阅读说明：本技术 一种能充分将溢散的硅锰矿粉回收的设备及其收纳机构 (Equipment capable of sufficiently recycling overflowing silicon-manganese mineral powder and containing mechanism thereof ) 是由 袁恒辉 于 2021-09-07 设计创作，主要内容包括：本发明涉及硅锰矿粉回收领域,尤其涉及一种能充分将溢散的硅锰矿粉回收的设备及其收纳机构,包括有收纳箱体、连接杆、开槽导向板、驱动导向部件、粉尘收纳刮离部件等；收纳箱体上固接有连接杆,连接杆一端固接有开槽导向板,驱动导向部件设于开槽导向板上,粉尘收纳刮离部件滑动式连接于收纳箱体上。通过粉尘收纳刮离部件,U型主动板与U型从动板将收纳箱体内壁附着的硅锰矿粉向下刮除,通过收纳箱体内凹槽的作用,U型主动板与U型从动板相向运动,使得U型主动板及U型从动板始终与收纳箱体内壁紧密贴合,U型主动板与U型从动板充分地将收纳箱体内壁附着的硅锰矿粉推至收纳箱体最下方。(The invention relates to the field of silicomanganese mineral powder recovery, in particular to equipment capable of fully recovering scattered silicomanganese mineral powder and a receiving mechanism thereof, wherein the equipment comprises a receiving box body, a connecting rod, a slotted guide plate, a driving guide part, a dust receiving scraping part and the like; the storage box body is fixedly connected with a connecting rod, one end of the connecting rod is fixedly connected with a slotted guide plate, a driving guide part is arranged on the slotted guide plate, and the dust storage scraping part is connected to the storage box body in a sliding mode. The dust collecting and scraping component is used for collecting and scraping the manganite powder attached to the inner wall of the storage box body downwards through the dust collecting and scraping component, the U-shaped driving plate and the U-shaped driven plate move oppositely under the action of an inner groove of the storage box body, so that the U-shaped driving plate and the U-shaped driven plate are always closely attached to the inner wall of the storage box body, and the manganite powder attached to the inner wall of the storage box body is fully pushed to the lowest part of the storage box body through the U-shaped driving plate and the U-shaped driven plate.)

1. The utility model provides an equipment that can fully retrieve silicon manganese powdered ore that overflows and receiving mechanism thereof, a serial communication port, including storage box (1), connecting rod (2), fluting deflector (3), drive guide part (4), dust is accomodate and is scraped part (5), blanking open and shut part (6) and isolation part (7), the rigid coupling has connecting rod (2) on storage box (1), connecting rod (2) one end rigid coupling has fluting deflector (3), drive guide part (4) are located on fluting deflector (3), dust is accomodate and is scraped part (5) sliding type and connect on storage box (1), be equipped with blanking open and shut part (6) on connecting rod (2), isolation part (7) are located on storage box (1).

2. The equipment and the receiving mechanism thereof for fully recycling the scattered silicon-manganese ore powder according to claim 1, wherein the driving guide part (4) comprises an electric push rod (41), a pulling plate (42), a rigid spring (43), an L-shaped guide rod (44), a movable push sleeve (45), a return spring (46), a limiting fixture block (47) and a homing spring (48), the electric push rod (41) is fixedly connected to the slotted guide plate (3), the pulling plate (42) is fixedly connected to a telescopic shaft of the electric push rod (41), the rigid spring (43) is fixedly connected to the bottom surface of the pulling plate (42), the L-shaped guide rod (44) is fixedly connected to one end of the pulling plate (42), the movable push sleeve (45) is slidably connected to the slotted guide plate (3), the return spring (46) is connected between the movable push sleeve (45) and the L-shaped guide rod (44), the slotting guide plate (3) is connected with a limiting clamping block (47) in a sliding mode, a homing spring (48) is connected between the limiting clamping block (47) and the slotting guide plate (3), and the movable push sleeve (45) is in contact with the limiting clamping block (47).

3. The equipment and the receiving mechanism thereof according to claim 2, wherein the dust collecting scraper component (5) comprises a U-shaped driving plate (51), a U-shaped driven plate (52), a first compression spring (53), a vertical rod (54) and a sealing plate (55), the U-shaped driving plate (51) is slidably connected in the receiving box (1), the U-shaped driven plate (52) is also slidably connected in the receiving box (1), the U-shaped driving plate (51) is slidably connected with the U-shaped driven plate (52), two pairs of first compression springs (53) are connected between the U-shaped driving plate (51) and the U-shaped driven plate (52), the vertical rod (54) is fixedly connected with the top surface of the U-shaped driving plate (51), the vertical rod (54) is fixedly connected with one end of the rigid spring (43), the sealing plate (55) is slidably connected on the vertical rod (54), the sealing plate (55) is connected with the containing box body (1) in a sliding way.

4. The equipment and the receiving mechanism thereof capable of sufficiently recycling the scattered silicon-manganese ore powder according to claim 3, wherein the blanking opening and closing part (6) comprises a movable frame (61), a second compression spring (62), a push rod (63), a push plate (64), a third compression spring (65), a fixed triangular plate (66), a cover plate (67), a chute frame (68), a top plate (69) and a fourth compression spring (610), the movable frame (61) is slidably connected on the connecting rod (2), the second compression spring (62) is connected between the movable frame (61) and the connecting rod (2), the push rod (63) is slidably connected on the movable frame (61), the push plate (64) is fixedly connected at the bottom end of the push rod (63), the third compression spring (65) is connected between the push plate (64) and the movable frame (61), the fixed triangular plate (66) is fixedly connected at one end of the connecting rod (2), the bottom of the storage box body (1) is connected with a cover plate (67) through a hinge, two sides of the storage box body (1) are fixedly connected with a chute frame (68), a top plate (69) is connected to a movable frame (61) in a sliding mode, the cover plate (67) is in contact with the top plate (69), the top plate (69) is in sliding fit with the two chute frames (68), and a fourth compression spring (610) is connected between the top plate (69) and the movable frame (61).

5. The equipment and the receiving mechanism thereof capable of sufficiently recovering the overflowing silicon-manganese ore powder according to claim 4, wherein the isolation component (7) comprises a filter screen frame (71), a hole-opening movable baffle (72), a fifth compression spring (73), a guide seat (74), a slotted swing rod (75), a push rod (76) with a triangular plate, a sixth compression spring (77) and an inclined plate (78), one side of the receiving box body (1) is fixedly connected with the filter screen frame (71), the filter screen frame (71) is slidably connected with the hole-opening movable baffle (72), the fifth compression spring (73) is connected between the hole-opening movable baffle (72) and the filter screen frame (71), the guide seat (74) is fixedly connected to the lower part of the receiving box body (1), the slotted swing rod (75) is rotatably connected to the guide seat (74), and the slotted swing rod (75) is slidably matched with the hole-opening movable baffle (72), the guide seat (74) is connected with a push rod (76) with a triangular plate in a sliding mode, a sixth compression spring (77) is connected between the push rod (76) with the triangular plate and the guide seat (74), the push rod (76) with the triangular plate is in contact with the slotted swing rod (75), one end of the top plate (69) is fixedly connected with an inclined plate (78), and the inclined plate (78) is in contact with the push rod (76) with the triangular plate.

6. The apparatus and the receiving mechanism thereof for sufficiently recycling the overflowed silicon-manganese ore powder according to claim 5, wherein the apparatus and the receiving mechanism thereof further comprise a shaking-off component (8), the shaking-off component (8) is disposed on the connecting rod (2), the shaking-off component (8) comprises a pushing frame (81) with a triangle plate, a movable guide rod (82), a seventh compression spring (83), a triangle strip (84) and a shaking spring (85), the pushing frame (81) with the triangle plate is slidably connected to the connecting rod (2), the movable guide rod (82) is fixedly connected to the pushing frame (81) with the triangle plate, the movable guide rod (82) is slidably connected to one of the inclined groove frames (68), the seventh compression spring (83) is connected between the pushing frame (81) with the connecting rod (2) with the triangle plate, the cover plate (67) is fixedly connected to a pair of shaking springs (85), one end of the shaking spring (85) is fixedly connected to the triangle strip (84), the movable guide rod (82) is in contact with the triangular strip (84), and the triangular strip (84) is in contact with the cover plate (67).

Technical Field

The invention relates to the field of silicomanganese mineral powder recovery, in particular to equipment capable of fully recovering overflowed silicomanganese mineral powder and a storage mechanism thereof.

Background

The silicomanganese alloy is mainly used as a medium material of a deoxidizing agent and an alloying agent for steel production and is also a main raw material for producing medium-low carbon ferromanganese, the silicomanganese alloy is an alloy consisting of manganese, silicon, iron, a small amount of carbon and other elements, is an iron alloy with wide application and high yield, and a large amount of silicomanganese mineral powder can be produced in silicomanganese smelting production and can be recycled and reused after treatment.

In the silicomanganese smelting production technology, when the existing mixing device recovers the silicomanganese mineral powder, the silicomanganese mineral powder needs to be unloaded, the discharge port of the device is manually opened, the unloading speed of the silicomanganese mineral powder cannot be controlled, and the silicomanganese mineral powder is easy to scatter on the ground, so that the material resources are wasted.

Disclosure of Invention

The invention aims to provide equipment and a containing mechanism thereof, which can recover overflowed silicomanganese ore powder, treat redundant residual silicomanganese ore powder on the equipment and control intermittent discharge of the silicomanganese ore powder and can fully recover the overflowed silicomanganese ore powder, so as to solve the problems that the discharge speed cannot be controlled and materials are easy to spill on the ground in the background technology.

The technical scheme is as follows: the utility model provides an equipment that can fully retrieve silicon manganese powdered ore that overflows and receiving mechanism thereof, including accomodate the box, the connecting rod, the fluting deflector, drive guide part, the dust is accomodate and is scraped from the part, blanking part and isolation part that opens and shuts, the rigid coupling has the connecting rod on accomodating the box, connecting rod one end rigid coupling has the fluting deflector, drive guide part locates on the fluting deflector, the dust is accomodate and is scraped from part slidingtype connection on accomodating the box, be equipped with the blanking part that opens and shuts on the connecting rod, isolation part locates on accomodating the box.

Preferably, the driving guide part comprises an electric push rod, a pull plate, a rigid spring, an L-shaped guide rod, a movable push sleeve, a reset spring, a limiting fixture block and a homing spring, the electric push rod is fixedly connected to the slotted guide plate, the pull plate is fixedly connected to an expansion shaft of the electric push rod, the rigid spring is fixedly connected to the bottom surface of the pull plate, the L-shaped guide rod is fixedly connected to one end of the pull plate, the movable push sleeve is slidably connected to the L-shaped guide rod, the movable push sleeve is slidably connected to the slotted guide plate, the reset spring is connected between the movable push sleeve and the L-shaped guide rod, the limiting fixture block is slidably connected to the slotted guide plate, the homing spring is connected between the limiting fixture block and the slotted guide plate, and the movable push sleeve and the limiting fixture block are in contact with each other.

Preferably, the dust collecting scraping part comprises a U-shaped driving plate, a U-shaped driven plate, first compression springs, a vertical rod and a sealing plate, the U-shaped driving plate is connected in the containing box in a sliding mode, the U-shaped driven plate is connected in the containing box in a sliding mode, the U-shaped driving plate is connected with the U-shaped driven plate in a sliding mode, two pairs of first compression springs are connected between the U-shaped driving plate and the U-shaped driven plate, the top surface of the U-shaped driving plate is fixedly connected with the vertical rod, the vertical rod is fixedly connected with one end of a rigid spring, the sealing plate is connected on the vertical rod in a sliding mode, and the sealing plate is connected with the containing box in a sliding mode.

Preferably, the blanking opening and closing part comprises a movable frame, a second compression spring, a push rod, a push plate, a third compression spring, a fixed triangular plate, a cover plate, a chute frame, a top plate and a fourth compression spring, a movable frame is connected to the connecting rod in a sliding mode, the second compression spring is connected between the movable frame and the connecting rod, the push rod is connected to the movable frame in a sliding mode, the bottom end of the push rod is fixedly connected with the push plate, the third compression spring is connected between the push plate and the movable frame, the fixed triangular plate is fixedly connected to one end of the connecting rod, the bottom of the storage box is connected with the cover plate through hinges, the chute frames are fixedly connected to two sides of the storage box, the top plate is connected to the movable frame in a sliding mode, the cover plate is in mutual contact with the top plate, the top plate is in sliding fit with the two chute frames, and the fourth compression spring is connected between the top plate and the movable frame.

Preferably, the isolation component comprises a filter screen frame, a hole-opening movable baffle, a fifth compression spring, a guide seat, a slotting swing rod, a push rod with a triangular plate, a sixth compression spring and an inclined plate, the filter screen frame is fixedly connected to one side of the storage box body, the hole-opening movable baffle is slidably connected to the filter screen frame, the fifth compression spring is connected between the hole-opening movable baffle and the filter screen frame, the guide seat is fixedly connected to the lower portion of the storage box body, the slotting swing rod is rotatably connected to the guide seat, the slotting swing rod is in sliding fit with the hole-opening movable baffle, the push rod with the triangular plate is slidably connected to the guide seat, the sixth compression spring is connected between the push rod with the triangular plate and the guide seat, the push rod with the triangular plate is in mutual contact with the slotting swing rod, the inclined plate is fixedly connected to one end of the top plate, and the inclined plate is in mutual contact with the push rod with the triangular plate.

Preferably, the shaking device is further included and is arranged on the connecting rod, the shaking device comprises a triangular plate pushing frame, a movable guide rod, a seventh compression spring, a triangular bar and a shaking spring, the triangular plate pushing frame is connected to the connecting rod in a sliding mode, the movable guide rod is fixedly connected to the triangular plate pushing frame and is connected with a chute frame in a sliding mode, the seventh compression spring is connected between the triangular plate pushing frame and the connecting rod, the cover plate is fixedly connected with a pair of shaking springs, one end of each shaking spring is fixedly connected with the triangular bar, the movable guide rod is in contact with the triangular bar, and the triangular bar is in contact with the cover plate.

The invention has the beneficial effects that: the dust collecting and scraping component is used for collecting and scraping the manganite powder attached to the inner wall of the storage box body downwards through the dust collecting and scraping component, the U-shaped driving plate and the U-shaped driven plate move oppositely under the action of an inner groove of the storage box body, so that the U-shaped driving plate and the U-shaped driven plate are always closely attached to the inner wall of the storage box body, and the manganite powder attached to the inner wall of the storage box body is fully pushed to the lowest part of the storage box body through the U-shaped driving plate and the U-shaped driven plate.

Through the blanking part that opens and shuts, roof downstream no longer supports the apron, receives the downward swing of gravity influence apron to open the containing box for the silicomanganese powdered ore drops from the containing box, and the staff of being convenient for collects the silicomanganese powdered ore.

Through the isolation component, the fifth compression spring in the stretching state resets and drives the opening movable baffle to move towards the direction close to the push rod with the triangular plate, the opening movable baffle blocks the filter screen frame, the air pump does not convey the silicomanganese mineral powder into the containing box through the filter screen frame, and the air pump continues to convey the silicomanganese mineral powder into the containing box when the cover plate is opened.

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 view of a first partial body structure according to the present invention.

FIG. 4 is a schematic view of a second partial body structure according to the present invention.

Fig. 5 is a schematic view of a partially cut-away and separated perspective structure of the present invention.

Fig. 6 is a partial perspective view of the driving guide member of the present invention.

Fig. 7 is a partially separated perspective view of the driving guide part of the present invention.

Fig. 8 is a schematic view of a first partially-separated body structure of the blanking opening and closing part of the invention.

Fig. 9 is a schematic view of a second partial structure of the blanking opening and closing component of the invention.

Fig. 10 is a schematic view of a first partial body construction of the spacer member of the present invention.

FIG. 11 is a schematic view of a second partial body construction of the spacer body of the present invention.

Fig. 12 is a schematic view of a first partially assembled body of the shake-off member of the present invention.

Fig. 13 is a schematic diagram of a second partial body structure of the shake-off member of the present invention.

Description of reference numerals: 1_ storage box, 2_ connecting rod, 3_ slotted guide plate, 4_ driving guide part, 41_ electric push rod, 42_ pull plate, 43_ rigid spring, 44_ L type guide rod, 45_ movable push sleeve, 46_ return spring, 47_ limit clamping block, 48_ homing spring, 5_ dust storage scraping part, 51_ U type driving plate, 52_ U type driven plate, 53_ first compression spring, 54_ vertical rod, 55_ sealing plate, 6_ blanking opening and closing part, 61_ movable frame, 62_ second compression spring, 63_ push rod, 64_ push plate, 65_ third compression spring, 66_ fixed triangle plate, 67_ cover plate, 68_ chute frame, 69_ top plate, 610_ fourth compression spring, 7_ isolation part, 71_ filter screen frame, 72_ perforated movable baffle, 73_ fifth compression spring, 74_ guide seat, 75_ slotted swing rod, 76_ push rod with triangle, 77_ sixth compression spring, 78_ sloping plate, 8_ shake-off component, 81_ push rack with triangle, 82_ movable guide rod, 83_ seventh compression spring, 84_ triangle bar, 85_ shake spring.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

The utility model provides an equipment that can fully retrieve scattered silicomanganese powdered ore and receiving mechanism thereof, as shown in fig. 1-13, including the storage box 1, connecting rod 2, fluting deflector 3, drive guide part 4, dust is accomodate and is scraped off part 5, blanking switching part 6 and isolation part 7, the rigid coupling has connecting rod 2 on the storage box 1 for accomodating silicomanganese powdered ore, connecting rod 2 one end rigid coupling has the fluting deflector 3 that is used for the direction, drive guide part 4 is located on fluting deflector 3, dust is accomodate and is scraped off part 5 sliding type connection on storage box 1, dust is accomodate and is scraped off part 5 and be used for scraping off the silicomanganese powdered ore that adheres to the inner wall of storage box 1 downwards, be equipped with blanking switching part 6 on connecting rod 2, isolation part 7 for keeping apart silicomanganese powdered ore is located on storage box 1.

The driving guide component 4 comprises an electric push rod 41, a pulling plate 42, a rigid spring 43, an L-shaped guide rod 44, a movable push sleeve 45, a return spring 46, a limiting fixture block 47 and a return spring 48, an electric push rod 41 is fixedly connected to the slotted guide plate 3, a pull plate 42 is fixedly connected to a telescopic shaft of the electric push rod 41, a rigid spring 43 is fixedly connected to the bottom surface of the pull plate 42, an L-shaped guide rod 44 is fixedly connected to one end of the pull plate 42, a movable push sleeve 45 is slidably connected to the L-shaped guide rod 44 far away from the pull plate 42, the movable push sleeve 45 is slidably connected to the slotted guide plate 3, a reset spring 46 is connected between the movable push sleeve 45 and the L-shaped guide rod 44, a limiting clamping block 47 is slidably connected to the slotted guide plate 3, a homing spring 48 is connected between the limiting clamping block 47 and the slotted guide plate 3, the movable push sleeve 45 is in contact with the limiting clamping block 47, and the limiting clamping block 47 is used for blocking the movable push sleeve 45.

The dust collecting scraping component 5 comprises a U-shaped driving plate 51 and a U-shaped driven plate 52, the storage box comprises first compression springs 53, vertical rods 54 and sealing plates 55, a U-shaped driving plate 51 is connected in the storage box 1 in a sliding mode, the U-shaped driving plate 51 is used for scraping the manganite powder attached to the inner wall of the storage box 1 downwards, a U-shaped driven plate 52 is connected in the storage box 1 in a sliding mode likewise, the U-shaped driven plate 52 is used for scraping the manganite powder attached to the inner wall of the storage box 1 downwards, the U-shaped driving plate 51 is connected with the U-shaped driven plate 52 in a sliding mode, two pairs of first compression springs 53 are connected between the U-shaped driving plate 51 and the U-shaped driven plate 52, the vertical rods 54 are fixedly connected to the top face of the U-shaped driving plate 51, the vertical rods 54 are fixedly connected with one ends of the rigid springs 43 far away from the pulling plate 42, the sealing plates 55 are connected on the vertical rods 54 in a sliding mode, the sealing plates 55 are used for sealing the storage box 1, and the sealing plates 55 are connected with the storage box 1 in a sliding mode.

The blanking opening and closing part 6 comprises a movable frame 61, a second compression spring 62, a pushing rod 63, a pushing plate 64, a third compression spring 65, a fixed triangle plate 66, a cover plate 67, a chute frame 68, a top plate 69 and a fourth compression spring 610, wherein the connecting rod 2 is slidably connected with the movable frame 61, the second compression spring 62 is connected between the movable frame 61 and the connecting rod 2, the pushing rod 63 is slidably connected on the movable frame 61 close to the connecting rod 2, the pushing plate 64 is fixedly connected at the bottom end of the pushing rod 63, the third compression spring 65 is connected between the pushing plate 64 and the movable frame 61, one end of the connecting rod 2 far away from the chute guide plate 3 is fixedly connected with the fixed triangle plate 66, the fixed triangle plate 66 is used for pushing the pushing plate 64 and the pushing rod 63 to move downwards, the bottom of the containing box body 1 is connected with the cover plate 67 through a hinge, the cover plate 67 is used for covering the bottom of the containing box body 1, the chute frames 68 are fixedly connected at two sides of the containing box body 1, the top plate 69 is slidably connected to the movable frame 61, the cover plate 67 and the top plate 69 are in contact with each other, the top plate 69 is used for supporting the cover plate 67, the top plate 69 is slidably matched with the two chute frames 68, the chute frames 68 are used for guiding the top plate 69, and a fourth compression spring 610 is connected between the top plate 69 and the movable frame 61.

The isolation component 7 comprises a filter screen frame 71, a hole-opening movable baffle 72, a fifth compression spring 73, a guide seat 74, a slotted swing rod 75, a push rod with a triangular plate 76, a sixth compression spring 77 and an inclined plate 78, wherein one side of the containing box body 1 is fixedly connected with the filter screen frame 71, the filter screen frame 71 is slidably connected with the hole-opening movable baffle 72, the hole-opening movable baffle 72 is used for blocking the filter screen frame 71, the fifth compression spring 73 is connected between the hole-opening movable baffle 72 and the filter screen frame 71, the lower part of the containing box body 1 is fixedly connected with the guide seat 74, the guide seat 74 is rotatably connected with the slotted swing rod 75, the slotted swing rod 75 is slidably matched with the hole-opening movable baffle 72, the guide seat 74 is slidably connected with a push rod with a triangular plate 76, the push rod with the triangular plate 76 is used for pushing the slotted swing rod 75, and the sixth compression spring 77 is connected between the push rod with the guide seat 74, the push rod 76 with the triangular plate is contacted with the slotted swing rod 75, one end of the top plate 69 is fixedly connected with an inclined plate 78, the inclined plate 78 is contacted with the push rod 76 with the triangular plate, and the inclined plate 78 is used for pushing the push rod 76 with the triangular plate.

When the silicon-manganese ore powder overflowing from the air needs to be recovered, an air pump outside the filter screen frame 71 is connected, the silicon-manganese ore powder is sucked into the containing box body 1 through the air pump, a worker manually controls the electric push rod 41 to contract, the electric push rod 41 contracts to drive the pull plate 42 to move downwards, the pull plate 42 pushes the vertical rod 54 and the upper device thereof to move downwards through the rigid spring 43, the U-shaped driving plate 51 drives the U-shaped driven plate 52 to move downwards, the U-shaped driving plate 51 and the U-shaped driven plate 52 scrape the silicon-manganese ore powder attached to the inner wall of the containing box body 1 downwards, the U-shaped driving plate 51 and the U-shaped driven plate 52 move towards each other through the action of the grooves in the containing box body 1, the first compression spring 53 is compressed, the U-shaped driving plate 51 and the U-shaped driven plate 52 are always tightly attached to the inner wall of the containing box body 1, and the U-shaped driving plate 51 and the U-shaped driven plate 52 fully push the silicon-manganese ore powder attached to the lowest part of the containing box body 1, at this time, the U-shaped driving plate 51 and the U-shaped driven plate 52 move to the lowest part of the groove in the storage box 1, and the vertical rod 54 and the device thereon do not move downward any more.

The telescopic rod of the electric push rod 41 continues to drive the pulling plate 42 to move downwards, the rigid spring 43 is compressed, the pulling plate 42 drives the L-shaped guide rod 44 and the upper device thereof to move downwards, the movable push sleeve 45 moves towards the direction far away from the containing box body 1 under the action of the groove of the slotted guide plate 3, when the movable pushing sleeve 45 contacts with the pushing rod 63, the movable pushing sleeve 45 pushes the pushing rod 63 and the upper device thereof to move away from the filter screen frame 71, the second compression spring 62 is compressed, the movable frame 61 drives the top plate 69 to move away from the filter screen frame 71, the top plate 69 is moved downward by the chute frame 68, the fourth compression spring 610 is compressed, the cover plate 67 is no longer supported by the downward movement of the top plate 69, the cover plate 67 swings downward under the influence of gravity to open the storage case 1, so that the silicomanganese mineral powder falls from the containing box body 1, and the staff collects the fallen silicomanganese mineral powder by using the containing frame. Meanwhile, the top plate 69 drives the inclined plate 78 to move downwards, the inclined plate 78 is separated from the push rod with the triangular plate 76, the push rod with the triangular plate 76 is driven to move away from the slotted oscillating rod 75 by resetting of the sixth compression spring 77 in a compression state, the push rod 76 with the triangular plate is separated from the slotted oscillating rod 75, the push rod 76 with the triangular plate is no longer used for blocking the slotted oscillating rod 75, the fifth compression spring 73 in a stretching state resets and drives the hole-opening movable baffle 72 to move towards the direction close to the push rod 76 with the triangular plate, the hole-opening movable baffle 72 pushes the slotted oscillating rod 75 to oscillate, the hole-opening movable baffle 72 moves towards the direction close to the push rod 76 with the triangular plate to block the filter screen frame 71, the air extractor is no longer used for conveying the silicomanganese mineral powder into the storage box body 1 through the filter screen frame 71, and the air extractor is prevented from continuously conveying the silicomanganese mineral powder into the storage box body 1 when the cover plate 67 is opened.

The movable pushing sleeve 45 continuously pushes the pushing rod 63 and the upper device thereof to move in the direction away from the filter screen frame 71, when the pushing plate 64 is contacted with the fixed triangular plate 66, the fixed triangular plate 66 pushes the pushing plate 64 and the pushing rod 63 to move downwards, the third compression spring 65 is stretched, the pushing rod 63 moves downwards to be separated from the movable pushing sleeve 45, the compressed second compression spring 62 resets to drive the movable frame 61 and the upper device thereof to reset, the movable frame 61 drives the pushing rod 63 and the pushing plate 64 to move towards the direction close to the filter screen frame 71, the pushing plate 64 is separated from the fixed triangular plate 66, and the stretched third compression spring 65 resets to drive the pushing rod 63 and the pushing plate 64 to move upwards to reset. Through the effect of the chute frame 68, the movable frame 61 drives the top plate 69 to move upwards, so that the top plate 69 pushes the cover plate 67 to swing upwards, and the cover plate 67 covers the bottom of the storage box 1. The top plate 69 drives the inclined plate 78 to move upwards, the inclined plate 78 pushes the pushing rod 76 with the triangular plate to move towards the direction close to the slotted swing rod 75, the sixth compression spring 77 is compressed, so that the pushing rod 76 with the triangular plate pushes the slotted swing rod 75 to swing, the slotted swing rod 75 swings to drive the hole-opening movable baffle plate 72 to move towards the direction far from the pushing rod 76 with the triangular plate, the fifth compression spring 73 is stretched, and the hole-opening movable baffle plate 72 does not block the filter screen frame 71 any more.

When the movable push sleeve 45 moves to the lowest part of the groove of the slotted guide plate 3, the reset spring 46 in a stretching state resets to drive the movable push sleeve 45 to move towards a direction away from the containing box body 1, then a worker controls the electric push rod 41 to stretch, the electric push rod 41 stretches to drive the pull plate 42 and the upper device thereof to move upwards, the pull plate 42 pulls the vertical rod 54 and the upper device thereof to move upwards through the rigid spring 43, the U-shaped driving plate 51 and the U-shaped driven plate 52 move relatively under the action of the groove in the containing box body 1, meanwhile, the pull plate 42 drives the L-shaped guide rod 44 and the upper device thereof to move upwards, the movable push sleeve 45 moves towards a direction close to the containing box body 1 under the action of the groove in the slotted guide plate 3, the reset spring 46 is stretched, when the movable push sleeve 45 contacts with the limit fixture block 47, the movable push sleeve 45 pushes the limit fixture block 47 to shrink, the return spring 48 is compressed, when the movable push sleeve 45 is separated from the limiting clamping block 47, the compressed return spring 48 resets to drive the limiting clamping block 47 to reset, the limiting clamping block 47 blocks the movable push sleeve 45, and the movable push sleeve 45 is prevented from being reset by the stretched return spring 46 to drive the movable push sleeve 45 to move towards the direction far away from the containing box body 1. And repeating the operation to recover the overflowing silicomanganese ore powder.

Example 2

In addition to the embodiment 1, as shown in fig. 12 to 13, the present invention further includes a shaking-off component 8, the shaking-off component 8 is disposed on the connecting rod 2, the shaking-off component 8 is used for shaking off the silicomanganese ore powder that does not slip off from the cover plate 67, the shaking-off component 8 includes a pushing frame 81 with a triangle plate, a movable guiding rod 82, a seventh compression spring 83, a triangle strip 84 and a shaking spring 85, the pushing frame 81 with the triangle plate is slidably connected to the connecting rod 2, the pushing frame 81 with the triangle plate is fixedly connected to the movable guiding rod 82, the movable guiding rod 82 far from the pushing frame 81 with the triangle plate is slidably connected to a chute frame 68, the seventh compression spring 83 is connected between the pushing frame 81 with the connecting rod 2 with the triangle plate, the cover plate 67 is fixedly connected to a pair of shaking springs 85, one end of the shaking spring 85 far from the cover plate 67 is fixedly connected to the triangle strip 84, the movable guiding rod 82 is in contact with the triangle strip 84, the movable guiding rod 82 is used for pushing the triangle strip 84, the triangular bar 84 is in contact with the cover 67, and the triangular bar 84 is used for pushing the cover 67 to shake.

The pulling plate 42 drives the L-shaped guide rod 44 and the device thereon to move downward, when the movable pushing sleeve 45 contacts the triangular plate pushing frame 81, the movable pushing sleeve 45 pushes the triangular plate pushing frame 81 to move toward the filtering screen frame 71, the seventh compression spring 83 is stretched, the movable guide rod 82 pushes the triangular bar 84 to move away from the slotting guide plate 3, and the shaking spring 85 is stretched. The movable pushing sleeve 45 and the upper device thereof continue to move downwards, when the movable pushing sleeve 45 is separated from the pushing frame 81 with the triangular plate, the stretched shaking spring 85 is reset to drive the triangular bar 84 to move towards the direction close to the slotted guide plate 3, the triangular bar 84 pushes the cover plate 67 to shake, and the cover plate 67 shakes to shake and shake the silicomanganese ore powder which does not slide off, so that more silicomanganese ore powder cannot be adhered to the cover plate 67.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.