CN203470117U - Super-white glass mineral raw material processing system - Google Patents

Super-white glass mineral raw material processing system Download PDF

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Publication number
CN203470117U
CN203470117U CN201320532629.1U CN201320532629U CN203470117U CN 203470117 U CN203470117 U CN 203470117U CN 201320532629 U CN201320532629 U CN 201320532629U CN 203470117 U CN203470117 U CN 203470117U
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sieve
discharging opening
discharge pipe
belt conveyor
charging aperture
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CN201320532629.1U
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林振盛
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Abstract

A super-white glass mineral raw material processing system relates to ore dressing equipment, and comprises a crushing mechanism, a photoelectric sorting mechanism, an ore grinding mechanism and a magnetic separation processing mechanism; a material outlet of the crushing mechanism is connected with a material feeding port of the photoelectric sorting mechanism, a material inlet of the ore grinding mechanism is connected with a material outlet of the photoelectric sorting mechanism, a material inlet of the magnetic separation processing mechanism is connected with a material outlet of the ore grinding mechanism; the crushing mechanism is provided with a forklift, a crusher, a first vibrating screen, a first screen upper material outlet pipe, a first screen lower material outlet pipe, a first belt conveyor and a feeder; the photoelectric sorting mechanism is provided with a photoelectric separator and a second belt conveyor; the ore grinding mechanism is provided with an ore grinding mill, a second vibrating screen, a second screen upper material outlet pipe, a second screen lower material outlet pipe and a third belt conveyor; a material inlet of the magnetic separation processing mechanism is connected with a material outlet of the third belt conveyor, and qualified ore is outputted from a material outlet of the magnetic separation processing mechanism.

Description

A kind of ultra-clear glasses raw mineral materials system of processing
Technical field
The utility model relates to a kind of preparation equipment, especially relates to a kind of ultra-clear glasses raw mineral materials system of processing.
Background technology
Ultra-clear glasses raw mineral materials (quartz sand, lime stone, dolomite etc.) requires Fe 2o 3content is less than 100ppm, and it is rare that nature meets the scale mineral deposit of this requirement.At present, raw mineral materials process technology is many carries out around reducing iron content, mainly contains: 1) magnetic separation, and remove magnetic mineral and weak magnetic mineral, but can not reject as landwaste and quartz particles surface attachment iron non magnetic ore; 2) pickling, can only remove quartz particles surface attachment iron, can not reject landwaste and so on ferrous contaminants, and because of environmental pollution or environmental protection cost is too high can not adopt; 3) flotation, mainly removes feldspar, mica and so on, because rejecting limitation and too high being difficult to of cost of dopant species, adopts.Although above various technology can comprehensively bundle use, as frit, cost is too high, especially environmental pollution restriction, and technical and economic feasibility is very poor, fails to adapt to flourish photovoltaic glass industry demand.And the sorting of lime stone and dolomite for ultra-clear glasses, is in the industry cycle unprecedented.
Summary of the invention
The purpose of this utility model is, for existing ultra-clear glasses raw mineral materials machining production line above shortcomings, to provide a kind of ultra-clear glasses raw mineral materials system of processing.
The utility model is provided with crushing mechanism, photometric sorting mechanism, ore grinding mechanism and magnetic separation processing mechanism; The discharging opening of described crushing mechanism connects the material inlet of photometric sorting mechanism, and the charging aperture of ore grinding mechanism is connected with the discharging opening of photometric sorting mechanism, and the charging aperture of magnetic separation processing mechanism is connected with the discharging opening of ore grinding mechanism;
Described crushing mechanism is provided with forklift, disintegrating machine, the 1st vibratory sieve, the 1st sieve top discharge pipe, the 1st sieve bottom discharge pipe, the 1st belt conveyor and batcher; Disintegrating machine is provided with charging aperture and discharging opening, charging aperture connects the feed hopper of forklift, discharging opening is connected with batcher successively with the 1st vibratory sieve, the 1st sieve bottom discharge pipe, the 1st belt conveyor, the charging aperture of the 1st sieve top discharge pipe connects the sieve top discharge mouth of the 1st vibratory sieve, and the discharging opening of the 1st sieve top discharge pipe connects the charging aperture of disintegrating machine;
Described photometric sorting mechanism is provided with photoelectric separator and the 2nd belt conveyor; The material inlet of photoelectric separator is connected with the discharging opening of batcher, and the charging aperture of the 2nd belt conveyor is connected with the discharging opening of photoelectric separator by pipeline;
Described ore grinding mechanism is provided with ore mill, the 2nd vibratory sieve, the 2nd sieve top discharge pipe, the 2nd sieve bottom discharge pipe and the 3rd belt conveyor; Ore mill, the 2nd vibratory sieve, the 2nd sieve bottom discharge pipe are connected successively with the 3rd belt conveyor, and the charging aperture of the 2nd sieve top discharge pipe connects the oversize outlet of the 2nd vibratory sieve, and the discharging opening of the 2nd sieve top discharge pipe connects the charging aperture of ore mill;
The charging aperture of described magnetic separation processing mechanism is connected with the discharging opening of the 3rd belt conveyor, and the discharging opening of magnetic separation processing mechanism is exported qualified ore.
Described magnetic separation processing mechanism can adopt high gradient magnetic separator.
Described crushing mechanism is for being crushed to pending mineral aggregate the granularity of setting.
Described photoelectric separation mechanism, according to optoelectronic induction principle, for the mineral aggregate of different optical character, adopts photoelectric sensor, starts High-pressure air valve, produces air-flow, will be harmful to ore particles and blow out, and rejects.
Described ore grinding mechanism, for useful mineral aggregate is carried out to ore grinding, makes mineral aggregate finally reach the granularity of glass industry standard-required.
Described magnetic separation processing mechanism adopts high gradient magnetic separator to reject the mechanical iron producing in this prosomite process.
The utility model carries out removal of impurities according to the Structural Tectonics of the distribution of frit iron in ore and mineral, under the feasible prerequisite of economically feasible, environmental protection, rejects the iron content particle in raw mineral materials.
Major advantage of the present utility model and technique effect are:
1. adopt brand-new technology path---optoelectronic induction sorting technology, reject the ferrous contaminants particle in quartz sand mineral aggregate; Sorting ultrawhite level lime stone and dolomite;
2. environmental protection: pollution-free ore dressing;
3. economy: sorting cost is in lower, the feasible scope of glass industry;
As can be seen here, the utility model builds a ultrawhite raw mineral materials supply system that photovoltaic glass is used, and what expanded widely nature ultra-clear glasses raw mineral materials looks for ore deposit scope.
Accompanying drawing explanation
Fig. 1 is that the structure of the utility model embodiment forms schematic diagram.
In Fig. 1, be respectively labeled as: 1 is forklift, and 2 is disintegrating machine, 3 is the 1st vibratory sieve, and 4 is the 1st sieve top discharge pipe, and 5 is the 1st sieve bottom discharge pipe, 6 is the 1st belt conveyor, and 7 is batcher, and 8 is photoelectric separator, 9 is the 2nd belt conveyor, and 10 is ore mill, and 11 is the 2nd vibratory sieve, 12 is the 2nd sieve top discharge pipe, 13 is the 2nd sieve bottom discharge pipe, and 14 is the 3rd belt conveyor, and 15 is high gradient magnetic separator.
Fig. 2 is the fundamental diagram of the photometric sorting mechanism of the utility model embodiment.
In Fig. 2, be respectively labeled as: 21 is ore feeder, and 22 is impurity particle, and 23 is ore particles, and 24 is skewed slot, and 25 is LED lamp, and 26 is photoelectric sensor, 27 for comparing plate, and 28 is high pressure air rifle, and 29 is qualified ore storage bin, and 210 is impurity ore storage bin.
The specific embodiment
Below in conjunction with accompanying drawing, the utility model is further described.
Referring to Fig. 1, the utility model embodiment is provided with crushing mechanism, photometric sorting mechanism, ore grinding mechanism and magnetic separation processing mechanism; The discharging opening of described crushing mechanism connects the material inlet of photometric sorting mechanism, and the charging aperture of ore grinding mechanism is connected with the discharging opening of photometric sorting mechanism, and the charging aperture of magnetic separation processing mechanism is connected with the discharging opening of ore grinding mechanism.
Described crushing mechanism is provided with forklift 1, disintegrating machine 2, the 1st vibratory sieve the 3, the 1st sieve top discharge pipe the 4, the 1st sieve bottom discharge pipe the 5, the 1st belt conveyor 6 and batcher 7; Disintegrating machine 2 is provided with charging aperture and discharging opening, charging aperture connects the feed hopper of forklift 1, discharging opening is connected with batcher 7 successively with the 1st vibratory sieve the 3, the 1st sieve bottom discharge pipe the 5, the 1st belt conveyor 6, the charging aperture of the 1st sieve top discharge pipe 4 connects the sieve top discharge mouth of the 1st vibratory sieve 3, and the discharging opening of the 1st sieve top discharge pipe 4 connects the charging aperture of disintegrating machine 2.
Described photometric sorting mechanism is provided with photoelectric separator 8 and the 2nd belt conveyor 9; The material inlet of photoelectric separator 8 is connected with the discharging opening of batcher 7, and the charging aperture of the 2nd belt conveyor 9 is connected with the discharging opening of photoelectric separator 8 by pipeline.
Described ore grinding mechanism is provided with ore mill 10, the 2nd vibratory sieve the 11, the 2nd sieve top discharge pipe the 12, the 2nd sieve bottom discharge pipe 13 and the 3rd belt conveyor 14; Ore mill 10, the 2nd vibratory sieve the 11, the 2nd sieve bottom discharge pipe 13 are connected successively with the 3rd belt conveyor 14, and the charging aperture of the 2nd sieve top discharge pipe 12 connects the oversize outlet of the 2nd vibratory sieve 11, and the discharging opening of the 2nd sieve top discharge pipe 12 connects the charging aperture of ore mill 10.
The charging aperture of described magnetic separation processing mechanism is connected with the discharging opening of the 3rd belt conveyor 14, and the discharging opening of magnetic separation processing mechanism is exported qualified ore.
Described magnetic separation processing mechanism adopts high gradient magnetic separator 15.
Described crushing mechanism is for being crushed to pending mineral aggregate the granularity of setting.
Described photoelectric separation mechanism, according to optoelectronic induction principle, for the mineral aggregate of different optical character, adopts photoelectric sensor, starts High-pressure air valve, produces air-flow, will be harmful to ore particles and blow out, and rejects.
Described ore grinding mechanism, for useful mineral aggregate is carried out to ore grinding, makes mineral aggregate finally reach the granularity of glass industry standard-required.
Described magnetic separation processing mechanism adopts high gradient magnetic separator to reject the mechanical iron producing in this prosomite process.
The utility model carries out removal of impurities according to the Structural Tectonics of the distribution of frit iron in ore and mineral, under the feasible prerequisite of economically feasible, environmental protection, rejects the iron content particle in raw mineral materials.
Below provide workflow of the present utility model:
Forklift 1 by ore bucket to ore deposit, disintegrating machine 2 is crushed to certain particle size by mineral aggregate, with the 1st vibratory sieve 3 screenings, oversize returns to disintegrating machine 2 by the 1st sieve top discharge pipe 4, minus mesh continues to be fed forward, by the 1st belt conveyor 6, give batcher 7 to ore deposit, photoelectric separator sub-elects qualified mineral aggregate and defective mineral aggregate, qualified mineral aggregate is delivered to ore mill 10 by the 2nd belt conveyor 9, be ground to glass industry desired particle size rank, deliver to the 2nd vibratory sieve 11, oversize returns to ore mill 10, minus mesh is delivered to high gradient magnetic separator 15 by the 3rd belt feeder 14, reject the mechanical iron that above link is sneaked into, finally deliver to warehouse for finished product.
Fig. 2 provides the fundamental diagram of photometric sorter:
Principle: mineral aggregate (comprising impurity particle 22 and ore particles 23) falls from ore feeder 21, to separation chamber, photoelectric sensor 26 captures and compares plate 27(impurity particle) identical optical information, send current-order, open the valve of high pressure air rifle 28, impurity particle 22 is ejected, and falls into impurity ore storage bin 210, thereby with qualified ore separation, qualified ore falls into qualified ore storage bin 29 along skewed slot.
In Fig. 2, mark 24 is skewed slot, and 25 is LED lamp.

Claims (5)

1. a ultra-clear glasses raw mineral materials system of processing, is characterized in that being provided with crushing mechanism, photometric sorting mechanism, ore grinding mechanism and magnetic separation processing mechanism; The discharging opening of described crushing mechanism connects the material inlet of photometric sorting mechanism, and the charging aperture of ore grinding mechanism is connected with the discharging opening of photometric sorting mechanism, and the charging aperture of magnetic separation processing mechanism is connected with the discharging opening of ore grinding mechanism.
2. a kind of ultra-clear glasses raw mineral materials system of processing as claimed in claim 1, is characterized in that described crushing mechanism is provided with forklift, disintegrating machine, the 1st vibratory sieve, the 1st sieve top discharge pipe, the 1st sieve bottom discharge pipe, the 1st belt conveyor and batcher; Disintegrating machine is provided with charging aperture and discharging opening, charging aperture connects the feed hopper of forklift, discharging opening is connected with batcher successively with the 1st vibratory sieve, the 1st sieve bottom discharge pipe, the 1st belt conveyor, the charging aperture of the 1st sieve top discharge pipe connects the sieve top discharge mouth of the 1st vibratory sieve, and the discharging opening of the 1st sieve top discharge pipe connects the charging aperture of disintegrating machine.
3. a kind of ultra-clear glasses raw mineral materials system of processing as claimed in claim 1, is characterized in that described photometric sorting mechanism is provided with photoelectric separator and the 2nd belt conveyor; The material inlet of photoelectric separator is connected with the discharging opening of batcher, and the charging aperture of the 2nd belt conveyor is connected with the discharging opening of photoelectric separator by pipeline.
4. a kind of ultra-clear glasses raw mineral materials system of processing as claimed in claim 1, is characterized in that described ore grinding mechanism is provided with ore mill, the 2nd vibratory sieve, the 2nd sieve top discharge pipe, the 2nd sieve bottom discharge pipe and the 3rd belt conveyor; Ore mill, the 2nd vibratory sieve, the 2nd sieve bottom discharge pipe are connected successively with the 3rd belt conveyor, the charging aperture of the 2nd sieve top discharge pipe connects the oversize outlet of the 2nd vibratory sieve, the discharging opening of the 2nd sieve top discharge pipe connects the charging aperture of ore mill, the charging aperture of described magnetic separation processing mechanism is connected with the discharging opening of the 3rd belt conveyor, and the discharging opening of magnetic separation processing mechanism is exported qualified ore.
5. a kind of ultra-clear glasses raw mineral materials system of processing as claimed in claim 1, is characterized in that described magnetic separation processing mechanism adopts magnetic separator.
CN201320532629.1U 2013-08-29 2013-08-29 Super-white glass mineral raw material processing system Expired - Fee Related CN203470117U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201320532629.1U CN203470117U (en) 2013-08-29 2013-08-29 Super-white glass mineral raw material processing system

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201320532629.1U CN203470117U (en) 2013-08-29 2013-08-29 Super-white glass mineral raw material processing system

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104193150A (en) * 2014-09-09 2014-12-10 国家电网公司 Preparation process of solar battery glass
CN112774777A (en) * 2021-02-08 2021-05-11 上海建工四建集团有限公司 Building glass recovery unit

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104193150A (en) * 2014-09-09 2014-12-10 国家电网公司 Preparation process of solar battery glass
CN112774777A (en) * 2021-02-08 2021-05-11 上海建工四建集团有限公司 Building glass recovery unit

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