CN213865379U - Automatic iron phosphate production device - Google Patents

Abstract

The utility model relates to a technical field of ferric phosphate production, more specifically relates to a ferric phosphate automated production device, including the phosphorus salt dissolving tank, the molysite dissolving tank, hydrogen peroxide solution metering tank, install the reation kettle of first pH meter, first pressure filter, dispersion tank, install the once ageing cauldron of first thermometer, install the secondary ageing cauldron and the second pressure filter of second pH meter and second thermometer, react, filter the washing, it is ageing, the dispersion, each process such as drying is controlled by DCS control system, phosphorus and heat resource in retrieval and utilization secondary lotion and the secondary mother liquor, can satisfy the complicated ferric phosphate synthesis technology and energy saving and consumption reduction's that new development, can realize the automated production of new technology and the automated monitoring of production flow again, be favorable to reduction in production cost and improvement production efficiency.

Description

Automatic iron phosphate production device

Technical Field

The utility model relates to a technical field of ferric phosphate production, more specifically relates to a ferric phosphate automated production device.

Background

At present, the mainstream iron phosphate is that monoclinic phase ferric phosphate is synthesized in two steps, basic ammonium ferric phosphate is generated in one step or two steps, and then the product is dehydrated in a kiln to prepare anhydrous iron phosphate. Most of the existing production devices rely on manual circulation and manual sampling detection, and have a plurality of defects: the method is only suitable for the existing mainstream simple flow iron phosphate production process, the production requirements cannot keep up with the newly developed complicated iron phosphate production process, for example, the existing process has proposed a multi-step secondary aging process and the recycling of phosphorus, ammonia resources and heat resources of wastewater, and the existing production equipment is difficult to meet and adapt to the newly developed process flow and technical requirements; the dependence of production circulation and detection on the manual work is higher, the automation degree is low, the improvement of the production efficiency is not facilitated, the production cost is increased, the manual detection has time delay and the instability of adding undetected data, and the production management and control are not facilitated and the product quality is improved.

Chinese patent CN102583293A discloses a method for producing battery grade ferric orthophosphate, which comprises the procedures of mixing reaction, filtering, washing, aging, washing aged slag, separating, drying and crushing, specifically, a, mixing reaction: taking clear liquid obtained after two-stage neutralization of feed-grade calcium hydrophosphate produced by wet-process phosphoric acid as a raw material, controlling reaction conditions, and carrying out mixing reaction to prepare crude iron phosphate; B. filtering, washing and aging: filtering and washing the iron phosphate slurry obtained by the mixing reaction, separating to obtain an iron phosphate filter cake, putting the iron phosphate filter cake into an ageing tank, and carrying out crystal conversion under the stirring action; C. washing and separating aged slag: repeatedly filtering and washing the aging slag obtained in the step B with water until the content of free phosphoric acid in the filter cake is less than or equal to 0.05 percent and the content of sulfuric acid in the filter cake is less than or equal to 0.0015 percent, and separating to obtain a filter cake with 25-50 percent of water; D. drying and crushing: and (4) drying, crushing and screening the filtered and washed aging slag of the filter cake in the step C to obtain a battery-grade dihydrate or anhydrous ferric phosphate product. Although the method can produce the battery-grade ferric phosphate by using cheap raw materials, the production process of the method cannot meet the production requirement of complicated ferric phosphate, and the method needs a large amount of manpower for matching and is not beneficial to production management and control.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome not enough among the prior art, provide an iron phosphate automated production device, can satisfy the iron phosphate synthesis technology that complicates of new development and energy saving and consumption reduction's technical requirement, can realize the automated production of new technology and the automated monitoring of production flow again, be favorable to reduction in production cost and improvement production efficiency.

In order to solve the technical problem, the utility model discloses a technical scheme is:

the utility model provides an iron phosphate automated production device, including phosphorus salt dissolving tank, molysite dissolving tank, hydrogen peroxide solution metering tank, install reation kettle, first pressure filter, dispersion tank of first pH meter, install an ageing cauldron of first thermometer, install secondary ageing cauldron and the second pressure filter of second pH meter and second thermometer:

the phosphorus salt dissolving tank, the ferric salt dissolving tank and the hydrogen peroxide metering tank are respectively communicated with the reaction kettle through a first flow pump, a second flow pump and a third flow pump; the measuring end of the first pH meter extends to a position below the liquid level of the reaction kettle, and the bottom of the reaction kettle is communicated with the first filter press through a first washing pump;

the first filter press is communicated with a first purified water supplementing pipeline, a primary mother liquid discharging pipeline and a primary washing liquid discharging pipeline, the primary washing liquid discharging pipeline is provided with a first conductivity meter, and the bottom of the first filter press is provided with a first discharging opening for discharging filter cakes to a first belt conveyor;

the dispersion kettle is arranged below the tail end of the first belt conveyor and is communicated with the primary aging kettle through a first transfer pump;

the primary aging kettle is communicated with a phosphoric acid supplementing pipeline, the measuring end of the first thermometer extends below the liquid level of the primary aging kettle, and the primary aging kettle is communicated with the secondary aging kettle;

the secondary aging kettle is communicated with an ammoniation agent supplementing pipeline, the measuring ends of the second pH meter and the second thermometer extend into the position below the liquid level of the secondary aging kettle, and the secondary aging kettle is communicated with a second filter press through a second washing pump;

the second filter press is communicated with a secondary washing liquid outlet pipeline and a secondary mother liquid outlet pipeline, the secondary washing liquid outlet pipeline is provided with a second conductivity meter, the bottom of the second filter press is provided with a second discharging port for discharging a filter cake to a second belt conveyor, and a dryer is arranged below the tail end of the second belt conveyor;

the first flow pump, the second flow pump, the third flow pump, the first pH meter, the second pH meter, the first thermometer, the second thermometer, the first conductivity meter, the second conductivity meter, the first washing pump, the second washing pump and the first transfer pump are all connected to the DCS control system.

The utility model discloses an iron phosphate automated production device:

adding a phosphorus salt raw material into a phosphorus salt dissolving tank for dissolution, adding an iron salt raw material into an iron salt dissolving tank for dissolution, and pumping quantitative phosphorus salt solution, iron salt solution and hydrogen peroxide solution into a reaction kettle by a first flow pump, a second flow pump and a third flow pump respectively and reacting in the reaction kettle; when the pH value tested by the first pH meter meets the technical index, transferring the amorphous slurry in the reaction kettle into a first filter press for primary washing and filtering;

supplying pure water into the first filter press through a first pure water supply pipeline for washing, removing primary mother liquor through a primary mother liquor discharge pipeline, removing primary washing liquor through a first washing liquor discharge pipeline, testing the conductivity of the primary washing liquor by adopting a first conductivity meter, and discharging first filter residues to a first belt conveyor through a first discharge port and conveying the filter residues to a dispersion kettle through the first belt conveyor after extruding and air drying when a test value is smaller than a set value; obtaining the solid content of the slurry in the dispersion kettle according to the weight of the added first filter residue and the weight of the liquid in the dispersion kettle, and transferring the dispersed slurry in the dispersion kettle into a primary aging kettle for aging when the solid content meets the set requirement;

in the primary aging kettle, adding quantitative phosphoric acid through a phosphoric acid adding pipeline according to the weight of the added dispersed slurry, aging for a set time at a set temperature to obtain monoclinic phase ferric phosphate dihydrate slurry, and transferring the monoclinic phase ferric phosphate dihydrate slurry to a secondary aging kettle;

in the secondary aging kettle, adding an ammoniating agent into the secondary aging kettle through an ammoniating agent supplementing pipeline to adjust the pH value of the monoclinic phase ferric phosphate dihydrate slurry to a set pH value, performing secondary aging at a set temperature, finishing the secondary aging after a set time is reached to obtain monoclinic phase basic ferric ammonium phosphate slurry, and transferring the monoclinic phase basic ferric ammonium phosphate slurry to a second filter press through a second washing pump;

in a second filter press, removing secondary mother liquor through a secondary mother liquor discharge pipeline, removing secondary washing liquor through a second washing liquor discharge pipeline, testing the conductivity of the secondary washing liquor by using a second conductivity meter, and when the test value is smaller than a set value, extruding and air-drying second filter residues, then discharging the second filter residues to a second belt conveyor through a second discharge port, conveying the second filter residues to a dryer through the second belt conveyor, and drying and dehydrating to finally obtain anhydrous iron phosphate;

the utility model discloses each process of preparing the iron phosphate is controlled by DCS control system, realizes that the automated production and the production process of iron phosphate detect, can satisfy the production needs of the iron phosphate that complicates, saves a large amount of manpowers, reduction in production cost, and do benefit to the production management and control.

Further, the bottom of the phosphorus salt dissolving tank is provided with a first wagon balance, the bottom of the ferric salt dissolving tank is provided with a second wagon balance, the bottom of the dispersion kettle is provided with a third wagon balance, and the first wagon balance, the second wagon balance and the third wagon balance are all connected to a DCS control system.

Furthermore, a first pumping pump and a phosphorus salt metering tank are arranged between the phosphorus salt dissolving tank and the first flow pump, and the first pumping pump is arranged between the phosphorus salt dissolving tank and the phosphorus salt metering tank; be equipped with second pump and molysite metering tank between molysite dissolving tank and the second flow pump, the second pump is located between molysite dissolving tank and the molysite metering tank, first pump, second pump are all connected in DCS control system.

Further, the dispersion kettle is provided with a feeding port located right below the tail end of the first belt conveyor, and the feeding port is of a conical structure with the size gradually reduced from top to bottom.

Further, the reaction kettle is also provided with a third thermometer, and the measuring end of the third thermometer extends into the liquid level of the reaction kettle; the reaction kettle is characterized in that a first jacket is arranged on the periphery of the reaction kettle, a first cavity for allowing cooling water to flow is formed between the first jacket and the outer wall of the reaction kettle, a water inlet is formed in the lower portion of the first jacket, and a water outlet is formed in the upper portion of the first jacket.

Furthermore, a second jacket is arranged on the periphery of the primary aging kettle, a second cavity for accommodating steam to flow is formed between the second jacket and the outer wall of the primary aging kettle, a steam inlet is formed in the upper part of the second jacket, and a steam outlet is formed in the lower part of the second jacket.

Further, the phosphorus salt dissolving tank is equipped with the phosphorus salt rabbling mechanism, the molysite dissolving tank is equipped with molysite rabbling mechanism, reation kettle is equipped with first stirring subassembly, dispersion tank is equipped with second stirring subassembly, an ageing cauldron is equipped with third stirring subassembly, the secondary ageing cauldron is equipped with fourth stirring subassembly.

Further, the secondary mother liquor outlet pipeline is connected with a plate heat exchanger, the plate heat exchanger is communicated with a second purified water supplementing pipeline, and the purified water and the secondary mother liquor are subjected to heat exchange in the plate heat exchanger; the secondary washing liquid outlet pipeline is communicated with the dispersion kettle.

Further, plate heat exchanger is equipped with the first liquid outlet that is used for flowing out the pure water and is used for flowing out the second liquid outlet of secondary mother liquor: the first liquid outlet is communicated with a hot water storage tank, and the hot water storage tank is communicated to a water inlet end of the second washing pump; and the second liquid outlet is communicated with a demagnetizing filter, and the demagnetizing filter is communicated with a phosphorus salt dissolving tank and an iron salt dissolving tank.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses an iron phosphate automated production device can satisfy new development's iron phosphate synthesis technology that complicates and energy saving and consumption reduction's technical requirement, can realize the automated production of new technology and the automated monitoring of production flow again, is favorable to reduction in production cost and improvement production efficiency.

Drawings

Fig. 1 is a schematic view of an automatic iron phosphate production apparatus according to the present invention;

in the drawings: 1-a phosphorus salt dissolving tank; 11-a first flow pump; 12-a first wagon balance; 13-a phosphorus salt feeding pipeline; 14-a phosphorus salt purified water pipeline; 15-a first pump; a 16-phosphonium salt metering tank; 17-a phosphonium salt stirring mechanism; 2-iron salt dissolving tank; 21-a second flow pump; 22-second wagon balance; 23-a ferric salt feeding pipeline; 24-ferric salt purified water pipe; 25-a second material pumping pump; 26-a ferric salt metering tank; 27-a ferric salt stirring mechanism; 3-a hydrogen peroxide metering tank; 31-a third flow pump; 4-a reaction kettle; 41-a first pH meter; 42-a third thermometer; 43-first jacket; 44-a water inlet; 45-water outlet; 46-a first stirring assembly; 5-a first filter press; 51-a first water replenishing pipeline; 52-primary mother liquor discharge pipeline; 53-primary washing liquid outlet pipe; 54-a first conductivity meter; 55-a first belt conveyor; 56-a first wash pump; 6-a dispersing kettle; 61-a first transfer pump; 62-third wagon balance; 63-feeding mouth; 64-a second stirring assembly; 7-a primary aging kettle; 71-a first thermometer; 72-phosphoric acid supply pipeline; 73-a second jacket; 74-steam inlet; 75-a steam outlet; 76-a weighing module; 77-a third stirring assembly; 8-secondary aging kettle; 81-a second pH meter; 82-a second thermometer; 83-ammoniating agent supply pipeline; 84-third jacket; 85-a fourth stirring assembly; 9-a second filter press; 91-a second wash pump; 92-a secondary washing liquid outlet pipeline; 93-secondary mother liquor discharge pipeline; 94-a second conductivity meter; 95-a second belt machine; 96-plate heat exchanger; 97-a second purified water supply pipeline; 98-hot water storage tank; 99-a degaussing filter; 10-a dryer.

Detailed Description

The present invention will be further described with reference to the following embodiments. Wherein the showings are for the purpose of illustration only and are shown by way of illustration only and not in actual form, and are not to be construed as limiting the present patent; for a better understanding of the embodiments of the present invention, some parts of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product; it will be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

The same or similar reference numerals in the drawings of the embodiments of the present invention correspond to the same or similar parts; in the description of the present invention, it should be understood that if there are the terms "upper", "lower", "left", "right", etc. indicating the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, it is only for convenience of description and simplification of the description, but it is not intended to indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and therefore the terms describing the positional relationship in the drawings are only for illustrative purposes and are not to be construed as limitations of the present patent, and those skilled in the art can understand the specific meanings of the terms according to specific situations.

Example one

Fig. 1 shows an embodiment of the automatic iron phosphate production apparatus of the present invention, which includes a phosphate dissolving tank 1, an iron salt dissolving tank 2, a hydrogen peroxide metering tank 3, a reaction kettle 4 equipped with a first pH meter 41, a first filter press 5, a dispersion kettle 6, a first aging kettle 7 equipped with a first thermometer 71, a second aging kettle 8 equipped with a second pH meter 81 and a second thermometer 82, and a second filter press 9:

the phosphorus salt dissolving tank 1, the iron salt dissolving tank 2 and the hydrogen peroxide metering tank 3 are respectively communicated with the reaction kettle 4 through a first flow pump 11, a second flow pump 21 and a third flow pump 31; the measuring end of the first pH meter 41 extends to a position below the liquid level of the reaction kettle 4, and the bottom of the reaction kettle 4 is communicated with the first filter press 5 through a first washing pump 56;

the first filter press 5 is communicated with a first pure water supplementing pipeline 51, a primary mother liquid discharging pipeline 52 and a primary washing liquid water outlet pipeline 53, the primary washing liquid water outlet pipeline 53 is provided with a first conductivity meter 54, and the bottom of the first filter press 5 is provided with a first discharging opening for discharging filter cakes to a first belt conveyor 55;

the dispersing kettle 6 is arranged below the tail end of the first belt conveyor 55, and the dispersing kettle 6 is communicated with the primary aging kettle 7 through a first transfer pump 61;

the primary aging kettle 7 is communicated with a phosphoric acid supplementing pipeline 72, the measuring end of a first thermometer 71 extends to be below the liquid level of the primary aging kettle 7, and the primary aging kettle 7 is communicated with a secondary aging kettle 8;

the secondary aging kettle 8 is communicated with an ammoniation agent supplementing pipeline 83, the measuring ends of a second pH meter 81 and a second thermometer 82 extend into the position below the liquid level of the secondary aging kettle 8, and the secondary aging kettle 8 is communicated with a second filter press 9 through a second washing pump 91;

the second filter press 9 is communicated with a secondary washing liquid outlet pipeline 92 and a secondary mother liquid outlet pipeline 93, the secondary washing liquid outlet pipeline 92 is provided with a second conductivity meter 94, the bottom of the second filter press 9 is provided with a second discharge port for discharging filter cakes to a second belt conveyor 95, and a dryer 10 is arranged below the tail end of the second belt conveyor 95;

the first flow pump 11, the second flow pump 21, the third flow pump 31, the first pH meter 41, the second pH meter 81, the first temperature meter 71, the second temperature meter 82, the first conductivity meter 54, the second conductivity meter 94, the first washing pump, the second washing pump 91, and the first transfer pump 61 are all connected to a DCS control system.

The present example was carried out as follows:

adding a phosphorus salt raw material into a phosphorus salt dissolving tank 1 for dissolving, adding an iron salt raw material into an iron salt dissolving tank 2 for dissolving, and pumping quantitative phosphorus salt solution, iron salt solution and hydrogen peroxide solution into a reaction kettle 4 by a first flow pump 11, a second flow pump 21 and a third flow pump 31 respectively and reacting in the reaction kettle 4; when the pH value tested by the first pH meter 41 meets the technical index, transferring the amorphous slurry in the reaction kettle 4 into a first filter press 5 for filtering by one-time washing;

supplying pure water into the first filter press 5 through a first pure water supply pipeline 51 for washing, removing primary mother liquid through a primary mother liquid discharge pipeline 52, removing primary washing liquid through a first washing liquid discharge pipeline, testing the conductivity of the primary washing liquid by using a first conductivity meter 54, and discharging and dropping first filter residues to a first belt conveyor 55 through a first discharge port and conveying the first belt conveyor 55 to the dispersion kettle 6 through the first belt conveyor 55 after extruding and air drying when the test value is smaller than a set value; obtaining the solid content of the slurry in the dispersing kettle 6 according to the weight of the added first filter residue and the weight of the liquid in the dispersing kettle 6, and when the solid content meets the set requirement, transferring the dispersed slurry in the dispersing kettle 6 into a primary aging kettle 7 for aging;

in the primary aging kettle 7, adding a certain amount of phosphoric acid through a phosphoric acid adding pipeline 72 according to the weight of the added dispersed slurry, aging for a set time at a set temperature to obtain monoclinic phase ferric phosphate dihydrate slurry, and transferring the monoclinic phase ferric phosphate dihydrate slurry to a secondary aging kettle 8;

in the secondary aging kettle 8, an ammoniating agent is supplemented into the secondary aging kettle 8 through an ammoniating agent supplementing pipeline 83 to adjust the pH value of the monoclinic phase ferric phosphate dihydrate slurry to a set pH value, secondary aging is carried out at a set temperature, after a set time is reached, secondary aging is finished to obtain monoclinic phase basic ferric ammonium phosphate slurry, and the monoclinic phase basic ferric ammonium phosphate slurry is transferred to a second filter press 9 through a second washing pump 91;

in the second filter press 9, the secondary mother liquor is removed through a secondary mother liquor discharge pipeline 93, the secondary washing liquor is removed through a second washing liquor discharge pipeline, the conductivity of the secondary washing liquor is tested by using a second conductivity meter 94, and when the test value is smaller than the set value, the second filter residue is extruded and air-dried, then is discharged through a second discharge port to a second belt conveyor 95, is conveyed to a dryer 10 through the second belt conveyor 95 for drying and dehydration, and finally anhydrous iron phosphate is obtained;

above-mentioned each process is controlled by DCS control system, realizes that the automated production and the production process of iron phosphate detect, can satisfy the production needs of the iron phosphate that complicates, saves a large amount of manpowers, reduction in production cost, and do benefit to the production management and control.

In one embodiment, places needing to be communicated in the automatic ferric phosphate production device are communicated by pipelines, electromagnetic valves controlled by a DCS control system are arranged on the pipelines, and the automatic control of the flow direction of slurry is realized by controlling the switches of the electromagnetic valves.

In one embodiment, the bottom of the phosphorus salt dissolving tank 1 is provided with a first wagon balance 12, the bottom of the iron salt dissolving tank 2 is provided with a second wagon balance 22, the bottom of the dispersing kettle 6 is provided with a third wagon balance 62, and the first wagon balance 12, the second wagon balance 22 and the third wagon balance 62 are all connected to the DCS control system. Specifically, the phosphorus salt dissolving tank 1 is provided with a phosphorus salt feeding pipeline 13 and a phosphorus salt supplementing pure water pipeline 14, pneumatic electromagnetic valves controlled by a DCS (distributed control system) are respectively arranged on the phosphorus salt feeding pipeline 13 and the phosphorus salt supplementing pure water pipeline 14, phosphorus salt and pure water are respectively fed into the phosphorus salt dissolving tank 1 through the phosphorus salt feeding pipeline 13 and the phosphorus salt supplementing pure water pipeline 14, and a diammonium phosphate solution with a set concentration can be obtained by controlling the feeding quality of phosphorus salt and pure water; the iron salt dissolving tank 2 is provided with an iron salt feeding pipeline 23 and an iron salt supplementing pure water pipeline 24, pneumatic electromagnetic valves controlled by a DCS control system are respectively arranged on the iron salt feeding pipeline 23 and the iron salt supplementing pure water pipeline 24, the iron salt feeding pipeline 23 and the iron salt supplementing pure water pipeline 24 respectively feed iron salt and pure water into the iron salt dissolving tank 2, and ferrous sulfate solution with set concentration can be obtained by controlling the feeding quality of the iron salt and the pure water. And then, adding the prepared ferrous sulfate solution and diammonium phosphate solution into the reaction kettle 4 under the control of a DCS control system. In order to promote the dissolution of the phosphorus salt and the iron salt, the phosphorus salt dissolving tank 1 of the present embodiment is provided with a phosphorus salt stirring mechanism, and the iron salt dissolving tank 2 is provided with an iron salt stirring mechanism.

In one embodiment, a first pumping pump 15 and a phosphorus salt metering tank 16 are arranged between the phosphorus salt dissolving tank 1 and the first flow pump 11, and the first pumping pump 15 is arranged between the phosphorus salt dissolving tank 1 and the phosphorus salt metering tank 16; be equipped with second pump 25 and molysite metering tank 26 between molysite dissolving tank 2 and the second flow pump 21, second pump 25 locates between molysite dissolving tank 2 and molysite metering tank 26, and first pump 15, second pump 25 all connect in DCS control system. In implementation, the phosphorus salt metering tank 16, the iron salt metering tank 26 and the hydrogen peroxide metering tank 3 are opened, phosphorus salt, iron salt and hydrogen peroxide are pumped until the upper limit values of the phosphorus salt metering tank 16, the iron salt metering tank 26 and the hydrogen peroxide metering tank 3 are reached, and dropwise addition reaction is carried out in the reaction kettle 4 through the first flow pump 11, the second flow pump 21 and the third flow pump 31 respectively.

In one embodiment, the reaction kettle 4 is further provided with a third thermometer 42, and the measuring end of the third thermometer 42 extends into the position below the liquid level of the reaction kettle 4; the periphery of the reaction kettle 4 is provided with a first jacket 43, a first cavity for cooling water to flow is formed between the first jacket 43 and the outer wall of the reaction kettle 4, the lower part of the first jacket 43 is provided with a water inlet 44, and the upper part of the first jacket 43 is provided with a water outlet 45. The reaction kettle 4 generates heat in a chemical reaction, the third thermometer 42 is used for monitoring the reaction temperature in real time, and cooling water flows in the first jacket 43 to prevent the temperature in the reaction kettle 4 from generating byproducts at high yield. In order to make the reaction complete, the reaction kettle 4 of the present embodiment is provided with the first stirring assembly 46, so that the phosphonium salt, the iron salt and the hydrogen peroxide are fully mixed and reacted in the reaction kettle 4. After the reaction is finished, the first pH meter 41 transmits the tested pH value to a DCS control system, after the technical index is confirmed to be met, the DCS control system opens a first washing pump, the first washing pump transfers the amorphous slurry in the reaction kettle 4 into a first filter press 5 for primary washing filtration, primary mother liquor is transferred through a primary mother liquor discharge pipeline 52, and an electromagnetic valve at the bottom of the reaction kettle 4 and an electromagnetic valve of the primary mother liquor discharge pipeline 52 are closed after the filtration is finished; during washing, the first pure water supplementing pipeline 51 and the primary washing liquid water outlet pipeline 53 are opened, pure water is used for washing until the first conductivity meter 54 tests that the conductivity of the primary washing liquid is less than or equal to 10000us/cm, the first pure water supplementing pipeline 51 and the primary washing liquid water outlet pipeline 53 are closed, subsequent extrusion and air drying operations are carried out, then the DCS control system controls the first discharge opening to be opened, the first filter cake in the first filter press 5 is discharged onto the first belt conveyor 55, and the first filter cake is conveyed into the dispersion kettle 6 through the first belt conveyor 55.

In one embodiment, the dispersing tank 6 is provided with a feeding port 63 located right below the end of the first belt conveyor 55, and the feeding port 63 is a tapered structure with gradually decreasing size from top to bottom. The shape of the feeding port 63 and the shape of the feeding port 63 are preferably provided to prevent the first residue from leaking, and are not intended to be restrictive in the present invention. In order to facilitate the dispersion of the first filter residue, the second stirring assembly is installed in the dispersing kettle 6 in the embodiment. In the dispersing kettle 6, the solid content of the slurry can be calculated by the weight of the added first filter cake and the weight of the added liquid, and if the solid content is normal, the subsequent dispersing operation is carried out.

In one embodiment, a second jacket 73 is arranged on the periphery of primary aging kettle 7, a second cavity for steam to flow is formed between second jacket 73 and the outer wall of primary aging kettle 7, a steam inlet 74 is arranged at the upper part of second jacket 73, and a steam outlet 75 is arranged at the lower part of second jacket 73. The primary aging kettle 7 is provided with a weighing module 76 which is convenient for measuring the weight of the slurry added into the primary aging kettle 7 and calculating the amount of phosphoric acid to be added according to the detected weight of the slurry. The temperature rise and the heat preservation are realized by the steam flowing in the second jacket 73, and the monoclinic phase dihydrate ferric phosphate slurry is obtained after the primary aging is carried out at the set temperature and is continuously carried out for the set time. In the embodiment, the secondary aging kettle 8 can be arranged below the primary aging kettle 7, and the monoclinic phase ferric phosphate dihydrate slurry in the primary aging kettle 7 falls into the secondary aging kettle 8 under the action of self gravity. In order to facilitate the primary aging, the primary aging kettle 7 is provided with a third stirring component 77 in the embodiment. In the secondary aging kettle 8, a second pH meter 81 detects the pH value of the slurry in the aging kettle, and an ammoniating agent is added through an ammoniating agent supplementing pipeline 83 to adjust the pH value to a set value. A third jacket 84 is arranged on the periphery of the secondary aging kettle 8, a third cavity for allowing steam to flow is formed between the third jacket 84 and the outer wall of the secondary aging kettle 8, the temperature rise and the heat preservation of the steam flowing in the third jacket 84 are realized, and the monoclinic phase basic ferric ammonium phosphate slurry is obtained after the secondary aging is carried out at a set temperature and is continuously carried out for a set time. The DCS control system opens a second washing pump 91, the second washing pump 91 transfers the monoclinic phase basic ferric ammonium phosphate slurry in the primary aging kettle 7 into a second filter press 9 for secondary washing filtration, secondary mother liquor is transferred through a secondary mother liquor discharge pipeline 93, and an electromagnetic valve at the bottom of the secondary aging kettle 8 and the electromagnetic valve of the secondary mother liquor discharge pipeline 93 are closed after filtration is completed; and during washing, opening a secondary washing liquid water outlet pipeline 92, washing by using pure water until the conductivity of the secondary washing liquid is less than or equal to 10000us/cm when the second conductivity meter 94 tests, closing the secondary washing liquid water outlet pipeline 92, performing subsequent extrusion and air drying operation, controlling a second discharge opening to be opened by a DCS (distributed control system), discharging a second filter cake in the second filter press 9 onto a second belt conveyor 95, and conveying the second filter cake into the dryer 10 by the second belt conveyor 95. In order to facilitate the secondary aging, the secondary aging kettle 8 is provided with a fourth stirring component 85 in the embodiment.

In one embodiment, the secondary mother liquor outlet pipeline is connected with a plate heat exchanger 96, the plate heat exchanger 96 is communicated with a second pure water supplementing pipeline 97, and pure water and secondary mother liquor are subjected to heat exchange in the plate heat exchanger 96; the secondary washing liquid outlet pipe 92 is communicated with the dispersion kettle 6. The filtered secondary mother liquor is transferred to the plate heat exchanger 96 through a secondary mother liquor outlet pipeline, pure water is supplemented into the plate heat exchanger 96 through a second pure water supplementing pipeline 97, and the secondary mother liquor exchanges heat with the pure water in the plate heat exchanger 96. The secondary washing liquid is transferred to the dispersing kettle 6 through the secondary washing liquid outlet pipeline 92 to be used as dispersing water for the next batch of materials, phosphorus and heat resources in the secondary washing liquid can be recycled, the additional value of the waste water is improved, the generation amount of the waste water and the use amount of pure water are reduced, and the production cost is reduced.

In one embodiment, the plate heat exchanger 96 is provided with a first liquid outlet for flowing out pure water and a second liquid outlet for flowing out secondary mother liquid: the first liquid outlet is communicated with a hot water storage tank 98, and the hot water storage tank 98 is communicated to the water inlet end of the second washing pump 91; the second liquid outlet is communicated with a magnetic removal filter 99, and the magnetic removal filter 99 is communicated with a phosphorus salt dissolving tank 1 and an iron salt dissolving tank 2. Pure water flows to the hot water storage tank 98 for secondary washing after being heated, the secondary mother liquor is demagnetized and filtered after being cooled, and then is transferred to the ferric salt and phosphorus salt dissolving tank 1 of the batching section through a secondary mother liquor supplementing pipeline to be used as dissolving water of next batch of materials, phosphorus and heat resources in the secondary mother liquor can be recycled, the additional value of the waste water is improved, the generation amount of the waste water and the use amount of the pure water are reduced, and the production cost is reduced.

In the detailed description of the embodiments, various technical features may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

It is obvious that the above embodiments of the present invention are only examples for clearly illustrating the present invention, and are not limitations to the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.

Claims (10)

1. The utility model provides an iron phosphate automated production device, its characterized in that, includes phosphorus salt dissolving tank, molysite dissolving tank, hydrogen peroxide solution metering tank, installs reation kettle, first pressure filter, dispersion tank of first pH meter, installs an ageing cauldron of first thermometer, installs secondary ageing cauldron and the second pressure filter of second pH meter and second thermometer:

the phosphorus salt dissolving tank, the ferric salt dissolving tank and the hydrogen peroxide metering tank are respectively communicated with the reaction kettle through a first flow pump, a second flow pump and a third flow pump; the measuring end of the first pH meter extends to a position below the liquid level of the reaction kettle, and the bottom of the reaction kettle is communicated with the first filter press through a first washing pump;

the first filter press is communicated with a first purified water supplementing pipeline, a primary mother liquid discharging pipeline and a primary washing liquid discharging pipeline, the primary washing liquid discharging pipeline is provided with a first conductivity meter, and the bottom of the first filter press is provided with a first discharging opening for discharging filter cakes to a first belt conveyor;

the dispersion kettle is arranged below the tail end of the first belt conveyor and is communicated with the primary aging kettle through a first transfer pump;

the primary aging kettle is communicated with a phosphoric acid supplementing pipeline, the measuring end of the first thermometer extends below the liquid level of the primary aging kettle, and the primary aging kettle is communicated with the secondary aging kettle;

the secondary aging kettle is communicated with an ammoniation agent supplementing pipeline, the measuring ends of the second pH meter and the second thermometer extend into the position below the liquid level of the secondary aging kettle, and the secondary aging kettle is communicated with a second filter press through a second washing pump;

the second filter press is communicated with a secondary washing liquid outlet pipeline and a secondary mother liquid outlet pipeline, the secondary washing liquid outlet pipeline is provided with a second conductivity meter, the bottom of the second filter press is provided with a second discharging port for discharging a filter cake to a second belt conveyor, and a dryer is arranged below the tail end of the second belt conveyor;

the first flow pump, the second flow pump, the third flow pump, the first pH meter, the second pH meter, the first thermometer, the second thermometer, the first conductivity meter, the second conductivity meter, the first washing pump, the second washing pump and the first transfer pump are all connected to the DCS control system.

2. The automatic ferric phosphate production device of claim 1, wherein the bottom of the phosphorus salt dissolving tank is provided with a first wagon balance, the bottom of the ferric salt dissolving tank is provided with a second wagon balance, the bottom of the dispersion tank is provided with a third wagon balance, and the first wagon balance, the second wagon balance and the third wagon balance are all connected to a DCS control system.

3. The automatic ferric phosphate production device according to claim 2, wherein a first pumping pump and a phosphorus salt metering tank are arranged between the phosphorus salt dissolving tank and the first flow pump, and the first pumping pump is arranged between the phosphorus salt dissolving tank and the phosphorus salt metering tank; be equipped with second pump and molysite metering tank between molysite dissolving tank and the second flow pump, the second pump is located between molysite dissolving tank and the molysite metering tank, first pump, second pump are all connected in DCS control system.

4. The automatic ferric phosphate production device according to claim 1, wherein the dispersion tank is provided with a feeding port which is positioned right below the tail end of the first belt conveyor, and the feeding port is of a conical structure with the size gradually decreasing from top to bottom.

5. The automatic ferric phosphate production device according to claim 1, wherein the reaction kettle is further provided with a third thermometer, and a measuring end of the third thermometer extends below the liquid level of the reaction kettle; the reaction kettle is characterized in that a first jacket is arranged on the periphery of the reaction kettle, a first cavity for allowing cooling water to flow is formed between the first jacket and the outer wall of the reaction kettle, a water inlet is formed in the lower portion of the first jacket, and a water outlet is formed in the upper portion of the first jacket.

6. The automatic ferric phosphate production device according to claim 1, wherein a second jacket is arranged on the periphery of the primary aging kettle, a second cavity for allowing steam to flow is formed between the second jacket and the outer wall of the primary aging kettle, a steam inlet is arranged at the upper part of the second jacket, and a steam outlet is arranged at the lower part of the second jacket.

7. The automatic ferric phosphate production device according to any one of claims 1 to 6, wherein the phosphorus salt dissolving tank is provided with a phosphorus salt stirring mechanism, the ferric salt dissolving tank is provided with a ferric salt stirring mechanism, the reaction kettle is provided with a first stirring component, the dispersion kettle is provided with a second stirring component, the primary aging kettle is provided with a third stirring component, and the secondary aging kettle is provided with a fourth stirring component.

8. The automatic iron phosphate production device according to any one of claims 1 to 6, wherein the secondary mother liquor outlet pipeline is connected with a plate heat exchanger, the plate heat exchanger is communicated with a second purified water supplementing pipeline, and the purified water and the secondary mother liquor exchange heat in the plate heat exchanger.

9. The automatic ferric phosphate production device according to claim 8, wherein the secondary washing liquid outlet pipeline is communicated with the dispersion tank.

10. The automatic ferric phosphate production device of claim 8, wherein the plate heat exchanger is provided with a first liquid outlet for flowing pure water and a second liquid outlet for flowing secondary mother liquor: the first liquid outlet is communicated with a hot water storage tank, and the hot water storage tank is communicated to a water inlet end of the second washing pump; and the second liquid outlet is communicated with a demagnetizing filter, and the demagnetizing filter is communicated with a phosphorus salt dissolving tank and an iron salt dissolving tank.

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