CN210965432U - Clean and environment-friendly raw material processing system for anhydrous stemming production - Google Patents

Abstract

The utility model discloses a clean and environment-friendly raw material processing system for producing anhydrous stemming, which comprises a crusher, a bucket elevator and a vibrating screening machine; the discharge hole of the crusher is connected with the feed inlet of the bucket elevator; the discharging opening of the bucket elevator is connected with the material receiving opening of the vibrating screen classifier; a material shifting mechanism is arranged at a feed inlet of the bucket elevator; the material stirring mechanism is hinged with the upper edge of the feeding hole; the lower part of the bucket elevator is also provided with a material receiving box; the upper end of the material receiving box is communicated with the interior of the bucket elevator; a discharge opening is formed in the bottom of the vibrating screen; a material receiving platform is arranged below the discharge opening; the utility model discloses the technical scheme who takes has solved current raw materials processing system and has promoted the problem that the feeding is smooth and utilization ratio of raw materials is low.

Description

Clean and environment-friendly raw material processing system for anhydrous stemming production

Technical Field

The utility model relates to a stemming production facility technical field, concretely relates to clean and environment-friendly anhydrous stemming production raw materials processing system.

Background

The stemming is a refractory material for plugging a taphole and is obtained by stirring and mixing refractory aggregate and a binding agent. The production raw materials of the stemming comprise silicon carbide, brown corundum, high-aluminum aggregate and other raw materials; in order to improve the utilization rate of raw materials, various raw materials need to be crushed; the broken raw materials that pass through bucket elevator again carry the shale shaker in to sieve out different particle sizes, and these raw materials can directly sell after the partial shipment packing according to different particle sizes, also can carry out follow-up processing as the stemming raw materials and produce the stemming. However, the existing raw material processing system has the problems that the feeding smoothness is affected by the blocking condition easily due to too much feeding at the feeding port of the bucket elevator, the utilization rate of raw materials is not high due to the fact that scattered materials accumulated at the bottom of the bucket elevator cannot be well recycled, and the problem that the materials are scattered due to the fact that the flowing packaging bags of particle materials are prone to toppling when the materials are received below the vibrating screen classifier.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a clean and environment-friendly anhydrous stemming production is with raw materials processing system solves current raw materials processing system and promotes the problem that the feeding is smooth and utilization ratio of raw materials is low.

In order to solve the technical problem, the utility model adopts the following technical scheme: a clean environment-friendly raw material processing system for producing anhydrous stemming comprises a crusher, a bucket elevator and a vibrating screening machine; the discharge hole of the crusher is connected with the feed inlet of the bucket elevator; the discharging opening of the bucket elevator is connected with the material receiving opening of the vibrating screen classifier; a material shifting mechanism is arranged at a feed inlet of the bucket elevator; the material stirring mechanism is hinged with the upper edge of the feeding hole; the lower part of the bucket elevator is also provided with a material receiving box; the upper end of the material receiving box is communicated with the interior of the bucket elevator; a discharge opening is formed in the bottom of the vibrating screen; a material receiving platform is arranged below the discharge opening;

furthermore, the material poking mechanism comprises a connecting part, a cross rod and a material poking rod; the connecting part is oppositely arranged above the feed inlet; two ends of the cross rod are erected above the feed inlet in an inclined manner through connecting parts; the material poking rod is hinged with the cross rod;

furthermore, a hook-up part is arranged at the end part of the material poking rod; the surface of the material poking rod is also provided with material breaking teeth;

furthermore, the material receiving platform comprises a supporting seat, a material receiving disc and a check ring; the material receiving disc is arranged on the supporting seat; a circle of clamping grooves are formed in the edge of the upper surface of the material receiving disc; the check ring is arranged in the sliding groove in a sliding manner;

further, the retainer ring is an arc-shaped plate; the upper edge of the baffle ring is provided with a rubber strip;

a material distributing sieve plate is arranged in the material receiving box; the material distributing sieve plate divides the material receiving box into a first material outlet cavity and a second material outlet cavity from top to bottom;

a first discharging door is arranged on the side wall of the first discharging cavity; the lower edge of the first discharging door is hinged to the side wall of the first discharging cavity; a second discharging door is arranged on the side wall of the second discharging cavity; and the lower edge of the second discharging door is hinged to the side wall of the second discharging cavity.

Compared with the prior art, the beneficial effects of the utility model are one of following at least:

1. the material shifting mechanism arranged on the feed port of the bucket elevator can swing in and out of the feed port under the impact force of materials when the materials pass through the feed hopper, so that the effect of shifting the materials is achieved, the materials can be fed successively, and the feed port cannot be blocked due to excessive feeding once;

2. when the materials pass through, the material stirring mechanism is hinged and can be jacked for a certain angle to allow a certain amount of materials to pass through, and along with the falling of the materials, the material stirring mechanism can naturally fall and reset through the hinged element and gravity, so that the excessive passing of the materials is avoided, the occurrence of blocking is reduced, and the smoothness of feeding is improved;

3. the material receiving platform can be used for placing packaging bags during material receiving, and through the protection effect of the material receiving platform, the occurrence of the situation of material dumping is reduced, the material loss is reduced, and the utilization rate of raw materials is improved;

4. connect the workbin to set up in bucket elevator lower part, the inside lifting bucket of bucket elevator shifts after collecting by connecing the workbin owing to the material that the vibration of promotion scatters, carries out breakage processing again according to the size particle diameter again, improves the utilization ratio of raw materials, reduces the raw materials loss.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic view of a part of the structure of the present invention.

Fig. 3 is a schematic structural diagram of the material poking mechanism.

Fig. 4 is a schematic structural view of the material receiving platform.

Fig. 5 is a top view of the receiving platform.

Fig. 6 is a schematic diagram of the structure of the material receiving box.

In the drawings: 1. a crusher; 2. a bucket elevator; 3. a vibrating screen classifier; 4. a material poking mechanism; 41. a connecting portion; 42. a cross bar; 43. a material poking rod; 44. a hook-up portion; 45. breaking the material teeth; 5. a material receiving box; 51. a material distributing sieve plate; 52. a first discharge chamber; 53. a second discharge chamber; 54. a first discharge door; 55. a second discharge door; 6. a material receiving platform; 61. a supporting seat; 62. a material receiving disc; 63. a retainer ring; 64. a chute; 65. a rubber strip.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Example 1: as shown in fig. 1 to 6, a raw material processing system for producing clean and environment-friendly anhydrous stemming comprises a crusher 1, a bucket elevator 2 and a vibrating screen classifier 3; the discharge hole of the crusher 1 is connected with the feed inlet of the bucket elevator 2; the discharging opening of the bucket elevator 2 is connected with the material receiving opening of the vibrating sieving machine 3; a material stirring mechanism 4 is arranged at a feed inlet of the bucket elevator 2; the material stirring mechanism 4 is hinged with the upper edge of the feeding hole; the lower part of the bucket elevator 2 is also provided with a material receiving box 5; the upper end of the material receiving box 5 is communicated with the interior of the bucket elevator; the bottom of the vibrating screening machine 3 is provided with a discharge port; a material receiving platform 6 is arranged below the discharge opening; the material shifting mechanism 4 arranged on the feeding port of the bucket elevator 2 can swing in and out of the feeding port under the impact force of materials when the materials pass through the feeding hopper, so that the effect of shifting the materials is achieved, the materials can be fed successively, and the blockage of the feeding port due to too much feeding at one time is avoided; when the materials pass through, the material stirring mechanism 4 is hinged and can be jacked for a certain angle to allow a certain amount of materials to pass through, and the material stirring mechanism 4 can naturally fall and reset through the hinged piece and gravity along with the falling of the materials, so that the excessive passing of the materials is avoided, the occurrence of blocking is reduced, and the smoothness of feeding is improved; the material receiving platform 6 can be used for placing packaging bags during material receiving, and through the protection effect of the material receiving platform 6, the occurrence of material dumping is reduced, material loss is reduced, and the utilization rate of raw materials is improved; connect workbin 5 to set up in bucket elevator 2 lower part, the inside lifting bucket of bucket elevator 2 shifts after collecting by connecing workbin 5 owing to the material that the vibration that promotes scatters, carries out breakage processing again according to the size particle diameter again, improves the utilization ratio of raw materials, reduces the raw materials loss.

The material shifting mechanism 4 comprises a connecting part 41, a cross rod 42 and a material shifting rod 43; the connecting part 41 is oppositely arranged above the feeding hole; the two ends of the cross rod 42 are erected above the feed inlet in an inclined way through the connecting part 41; the material poking rod 43 is hinged with the cross rod 42; in this embodiment, the material stirring rod 43 and the cross rod 42 may be hinged by a conventional shaft pin, or the cross rod 42 may be sleeved with a torsion spring to connect the torsion spring with the material stirring rod 43; the reset force generated by the elastic deformation of the torsion spring can push the material stirring rod 43 to reset, so that the material with larger grain diameter can be stirred; the connecting parts 41 comprise two connecting parts, the cross rods 42 are erected above the feed inlet in an inclined mode through the connecting rods, and a proper space is reserved for rotation of the material poking rods 43.

The end part of the material poking rod 43 is provided with a hook part 44; the surface of the material poking rod 43 is also provided with material breaking teeth 45; the hooking part 44 of the material poking rod 43 can push down the piled materials, and the hooking angle adapts to the material poking rod without influencing the normal falling of the material blocks; the material poking teeth arranged on the surface of the material poking rod 43 can crush some materials, and the occurrence of the blocking condition of large materials is reduced.

The material receiving platform 6 comprises a supporting seat 61, a material receiving disc 62 and a retainer ring 63; the material receiving disc 62 is arranged on the supporting seat 61; a circle of clamping grooves are formed in the edge of the upper surface of the material receiving disc 62; the retainer ring 63 is arranged in the sliding groove 64 in a sliding manner; the supporting seat 61 is used for supporting the material receiving disc 62 at a certain height, packaging bags are placed on the material receiving disc 62, the check ring 63 can block the packaging bags at the edge of the material receiving disc, the packaging bags lean against the check ring 63 conveniently, the falling and scattering of materials are avoided, the check ring 63 is arranged in the sliding groove 64 in a sliding mode, and the position of the check ring 63 can be adjusted as required to be suitable for placing the packaging bags. In the embodiment, the supporting seat, the material receiving disc and the check ring are all made of conventional steel materials with appropriate mechanical strength; any reasonably suitable other material may be used.

The retainer ring 63 is an arc-shaped plate; the upper edge of the retainer ring 63 is provided with a rubber strip 65; the retainer ring 63 is an arc-shaped plate and can be matched with the material receiving disc 62 and the packaging bag, so that the material blocking effect is improved; when the rubber strip is used, the upper edge of the retainer ring 63 can be directly held to move, the rubber strip 65 can protect hands of operators from being cut, and the use performance is improved.

A material distributing sieve plate 51 is arranged in the material receiving box 5; the material distributing sieve plate 51 divides the material receiving box 5 into a first material outlet cavity 52 and a second material outlet cavity 53 from top to bottom; connect workbin 5 inner cross frame to have branch material sieve 51, divide the sieve mesh size of material sieve 51 to select as required, and the material that bucket elevator 2 fell gets into and connects workbin 5 back, is selected two sets of different particle diameters by the branch material screening, and gets into first play material chamber 52 and second play material chamber 53 respectively, then the ejection of compact respectively again, can utilize respectively to the scattered material, improves the utilization ratio of raw materials, reduces extravagantly.

A first discharging door 54 is arranged on the side wall of the first discharging cavity 52; the lower edge of the first discharging door 54 is hinged on the side wall of the first discharging cavity 52; a second discharging door 55 is arranged on the side wall of the second discharging cavity 53; the lower edge of the second discharging door 55 is hinged on the side wall of the second discharging cavity 53; the lower edge of the first discharging door 54 is hinged, the upper edge can be clamped conventionally, the second discharging door 55 is similar, and during discharging, the first discharging door 54 and the second discharging door 55 are turned downwards to be used as a material guide plate, so that the discharging convenience is improved.

Although the invention has been described herein with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this invention. More specifically, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, other uses will also be apparent to those skilled in the art.

Claims (7)

1. A clean environment-friendly raw material processing system for anhydrous stemming production comprises a crusher (1), a bucket elevator (2) and a vibrating screening machine (3); the discharge hole of the crusher (1) is connected with the feed inlet of the bucket elevator (2); the feed opening of the bucket elevator (2) is connected with the feed receiving opening of the vibrating screen classifier (3); the method is characterized in that: a material stirring mechanism (4) is arranged at a material inlet of the bucket elevator (2); the material stirring mechanism (4) is hinged with the upper edge of the feeding hole; the lower part of the bucket elevator (2) is also provided with a material receiving box (5); the upper end of the material receiving box (5) is communicated with the interior of the bucket elevator; the bottom of the vibrating screening machine (3) is provided with a discharge opening; and a material receiving platform (6) is arranged below the discharge opening.

2. The clean and environment-friendly raw material processing system for anhydrous stemming production according to claim 1, characterized in that: the material poking mechanism (4) comprises a connecting part (41), a cross rod (42) and a material poking rod (43); the connecting part (41) is oppositely arranged above the feeding hole; two ends of the cross rod (42) are erected above the feed inlet in an inclined mode through connecting parts (41); the material poking rod (43) is hinged with the cross rod (42).

3. The clean and environment-friendly raw material processing system for producing anhydrous stemming according to claim 2, characterized in that: a hook-up part (44) is arranged at the end part of the material poking rod (43); the surface of the material poking rod (43) is also provided with material breaking teeth (45).

4. The clean and environment-friendly raw material processing system for anhydrous stemming production according to claim 1, characterized in that: the material receiving platform (6) comprises a supporting seat (61), a material receiving disc (62) and a check ring (63); the material receiving disc (62) is arranged on the supporting seat (61); a circle of clamping grooves are formed in the edge of the upper surface of the material receiving disc (62); the retainer ring (63) is arranged in the sliding groove (64) in a sliding mode.

5. The clean and environment-friendly raw material processing system for anhydrous stemming production according to claim 4, characterized in that: the retainer ring (63) is an arc-shaped plate; the upper edge of the retainer ring (63) is provided with a rubber strip (65).

6. The clean and environment-friendly raw material processing system for anhydrous stemming production according to claim 1, characterized in that: a material distributing sieve plate (51) is arranged in the material receiving box (5); the material distributing sieve plate (51) divides the material receiving box (5) into a first material outlet cavity (52) and a second material outlet cavity (53) from top to bottom.

7. The clean and environment-friendly raw material processing system for anhydrous stemming production according to claim 6, characterized in that: a first discharging door (54) is arranged on the side wall of the first discharging cavity (52); the lower edge of the first discharging door (54) is hinged on the side wall of the first discharging cavity (52); a second discharging door (55) is arranged on the side wall of the second discharging cavity (53); the lower edge of the second discharging door is hinged to the side wall of the second discharging cavity (53).

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