CN214652095U - Stone warehouse - Google Patents

Abstract

The utility model provides a stone storehouse, aim at solving the stone storehouse among the prior art and generally only dispose the feed bin, need dispose another set of independent stone storehouse system when output increases and lead to the higher problem of cost. A stone storehouse comprises two bins, a lifter and a batching mechanism; the two bins are provided with a feed inlet positioned at the top and a discharge outlet positioned at the bottom; a tee joint is arranged between the two bins and the elevator, and the tee joint comprises a feeding port for receiving stones lifted by the elevator and two connectors respectively connected with the feeding ports of the two bins; the batching mechanism comprises a first electronic belt metering scale, a batching conveyor belt and a first material receiving groove; the batching mechanism further comprises a conveying pipe, a second material receiving groove and a second electronic belt metering scale. The stone storehouse in this disclosure is equipped with two feed bins that are used for holding the stone, and two feed bins carry out the material loading through tee bend sharing a lifting machine, for two sets of independent stone storehouse batching, have saved the cost.

Description

Stone warehouse

Technical Field

The disclosure belongs to the technical field of mortar production, and particularly relates to a stone storehouse.

Background

The stone storehouse is equipment for storing stones in the mortar production process; when sand is manufactured, stones need to be transported to a sand manufacturing production line from a stone warehouse, and then the stones are crushed into fine sand. However, the existing stone storehouses have the following problems that a general production line is only provided with one stone storehouse, when large-scale production is needed, the quantity of the stone storehouses needs to be increased to increase the reserve quantity of stones, but each stone storehouse needs to be provided with a set of transfer equipment, so that the cost is high; in addition, current stone storehouse is unloading the in-process, can produce a large amount of dusts, influences the air quality in workshop, although some present stone storehouses dispose the dust remover, disposes a small amount of dust removers, and the dust removal effect is relatively poor, and when disposing a plurality of dust removers, the cost is higher.

SUMMERY OF THE UTILITY MODEL

The utility model provides a stone storehouse, aim at solving the stone storehouse among the prior art and generally only dispose the feed bin, need dispose another set of independent stone storehouse system when output increases and lead to the higher problem of cost.

In order to solve the technical problem, the technical scheme adopted by the disclosure is as follows: a stone storehouse comprises two bins for containing stones, a hoisting machine arranged between the two bins and a batching mechanism arranged at the bottoms of the two bins; the two bins are a first bin and a second bin respectively; the two bins are provided with a feed inlet positioned at the top and a discharge outlet positioned at the bottom; a tee joint is arranged between the two bins and the elevator, and the tee joint comprises a feeding port for receiving stones lifted by the elevator and two connectors respectively connected with the feeding ports of the two bins; the batching mechanism comprises a first electronic belt metering scale, a batching conveyor belt and a first material receiving groove positioned at the discharge end of the batching conveyor belt; the material receiving end of the first electronic belt weigher is positioned below the material outlet of the first material bin, and the material outlet end of the first electronic belt weigher is positioned above the material receiving end of the batching conveyor belt; the batching mechanism also comprises a conveying pipe positioned at the lower end of the discharge hole of the second material bin, a second material receiving groove arranged at the outlet of the conveying pipe and a second electronic belt weigher arranged at the discharge hole of the second material receiving groove; the first material receiving groove is close to the second material receiving groove.

According to a further improved scheme, the stone warehouse further comprises an output system, and the input end of the output system is located below the discharge end of the second electronic belt metering scale.

Based on the technical scheme, the stones discharged from the stone storeroom can be transported to a sand production line through the transportation system.

According to a further improved scheme, the discharge end of the first material receiving groove is inserted into the feed inlet of the second material receiving groove; and a dust remover is arranged at the feed inlet of the second material receiving groove.

Based on above-mentioned technical scheme, the discharge end that connects the silo is pegged graft in the feed inlet that connects the silo No. two, only needs to connect a dust remover of feed inlet department configuration of silo No. two, need additionally dispose a dust remover when avoiding the discharge end that connects the silo alone to ejection of compact, has practiced thrift the cost.

According to a further improved scheme, each bin is fixed and suspended above the ground through a support frame, and a discharge port of the second material receiving groove and the second electronic belt weigher are positioned in a groove formed by sinking the ground; the dust suction port of the dust remover is arranged towards the groove.

Based on above-mentioned technical scheme, the discharge gate that connects the silo No. two and No. two electronic belt weighers are located the recessed recess that forms in ground, can be so that when unloading, the dust that produces when the discharge gate that connects the silo No. two and No. two electronic belt weighers are unloaded can not be to diffusion all around, is favorable to improving the dust removal effect of dust remover.

According to a further improved scheme, a dustproof chamber enclosed by a plurality of transparent dust baffles is fixed on the support frame material, and the dustproof chamber is enclosed outside the batching mechanism; the dust-proof chamber is provided with an air inlet and an air outlet, the air inlet of the dust-proof chamber is arranged close to the discharge hole of the first storage bin, and the air outlet of the dust-proof chamber is arranged close to the groove; and the dust suction port of the dust remover is connected with the air outlet of the dust-proof chamber.

Based on above-mentioned technical scheme, set up the dust proof room and can prevent that the dust that batching mechanism produced when unloading from spreading everywhere, and when removing dust for the dust is from the air inlet towards the directional flow of gas outlet, and the dust remover setting is favorable to improving the dust removal effect of dust remover at the gas outlet.

According to a further improved scheme, the discharge end of the first material receiving groove is located above the input end of the output system.

In a further improved scheme, the output system comprises a plurality of conveyor belt mechanisms.

According to the further improved scheme, the upper portion of each bin is provided with a feeding level meter, and the lower portion of each bin is provided with a discharging level meter.

Based on above-mentioned technical scheme, set up the material loading position appearance and can monitor whether the feed bin is full of the stone, set up the material unloading position appearance and can monitor whether the stone is used up.

According to a further improved scheme, the bottom of each bin is in a conical shape with a large upper part and a small lower part, and a vibration motor is arranged at the bottom of each bin.

Based on above-mentioned technical scheme, set up vibrating motor, be favorable to when taking place to block up, the stone can be smoothly discharged from conical feed bin bottom smoothly.

According to a further improved scheme, a bag type dust collector is arranged at the top of each bin.

The beneficial effect of this disclosure does:

the stone storeroom is provided with the two material bins for containing stones, the two material bins share one elevator through the tee joint for feeding, and compared with two sets of independent stone storerooms, the cost is saved; in addition, the first material receiving groove is arranged close to the second material receiving groove through the batching conveying belt, so that the first material receiving groove and the second material receiving groove can share one set of output system, and the cost is saved; the two bins in the device can discharge materials respectively or simultaneously, and the flexibility is strong; the two storage bins are used together in a centralized mode, so that the storage capacity is enlarged, part of equipment is shared, and the cost is saved. The first electronic belt weigher and the second electronic belt weigher are arranged in the device, so that the material discharge amount of the two storage bins can be accurately measured; the lower extreme of No. two feed bins discharge gates sets up the conveyer pipe and can lead to the stone material that No. two feed bins discharged.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present disclosure, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present disclosure and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings may be obtained from the drawings without inventive effort.

FIG. 1 is a schematic diagram of the structure of a stone library according to the first embodiment.

FIG. 2 is a schematic diagram of the structure of the stone library in the second embodiment.

FIG. 3 is a schematic diagram of the structure of the stone library in the third embodiment.

The reference numbers in the figures illustrate:

1-a first storage bin; 2-second bunker; 3, a hoisting machine; 4-a tee joint; 5-a support frame; 6-a vibration motor; 7-a first electronic belt weigher; 8-ingredient conveying belt; 9-second electronic belt weighing scale; 10-a groove; a No. 11-second material receiving groove; 12-an output system; 13-a material receiving groove; 14-a delivery pipe; 15-a dust remover; 16-a bag house; 17-a loading level meter; 18-a blanking level meter; 19-dust-proof room.

Detailed Description

The technical solution in the embodiments of the present disclosure will be clearly and completely described below with reference to the drawings in the embodiments of the present disclosure. It should be understood that the specific embodiments described herein are merely illustrative of the disclosure and are not intended to limit the disclosure. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the disclosure without inventive step, are within the scope of the disclosure.

The first embodiment is as follows:

referring to fig. 1, a stone storehouse comprises two bins for holding stones, a lifter 3 arranged between the two bins, and a batching mechanism arranged at the bottoms of the two bins; the two bins are a first bin 1 and a second bin 2 respectively; the two bins are provided with a feed inlet positioned at the top and a discharge outlet positioned at the bottom; a tee joint 4 is arranged between the two bins and the elevator 3, and the tee joint 4 comprises a feeding port for receiving stones lifted by the elevator 3 and two connectors respectively connected with the feeding ports of the two bins; the batching mechanism comprises a first electronic belt metering scale 7, a batching conveyor belt 8 and a first material receiving groove 13 positioned at the discharge end of the batching conveyor belt 8; the receiving end of the first electronic belt weigher 7 is positioned below the discharge port of the first storage bin 1, and the discharge end of the first electronic belt weigher 7 is positioned above the receiving end of the batching conveyor belt 8; the batching mechanism also comprises a conveying pipe 14 positioned at the lower end of a discharge port of the second storage hopper 2, a second material receiving groove 11 arranged at an outlet of the conveying pipe 14 and a second electronic belt metering scale 9 arranged at a discharge port of the second material receiving groove 11; the first material receiving groove 13 is arranged close to the second material receiving groove 11.

Wherein, connect the silo to be big-end-up's taper groove and bottom and be equipped with the blowing pipe.

On the basis of the scheme, the stone storage further comprises an output system 12, and the input end of the output system 12 is positioned below the discharge end of the second electronic belt weigher 9. The stones discharged from the stone storeroom can be transported to a sand production line through a transportation system. Wherein the output system 12 comprises several conveyor belt mechanisms.

In order to save cost, on the basis of the scheme, the discharge end of the first material receiving groove 13 is inserted into the feed inlet of the second material receiving groove 11; and a dust remover 15 is arranged at the feed inlet of the second material receiving groove 11. Connect the discharge end of silo 13 to peg graft in the feed inlet that connects silo 11 No. two, only need connect the feed inlet department of silo 11 to dispose a dust remover 15 No. two, need additionally dispose a dust remover 15 when avoiding the independent ejection of compact of discharge end that connects silo 13. The dust separator 15 may be a bag type dust separator.

In order to improve the dust removal effect of the dust remover 15, on the basis of the scheme, each bin is fixed and suspended above the ground through a support frame 5, and a discharge port of the second material receiving groove 11 and the second electronic belt weigher 9 are positioned in a groove 10 formed by sinking the ground; the dust suction opening of the dust catcher 15 is arranged towards the groove 10. The discharge hole of the second material receiving groove 11 and the second electronic belt weigher 9 are positioned in a groove 10 formed by sinking the ground, so that when discharging, dust generated when the discharge hole of the second material receiving groove 11 and the second electronic belt weigher 9 discharge can not spread all around.

On the basis of any scheme, the upper part in each bin is provided with a feeding level meter 17, and the lower part of each bin is provided with a discharging level meter 18. The loading level meter 17 is arranged to monitor whether the bin is full of stones, and the unloading level meter 18 is arranged to monitor whether the stones are used up.

On the basis of any scheme, the bottom of each bin is in a conical shape with a large upper part and a small lower part, and the bottom of each bin is provided with a vibration motor 6. The vibrating motor 6 is arranged, so that when blockage occurs, stones can be smoothly discharged from the bottom of the conical storage bin.

On the basis of any scheme, a bag type dust collector 16 is arranged at the top of each bin.

The present embodiment is further described below with reference to the working principle:

when the first storage bin 1 discharges, stones are discharged from the first storage bin 1, then sequentially pass through the first electronic belt weigher 7, the batching conveyor belt 8, the first material receiving groove 13, the second material receiving groove 11 and the second electronic belt weigher 9, and then enter the output system 12. When the second storage bin 2 discharges materials, stones are discharged from the second storage bin 2, sequentially pass through the second receiving groove 11 and the second electronic belt metering scale 9 through the conveying pipe 14, and then enter the output system 12. The first electronic belt weigher 7 can measure the quantity of stones discharged from the first storage hopper 1, and the second electronic belt weigher 9 can measure the quantity of stones discharged from the second storage hopper 2.

Example two:

referring to fig. 2, on the basis of the first embodiment, a dust-proof chamber 19 enclosed by a plurality of transparent dust baffles is fixed on the supporting frame 5, and the dust-proof chamber 19 is enclosed outside the batching mechanism; the dust-proof chamber 19 is provided with an air inlet and an air outlet, the air inlet of the dust-proof chamber 19 is arranged close to the discharge hole of the first storage bin 1, and the air outlet of the dust-proof chamber 19 is arranged close to the groove 10; the dust suction port of the dust remover 15 is connected with the air outlet of the dust-proof chamber 19. The dust-proof chamber 19 is arranged to prevent dust generated by the batching mechanism during unloading from diffusing everywhere, and when dust is removed, the dust flows directionally from the air inlet to the air outlet, and the dust remover 15 is arranged at the air outlet, so that the dust removing effect of the dust remover 15 is improved.

Example three:

referring to fig. 3, the difference from the first embodiment is that the discharge end of the first receiving chute 13 is located above the input end of the output system 12. The first material receiving groove 13 and the second material receiving groove 11 respectively discharge materials to the output system 12.

The present disclosure is not limited to the above optional embodiments, and on the premise of no conflict, the schemes can be combined arbitrarily; any other products in various forms can be obtained in the light of the present disclosure, but any changes in shape or structure thereof fall within the scope of the present disclosure, which is defined by the claims.

Claims (10)

1. A stone bank, characterized by: the automatic stone-filling machine comprises two bins for holding stones, a lifting machine arranged between the two bins and a batching mechanism arranged at the bottoms of the two bins; the two bins are a first bin and a second bin respectively;

the two bins are provided with a feed inlet positioned at the top and a discharge outlet positioned at the bottom; a tee joint is arranged between the two bins and the elevator, and the tee joint comprises a feeding port for receiving stones lifted by the elevator and two connectors respectively connected with the feeding ports of the two bins;

the batching mechanism comprises a first electronic belt metering scale, a batching conveyor belt and a first material receiving groove positioned at the discharge end of the batching conveyor belt; the material receiving end of the first electronic belt weigher is positioned below the material outlet of the first material bin, and the material outlet end of the first electronic belt weigher is positioned above the material receiving end of the batching conveyor belt; the batching mechanism also comprises a conveying pipe positioned at the lower end of the discharge hole of the second material bin, a second material receiving groove arranged at the outlet of the conveying pipe and a second electronic belt weigher arranged at the discharge hole of the second material receiving groove; the first material receiving groove is close to the second material receiving groove.

2. A stone bank as claimed in claim 1 wherein: the input end of the output system is positioned below the discharge end of the second electronic belt metering scale.

3. A stone bank as claimed in claim 2 wherein: the discharge end of the first material receiving groove is inserted into the feed inlet of the second material receiving groove; and a dust remover is arranged at the feed inlet of the second material receiving groove.

4. A stone bank as claimed in claim 3 wherein: each bin is fixed and suspended above the ground through a support frame, and a discharge port of the second material receiving groove and the second electronic belt weigher are positioned in a groove formed by sinking the ground; the dust suction port of the dust remover is arranged towards the groove.

5. A stone bank as claimed in claim 4 wherein: a dustproof chamber enclosed by a plurality of transparent dust baffles is fixed on the support frame material, and the dustproof chamber is enclosed outside the batching mechanism; the dust-proof chamber is provided with an air inlet and an air outlet, the air inlet of the dust-proof chamber is arranged close to the discharge hole of the first storage bin, and the air outlet of the dust-proof chamber is arranged close to the groove; and the dust suction port of the dust remover is connected with the air outlet of the dust-proof chamber.

6. A stone bank as claimed in claim 2 wherein: the discharge end of the first material receiving groove is located above the input end of the output system.

7. A stone bank as claimed in claim 2 wherein: the output system comprises a plurality of conveyor belt mechanisms.

8. A stone bank as claimed in claim 1 wherein: the upper portion all is equipped with material loading level appearance in every feed bin, and the lower part of every feed bin all is equipped with unloading level appearance.

9. A stone bank as claimed in claim 1 wherein: the bottom of each bin is a cone with a large upper part and a small lower part, and the bottom of each bin is provided with a vibrating motor.

10. A stone bank as claimed in claim 1 wherein: and a bag type dust collector is arranged at the top of each bin.

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