CN109437219B - Production line of albite powder - Google Patents

Abstract

The utility model provides a production line of albite powder, includes broken part, crocus part, screening edulcoration part, flotation part, finished product output part and gas collection dust removal part, broken part, crocus part, screening edulcoration part, flotation part, finished product output part connect gradually, gas collection dust removal part locates the top of crocus part, screening edulcoration part is including first screening machine, first hierarchical swirler, first electromagnetism ore dressing device, second screening machine, second hierarchical swirler and the second electromagnetism ore dressing device that connect gradually, first screening machine with the crocus part passes through the conveyer belt and connects.

Description

Production line of albite powder

Technical Field

The invention relates to the technical field of mineral powder production, in particular to a production line of albite powder.

Background

Albite is one of feldspars, a common feldspar mineral, and is sodium aluminosilicate. Albite is generally a glassy crystal, and may be colorless or white, yellow, red, green or black. It is a raw material for manufacturing glass and ceramics. Many rocks contain albite as a component, and such minerals are called diagenetic minerals. Albite is mainly used for manufacturing ceramics, soap, ceramic tiles, floor tiles, glass, abrasive tools and the like, and is mainly used for glaze on the ceramics.

With the development of industry, the use of albite powder as a raw material or an additive has been increasingly required, and the albite powder not only has a fine particle size, but also has a low impurity content in the powder. The production of the traditional albite powder generally comprises the steps of crushing, grinding, impurity removal, precipitation and the like, and the powder is produced by simple processes and equipment. The powder has the problems that the removal of iron-containing substances is not clean and the like in the production process.

Disclosure of Invention

In view of the above problems, the present invention aims to provide a production line for producing potassium-sodium feldspar powder, so as to sufficiently remove iron-containing materials in the potassium-sodium feldspar powder and improve the purity of the potassium-sodium feldspar powder.

In order to achieve the purpose, the invention adopts the technical scheme that:

a production line of albite powder comprises a crushing part, a milling part, a screening and impurity removing part, a flotation part, a finished product output part and a gas collection and dust removal part, wherein the crushing part, the milling part, the screening and impurity removing part, the flotation part and the finished product output part are sequentially connected, the gas collection and dust removal part is arranged above the milling part, a first electromagnetic ore dressing device comprises a feeding pipe, a barrel body, a first motor and a second motor, an upper opening for the feeding pipe to extend into is formed in the top of the barrel body, a detachable stirring paddle is arranged in the barrel body, one end of the stirring paddle is connected with the first motor arranged on the barrel body, and the other end of the stirring paddle extends into the barrel body; electromagnets are arranged on two opposite sides in the barrel, a material collecting groove is arranged below the electromagnets and is connected with the barrel in a sliding manner through a guide rail, and the guide rail is arranged on a positioning plate which is vertical to the side wall of the barrel; an opening with the size equivalent to the end face of the material collecting groove is formed in the side wall of the cylinder body, so that the material collecting groove can be moved out in a sliding mode; a scraping rod which is contacted with the surface of the electromagnet is also arranged in the cylinder body, one end of the scraping rod is connected with a rotating shaft of the second motor, the rotating shaft penetrates through the center of the electromagnet, and the second motor is arranged outside the cylinder body;

a material level sensor is further arranged on the inner side wall, far away from the bottom, of the material collecting groove and is connected with a controller arranged on the side wall of the barrel body, and the controller is connected with an alarm arranged on the side wall of the barrel body; the first motor and the second motor are both connected with the controller; the second electromagnetic ore dressing device has the same structure as the first electromagnetic ore dressing device.

Further, the bottom of the cylinder is arranged in an inclined mode, a discharge hole is formed in the lower end of the bottom of the cylinder, and the discharge hole is connected with the second screening machine through a conveying belt.

Further, the first electromagnetic ore dressing device further comprises supporting legs, wherein the supporting legs are arranged on the side wall, close to the bottom, of the barrel body and used for supporting the barrel body.

Further, the surface of the scraping rod facing the electromagnet is coated with a wear-resistant layer.

Further, the crushing section comprises a jaw crusher and a cone crusher connected by a conveyor belt.

Further, the powder grinding part comprises a Raymond mill and a ball mill which are connected through a conveying belt, the Raymond mill is connected with the cone crusher through the conveying belt, the ball mill is connected with the first screening machine through the conveying belt, and the ball-material ratio of the ball mill is 2-3: 1.

further, the wear-resistant layer is prepared from the following raw materials in parts by weight: 27-36 parts of nitrile rubber, 17-30 parts of epoxy resin, 12-18 parts of polyvinyl chloride resin, 10-18 parts of aluminate, 6-10 parts of alumina, 5-8 parts of boron nitride, 5-8 parts of sodium sulfate, 5-8 parts of aluminum hydroxide, 3-6 parts of tungsten carbide and 1-5 parts of glass fiber.

Further, the flotation part comprises a flushing tank and a stirring paddle arranged in the flushing tank, and the flushing tank is connected with the second electromagnetic ore dressing device through a conveying belt; the flushing liquid in the flushing tank comprises two or more than two of turpentine, octadecylamine, dodecylamine acetate and tetradecyltrimethylammonium chloride.

Furthermore, the gas collection and dust removal part comprises a dust hood and an exhaust pipe connected with the dust hood, and the other end of the exhaust pipe is connected with the dust removal chamber.

Further, the product output section includes a thickening tower connected to the rinse tank.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

(1) in the first electromagnetic ore dressing device, potassium-sodium feldspar powder entering the cylinder is stirred by the stirring paddle, and the electromagnet is arranged on the inner side wall of the cylinder, so that the potassium-sodium feldspar powder can fly and move in the stirring process, iron-containing materials in the flying potassium-sodium feldspar powder can be more fully adsorbed by the electromagnet, and the iron-containing materials are adsorbed on the electromagnet and then scraped into the material collecting tank by the material scraping rod, so that the iron-containing materials in the potassium-sodium feldspar powder are fully removed, and the purity of the potassium-sodium feldspar powder is improved. In addition, the scraper bar can timely scrape off the iron-containing materials on the electromagnet, and the problem that the electromagnet cannot continue to adsorb after being adsorbed on the surface too much is avoided. When the material level sensor detects that the iron-containing material in the material collecting tank is full, information is transmitted to the controller, the controller controls the alarm to give an alarm, and the operator is informed to timely transfer the material in the material collecting tank out, so that the iron-containing material in the material collecting tank is prevented from falling into the iron-removed powder after being too much, and secondary pollution is avoided.

(2) The wear-resistant layer is coated on the surface, which is in contact with the first electromagnet, of the scraping rod, when the wear-resistant layer is manufactured, the nitrile rubber is utilized to have good wear resistance and adhesion, the high-hardness and corrosion-resistant aluminum oxide and boron nitride are added into the mixture of the rubber and the resin, sodium persulfate dehydration, aluminum hydroxide flame retardance and glass fiber toughening are carried out, and the aluminate is added, so that the adhesion of the rubber, the resin and other components is effectively promoted by the aluminate, the catalysis effect is achieved, the impact strength of the wear-resistant layer is improved, the adhesion degree of the wear-resistant layer is finally high, the wear resistance is good, the hardness is high, the flame retardance is good, the impact strength is high, and the use effect and the service life of the scraping rod are greatly improved.

Drawings

FIG. 1 is a block diagram showing the structure of a production line for albite powder according to example 1 of the present invention;

fig. 2 is a schematic structural diagram of a first electromagnetic beneficiation apparatus in a production line of albite powder in embodiment 1 of the present invention;

fig. 3 is a left side view of a first electromagnetic beneficiation apparatus in a production line of albite powder according to embodiment 1 of the present invention.

In the figure, 1-jaw crusher, 2-cone crusher, 3-Raymond mill, 4-ball mill, 5-first sieving machine, 6-first grading cyclone, 7-first electromagnetic ore dressing device, 7-1-feeding pipe, 7-2-cylinder, 7-3-supporting leg, 7-4-first motor, 7-5-second motor, 7-6-electromagnet, 7-7-collecting tank, 7-7-positioning plate, 7-9-scraping rod, 7-10-discharging port, 7-11-controller, 7-12-alarm, 8-second sieving machine, 9-second grading cyclone, 10-second electromagnetic ore dressing device, 11-flushing tank, 12-a dust hood, 13-an exhaust pipe, 14-a dust removal chamber, 15-a concentration tower, 16-a first sedimentation tank, 17-a second sedimentation tank and 18-a third sedimentation tank.

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.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When a component is referred to as being "connected" to another component, it can be directly connected to the other component or intervening components may also be present. When a component is referred to as being "disposed on" another component, it can be directly on the other component or intervening components may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Example 1

Referring to fig. 1, the production line for the albite powder comprises a crushing part, a milling part, a screening and impurity removing part, a flotation part, a finished product output part and a gas collection and dust removal part, wherein the crushing part, the milling part, the screening and impurity removing part, the flotation part and the finished product output part are sequentially connected through a conveying belt, and the gas collection and dust removal part is arranged above the milling part.

The crushing section comprises a jaw crusher 1 and a cone crusher 2 connected by a conveyor belt.

The powder grinding part comprises a Raymond mill 3 and a ball mill 4 which are connected through a conveying belt, the Raymond mill 3 is connected with the conical crusher 2 through the conveying belt, and the ball-material ratio of the ball mill 4 is 2-3: 1, preferably 3: 1, sufficiently ball-milling albite to improve the fineness of the albite powder.

Screening edulcoration part is including the first screening machine 5, first hierarchical swirler 6, first electromagnetism ore dressing device 7, second screening machine 8, second hierarchical swirler 9 and the second electromagnetism ore dressing device 10 that connect gradually, first screening machine 5 with ball mill 4 passes through the conveyer belt and is connected. In addition, the qualified slurry after passing through the first screening machine 5 and the second screening machine 8 enters a grading cyclone for grading separation, and the excess water and a small amount of fine silt after passing through the first grading cyclone 6 and the second grading cyclone 9 are discharged to a first sedimentation tank 16.

Referring to fig. 2 and 3, the first electromagnetic ore dressing device 7 includes a feeding pipe 7-1, a cylinder 7-2, a first motor 7-3, a second motor 7-4 and a supporting foot 7-5. The top of the cylinder 7-2 is provided with an upper opening for the feed pipe 7-1 to extend into. The improved drum is characterized in that a detachable stirring paddle 7-6 is arranged in the drum body 7-2, one end of the stirring paddle 7-6 is connected with a first motor 7-3 arranged on the drum body 7-2, and the other end of the stirring paddle 7-6 extends into the drum body 7-2. Electromagnets 7-7 are arranged on two opposite sides in the cylinder 7-2, a material collecting groove 7-8 is arranged below the electromagnets 7-7, the material collecting groove 7-8 is connected with the cylinder 7-2 in a sliding manner through a guide rail (not shown), and the guide rail is arranged on a positioning plate 7-13 which is perpendicular to the side wall of the cylinder 7-2. An opening with the size equivalent to the end face of the material collecting groove 7-8 is formed in the side wall of the cylinder body 7-2, so that the material collecting groove 7-8 can be moved out in a sliding mode. The barrel 7-2 is further internally provided with a scraping rod 7-9 which can rotate on the surface of the electromagnet 7-7 and is in contact with the surface of the electromagnet 7-7, one end of the scraping rod 7-9 is connected with a rotating shaft of the second motor 7-4, the rotating shaft penetrates through the center of the electromagnet 7-7, and the second motor 7-5 is arranged on the outer side wall of the barrel 7-2. The supporting legs 7-5 are arranged on the side wall, close to the bottom, of the cylinder 7-2 and used for supporting the cylinder 7-2.

The bottom of the cylinder 7-2 is obliquely arranged, a discharge port 7-10 is formed in the lower end of the bottom of the cylinder 7-2, and the discharge port 7-10 is connected with the second screening machine 8 through a conveying belt. Through the inclined arrangement, the albite powder with iron removed completely can smoothly and quickly slide out, and the influence on the stirring of the stirring paddle 7-6, the sliding of the material collecting groove 7-8 and the like caused by excessive accumulation of the albite powder in the cylinder 7-2 is prevented.

A material level sensor (not shown) is further arranged on the inner side wall, far away from the bottom, of the material collecting groove 7-8, the material level sensor is connected with a controller 7-11 arranged on the side wall of the barrel body 7-2, and the controller 7-11 is connected with an alarm 7-12 arranged on the side wall of the barrel body 7-2. The first motor 7-3 and the second motor 7-4 are both connected with the controller 7-11. The second electromagnetic ore dressing device 11 has the same structure as the first electromagnetic ore dressing device 8.

The scraping rod 7-9 in the embodiment is designed to be a cuboid, and the scraping rod is in surface-to-surface contact with the electromagnet 7-7, so that the contact area between the scraping rod 7-9 and the electromagnet 7-7 is increased, and the risk that the electromagnet 7-7 is easily scratched when the edge of the scraping rod is in contact with the electromagnet 7-7 (namely, the scraping rod 7-9 is in line-to-surface contact with the electromagnet 7-7) is avoided. And the surface-to-surface contact is more beneficial to the better rotation of the scraping rod 7-9 on the surface of the electromagnet 7-7, so that the iron-containing materials adsorbed on the surface of the electromagnet 7-7 are scraped completely.

In the first electromagnetic ore dressing device 7, potassium-sodium feldspar powder entering the cylinder 7-2 is stirred through the stirring paddle 7-6, the electromagnet 7-7 is arranged on the inner side wall of the cylinder 7-2, the potassium-sodium feldspar powder can fly and move in the stirring process, iron-containing materials in the flying potassium-sodium feldspar powder can be fully adsorbed by the electromagnet 7-7, and the iron-containing materials are adsorbed on the electromagnet 7-7 and then scraped down to the material collecting tank 7-8 through the material scraping rod 7-9, so that the iron-containing materials in the potassium-sodium feldspar powder are fully removed, and the purity of the potassium-sodium feldspar powder is improved. In addition, the material scraping rod 7-9 can timely scrape the iron-containing materials on the electromagnet 7-7, and the problem that the electromagnet 7-7 cannot continue to adsorb after being excessively adsorbed on the surface is solved. When the material level sensor detects that the material collecting tank 7-8 is full of materials, the information is transmitted to the controller 7-11, the controller 7-11 controls the alarm 7-12 to give an alarm, and a worker is informed to timely transfer the materials in the material collecting tank 7-8 out, so that the iron-containing materials are prevented from falling into the iron-removed powder, and secondary pollution is prevented.

The second electromagnetic ore dressing device 10 has the same structure as the first electromagnetic ore dressing device 7.

Further, the surface of the scraping rod 7-9 facing the electromagnet 7-6 is coated with a wear resistant layer. The wear-resistant layer is prepared from the following raw materials in parts by weight: 28 parts of nitrile rubber, 18 parts of epoxy resin, 12 parts of polyvinyl chloride resin, 10 parts of aluminate, 6 parts of alumina, 5 parts of boron nitride, 5 parts of sodium sulfate, 5 parts of aluminum hydroxide, 3 parts of tungsten carbide and 1 part of glass fiber. When the wear-resistant layer is manufactured, the nitrile rubber is utilized to have good wear resistance and adhesion, aluminum oxide and boron nitride which are high in hardness and corrosion resistant are added into a rubber and resin mixture, sodium sulfate is used for dehydration, aluminum hydroxide is used for flame retardance and glass fiber is used for toughening, and aluminate is added, so that the aluminate effectively promotes the adhesion of rubber, resin and other components, the catalysis effect is achieved, the impact strength of the wear-resistant layer is improved, the adhesion degree of the wear-resistant layer is finally high, the wear resistance is good, the hardness is high, the flame retardance is good, the impact strength is high, the using effect of the scraping rod 7-9 is greatly improved, and the service life of the scraping rod is greatly prolonged.

The specific structure of the first sifter 8 is the same as that of the first sifter in patent CN 107413518B, and will not be repeated here.

The flotation part comprises a flushing tank 11 and a stirring paddle (not shown) arranged in the flushing tank 11, and the flushing tank 11 is connected with the second electromagnetic ore dressing device 10 through a conveying belt. The rinsed water and mica are introduced into a second sedimentation tank 17, and the rinsed slurry enters a concentration tower 15 for concentration, so that solid and liquid are separated. The flushing liquid in the flushing tank 11 comprises two or more than two of turpentine, octadecylamine, dodecylamine acetate and tetradecyltrimethylammonium chloride, and the impurities such as mica and the like can be well removed by the flushing liquid. In this embodiment, the washing liquid preferably includes turpentine, octadecylamine and dodecylamine acetate, and the mass ratio of the turpentine, the octadecylamine and the dodecylamine acetate is 1:0.3: 0.1.

The gas collection and dust removal part comprises a dust hood 12 and an exhaust pipe 13 connected with the dust hood 12, and the other end of the exhaust pipe 13 is connected with a dust chamber 14.

The product output section comprises a thickening tower 15 connected to the flushing tank 11, the thickening tower 15 being used for dewatering the pulp. Concentrating and drying the mixture in a concentration tower 15 to obtain the finished product of the albite powder, and introducing redundant water into a third sedimentation tank 18.

Example 2

In this example, the same as example 1 was used except that the abrasion resistant layer was made of a different composition of the raw material.

In this embodiment, the wear-resistant layer is made of the following raw materials in parts by weight: 36 parts of nitrile rubber, 30 parts of epoxy resin, 18 parts of polyvinyl chloride resin, 18 parts of aluminate, 10 parts of alumina, 8 parts of boron nitride, 8 parts of sodium sulfate, 8 parts of aluminum hydroxide, 6 parts of tungsten carbide and 5 parts of glass fiber.

Example 3

In this example, the same as example 1 was used except that the abrasion resistant layer was made of a different composition of the raw material.

In this embodiment, the wear-resistant layer is made of the following raw materials in parts by weight: 30 parts of nitrile-butadiene rubber, 25 parts of epoxy resin, 15 parts of polyvinyl chloride resin, 14 parts of aluminate, 8 parts of alumina, 6 parts of boron nitride, 6 parts of sodium sulfate, 6 parts of aluminum hydroxide, 5 parts of tungsten carbide and 3 parts of glass fiber.

The above description is intended to describe in detail the preferred embodiments of the present invention, but the embodiments are not intended to limit the scope of the claims of the present invention, and all equivalent changes and modifications made within the technical spirit of the present invention should fall within the scope of the claims of the present invention.

Claims (8)

1. A production line of albite powder comprises a crushing part, a milling part, a screening and impurity removing part, a flotation part, a finished product output part and a gas-collecting and dust-removing part, wherein the crushing part, the milling part, the screening and impurity removing part, the flotation part and the finished product output part are sequentially connected, and the gas-collecting and dust-removing part is arranged above the milling part;

the first electromagnetic ore dressing device comprises a feeding pipe, a barrel, a first motor and a second motor, wherein an upper opening for the feeding pipe to extend into is formed in the top of the barrel, a detachable stirring paddle is arranged in the barrel, one end of the stirring paddle is connected with the first motor arranged on the barrel, and the other end of the stirring paddle extends into the barrel; electromagnets are arranged on two opposite sides in the barrel, a material collecting groove is arranged below the electromagnets and is connected with the barrel in a sliding manner through a guide rail, and the guide rail is arranged on a positioning plate which is vertical to the side wall of the barrel; an opening with the size equivalent to the end face of the material collecting groove is formed in the side wall of the cylinder body, so that the material collecting groove can be moved out in a sliding mode; a scraping rod which is contacted with the surface of the electromagnet is also arranged in the cylinder body, one end of the scraping rod is connected with a rotating shaft of the second motor, the rotating shaft penetrates through the center of the electromagnet, and the second motor is arranged outside the cylinder body;

the surface of the scraping rod facing the electromagnet is coated with a wear-resistant layer, and the wear-resistant layer is prepared from the following raw materials in parts by weight: 27-36 parts of nitrile rubber, 17-30 parts of epoxy resin, 12-18 parts of polyvinyl chloride resin, 10-18 parts of aluminate, 6-10 parts of alumina, 5-8 parts of boron nitride, 5-8 parts of sodium sulfate, 5-8 parts of aluminum hydroxide, 3-6 parts of tungsten carbide and 1-5 parts of glass fiber;

a material level sensor is further arranged on the inner side wall, far away from the bottom, of the material collecting groove and is connected with a controller arranged on the side wall of the barrel body, and the controller is connected with an alarm arranged on the side wall of the barrel body; the first motor and the second motor are both connected with the controller; the second electromagnetic ore dressing device has the same structure as the first electromagnetic ore dressing device.

2. The production line of albite powder as claimed in claim 1, wherein the bottom of the cylinder is inclined, and a discharge port is formed at the lower end of the bottom of the cylinder and connected with the second sieving machine through a conveying belt.

3. The production line of albite powder as claimed in claim 2, wherein the first electromagnetic ore dressing device further comprises supporting legs, and the supporting legs are arranged on the side wall of the cylinder body close to the bottom and used for supporting the cylinder body.

4. The production line of albite flour as claimed in claim 1, wherein the crushing section comprises a jaw crusher and a cone crusher connected by a conveyor belt.

5. The production line of albite powder as claimed in claim 4, wherein the milling part comprises a Raymond mill and a ball mill which are connected through a conveyer belt, the Raymond mill is connected with the cone crusher through the conveyer belt, the ball mill is connected with the first screening machine through the conveyer belt, and the ball-material ratio of the ball mill is 2-3: 1.

6. the production line of albite powder as claimed in claim 4, wherein the flotation section comprises a flushing tank and a stirring paddle arranged in the flushing tank, and the flushing tank is connected with the second electromagnetic ore dressing device through a conveying belt; the flushing liquid in the flushing tank comprises two or more than two of turpentine, octadecylamine, dodecylamine acetate and tetradecyltrimethylammonium chloride.

7. The production line of albite powder as claimed in claim 1, wherein the gas collection and dust removal part comprises a dust hood and an exhaust duct connected with the dust hood, and the other end of the exhaust duct is connected with a dust chamber.

8. The production line of albite powder as recited in claim 6, wherein the finished product output section includes a concentrating tower connected to the flushing tank.

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