CN113280596B - Drying equipment is used in tombarthite production and processing - Google Patents

Abstract

The invention relates to a drying device, in particular to a drying device for rare earth production and processing. The invention aims to solve the technical problem of providing the drying equipment for producing and processing rare earth, which can stir the rare earth, improve the drying effect and continuously feed the rare earth. In order to solve the technical problem, the invention provides a drying device for producing and processing rare earth, which comprises: the top of the bottom frame is connected with a first fixing frame; the high-temperature furnace is connected to the first fixing frame; an exhaust pipe connected to one side of the top of the high temperature furnace; the stirring mechanism is arranged at the top of the high-temperature furnace; and the material blocking mechanism is connected to the bottom of the high-temperature furnace. According to the invention, rare earth can be dried through the high-temperature furnace, the rare earth can be uniformly heated through the stirring mechanism, the drying effect is improved, and the dried rare earth can be conveniently removed through the stop mechanism.

Description

Drying equipment is used in tombarthite production and processing

Technical Field

The invention relates to a drying device, in particular to a drying device for producing and processing rare earth.

Background

Through searching, the patent application number is: CN 201922116927.2's patent discloses a drying device is used in tombarthite production, including the drying cabinet box, the top fixedly connected with feeder hopper of drying cabinet box, the top inner wall of drying cabinet box is fixed can be connected with two symmetrical air heaters, the equal fixedly connected with fixed block of both sides inner wall of drying cabinet box, two the inner wall of fixed block all rotates and is connected with the squeeze roll, two intermeshing between the squeeze roll, two be located between the fixed block the below of squeeze roll has sealed chamber, the bottom inner wall sliding connection of drying cabinet box has the drawer, the bottom integrated into one piece of fixed block has the extension board, just the top of drawer seted up with extension board complex recess, air heater and external power source electric connection.

The above patents suffer from the following drawbacks: when carrying out the drying to the tombarthite, can't stir the tombarthite, lead to that the tombarthite is dry inhomogeneous, the stoving effect is poor, and the artifical tombarthite that need last in the feeder hopper of pouring into moreover, its intensity of labour is high, can't guarantee the continuity that the tombarthite was dried.

Disclosure of Invention

(1) Technical problem to be solved

The invention aims to overcome the defects that when the existing drying equipment dries rare earth, the rare earth cannot be stirred, so that the rare earth is not uniformly dried and the drying effect is poor, and the technical problem to be solved is to provide the drying equipment for producing and processing rare earth, which can stir the rare earth, improve the drying effect and continuously feed the rare earth.

(2) Technical scheme

In order to solve the technical problem, the invention provides a drying device for producing and processing rare earth, which comprises: the top of the bottom frame is connected with a first fixing frame; the high-temperature furnace is connected to the first fixing frame; an exhaust pipe connected to one side of the top of the high temperature furnace; the stirring mechanism is arranged at the top of the high-temperature furnace; and the material blocking mechanism is connected to the bottom of the high-temperature furnace.

Preferably, the stirring mechanism comprises: the second fixing frame is arranged on the outer side of the top of the high-temperature furnace; the first cover plate is connected to the lower part of the second fixing frame, and the first cover plate covers the top of the high-temperature furnace; and the stirrer is arranged at the top of the second fixing frame, penetrates through the first cover plate and extends into the high-temperature furnace.

Preferably, the stock stop includes: the stop block is connected to one side of the bottom of the high-temperature furnace; a connecting rod rotatably connected to one side of the bottom of the high temperature furnace; the first material baffle is connected to the connecting rod, and one end of the first material baffle blocks the bottom of the high-temperature furnace; and the first torsion spring is connected between the first striker plate and the high-temperature furnace.

Preferably, still including shedding mechanism, shedding mechanism includes: the third fixing frame is connected to one side of the high-temperature furnace; the low-speed motor is arranged on the third fixing frame; a rotating shaft connected to an output shaft of the low-speed motor; the first straight gear is connected to the rotating shaft; the guide sliding shaft sleeve is connected to the outer side of the high-temperature furnace; the second straight gear is rotatably connected to the sliding guide shaft sleeve and is meshed with the first straight gear; and the pushing block is connected to the bottom of the second straight gear and matched with the first material baffle plate.

Preferably, still including unloading mechanism, unloading mechanism is including: the wedge block is connected to the top of the second straight gear; the first support frame is connected to the first fixing frame; the feeding hopper is connected to the first support frame and communicated with the high-temperature furnace; the first fixing block is connected to one side of the high-temperature furnace; a guide frame connected to the lower part of the high temperature furnace; the second material baffle plate is connected to the guide carriage in a sliding manner, and the wedge-shaped block is matched with the second material baffle plate; and the tension spring is connected between the second material retaining plate and the first fixing block.

Preferably, still include dustproof mechanism, dustproof mechanism includes: the second fixed block is connected to one side of the top of the discharging hopper; the second cover plate is rotatably connected to the second fixed block; the second torsion spring is connected between the second cover plate and the second fixing block; the first handle is connected to the top of the second cover plate.

Preferably, still including receiving mechanism, receiving mechanism is including: the second support frame is connected to the top of the underframe; the receiving hopper is connected to the top of the second supporting frame; the material receiving box is connected to the second support frame in a sliding manner; the second handle is connected to the material receiving box.

Preferably, the exhaust pipe is connected with the high-temperature furnace in a threaded manner.

(3) Advantageous effects

1. According to the invention, rare earth can be dried through the high-temperature furnace, the rare earth can be uniformly heated through the stirring mechanism, the drying effect is improved, the dried rare earth can be conveniently removed through the material blocking mechanism, and the drying efficiency is improved.

2. Can not need the manual work to promote first striker plate through shedding mechanism, make the operation more convenient, can realize carrying out the unloading to the high temperature furnace through unloading mechanism moreover, do not need the manual work to stimulate second mount rebound, reduce artificial intensity of labour, further improve work efficiency.

3. Can prevent through dustproof mechanism that external impurity from falling into down in the hopper, avoid tombarthite to receive the pollution, guarantee the quality of tombarthite.

Drawings

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

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

Fig. 3 is a schematic perspective view of a stirring mechanism and a material blocking mechanism of the invention.

Fig. 4 is a schematic perspective view of the discharging mechanism of the present invention.

Fig. 5 is a schematic perspective view of the blanking mechanism of the present invention.

Fig. 6 is a schematic perspective view of the dust-proof mechanism of the present invention.

Fig. 7 is a schematic perspective view of the receiving mechanism of the present invention.

The symbols in the drawings are: 1-bottom frame, 2-first fixing frame, 3-high temperature furnace, 31-exhaust pipe, 4-stirring mechanism, 41-second fixing frame, 42-first cover plate, 43-stirrer, 5-baffle mechanism, 51-baffle block, 52-connecting rod, 53-first baffle plate, 54-first torsion spring, 6-unloading mechanism, 61-third fixing frame, 62-low-speed motor, 63-rotating shaft, 64-first straight gear, 65-sliding guide shaft sleeve, 66-second straight gear, 67-push block, 7-blanking mechanism, 71-wedge block, 72-first supporting frame, 73-blanking hopper, 74-first fixing block, 75-sliding guide frame, 76-second baffle plate, 77-tension spring, 8-dustproof mechanism, 81-second fixed block, 82-second cover plate, 83-second torsion spring, 84-first handle, 9-material receiving mechanism, 91-second support frame, 92-material receiving hopper, 93-material receiving box and 94-second handle.

Detailed Description

The invention is further described below with reference to the figures and examples.

Example 1

The utility model provides a drying equipment is used in tombarthite production and processing, as shown in fig. 1-3, including chassis 1, first mount 2, high temperature furnace 3, blast pipe 31, rabbling mechanism 4 and stock stop 5, chassis 1 top is connected with first mount 2, is connected with high temperature furnace 3 on the first mount 2, and the top right side of high temperature furnace 3 is connected with blast pipe 31, and rabbling mechanism 4 is installed at the top of high temperature furnace 3, and the bottom of high temperature furnace 3 is connected with stock stop 5.

Rabbling mechanism 4 has placed second mount 41 including second mount 41, first apron 42 and agitator 43 in the top outside of high temperature furnace 3, and second mount 41 sub-unit connection has first apron 42, and first apron 42 lid is at the top of high temperature furnace 3, and agitator 43 is installed at the top of second mount 41, and agitator 43 passes first apron 42 and stretches into in the high temperature furnace 3.

The material blocking mechanism 5 comprises a stop block 51, a connecting rod 52, a first material blocking plate 53 and a first torsion spring 54, the bottom of the high-temperature furnace 3 is connected with the two stop blocks 51, the connecting rod 52 is connected with the right side of the bottom of the high-temperature furnace 3 in a rotating mode, the bottom of the connecting rod 52 is connected with the first material blocking plate 53, the left end of the first material blocking plate 53 blocks a discharge hole in the bottom of the high-temperature furnace 3, the bottom of the first material blocking plate 53 is in top contact with the stop block 51, and the first torsion spring 54 is connected between the first material blocking plate 53 and the high-temperature furnace 3.

When the rare earth needs to be dried, the second fixing frame 41 is manually pulled upwards, the stirrer 43 and the first cover plate 42 move upwards along with the first cover plate 42, the top of the high-temperature furnace 3 is not blocked by the first cover plate 42, then the rare earth is manually poured into the high-temperature furnace 3, the second fixing frame 41 and the first cover plate 42 are placed on the high-temperature furnace 3 again, then the high-temperature furnace 3 is started to work to heat the rare earth, steam generated after the rare earth is heated is discharged through the exhaust pipe 31, meanwhile, the stirrer 43 is started to work, the rare earth in the high-temperature furnace 3 is stirred by the operation of the stirrer 43, so that the rare earth is uniformly heated, the drying effect of the rare earth is improved, after the rare earth in the high-temperature furnace 3 is dried, the right end of the first material blocking plate 53 is manually pushed to move backwards, the first material blocking plate 53 rotates anticlockwise, the first torsion spring 54 is compressed, so that the first material blocking plate 53 moves away from a discharge port at the bottom of the high-temperature furnace 3, when all the rare earth is discharged, the first baffle plate 53 is loosened, the first baffle plate 53 is driven to reset under the action of the first torsion spring 54, and then the stirrer 43 and the high-temperature furnace 3 are closed, so that the rare earth can be dried.

Example 2

On the basis of embodiment 1, as shown in fig. 4 to 5, the discharging device further includes a discharging mechanism 6, the discharging mechanism 6 includes a third fixing frame 61, a low-speed motor 62, a rotating shaft 63, a first straight gear 64, a sliding guide shaft sleeve 65, a second straight gear 66 and a pushing block 67, the third fixing frame 61 is connected to the right side of the middle portion of the high-temperature furnace 3, the low-speed motor 62 is mounted on the third fixing frame 61, the rotating shaft 63 is connected to an output shaft of the low-speed motor 62, the lower end of the rotating shaft 63 is connected to the first straight gear 64, the sliding guide shaft sleeve 65 is connected to the outer side of the lower portion of the high-temperature furnace 3, the second straight gear 66 is rotatably connected to the outer side of the sliding guide shaft sleeve 65, the second straight gear 66 is engaged with the first straight gear 64, the pushing block 67 is connected to the bottom of the second straight gear 66, and the pushing block 67 is engaged with the first striker plate 53.

When the rare earth in the high temperature furnace 3 needs to be discharged, the low-speed motor 62 is started to work, the low-speed motor 62 works to drive the first straight gear 64 to rotate through the rotating shaft 63, the first straight gear 64 rotates to drive the second straight gear 66 to rotate, the push block 67 moves along with the first straight gear, the push block 67 moves to push the first baffle plate 53 to rotate anticlockwise, the first torsion spring 54 is compressed, the rare earth in the high temperature furnace 3 is discharged downwards through the discharge port, when the push block 67 is not in contact with the first baffle plate 53, the first baffle plate 53 is driven to reset under the action of the first torsion spring 54, so that the first baffle plate 53 does not need to be manually pushed, and the operation is more convenient.

The blanking mechanism 7 comprises a wedge block 71, a first support frame 72, a blanking hopper 73, a first fixing block 74, a sliding guide frame 75, a second blanking plate 76 and a tension spring 77, the top of the second straight gear 66 is connected with the wedge block 71, the left side of the first fixing frame 2 is connected with the first support frame 72, the first support frame 72 is connected with the blanking hopper 73, the blanking hopper 73 is connected with the high-temperature furnace 3, the upper portion of the left side of the high-temperature furnace 3 is connected with the first fixing block 74, the lower portion of the high-temperature furnace 3 is connected with the sliding guide frame 75, the sliding guide frame 75 is connected with the second blanking plate 76 in a sliding mode, the wedge block 71 is matched with the second blanking plate 76, the second blanking plate 76 is connected with the lower portion of the blanking hopper 73 in a sliding mode, and the tension spring 77 is connected between the second blanking plate 76 and the first fixing block 74.

Rare earth is poured into the blanking hopper 73, when the second straight gear 66 rotates, the wedge 71 rotates along with the wedge 71, when the wedge 71 rotates to be in contact with the second baffle plate 76, the wedge 71 continues to move to push the second baffle plate 76 to move upwards, the tension spring 77 is compressed, the blanking hopper 73 is not blocked after the second baffle plate 76 moves upwards, therefore, the rare earth in the blanking hopper 73 flows into the high-temperature furnace 3, when the wedge 71 does not contact with the second baffle plate 76, the second baffle plate 76 is driven to reset downwards under the action of the tension spring 77 to block the blanking hopper 73, blanking of the high-temperature furnace 3 can be realized, the second fixing frame 41 does not need to be pulled to move upwards, the labor intensity of workers is reduced, and the working efficiency is improved.

Example 3

On the basis of embodiment 2, as shown in fig. 6 to 7, the dust-proof mechanism 8 is further included, the dust-proof mechanism 8 includes a second fixing block 81, a second cover plate 82, a second torsion spring 83 and a first handle 84, the second fixing block 81 is connected to the front side of the top of the discharging hopper 73, the second cover plate 82 is rotatably connected to the second fixing block 81, the second torsion spring 83 is connected between the second cover plate 82 and the second fixing block 81, and the first handle 84 is connected to the top of the second cover plate 82.

When rare earth needs to be poured into the hopper 73, the second cover plate 82 is opened by manually holding the first handle 84, the second torsion spring 83 compresses, then the rare earth can be poured into the hopper 73, after the rare earth is poured into the hopper, the first handle 84 is loosened, the second cover plate 82 is driven to reset under the action of the second torsion spring 83, and therefore the second cover plate 82 can prevent external impurities from falling into the hopper 73.

Still including receiving mechanism 9, receiving mechanism 9 is including second support frame 91, connect hopper 92, connect workbin 93 and second handle 94, and 1 top intermediate junction of chassis has second support frame 91, and second support frame 91 top is connected with and connects hopper 92, and second support frame 91 inboard is connected with to connect workbin 93 slidingly, connects workbin 93 front side to be connected with second handle 94.

The tombarthite after drying through high temperature furnace 3 discharges and drops in connecing hopper 92 in, the tombarthite again through connecing hopper 92 to drop downwards in connecing workbin 93, when the tombarthite in connecing workbin 93 need to be poured, artifical pulling second handle 94 moves forward, so can be with connecing workbin 93 to pull out from second support frame 91, then will connect the tombarthite in the workbin 93 to pour out can.

The above examples are merely representative of preferred embodiments of the present invention, and the description thereof is more specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, various changes, modifications and substitutions can be made without departing from the spirit of the present invention, and these are all within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (4)

1. The utility model provides a drying equipment is used in tombarthite production and processing which characterized in that, including:

the top of the bottom frame (1) is connected with a first fixing frame (2);

a high temperature furnace (3) connected to the first fixing frame (2);

an exhaust pipe (31) connected to the top side of the high-temperature furnace (3);

a stirring mechanism (4) arranged on the top of the high-temperature furnace (3);

the material blocking mechanism (5) is connected to the bottom of the high-temperature furnace (3);

the stirring mechanism (4) comprises:

a second fixing frame (41) which is arranged outside the top of the high-temperature furnace (3);

a first cover plate (42) connected to the lower part of the second fixing frame (41), the first cover plate (42) covering the top of the high temperature furnace (3);

the stirrer (43) is arranged at the top of the second fixing frame (41), and the stirrer (43) penetrates through the first cover plate (42) and extends into the high-temperature furnace (3);

stock stop (5) including:

the block (51), the block (51) is connected to one side of the bottom of the high-temperature furnace (3);

a connecting rod (52) which is rotatably connected to one side of the bottom of the high-temperature furnace (3);

the first material baffle plate (53) is connected to the connecting rod (52), and one end of the first material baffle plate (53) blocks the bottom of the high-temperature furnace (3);

a first torsion spring (54) connected between the first striker plate (53) and the high temperature furnace (3);

still including shedding mechanism (6), shedding mechanism (6) including:

a third fixing frame (61) connected to one side of the high-temperature furnace (3);

a low-speed motor (62) mounted on the third mount (61);

a rotating shaft (63) connected to the output shaft of the low-speed motor (62);

a first straight gear (64) connected to the rotating shaft (63);

a slide guide shaft sleeve (65) connected to the outer side of the high temperature furnace (3);

a second spur gear (66) rotatably connected to the sliding guide shaft sleeve (65), the second spur gear (66) being engaged with the first spur gear (64);

the pushing block (67) is connected to the bottom of the second straight gear (66), and the pushing block (67) is matched with the first material baffle plate (53);

still including unloading mechanism (7), unloading mechanism (7) including:

a wedge block (71) connected to the top of the second spur gear (66);

a first support frame (72) connected to the first fixing frame (2);

the lower hopper (73) is connected to the first support frame (72), and the lower hopper (73) is communicated with the high-temperature furnace (3);

a first fixing block (74) connected to one side of the high temperature furnace (3);

a guide frame (75) connected to the lower part of the high-temperature furnace (3);

the second material blocking plate (76) is connected to the guide frame (75) in a sliding mode, and the wedge-shaped block (71) is matched with the second material blocking plate (76);

and the tension spring (77) is connected between the second baffle plate (76) and the first fixing block (74).

2. The drying equipment for the production and processing of rare earth according to claim 1, further comprising a dust-proof mechanism (8), wherein the dust-proof mechanism (8) comprises:

a second fixed block (81) connected to one side of the top of the discharge hopper (73);

a second cover plate (82) rotatably connected to the second fixing block (81);

a second torsion spring (83) connected between the second cover plate (82) and the second fixing block (81);

a first handle (84) connected to the top of the second cover (82).

3. The drying equipment for producing and processing rare earth according to claim 2, further comprising a material receiving mechanism (9), wherein the material receiving mechanism (9) comprises:

a second support frame (91) connected to the top of the chassis (1);

a receiving hopper (92) connected to the top of the second support frame (91);

a material receiving box (93) which is connected on the second supporting frame (91) in a sliding way;

a second handle (94) connected to the material receiving box (93).

4. The drying equipment for producing and processing rare earth according to claim 3, wherein the exhaust pipe (31) is connected with the high temperature furnace (3) in a threaded manner.

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