the same as a moving direction of the first moving block 21; the connecting member 322 is bonded with the transmission belt, the second driving member 3212 is connected with one of the pulleys 3211, the second driving member 3212 is a servo motor, the second driving member 3212 is used to drive the pulleys 3211 to rotate, and the second driving member 3212 drives one of the pulleys 3211 to rotate while the transmission belt is transmitted along the circumferential side walls of the two pulleys 3211, so that the connecting member 322 moves along the first moving groove 11.

Referring to fig. 1 to 4, the adjusting assembly 4 includes a first adjusting member 41, a second adjusting member 42 and a third adjusting member 43, the first adjusting member 41 includes two first adjusting drives 411 symmetrically disposed at two ends of the second moving slot 12, output ends of the two first adjusting drives 411 can abut against a side wall of the second moving block 31, and the first adjusting drives 411 are oil cylinders. Both the first adjustment drives 411 can push the second moving block 31 so that the second moving block 31 slides along the second moving groove 12.

Referring to fig. 1, a second adjusting member 42 is disposed at one end of each first moving groove 11 close to the second moving groove 12, the second adjusting member 42 includes a second adjusting driver 421 and an electromagnetic member 422, the second adjusting driver 421 is an air cylinder, an output end of the second adjusting driver 421 faces the second moving block 31, a housing of the second adjusting driver 421 is connected to the mounting base 1, and the electromagnetic member 422 is connected between the output end of the second adjusting driver 421 and the second moving block 31 through a bolt. When the second moving block 31 is located at one end of the first moving groove 11 close to the second moving groove 12, the second adjusting driver 421 is started, and the second adjusting driver 421 pushes the second moving element into the first moving groove 11, so that the latch 311 on the second moving block 31 is elastically latched with the latch groove 3221 on the connecting member 322, and the second driving mechanism 321 drives the second moving block 31 to move along the first moving groove 11. When the second moving block 31 needs to be detached from the first moving groove 11, the second adjusting drive 421 is started to approach the second moving block 31, and the electromagnet is started to attract the second moving block 31 and retract to the output end of the second adjusting drive 421, so that the second adjusting drive 421 pulls the second moving block 31 out of the first moving groove 11.

Referring to fig. 2 and 4, the third adjusting member 43 is disposed below the second moving block 31, the third adjusting member 43 is an air cylinder, an output end of the third adjusting member 43 abuts against the second moving block 31, a housing of the third adjusting member 43 is fixedly connected to the mounting base 1 by a bolt, the third adjusting member 43 is activated, and the third adjusting member 43 can drive the second moving block 31 to move up and down along the second moving groove 12.

In addition, referring to fig. 2, a limit block 312 is welded on one side of the second moving block 31 away from the first moving groove 11, a limit member 14 is arranged at one end of the mounting base 1 close to the limit block 312, and the limit member 14 is an inverted L-shaped limit plate; when the upper surface of the stopper 312 abuts against the surface of the stopper 14 close to the stopper 312, the surface of the second moving block 31 close to the second moving groove 12 can slide along the surface of the fixing plate 223 away from the bottom surface of the first moving groove 11.

Referring to fig. 1, in order to facilitate monitoring of the temperature in the control system, the cooling assembly 5 on the second moving block 31 is convenient to accurately cool the hotter electrode, the mounting base 1 is fixedly connected with a temperature sensor 6 and a controller 7 through bolts, the temperature sensor 6 is electrically connected with the controller 7, and the controller 7 is a PLC controller 7.

The implementation principle of the electrode control system of the hot stove in ferrosilicon ore of the embodiment of the application is: when the electrode temperature of a certain position in the control system increases, temperature sensor 6 transmits a signal to controller 7, controller 7 controls first removal subassembly 2, second removal subassembly 3 and adjusting part 4, adjusting part 4 controls second removal subassembly 3 and is close to the higher position of electrode temperature, the first removal subassembly 2 that is close to the higher position of electrode temperature of simultaneous control also removes, make cooling module 5 above first removal subassembly 2 and the cooling module 5 above second removal subassembly 3 lower the temperature to the electrode simultaneously, thereby reduce control system's temperature.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims

1. The utility model provides an electrode control system of hot stove in ferrosilicon ore, includes mount pad (1), first removal subassembly (2), second removal subassembly (3) and adjusting part (4), its characterized in that:

the mounting seat comprises a mounting seat (1), wherein a plurality of first moving grooves (11) are formed in the mounting seat (1) at intervals along the length direction of the mounting seat, a second moving groove (12) is formed in the mounting seat (1) along the width direction of the mounting seat, the second moving groove (12) is located at the same end of the plurality of first moving grooves (11), and openings are formed in the upper surfaces, close to the mounting seat (1), of the first moving grooves (11) and the second moving grooves (12);

the first moving component (2) comprises a first moving block (21) and a first driving part (22), the first moving block (21) slides along the first moving groove (11), and the first driving part (22) is connected with the first moving block (21) and is used for driving the first moving block (21) to slide in the first moving groove (11);

the second moving assembly (3), the second moving assembly (3) comprises a second moving block (31) and a second driving part (32), the second moving block (31) can slide along the first moving groove (11) and can slide along the second moving groove (12), the second driving part (32) is detachably connected with the second moving block (31), and the second driving part (32) is used for driving the second moving block (31) to slide along the first moving groove (11);

the adjusting assembly (4) is arranged at one end, close to the second moving groove (12), of the mounting base (1), the adjusting assembly (4) comprises a first adjusting piece (41) and a second adjusting piece (42), the first adjusting piece (41) is connected with one end, close to the second moving groove (12), of the mounting base (1), the first adjusting piece (41) is used for driving the second moving block (31) to slide along the second moving groove (12), the second adjusting piece (42) is used for pushing the second moving block (31) into the first moving groove (11), and the second moving block (31) is connected with the second driving part (32) in a clamping mode;

and one end of the first moving block (21) far away from the mounting seat (1) and one end of the second moving block (31) far away from the mounting seat (1) are both provided with a cooling assembly (5), and the cooling assembly (5) is used for cooling the electrode.

2. The electrode control system of the hot stove of ferrosilicon ore of claim 1, characterized in that: the first driving part (22) comprises a screw rod (221) and a first driving part (222), one end, close to the second moving groove (12), of the first moving groove (11) is provided with a fixing plate (223), the side wall, close to the second moving groove (12), of the fixing plate (223) is flush with the side wall, close to the fixing plate (223), of the second moving groove (12), the height of the fixing plate (223) is one half of the depth of the first moving groove (11), one end of the screw rod (221) is rotatably connected with one end, far away from the second moving groove (12), of the mounting base (1), the other end of the screw rod penetrates through the first moving block (21) and is rotatably connected with the fixing plate (223), the axis of the screw rod (221) is identical to the length direction of the first moving groove (11), and the first driving part (222) is connected with the screw rod (221) and is used for driving the screw rod (221) to rotate.

3. The electrode control system for the ferrosilicon ore heating furnace according to claim 1, wherein: the second driving component (32) comprises a second driving mechanism (321) and a connecting piece (322), a sliding groove (13) is formed in the side wall, close to the first moving groove (11), of the mounting seat (1), the connecting piece (322) slides along the sliding groove (13), the sliding direction of the connecting piece (322) is the same as that of the first moving block (21), clamping grooves (3221) are formed in the side wall, far away from the first moving groove (11), of the connecting piece (322), clamping blocks (311) are connected to the second moving block (31), and the clamping blocks (311) are clamped with the clamping grooves (3221); the connecting piece (322) is connected with a second driving mechanism (321), and the second driving mechanism (321) is used for driving the connecting piece (322) to slide along the first moving groove (11).

4. The electrode control system for the ferrosilicon ore heating furnace according to claim 3, wherein: the second driving mechanism (321) comprises two belt pulleys (3211) and a second driving part (3212), one belt pulley (3211) is rotatably connected to one end of the mounting seat (1) far away from the second moving groove (12) in the first moving groove (11), the other belt pulley (3211) is rotatably connected to one end of the mounting seat (1) near the second moving groove (12) in the first moving groove (11), a conveyor belt (3213) is sleeved on the two belt pulleys (3211), the connecting part (322) is connected with the conveyor belt, the second driving part (3212) is connected with one of the belt pulleys (3211), the second driving part (3212) is used for driving the belt pulleys (3211) to rotate, and the conveying direction of the conveyor belt (3213) is the same as the sliding direction of the first moving block (21).

5. The electrode control system for the ferrosilicon ore heating furnace according to claim 1, wherein: the adjusting assembly (4) further comprises a third adjusting piece (43), the third adjusting piece (43) is arranged below the second moving block (31), the output end of the third adjusting piece (43) is connected with the second moving block (31), and the third adjusting piece (43) is used for driving the second moving block (31) to ascend and descend along the second moving groove (12).

6. The electrode control system for a ferrosilicon ore heating furnace according to claim 5, wherein: one side, far away from the first moving groove (11), of the second moving block (31) is provided with a limiting block (312), one end, close to the limiting block (312), of the mounting base (1) is provided with a limiting piece (14), and when the upper surface of the limiting block (312) is abutted to one surface, close to the limiting block (312), of the limiting piece (14), one surface, close to the second moving groove (12), of the second moving block (31) can slide along one surface, far away from the bottom surface of the first moving groove (11), of the fixing plate (223).

7. The electrode control system for the ferrosilicon ore heating furnace according to claim 1, wherein: the first adjusting piece (41) comprises two first adjusting drives (411) symmetrically arranged at two ends of the second moving groove (12), and output ends of the two first adjusting drives (411) can be abutted to side walls of the second moving block (31).

8. The electrode control system for the ferrosilicon ore heating furnace according to claim 1, wherein: the second adjusting part (42) comprises a second adjusting drive (421) and an electromagnetic part (422), the output end of the second adjusting drive (421) faces the second moving block (31), and the electromagnetic part (422) is arranged between the output end of the second adjusting drive (421) and the second moving block (31).

9. The electrode control system for the ferrosilicon ore heating furnace according to claim 1, wherein: the temperature sensor (6) and the controller (7) are arranged on the mounting seat (1), and the temperature sensor (6) is electrically connected with the controller (7).