CN201587859U

CN201587859U - Lithium iron phosphate micro-wave heating horizontal continuous production equipment

Info

Publication number: CN201587859U
Application number: CN2009202763929U
Authority: CN
Inventors: 刘新保; 李恩惠; 吴铁雷; 周永刚; 蔡俊明
Original assignee: HENAN UNION NEW ENERGY CO Ltd
Current assignee: HENAN UNION NEW ENERGY CO Ltd
Priority date: 2009-12-11
Filing date: 2009-12-11
Publication date: 2010-09-22
Anticipated expiration: 2019-12-11

Abstract

The utility model discloses lithium iron phosphate micro-wave heating horizontal continuous production equipment, which comprises a feed opening, a feeding ventilation chamber, a preprocessing unit furnace, a presintering unit furnace, a sintering unit furnace, a discharging ventilation chamber, a cooling, temperature-reducing and discharging mechanism, a discharge opening, a vacuum pumping device, a shielded gas input device and an equipment control circuit; three sets of unit furnaces including the preprocessing unit furnace, the presintering unit furnace and the sintering unit furnace identically comprise an unit furnace feed opening, an unit furnace body, a microwave shielding heat-insulation structural layer outside the unit furnace, a microwave source, a certain number of microwave pipes, at least one air intake and extraction pipe, an unit furnace discharge opening and an auger conveyer; the three sets of unit furnaces are horizontally disposed; and the discharge opening of the unit furnaces is directly communicated with the feed opening in sequence. The microwave sintering of the utility model enhances internal crystal densification of the product, thereby effectively improving product quality; the multiple unit furnaces are applied to continuous microwave sintering, thereby improving sintering efficiency; and the industrialized mass production efficiency and the economic benefit are considerable.

Description

LiFePO 4 by microwaves heats horizontal continuous production equipment

One, technical field:

The utility model relates to new forms of energy battery material agglomerating plant field, and particularly a kind of LiFePO 4 by microwaves heats horizontal continuous production equipment.

Two, background technology:

Advantages such as lithium ion battery has discharge-rate height, use temperature wide ranges, cycle performance is good, security good, environment friendly and pollution-free, since coming out, be widely used in the portable electric appts such as mobile telephone, laptop computer, miniature camera, as energy and material of new generation, use constantly propelling in fields such as electromobile, satellite, space flight and military affairs, have a extensive future.Positive electrode material is the important component part of lithium ion battery, is the key point of research and development high performance lithium ion battery.Iron lithium phosphate (LiFePO ₄) as anode material of lithium battery, have that starting material sources is abundant, cheap, non-environmental-pollution, advantage such as capacity is higher, cycle performance is good, good stability, preparation battery safety are given prominence to, in various battery powers field, particularly there are great market outlook large-sized power application of power aspect, is one of the most promising anode material for lithium-ion batteries.

Current iron lithium phosphate (LiFePO ₄) the stove equipment such as atmosphere protection pusher furnace, atmosphere protection rotary kiln that mainly contain of agglomerating plant comparative maturity; these agglomerating plants are generally Electric heating; Heating element is resistance wire, globars; thermosteresis is big; and thermograde is big; cause product composition and granularity inhomogeneous easily, occupation area of equipment is big simultaneously, the cost of investment height.Microwave sintering mainly is the coupling that utilizes micro-wave energy and material, be transformed into heat energy direct heating material to sintering temperature by the dielectric loss of material and the in-fighting of magnetic dielectric loss consumption generation, being sintered material itself is exactly heating element, thereby thermosteresis is little, and because of the penetration depth of microwave is big, thermograde is very little, can heat up apace and lower the temperature, thereby whole sintering process is shortened significantly, do not have shade influence, now microwave technology has become one of sintering technology of tool development prospect.Iron lithium phosphate (LiFePO ₄) microwave sintering generally use the industrialized microwave stove, can't continuous production, level of automation is low, scale and benefit are poor, at present still needleless to iron lithium phosphate (LiFePO ₄) the microwave continuous agglomerating plant of the special suitability for industrialized production that proposes of sintering process characteristics.Utility model patent ZL200520051470.7 proposes " a kind of continuous powdery material microwave sintering oven ", comprise feed mechanism, microwave source, transition waceguide, body of heater, burner hearth, discharging mechanism, thermal insulation layer, temperature measurer, microwave-assisted absorbing material, body of heater is up big and down small awl bucket shape structure, be provided with helical-ribbon type taper agitator in it, link to each other with transmission rig; Feed mechanism is the screw feeder structure, and discharging mechanism is a water-cooled spiral discharging mechanism; One cover microwave source is arranged around body of heater with the combination of many cover transition waceguides; At least one group of inlet mouth and venting port are provided with the stainless steel microporous filter, and body of heater is provided with the observation port of infrared thermometer, and body of heater is a ceramic material, and helical-ribbon type taper agitator is steel construction surface lining stupalith or stainless steel.This utility model is simple in structure, cost is low, and does not need boat, health environment-friendly, efficient, is suitable for the microwave sintering of some polarity powder body materials.But there is the problem that can not carry out the substep continuous microwave fritting according to iron lithium phosphate agglomerating processing requirement in this utility model, can't realize industrialization scale operation, and production cost is also high.

Three, summary of the invention

Technical problem to be solved in the utility model is: overcome weak point of the prior art, provide a kind of and can realize substep stoking, microwave continuous agglomerating plant that can large-scale production.

The utility model is achieved in that

A kind of LiFePO 4 by microwaves heats horizontal continuous production equipment, comprise opening for feed, the charging air-exchanging chamber, the pretreatment unit stove, presintering unit stove, sintering unit stove, the discharging air-exchanging chamber, discharging mechanism cools, discharge port, vacuum extractor, shielding gas input unit and equipment control circuit, the pretreatment unit stove, presintering unit stove, sintering unit stove three cover unit stoves, contain unit stove opening for feed equally, the unit body of heater, the outer micro-wave screening insulation construction layer of unit body of heater, microwave source, a certain number of microwave tube, at least one is advanced extraction pipe, unit furnace discharge mouth, the auger handling machinery, each vacuum tightness is installed in each unit body of heater at least surveys probe, temperature measurement probe and pressure survey probe, the unit body of heater is that the closed horizontal hollow is cylindric, its cross-sectional shape is an annular, the unit body of heater is wrapped with the outer micro-wave screening insulation construction layer of unit body of heater, opening for feed is positioned at unit body of heater one end top, unit furnace discharge mouth is positioned at body of heater the other end bottom, unit, microwave source is arranged in unit body of heater outer periphery and links to each other with microwave tube, microwave tube is arranged on the furnace body outer wall, advancing extraction pipe is communicated with unit body of heater inner chamber, be communicated with vacuum extractor and shielding gas input unit by the band valve pipe, auger handling machinery axis and unit body of heater axis are installed in parallel in the unit body of heater, its two ends link to each other with the drive unit that is located at the outer both ends of the surface of unit body of heater respectively, vacuum tightness is surveyed probe, temperature measurement probe and pressure survey probe are installed in inboard wall of furnace body top, unit, are connected with the equipment control circuit corresponding circuits by data line; The horizontal layout of three cover unit stove levels; discharge port directly is communicated with opening for feed successively between the unit stove; opening for feed is communicated with pretreatment unit stove opening for feed near vertical by the charging air-exchanging chamber; pretreatment unit furnace discharge mouth directly is communicated with the opening for feed of presintering unit stove; the discharge port of presintering unit stove directly is communicated with the opening for feed of sintering unit stove; the discharge port of sintering unit stove is communicated with cool discharging mechanism and discharge port by the discharging air-exchanging chamber; each unit stove; the charging air-exchanging chamber; vacuum extractor; the shielding gas input unit; the discharging air-exchanging chamber; the discharging mechanism that cools is connected with the equipment control circuit corresponding circuits by data line.

Microwave source links to each other with certain group of number microwave tube in described each unit stove, every group by the parallel connection of some amount microwave tube, microwave tube is evenly arranged on the unit furnace body outer wall, or be evenly arranged in around the unit body of heater, wherein pretreatment unit stove, presintering unit stove microwave source power are 10～15kw, and sintering unit stove microwave source power is 30～100kw; Each unit body of heater is provided with a vapor pipe at least, is drawn into gas tube orifice and exhaust pipe mouth is equipped with microporous filter; Described each unit body of heater material is the optional one of silica glass or pottery, and the auger handling machinery is that silica glass, steel construction surface lining stupalith or stainless steel are optional wherein a kind of; Unit furnace discharge mouth is provided with unit furnace discharge valve, and the bleeder valve valve plate is the arc that mates with the unit body of heater; Sintering unit body of heater length is pretreatment unit body of heater, presintering unit body of heater length 3～5 times.

Described charging air-exchanging chamber, comprise that hopper, feed valve, bleeder valve, vacuum tightness survey probe and at least one and advance extraction pipe, the hopper upper port is communicated with opening for feed, lower port is communicated with pretreatment unit stove opening for feed, hopper upper and lower end portion is provided with feed valve and bleeder valve respectively, advance the extraction pipe opening and be arranged on the hopper upper inside wall, be communicated with vacuum extractor by the band valve pipe, vacuum tightness is surveyed probe and is installed in the hopper upper inside wall; Described discharging air-exchanging chamber, comprise that hopper, bleeder valve, vacuum tightness survey probe and at least one and advance extraction pipe, the hopper upper port is communicated with sintering unit furnace discharge mouth, lower port is communicated with the discharging mechanism that cools, bleeder valve is located at the hopper bottom, advance the extraction pipe opening and be arranged on the hopper upper inside wall, be communicated with vacuum extractor by the band valve pipe, vacuum tightness is surveyed probe and is installed in the hopper upper inside wall.

The described discharging mechanism that cools, comprise Material pipeline, interlayer cover, water-in, water outlet, auger handling machinery, bleeder valve, Material pipeline is a stainless steel, and the interlayer cover is wrapped on the Material pipeline pipeline outer wall, and the one end is provided with water-in, the other end is provided with water outlet, the auger handling machinery is installed in material conveying pipe inside, and outer with being located at the outer both ends of the surface of the pipeline respectively auger handling machinery drive unit in its two ends links to each other, and bleeder valve is located at discharge port top.

Described equipment control circuit contains touch-screen, and touch-screen is communicated with pretreatment unit stove PLC pilot circuit, presintering unit stove PLC pilot circuit, sintering unit stove PLC pilot circuit, the charging ventilation/discharging discharging PLC pilot circuit of taking a breath/cool respectively by data bus; Described pretreatment unit stove PLC pilot circuit, presintering unit stove PLC pilot circuit, sintering unit stove PLC pilot circuit, contain unit stove PLC, PLC external circuits, unit stove signal acquisition circuit equally, auger drive control circuit, the microwave source pilot circuit, the air extractor pilot circuit; Described PLC external circuits, the manual switch that contains the some amount that links to each other with input terminus, the switch signal circuit of signal acquisition circuit, and the servo-driver that links to each other with output terminal, unit furnace discharge valve control ac contactor coil, shielding gas control ac contactor coil, venting control ac contactor coil, vacuum pump control ac contactor coil, microwave source control ac contactor coil and pilot lamp; Described unit stove signal acquisition circuit contains input terminus and links to each other with unit stove vacuum tightness probe, the vacuum meter that output terminal links to each other with unit stove PLC input terminus, input terminus links to each other with unit furnace temperature measuring sonde, the temperature controller that output terminal links to each other with unit stove PLC input terminus links to each other with unit furnace pressure power measuring sonde with input terminus, the pressure controller that output terminal links to each other with unit stove PLC input terminus; Described auger handling machinery drive unit driving circuit contains the servo-driver that an end links to each other with two-phase power supply, and servo-driver connects the output terminal of servomotor and unit stove PLC; Described microwave source pilot circuit, the microwave transformer that contains the some amount that links to each other with three-phase supply, hold the microwave tube circuit that links to each other with the microwave transformer, be in series with a contact of temperature control protection switch and multiple contact alternating current contactor on the former end input line of microwave transformer, the output terminal of the coil connector element stove PLC of alternating current contactor; Described air extractor pilot circuit contains the alternating current contactor that an end links to each other with three-phase supply, and the other end of alternating current contactor links to each other with the air extractor motor by isolating switch, the coil connector element stove PLC output terminal of alternating current contactor; Described touch-screen and pretreatment unit stove PLC pilot circuit, presintering unit stove PLC pilot circuit, sintering unit stove PLC pilot circuit, the charging ventilation/discharging discharging PLC pilot circuit of taking a breath/cool is communicated with by the RS422/485 bus.

The horizontal continuous production equipment of a kind of LiFePO 4 by microwaves heating inclination, comprise opening for feed, the charging air-exchanging chamber, the pretreatment unit stove, presintering unit stove, sintering unit stove, the discharging air-exchanging chamber, discharging mechanism cools, discharge port, vacuum extractor, shielding gas input unit and equipment control circuit, the pretreatment unit stove, presintering unit stove, sintering unit stove three cover unit stoves, contain unit stove opening for feed equally, the unit body of heater, the outer micro-wave screening insulation construction layer of unit body of heater, microwave source, a certain number of microwave tube, at least one is advanced extraction pipe, unit furnace discharge mouth, the auger handling machinery, each vacuum tightness is installed in each unit body of heater at least surveys probe, temperature measurement probe and pressure survey probe, the unit body of heater is a closed inclination hollow cylindrical, its axis normal cross-sectional shape is an annular, the unit body of heater is wrapped with the outer micro-wave screening insulation construction layer of unit body of heater, opening for feed is positioned at unit body of heater one end top, unit furnace discharge mouth is positioned at body of heater the other end bottom, unit, microwave source is arranged in unit body of heater outer periphery and links to each other with microwave tube, microwave tube is arranged on the furnace body outer wall, advancing extraction pipe is communicated with unit body of heater inner chamber, be communicated with vacuum extractor and shielding gas input unit by the band valve pipe, auger handling machinery axis and unit body of heater axis are installed in parallel in the unit body of heater, its two ends link to each other with the drive unit that is located at the outer both ends of the surface of unit body of heater respectively, vacuum tightness is surveyed probe, temperature measurement probe and pressure survey probe are installed in inboard wall of furnace body top, unit, are connected with the equipment control circuit corresponding circuits by data line; The parallel horizontal inclined layout of three cover unit stoves; the pitch angle is α; discharge port directly is communicated with opening for feed successively between the unit stove; opening for feed is communicated with pretreatment unit stove opening for feed near vertical by the charging air-exchanging chamber; pretreatment unit furnace discharge mouth directly is communicated with the opening for feed of presintering unit stove; the discharge port of presintering unit stove directly is communicated with the opening for feed of sintering unit stove; the discharge port of sintering unit stove is communicated with cool discharging mechanism and discharge port by the discharging air-exchanging chamber; each unit stove; the charging air-exchanging chamber; vacuum extractor; the shielding gas input unit; the discharging air-exchanging chamber; the discharging mechanism that cools is connected with the equipment control circuit corresponding circuits by data line.

Microwave source links to each other with certain group of number microwave tube in described each unit stove, every group by the parallel connection of some amount microwave tube, microwave tube is evenly arranged on the unit furnace body outer wall, or be evenly arranged in around the unit body of heater, wherein pretreatment unit stove, presintering unit stove microwave source power are 10～15kw, and sintering unit stove microwave source power is 30～100kw; Each unit body of heater is provided with a vapor pipe at least, is drawn into gas tube orifice and exhaust pipe mouth is equipped with microporous filter; Described each unit body of heater material is the optional one of silica glass or pottery, and the auger handling machinery is that silica glass, steel construction surface lining stupalith or stainless steel are optional wherein a kind of; Unit furnace discharge mouth is provided with unit furnace discharge valve, and the bleeder valve valve plate is the arc that mates with the unit body of heater; Sintering unit body of heater length is pretreatment unit body of heater, presintering unit body of heater length 3～5 times, and each unit stove parallel oblique arranges, unit body of heater axis downwards and the horizontal direction angle be inclined angle alpha, 0 °＜α≤30 °.

The beneficial effects of the utility model are:

1, the conventional sintering method of iron lithium phosphate mainly is an electrical heating method, and this method is utilized heat-conduction principle, begins heating from the outside and is transmitted to inside again, and heat transfer rate is slow, and production efficiency low frit yield rate is low.Use microwave sintering iron lithium phosphate (LiFePO ₄) shortened sintering time greatly, have only about 20% of traditional method, reduced sintering energy consumption, economize on electricity is more than 80%, and production cost significantly reduces.The utility model microwave sintering can promote the inner crystal grain densification of product, particle is tiny, size distribution is more even, improves product quality effectively, and the finished product have the superior characteristics of purity height, Stability Analysis of Structures, good cycle, conductivity and discharge performance.

2, microwave sintering apparatus of the present utility model is thermal source with the microwave, combine the advantage of conventional sintering stove, vacuum sintering furnace and microwave agglomerating furnace, divide 3 unit stoves to handle stage by stage, sintering process is carried out the substep sequential control, fully realize processing requirement, guaranteed product quality.A plurality of unit stove is set has improved sintering efficient effectively, between a plurality of unit stove material conveying device is set, a plurality of unit stove is connected into an integral body, thereby realize continuous production, industrialization scale operation becomes possibility.Under the effect of auger handling machinery, material stir to move along the unit furnace body wall, and material is heated evenly, and has accelerated the sintering of material, has guaranteed the homogeneity and the continuity of inlet amount, input speed.Calculated by 3 hours whole sintering process time, but discharging every day 600kg at least compare with common monomer industrial microwave oven sintering process, production efficiency has improved more than 3 times, economize on electricity is more than 60%, yield rate was brought up to more than 90% by 80% of the past.Improved more than 5 times than the production efficiency of traditional sintering oven about 20 hours, economize on electricity is more than 80%, and commercial scale production efficient and economic benefit are considerable.

3, microwave sintering makes the product self-heating, has reduced the waste of energy to greatest extent, has improved Working environment; Charging, sintering, discharging are carried out continuously, do not need manually repeatedly to load and unload material, the production efficiency height, and do not have dust from flying, and health environment-friendly does not have " three wastes " and produces, and clean production realized the hommization Working environment.

4, being provided with one group of inlet mouth around each unit body of heater at least feeds in the unit body of heater; input top is provided with one group of venting port at least; be provided with microporous filter on the gas port like this; both be convenient to input, got rid of protection or reaction atmosphere; prevented that dust from raising outward, shielded microwave leakage effectively.

5, device control of the present utility model adopts touch-screen and many PLC centralized Control, realize the plant continuous production of step of multiplex (MUX), improved the level of automation and the craft precision of entire equipment, guaranteed the quality of product, realize industrial large-scale production, improved production efficiency.

6, touch-screen, PLC centralized Control, man-machine interactive operation is intuitively easy, and equipment debugging is safeguarded simple, and it is convenient to regulate processing parameter, reliable working performance.

Four, description of drawings:

Fig. 1 heats horizontal continuous production device structure synoptic diagram for LiFePO 4 by microwaves of the present utility model;

Fig. 2 heats horizontal continuous production equipment charging air-exchanging chamber structural representation for LiFePO 4 by microwaves of the present utility model;

Fig. 3 heats horizontal continuous production equipment pretreatment unit furnace structure synoptic diagram for LiFePO 4 by microwaves of the present utility model;

Fig. 4 heats horizontal continuous production equipment presintering unit furnace structure synoptic diagram for LiFePO 4 by microwaves of the present utility model;

Fig. 5 heats horizontal continuous production equipment sintering unit furnace structure synoptic diagram for LiFePO 4 by microwaves of the present utility model;

Fig. 6 heats horizontal continuous production equipment discharging air-exchanging chamber structural representation for LiFePO 4 by microwaves of the present utility model;

Fig. 7 heats horizontal continuous production apparatus cools cooling discharge mechanism structure synoptic diagram for LiFePO 4 by microwaves of the present utility model;

Fig. 8 heats the equipment control circuit schematic block diagram of horizontal continuous production equipment for LiFePO 4 by microwaves of the present utility model;

Fig. 9 heats the unit stove pilot circuit PLC wiring circuit diagram of horizontal continuous production equipment for LiFePO 4 by microwaves of the present utility model;

Figure 10 heats the unit stove pilot circuit synoptic diagram of horizontal continuous production equipment for LiFePO 4 by microwaves of the present utility model;

Figure 11 is the horizontal continuous production device structure synoptic diagram of LiFePO 4 by microwaves heating inclination of the present utility model.

Among the figure, 1-opening for feed, 2-charging air-exchanging chamber; 3-pretreatment unit stove; 4-material transmission path, 5-presintering unit stove, 6-sintering unit stove; 7-discharging air-exchanging chamber; the 8-discharging mechanism that cools, 9-discharge port, 10-vacuum extractor; 11-shielding gas input unit; 12-charging/bleeder valve, 13-vacuum tightness is surveyed probe, and 14-advances extraction pipe; 15-charging air-exchanging chamber hopper; 16-unit stove opening for feed, the outer micro-wave screening insulation construction layer of 17-unit body of heater, 18-unit body of heater; the 19-microwave source; the 20-microwave tube, 21-unit furnace discharge mouth, 22-unit furnace discharge valve; 23-auger handling machinery; the 24-temperature measurement probe, 25-pressure survey probe, 26-vapor pipe; 27-auger handling machinery drive unit; 28-discharging air-exchanging chamber hopper, 29-interlayer cover, 30-Material pipeline; the 31-water outlet; the 32-water-in, 33-pretreatment unit stove PLC pilot circuit, 34-presintering unit stove PLC pilot circuit; 35-sintering unit stove PLC pilot circuit; the 36-charging ventilation/discharging discharging PLC pilot circuit of taking a breath/cool, 37-unit stove signal acquisition circuit, 38-auger handling machinery drive unit driving circuit; 39-microwave source pilot circuit, 40-air extractor pilot circuit.

Five, embodiment:

Embodiment one: a kind of LiFePO 4 by microwaves heats horizontal continuous production equipment, referring to Fig. 1-Figure 10, comprise opening for feed 1, charging air-exchanging chamber 2, pretreatment unit stove 3, presintering unit stove 5, sintering unit stove 6, discharging air-exchanging chamber 7, discharging mechanism 8 cools, discharge port 9, vacuum extractor 10, shielding gas input unit 11 and equipment control circuit, pretreatment unit stove 5, presintering unit stove 6, sintering unit stove 7 three cover unit stoves, contain unit stove opening for feed 16 equally, the outer micro-wave screening insulation construction layer 17 of unit body of heater, unit body of heater 18, microwave source 19, number microwave tube 20, advance extraction pipe 14, unit furnace discharge mouth 21, auger handling machinery 23, each vacuum tightness is installed in each unit body of heater surveys probe 13, temperature measurement probe 24 and pressure survey probe 25, unit body of heater 19 is that the closed horizontal hollow is cylindric, its cross-sectional shape is an annular, unit body of heater 18 is wrapped with the outer micro-wave screening insulation construction layer 17 of unit body of heater, opening for feed 16 is positioned at unit body of heater one end top, unit furnace discharge mouth 21 is positioned at body of heater the other end bottom, unit, unit furnace discharge mouth 21 is provided with bleeder valve 22, microwave source 19 is arranged in unit body of heater outer periphery and links to each other with microwave tube 20, microwave tube 20 is arranged on the furnace body outer wall, advancing extraction pipe 14 is communicated with unit body of heater 19 inner chambers, be communicated with vacuum extractor 10 and shielding gas input unit 11 by the band valve pipe, auger handling machinery 23 axis and unit body of heater 19 axis are installed in parallel in the unit body of heater, its two ends link to each other with the drive unit 27 that is located at the outer both ends of the surface of unit body of heater respectively, vacuum tightness is surveyed probe 13, temperature measurement probe 24 and pressure survey probe 25 are installed in unit body of heater 19 inwall tops, are connected with the equipment control circuit corresponding circuits by data line; The horizontal layout of three cover unit stove levels; discharge port directly is communicated with opening for feed successively between the unit stove; opening for feed 1 is communicated with pretreatment unit stove 3 opening for feeds 16 near verticals by the charging air-exchanging chamber; pretreatment unit stove 3 discharge ports 21 directly are communicated with the opening for feed 16 of presintering unit stove 5; the discharge port 21 of presintering unit stove 5 directly is communicated with the opening for feed 16 of sintering unit stove 6; the discharge port 21 of sintering unit stove 6 is communicated with cool discharging mechanism 8 and discharge port 9 by discharging air-exchanging chamber 7; unit stove 3; 5; 6; charging air-exchanging chamber 2; vacuum extractor 10; shielding gas input unit 11; discharging air-exchanging chamber 7; the discharging mechanism 8 that cools is connected with the equipment control circuit corresponding circuits by data line.

Wherein, microwave source 19 links to each other with 6 groups of microwave tubes in each unit stove, every group of 3 microwave tube parallel connections, and microwave tube 20 is evenly arranged on unit body of heater 18 walls, wherein pretreatment unit stove 3, presintering unit stove 5 microwave source power are 15kw, and stove 6 microwave source power in sintering unit are 100kw; Each unit body of heater 18 is provided with a vapor pipe 26, is drawn into 14 mouthfuls of tracheaes and vapor pipe and is equipped with microporous filter for 26 mouthfuls; Each unit body of heater 18 material is a silica glass, and auger handling machinery 23 is a silica glass; Unit furnace discharge mouth 21 is provided with unit furnace discharge valve 22, and the bleeder valve valve plate is the arc that mates with the unit body of heater; Stove 6 unit body of heater length in sintering unit are pretreatment unit stove, presintering unit body of heater length 4 times.

Charging air-exchanging chamber 2, comprise hopper 15, feed valve 12, bleeder valve 12, vacuum tightness detection probe 13 and advance extraction pipe 14, hopper 15 upper port are communicated with opening for feed 1, lower port is communicated with pretreatment unit stove opening for feed 16, hopper 15 upper and lower end portions are provided with feed valve 12 and bleeder valve 12 respectively, advance extraction pipe 14 openings and be arranged on hopper 15 upper inside wall, be communicated with vacuum extractor 10 by the band valve pipe, vacuum tightness is surveyed probe 13 and is installed in the hopper upper inside wall.

Discharging air-exchanging chamber 7, comprise hopper 28, bleeder valve 12, vacuum tightness detection probe 13 and advance extraction pipe 14, the hopper upper port is communicated with sintering unit furnace discharge mouth 21, lower port is communicated with the discharging mechanism 9 that cools, bleeder valve 12 is located at hopper 28 bottoms, advance extraction pipe 14 openings and be arranged on hopper 28 upper inside wall, be communicated with vacuum extractor 10 by the band valve pipe, vacuum tightness is surveyed probe 13 and is installed in hopper 28 upper inside wall.

Discharging mechanism 8 cools, comprise interlayer cover 29, Material pipeline 30, water-in 33, water outlet 31, auger handling machinery 23, bleeder valve 12, Material pipeline 30 is a stainless steel, interlayer cover 29 is wrapped on material conveying pipe 30 outer walls, the one end is provided with water-in 32, the other end is provided with water outlet 31, auger handling machinery 23 is installed in material conveying pipe 30 inside, outer with the being located at the pipe ends face respectively auger handling machinery drive unit 27 in its two ends links to each other, and bleeder valve 12 is located at discharge port 9 tops.

Equipment control circuit contains touch-screen, and touch-screen is communicated with 36 with pretreatment unit stove PLC pilot circuit 33, presintering unit stove PLC pilot circuit 34, sintering unit stove PLC pilot circuit 35, the charging ventilation/discharging discharging PLC pilot circuit of taking a breath/cool respectively by data bus RS422/485; Pretreatment unit stove PLC pilot circuit 33, presintering unit stove PLC pilot circuit 34, sintering unit stove PLC pilot circuit 35, contain unit stove PLC, PLC external circuits, unit stove signal acquisition circuit 37 equally, auger drive control circuit 38, microwave source pilot circuit 39, air extractor pilot circuit 40; The PLC external circuits, contain the manual switch B2-B11 that links to each other with input terminus, the switch signal circuit of signal acquisition circuit 37, and the servo-driver that links to each other with output terminal, unit furnace discharge valve control ac contactor coil KF1, shielding gas control ac contactor coil KF2, venting control ac contactor coil KF3, vacuum extractor control ac contactor coil KM1, microwave source control ac contactor coil KA1-KA18 and pilot lamp L3-L14; Unit stove signal acquisition circuit 37 contains input terminus and links to each other with unit stove vacuum tightness probe 13, the vacuum meter that output terminal links to each other with unit stove PLC input terminus, input terminus links to each other with unit furnace temperature measuring sonde 24, the temperature controller that output terminal links to each other with unit stove PLC input terminus links to each other with unit furnace pressure power measuring sonde 25 with input terminus, the pressure controller that output terminal links to each other with unit stove PLC input terminus; Auger handling machinery drive unit driving circuit 38 contains the servo-driver that an end links to each other with two-phase power supply, and servo-driver connects the output terminal of servomotor SM1 and unit stove PLC; Microwave source pilot circuit 39, contain 18 microwave transformer T1-T18 that link to each other with three-phase supply, hold the microwave tube circuit that links to each other with the microwave transformer, be in series with a contact of temperature control protection switch DZ2-DZ19 and three contact alternating current contactors on the former end input line of microwave transformer, be respectively KA1-KA18, the output terminal of the coil connector element stove PLC of alternating current contactor; Air extractor pilot circuit 40 contains the alternating current contactor KM1 that an end links to each other with three-phase supply, and the other end of alternating current contactor links to each other the coil connector element stove PLC output terminal of alternating current contactor KM1 by isolating switch DZ20 with air extractor motor M 1.

It is thermal source with the microwave that LiFePO 4 by microwaves of the present utility model heats horizontal continuous production equipment, from iron lithium phosphate (LiFePO ₄) sintering process set out, combine the advantage of conventional sintering stove, vacuum sintering furnace and microwave agglomerating furnace, realize pre-treatment, presintering and three technical process of sintering, whole agglomerating plant is divided into 3 unit stoves, each unit stove is finished a technical process, directly is communicated with by discharge port, opening for feed between the unit stove, a plurality of unit stove is connected into an integral body realize continuous production, can raise the efficiency like this, promote output.As Fig. 1, Fig. 3-shown in Figure 5, three unit furnace bodies 18 are airtight round shape, and the body of heater material is a silica glass, the about 250mm of furnace diameter, pretreatment unit stove 3 and the about 4m of presintering unit stove 5 length, sintering unit stove 6 length are about 16m, and silica glass tubular structure more becomes simply than thorax structure in the stainless steel of traditional microwave sintering oven, and the whole stopping property of body of heater is better, microwave source is evenly distributed on furnace body outer wall, the microwave penetrating body of heater adds thermal material, can reduce lossy microwave, improves heating efficiency.Body of heater outer micro-wave screening insulation construction layer 17 in unit is a multilayered structure, and what internal layer and body of heater 18 were complementary is microwave shielding layer, adopts stainless material processing, and micro-wave screening is effective, can prevent microwave leakage; Screen layer is outward the thermal insulation layer by the lagging material parcel, reduces the loss of heat.The unit stove reaches non-oxide atmosphere; need be to vacuumizing in the stove and input protection gas; each unit stove is provided with into, and extraction pipe 14 is communicated with unit body of heater inner chamber; be communicated with vacuum extractor 10 and shielding gas input unit 11 by the band valve pipe; valve is a gas solenoid valve; before being installed in vacuum extractor and shielding gas input unit respectively, the switch signal control of the opening of gas solenoid valve, closed output circuit output by each unit stove PLC.The transmission of sintered material generally realizes by push pedal, travelling belt in the conventional sintering stove, but this mode often causes whole furnace sealing degradation, complex structure, the cost costliness, the shielding gas loss is bigger in the production process, the unsteady problem of quality product, mass transport in the utility model in the stove, realize by the auger handling machinery 23 that is located in the stove, mass transport between the unit stove, by the material self gravitation, enter in the next body of heater by bleeder valve 22 controls by approximately perpendicular material transmission path; Auger handling machinery 23 and the parallel installation of body of heater axis in the unit stove, its screw-blade lower edge and bottom of furnace body inwall are adjoint, material under screw-blade promotes constantly upset end in the stove move to the other end, outer with the being located at the unit body of heater respectively drive unit 27 in auger handling machinery two ends links to each other, drive unit 27 is the servomotor of unit stove PLC control, also can use motor, variator, speed regulation device to realize, by servomotor is controlled, the auger handling machinery keeps 0.5-1 rev/min rotating speed, and material is steadily moved at a slow speed in body of heater; Auger handling machinery 23 is a silica glass for material, and the microwave penetrating rate is good, and loss is little; Each stove inwall top, unit is provided with vacuum tightness and surveys probe 13, temperature measurement probe 24 and pressure survey probe 25, and vacuum tightness signal, temperature signal, pressure signal that probe is gathered link by signal acquisition circuit 37 and unit stove PLC input terminus; Each unit body of heater is provided with a vapor pipe 26, and vapor pipe one end is equipped with exhaust solenoid valve, by unit stove PLC control, is drawn into gas tube orifice with exhaust pipe mouth is provided with microporous filter, reduces the pollution in the production; Discharge port 21 in each unit stove is provided with unit furnace discharge valve 22, the transmission and the process of control material, do not establish the material transmission path between each unit stove, directly be communicated with, bleeder valve 22 is electronic push-pull valve, the arc that valve plate is and the unit body of heater mates, sintering unit stove 6 bleeder valves are communicated with the electronic push-pull valve of discharging air-exchanging chamber 7 optional usefulness, electrical ball valve, electric butterfly valve, electronic bleeder valve, and the opening and closing of unit furnace discharge valve 22 are by the switch signal control of unit stove PLC output.

Each unit stove microwave source 19 adopts 6 groups of microwave tubes to link to each other, the structure of every group of 3 microwave tube parallel connections, microwave tube can adopt the industrial magnetron of 0.8kw/2450MHz, this many group microwave tube power synthesis modes, guarantee that microwave heating is even in the stove, Heating temperature, power control are accurately; Whole microwave source is provided with temperature protective device, can the long-time continuous stable reliable operation.

Charging air-exchanging chamber 2, discharging air-exchanging chamber 7 guarantee in the equipment continuous flow procedure, can not destroy the non-oxygen environment in the unit stove when dropping into raw material, product discharging, realize continuous production.As Fig. 2, shown in Figure 6, charging air-exchanging chamber 2 is provided with hopper 15, feed valve 12,

bleeder valve

12,13 and one of vacuum tightness probes advance extraction pipe 14, airtight hopper inner chamber adopts stainless steel processing, cross-sectional shape is square, also can do circular as required or rectangle, feed valve 12 is established in hopper 15 upper ends, and bleeder valve 12 is established in the bottom, and feed valve, bleeder valve are the driven plate valve, also can select electronic push-pull valve, electrical ball valve, electric butterfly valve, electronic bleeder valve for use, the opening and closing of material valve are by the switch signal control of PLC output; Vacuum tightness probe 13, principle of work and each unit stove identical of advancing extraction pipe 14, effect is under the hopper closed state, the non-oxygen environment of vacuumize, the formation of input protection gas is consistent with the unit stove.The structure and the working process of the structure of discharging air-exchanging chamber 7 and charging air-exchanging chamber are basic identical, owing to link to each other with the bleeder valve of sintering unit stove, the discharging air-exchanging chamber is not established feed valve.

The discharging mechanism 8 that cools can make the finished product fast cooling after finishing last sintering process flow process, guarantee continuous production.As shown in Figure 7, the discharging mechanism that cools adopts water-cooling pattern, mass transport is used the auger handling machinery, and Material pipeline 30 is a stainless steel, and length is 6m, interlayer cover 29 is wrapped on Material pipeline 30 outer walls, the one end is provided with water-in 32, and the other end is provided with water outlet 31, sets the flow 80L/min of water, water inlet control is controlled by the electromagnetism water valve that is located at the water inlet, and the opening and closing of electromagnetism water valve are by the switch signal control of PLC output; Auger handling machinery drive unit 27 is the servomotor of PLC control, also can use motor, variator, speed regulation device to realize; Bleeder valve 12 is the driven plate valve, also can select electronic push-pull valve, electrical ball valve, electric butterfly valve, electronic bleeder valve for use, and the opening and closing of material valve are by the switch signal control of PLC output.

Equipment control circuit adopts the circuit structure of the many PLC of touch-screen centralized Control, realizes the automatic control of entire equipment.As shown in Figure 8, wherein touch-screen is a MT500 type touch-screen, touch-screen is communicated with pretreatment unit stove PLC pilot circuit 33, presintering unit stove PLC pilot circuit 34, sintering unit stove PLC pilot circuit 35, the charging ventilation/discharging discharging PLC pilot circuit 36 of taking a breath/cool respectively by the RS422/485 data bus, the process parameter of equipment, processing parameter setting, sequence of control, the programming of PLC all can be undertaken by the man-machine interface of touch-screen.PLC adopts Delta DVP40ES200RT type PLC, its input, output point number average are 24 points, pretreatment unit stove PLC pilot circuit, presintering unit stove PLC pilot circuit, sintering unit stove PLC pilot circuit, circuit structure and function are basic identical, contain unit stove PLC, PLC external circuits, unit stove signal acquisition circuit 37 equally, auger drive control circuit 38, microwave source pilot circuit 39, air extractor pilot circuit 40.

As shown in Figure 9, unit 24 input points of stove PLC input terminus are connected with ten manual switches of B2-B11, S3, and S5-S10 connects the switch signal of signal acquisition circuit.B2 connects PLC input terminus X0, be air extractor control manual switch, B3 connects X1, is the exhaust solenoid valve manual switch, B4 connects X2, be microwave group 1 manual switch, B5 connects X3, is microwave group 2 manual switches, B6 connects X4, be microwave group 3 manual switches, B7 connects X5, is microwave group 4 manual switches, B8 connects X6, be microwave group 5 manual switches, B9 connects X7, is microwave group 6 manual switches, B10 connects X17, be auger handling machinery drive unit manual switch, B11 connects X18, is unit furnace discharge valve manual switch; It is when equipment emerged in operation abnormal conditions that manual switch is set, and manually stops or using when starting relevant device.S3 connects PLC input terminus X10, is temperature switch, and S5, S6 connect X11, X12, be the temperature controller output switching signal, S7, S8 connect X13, X14, are the vacuum meter output switching signal, S9, S10 connect X15, X16, are the pressure controller output switching signal.Y0-Y18 in 24 input points of PLC output terminal, wherein Y0-Y3 connects servo-driver, Y4 connector element furnace discharge valve control ac contactor coil KF1, KF1 is parallel with pilot lamp L3; Y5 connects shielding gas control ac contactor coil KF2, i.e. electromagnetic gas valve coil, and KF2 is parallel with pilot lamp L4; Y6 connects venting control ac contactor coil KF3, i.e. electromagnetic gas valve coil, and KF3 is parallel with pilot lamp L5; Y7 connects vacuum pump control ac contactor coil KM1; Y10-Y12 connects temperature indicator L6 respectively, vacuum tightness pilot lamp L7, pressure indicator light L8; Y13-Y18 connects six microwave group control ac contactor coil KA1-3 respectively, KA4-6, and KA7-9, KA10-12, KA13-15, it is L9-L14 that KA16-18 and each coils from parallel connection of coils have pilot lamp.

Unit stove signal acquisition circuit 37, as shown in figure 10, containing input terminus links to each other with unit stove vacuum tightness probe, the vacuum meter that output terminal links to each other with unit stove PLC input terminus, the vacuum tightness probe signal enters vacuum meter, compare with the vacuum tightness higher limit of setting, lower value, reach in limited time, switch signal of vacuum meter upper limit output terminal output enters the X13 input terminus of PLC; Reach down in limited time, switch signal of vacuum meter lower limit output terminal output enters the X14 input terminus of PLC; The working process of temperature controller, pressure controller is the same with vacuum meter, temperature controller upper limit output terminal, lower limit output terminal connect X11, the X12 input terminus of PLC respectively, and pressure controller upper limit output terminal, lower limit output terminal connect X11, the X12 input terminus of PLC respectively.

Auger handling machinery drive unit driving circuit 38, contain the servo-driver that an end links to each other with two-phase power supply as shown in figure 10, its control signal input terminus links to each other with unit stove PLC output terminal X0-X3, servo-driver connects servomotor SM1, servomotor is as the drive unit of unit stove auger handling machinery, and control accuracy height, equipment connect simply, technology maturation, good reliability; Isolating switch DZ21 provide overcurrent protection.

Microwave source pilot circuit 39; as shown in figure 10; contain 18 microwave transformer T1-T18 that link to each other with three-phase supply; hold the microwave tube circuit that links to each other with the microwave transformer; each microwave tube circuit contains a microwave tube G1-G18; be in series with a contact of temperature control protection switch and three alternating current contactors on the former end input line of each microwave transformer; three contacts are one group; by one three contact alternating current contactor control; 18 microwave tubes have 6 groups altogether for 3 one group, and the ac contactor contact adhesive is controlled by PLC, by controlling the adhesive of corresponding alternating current contactor; start one group of corresponding three microwave tube, different microwave tube combinations realizes that power is synthetic.The temperature controlled switch effect is to surpass in limited time in the microwave tube working temperature, breaking circuits, and the protection microwave tube can not burn out.

Air extractor pilot circuit 40; as shown in figure 10; contain the alternating current contactor KM1 that an end links to each other with three-phase supply; the other end of alternating current contactor links to each other with air extractor motor M 1 by isolating switch DZ20; the coil connector element stove PLC output terminal of alternating current contactor KM1; the motor M of bleeding 1 is three-phase machine, and M1 starts the control signal control by PLC output, and isolating switch DZ20 provides overcurrent protection for motor M 1.

Charging ventilation/discharging discharging PLC the pilot circuit 36 of taking a breath/cool; the control of the charging/bleeder valve that relates to, vacuum tightness signals collecting, vacuumize, structure, the principle of work of interlock circuit is basic identical in process control such as the driving of the control of input protection gas, current, auger handling machinery and the unit stove, no longer draw to illustrate and repeat.

In the actual production, it at first is 200810237321.8 patent application according to the utility model people application number, " preparation method of ferric lithium phosphate precursor and charging battery electrode thereof ", prepare ferric lithium phosphate precursor, per hour pressing, 50 kilograms speed adds in the feed appliance, add the 25KG ferric lithium phosphate precursor, be numbered material A, drop into LiFePO 4 by microwaves of the present utility model and heat horizontal continuous production equipment opening for feed 1, each unit stove under the equipment original state, air-exchanging chamber charging/discharging valve plate all is in the closing seam state, at first equipment control circuit is opened charging air-exchanging chamber feed valve 12, the presoma material A enters hopper 15, the closure of feed valve 12 then, open the preceding electromagnetic gas valve of pump, and formation vacuumizes path and starts vacuum extractor 10 by being drawn into gas port 14, the charging air-exchanging chamber is vacuumized, the data that detect according to vacuum tightness detecting head in the charging air-exchanging chamber 13 determine to reach set vacuum tightness after, stop to bleed, finish fill process.Then pre-treatment stove 3 unit bodies of heater 18 are vacuumized; after vacuum tightness detection probe 13 detects and reaches set(ting)value; open charging air-exchanging chamber bleeder valve 12; the presoma material falls into pre-treatment stove 3 unit bodies of heater 18 through unit stove opening for feed 16; after material all enters the pretreatment unit stove; close charging air-exchanging chamber bleeder valve; open the preposition electromagnetic gas valve of shielding gas input unit; enter the unit body of heater 18 that vacuumizes by being drawn into tracheae 14 input nitrogen; after body of heater internal pressure measuring sonde 25 take off data determining unit body of heater internal pressures in unit reach normal pressure; close preposition electromagnetic gas valve and stop gas transmission; start microwave source 19; start 6 groups of microwave tubes that are located at body of heater outside, unit by equipment control circuit; setting the heating total power is 12kw; material is heated; reach 90 ℃ of temperature; start the auger handling machinery; by drive unit servomotor control auger handling machinery rotating speed is that per minute 1 changes; material steadily moves to the body of heater the other end under packing auger blade promotes, and whole materials arrive furnace discharge mouth place, unit after 30 minutes.Carry out getting the 25KG ferric lithium phosphate precursor again in the pretreatment technology process in material A, be numbered material B, drop into the agglomerating plant opening for feed, enter charging air-exchanging chamber hopper, the sealing air-exchanging chamber vacuumizes air-exchanging chamber, and material B is pending in charging air-exchanging chamber hopper.

The material A pretreatment technology later stage, to presintering unit stove evacuation, reach set(ting)value after, in presintering unit body of heater, import nitrogen by the shielding gas input unit, reach normal pressure.Material A is finished pretreatment technology, material to unit furnace discharge mouth end is concentrated, open unit furnace discharge valve 22, material is under the self gravitation effect, fall into the pre-burning freezing of a furnace, the auger handling machinery of pretreatment unit stove improves rotating speed, leftover materials is pushed discharge port fall in the pre-burning freezing of a furnace, pretreatment unit furnace discharge valve closure.After material enters the pre-burning freezing of a furnace, start microwave source 19, start 6 groups of microwave tubes that are located at body of heater outside, unit by equipment control circuit, setting the heating total power is 12kw, and material is heated, and reaches 230 ℃ of temperature, start the auger handling machinery, drive unit servomotor control auger handling machinery rotating speed is that per minute 1 changes, and material steadily moves to the body of heater the other end under packing auger blade promotes, and whole materials arrive furnace discharge mouth place, unit after 30 minutes.

After material A entered the pre-burning freezing of a furnace fully, after the bleeder valve closure of pretreatment unit stove, the material B in the charging air-exchanging chamber hopper entered the pretreatment technology that the pretreatment unit stove carries out, and all have material in pretreatment unit stove and the presintering unit stove this moment.Carry out getting the 25KG ferric lithium phosphate precursor again in the pretreatment technology process at material B, be numbered material C, drop into the agglomerating plant opening for feed, enter charging air-exchanging chamber hopper, the sealing air-exchanging chamber vacuumizes air-exchanging chamber, and material C is pending in charging air-exchanging chamber hopper.

In the material A pre-sintering process later stage, equipment control circuit starts vacuum extractor to sintering unit stove evacuation, reach set(ting)value after, the shielding gas input unit is imported nitrogen in presintering unit body of heater, reach normal pressure.Material A is finished pre-sintering process, material to unit furnace discharge mouth end is concentrated, open unit furnace discharge valve 22, material is under the self gravitation effect, fall in the stove by sintering unit stove opening for feed, the auger handling machinery of presintering unit stove improves rotating speed, leftover materials is pushed discharge port fall in the sintering oven, presintering unit furnace discharge valve closure.After material enters the pre-burning freezing of a furnace, start microwave source 19, start 6 groups of microwave tubes that are located at body of heater outside, unit by equipment control circuit, setting the heating total power is 30kw, material is heated, reach 550 ℃ of temperature, start the auger handling machinery, drive unit servomotor control auger handling machinery rotating speed is that per minute 1 changes, and material steadily moves to the body of heater the other end under packing auger blade promotes, and sintering oven length is 16m, be the pre-treatment stove, 4 times of presintering furnace length, under the identical situation of auger handling machinery rotating speed, material end in the stove reaches the other end needs the above two 4 times of times, after promptly 120 minutes all materials arrive furnace discharge mouth place, unit.In the material A sintering process, material B carries out pre-sintering process in the pre-burning freezing of a furnace handles, and material C carries out pretreatment technology in the pretreatment unit stove handles, and gets the 25KG ferric lithium phosphate precursor again, is numbered material D, enters in the charging air-exchanging chamber hopper pending.After material B, C finished treatment process, equipment control circuit was closed the microwave heating and the auger handling machinery of pretreatment unit stove and presintering unit stove, and wait material A sintering processes technology is finished.

In the material A sintering process later stage, equipment control circuit starts vacuum extractor the discharging air-exchanging chamber is vacuumized, and stops after reaching set(ting)value.After material A is finished sintering, material to unit furnace discharge mouth end is concentrated, open unit furnace discharge valve 22, material is under the self gravitation effect, fall into the discharging air-exchanging chamber, the auger handling machinery of sintering unit stove improves rotating speed, leftover materials is pushed discharge port fall into the discharging air-exchanging chamber, sintering unit furnace discharge valve closure.After discharging is finished, sintering unit furnace discharge valve closure, the bleeder valve of pre-burning freezing of a furnace unit stove is opened, unit stove auger handling machinery is sent unit furnace discharge mouth with material B and is entered in the sintering oven by the material transmission path, close presintering unit furnace discharge valve, material B carries out sintering process in sintering oven handles.After the presintering bleeder valve cuts out, material C in the pretreatment unit stove enters in the presintering unit stove through the material transmission path, carry out presintering, material D in the charging air-exchanging chamber is after the bleeder valve of pretreatment unit stove cuts out, enter and carry out pretreatment technology in the pretreatment unit stove, get the 25KG ferric lithium phosphate precursor again, be numbered material E, enter in the charging air-exchanging chamber hopper pending.

Material A enters the hopper of discharging air-exchanging chamber, after sintering unit furnace discharge valve closure, equipment control circuit is opened the bleeder valve of discharging air-exchanging chamber, material falls in the Material pipeline 31 of the mechanism 8 that cools in the self gravitation effect, after material A enters transfer lime fully, the bleeder valve of closed discharging air-exchanging chamber 7.The auger handling machinery pushes material and moves to discharge port end, quickens heat exchange with tube wall, and transfer lime is provided with the interlayer cover outward, the flow velocity of opening electromagnetism water valve water coolant 80L/min enters the interlayer cover by water-in, flow out from water outlet, take away the heat of transfer lime tube wall, shorten cooling the time.Material is transferred device and pushes to discharge port end after for some time, pilot circuit cuts out the electromagnetism water valve and stops water coolant, open bleeder valve and improve auger handling machinery rotating speed, push the iron lithium phosphate the finished product and enter the product storeroom from discharge port 9, material A is finished whole sintering processes.Pretreatment unit stove, presintering unit stove, sintering unit stove all have material to handle at this moment, and whole microwave sintering apparatus enters the continuous production state, and recirculation is carried out above each technical process, realizes the heavy industrialization continuous production.

LiFePO 4 by microwaves of the present utility model heats horizontal continuous production equipment a plurality of unit stove is set, can improve sintering efficient effectively, realize continuous production, carry out industrialization scale operation, calculated by 3 hours whole sintering process time, 600kg at least can manufacture a finished product every day, compare with common monomer industrial microwave oven sintering process, production efficiency has improved more than 3 times, and economize on electricity is more than 60%, and yield rate was brought up to more than 90% by 80% of the past.Improved more than 5 times than the production efficiency of traditional sintering oven about 20 hours, economize on electricity is more than 80%, and commercial scale production efficient and economic benefit are considerable.

Embodiment two: a kind of LiFePO 4 by microwaves heats horizontal continuous production equipment, basic identical with embodiment one, description of drawings no longer, content is identical, something in common no longer repeats, difference is that pretreatment unit stove 3, presintering unit stove 5 discharge ports 21 places do not establish bleeder valve, need vacuumize three unit stoves while integral body when material enters the unit stove in the production and charge into shielding gas; Each unit body of heater material is a stupalith, and auger handling machinery material is a steel construction surface lining stupalith in each unit stove; Microwave source links to each other with 5 groups of microwave tubes in each unit stove, and every group by 3 microwave tube parallel connections; Sintering unit body of heater length is pretreatment unit body of heater, presintering unit body of heater length 3 times.

Embodiment three: a kind of LiFePO 4 by microwaves heats horizontal continuous production equipment, and is basic identical with embodiment one, description of drawings no longer, and content is identical, and something in common no longer repeats, and difference is that auger handling machinery material is a stainless material in each unit stove; Microwave source links to each other with 8 groups of microwave tubes in each unit stove, and every group by 3 microwave tube parallel connections; Sintering unit body of heater length is pretreatment unit body of heater, presintering unit body of heater length 5 times.

Embodiment four: a kind of LiFePO 4 by microwaves heating horizontal continuous production equipment that tilts, referring to Figure 11, to number identically with embodiment one, and the content something in common no longer repeats.Difference is pretreatment unit stove 3, presintering unit stove 5 and sintering unit stove 6, and each unit body of heater is a closed inclination hollow cylindrical, and its axis normal cross-sectional shape is an annular, and each unit tilting furnace arranges that the pitch angle is α, α=8 °.

Embodiment five: a kind of LiFePO 4 by microwaves heats horizontal continuous production equipment, basic identical with embodiment four, description of drawings no longer, content is identical, something in common no longer repeats, and difference is that pretreatment unit stove 3, presintering unit stove 5 discharge port places do not establish bleeder valve; Each unit body of heater material is a stupalith, and auger handling machinery material is a steel construction surface lining stupalith in each unit stove; Microwave source links to each other with 5 groups of microwave tubes in each unit stove, and every group by 3 microwave tube parallel connections; Sintering unit body of heater length is pretreatment unit body of heater, presintering unit body of heater length 3 times.

Embodiment six: a kind of LiFePO 4 by microwaves heating horizontal continuous production equipment that tilts, and basic identical with embodiment four, description of drawings no longer, the content something in common no longer repeats, and difference is that each unit tilting furnace arranges that the pitch angle is α, α=15 °; Auger handling machinery material is a stainless material in each unit stove; Microwave source links to each other with 8 groups of microwave tubes in each unit stove, and every group by 3 microwave tube parallel connections; Sintering unit body of heater length is pretreatment unit body of heater, presintering unit body of heater length 5 times.

Embodiment seven: a kind of LiFePO 4 by microwaves heating horizontal continuous production equipment that tilts, and basic identical with embodiment four, description of drawings no longer, the content something in common no longer repeats, and difference is that each unit tilting furnace arranges that the pitch angle is α, α=30 °.

The above, it only is the utility model preferred embodiment, be not that the utility model is done any pro forma restriction, every foundation technical spirit of the present utility model all still belongs in the scope of technical solutions of the utility model any simple modification, equivalent variations and modification that above embodiment did.

Claims

1. a LiFePO 4 by microwaves heats horizontal continuous production equipment, it is characterized in that: comprise opening for feed, the charging air-exchanging chamber, the pretreatment unit stove, presintering unit stove, sintering unit stove, the discharging air-exchanging chamber, discharging mechanism cools, discharge port, vacuum extractor, shielding gas input unit and equipment control circuit, the pretreatment unit stove, presintering unit stove, sintering unit stove three cover unit stoves, contain unit stove opening for feed equally, the unit body of heater, the outer micro-wave screening insulation construction layer of unit body of heater, microwave source, a certain number of microwave tube, at least one is advanced extraction pipe, unit furnace discharge mouth, the auger handling machinery, each vacuum tightness is installed in each unit body of heater at least surveys probe, temperature measurement probe and pressure survey probe, the unit body of heater is that the closed horizontal hollow is cylindric, its cross-sectional shape is an annular, the unit body of heater is wrapped with the outer micro-wave screening insulation construction layer of unit body of heater, opening for feed is positioned at unit body of heater one end top, unit furnace discharge mouth is positioned at body of heater the other end bottom, unit, microwave source is arranged in unit body of heater outer periphery and links to each other with microwave tube, microwave tube is arranged on the furnace body outer wall, advancing extraction pipe is communicated with unit body of heater inner chamber, be communicated with vacuum extractor and shielding gas input unit by the band valve pipe, auger handling machinery axis and unit body of heater axis are installed in parallel in the unit body of heater, its two ends link to each other with the drive unit that is located at the outer both ends of the surface of unit body of heater respectively, vacuum tightness is surveyed probe, temperature measurement probe and pressure survey probe are installed in inboard wall of furnace body top, unit, are connected with the equipment control circuit corresponding circuits by data line; The horizontal layout of three cover unit stove levels; discharge port directly is communicated with opening for feed successively between the unit stove; opening for feed is communicated with pretreatment unit stove opening for feed near vertical by the charging air-exchanging chamber; pretreatment unit furnace discharge mouth directly is communicated with the opening for feed of presintering unit stove; the discharge port of presintering unit stove directly is communicated with the opening for feed of sintering unit stove; the discharge port of sintering unit stove is communicated with cool discharging mechanism and discharge port by the discharging air-exchanging chamber; each unit stove; the charging air-exchanging chamber; vacuum extractor; the shielding gas input unit; the discharging air-exchanging chamber; the discharging mechanism that cools is connected with the equipment control circuit corresponding circuits by data line.

2. the horizontal continuous production equipment of microwave heating according to claim 1, it is characterized in that: microwave source links to each other with certain group of number microwave tube in described each unit stove, every group by the parallel connection of some amount microwave tube, microwave tube is evenly arranged on the unit furnace body outer wall, or be evenly arranged in around the unit body of heater, wherein pretreatment unit stove, presintering unit stove microwave source power are 10～15kw, and sintering unit stove microwave source power is 30～100kw; Each unit body of heater is provided with a vapor pipe at least, is drawn into gas tube orifice and exhaust pipe mouth is equipped with microporous filter; Described each unit body of heater material is the optional one of silica glass or pottery, and the auger handling machinery is that silica glass, steel construction surface lining stupalith or stainless steel are optional wherein a kind of; Unit furnace discharge mouth is provided with unit furnace discharge valve, and the bleeder valve valve plate is the arc that mates with the unit body of heater; Sintering unit body of heater length is pretreatment unit body of heater, presintering unit body of heater length 3～5 times.

3. the horizontal continuous production equipment of microwave heating according to claim 1, it is characterized in that: described charging air-exchanging chamber, comprise that hopper, feed valve, bleeder valve, vacuum tightness survey probe and at least one and advance extraction pipe, the hopper upper port is communicated with opening for feed, lower port is communicated with pretreatment unit stove opening for feed, hopper upper and lower end portion is provided with feed valve and bleeder valve respectively, advance the extraction pipe opening and be arranged on the hopper upper inside wall, be communicated with vacuum extractor by the band valve pipe, vacuum tightness is surveyed probe and is installed in the hopper upper inside wall; Described discharging air-exchanging chamber, comprise that hopper, bleeder valve, vacuum tightness survey probe and at least one and advance extraction pipe, the hopper upper port is communicated with sintering unit furnace discharge mouth, lower port is communicated with the discharging mechanism that cools, bleeder valve is located at the hopper bottom, advance the extraction pipe opening and be arranged on the hopper upper inside wall, be communicated with vacuum extractor by the band valve pipe, vacuum tightness is surveyed probe and is installed in the hopper upper inside wall.

4. according to the horizontal continuous production equipment of the described microwave heating of the arbitrary claim of claim 1～3, it is characterized in that: the described discharging mechanism that cools, comprise Material pipeline, the interlayer cover, water-in, water outlet, the auger handling machinery, bleeder valve, Material pipeline is a stainless steel, the interlayer cover is wrapped on the Material pipeline pipeline outer wall, the one end is provided with water-in, the other end is provided with water outlet, the auger handling machinery is installed in material conveying pipe inside, outer with being located at the outer both ends of the surface of the pipeline respectively auger handling machinery drive unit in its two ends links to each other, and bleeder valve is located at discharge port top.

5. the horizontal continuous production equipment of microwave heating according to claim 4, it is characterized in that: described equipment control circuit contains touch-screen, and touch-screen is communicated with pretreatment unit stove PLC pilot circuit, presintering unit stove PLC pilot circuit, sintering unit stove PLC pilot circuit, the charging ventilation/discharging discharging PLC pilot circuit of taking a breath/cool respectively by data bus; Described pretreatment unit stove PLC pilot circuit, presintering unit stove PLC pilot circuit, sintering unit stove PLC pilot circuit, contain unit stove PLC, PLC external circuits, unit stove signal acquisition circuit equally, auger drive control circuit, the microwave source pilot circuit, the air extractor pilot circuit; Described PLC external circuits, the manual switch that contains the some amount that links to each other with input terminus, the switch signal circuit of signal acquisition circuit, and the servo-driver that links to each other with output terminal, unit furnace discharge valve control ac contactor coil, shielding gas control ac contactor coil, venting control ac contactor coil, vacuum pump control ac contactor coil, microwave source control ac contactor coil and pilot lamp; Described unit stove signal acquisition circuit contains input terminus and links to each other with unit stove vacuum tightness probe, the vacuum meter that output terminal links to each other with unit stove PLC input terminus, input terminus links to each other with unit furnace temperature measuring sonde, the temperature controller that output terminal links to each other with unit stove PLC input terminus links to each other with unit furnace pressure power measuring sonde with input terminus, the pressure controller that output terminal links to each other with unit stove PLC input terminus; Described auger handling machinery drive unit driving circuit contains the servo-driver that an end links to each other with two-phase power supply, and servo-driver connects the output terminal of servomotor and unit stove PLC; Described microwave source pilot circuit, the microwave transformer that contains the some amount that links to each other with three-phase supply, hold the microwave tube circuit that links to each other with the microwave transformer, be in series with a contact of temperature control protection switch and multiple contact alternating current contactor on the former end input line of microwave transformer, the output terminal of the coil connector element stove PLC of alternating current contactor; Described air extractor pilot circuit contains the alternating current contactor that an end links to each other with three-phase supply, and the other end of alternating current contactor links to each other with the air extractor motor by isolating switch, the coil connector element stove PLC output terminal of alternating current contactor; Described touch-screen and pretreatment unit stove PLC pilot circuit, presintering unit stove PLC pilot circuit, sintering unit stove PLC pilot circuit, the charging ventilation/discharging discharging PLC pilot circuit of taking a breath/cool is communicated with by the RS422/485 bus.

6. a LiFePO 4 by microwaves heats the horizontal continuous production equipment that tilts, it is characterized in that: comprise opening for feed, the charging air-exchanging chamber, the pretreatment unit stove, presintering unit stove, sintering unit stove, the discharging air-exchanging chamber, discharging mechanism cools, discharge port, vacuum extractor, shielding gas input unit and equipment control circuit, the pretreatment unit stove, presintering unit stove, sintering unit stove three cover unit stoves, contain unit stove opening for feed equally, the unit body of heater, the outer micro-wave screening insulation construction layer of unit body of heater, microwave source, a certain number of microwave tube, at least one is advanced extraction pipe, unit furnace discharge mouth, the auger handling machinery, each vacuum tightness is installed in each unit body of heater at least surveys probe, temperature measurement probe and pressure survey probe, the unit body of heater is a closed inclination hollow cylindrical, its axis normal cross-sectional shape is an annular, the unit body of heater is wrapped with the outer micro-wave screening insulation construction layer of unit body of heater, opening for feed is positioned at unit body of heater one end top, unit furnace discharge mouth is positioned at body of heater the other end bottom, unit, microwave source is arranged in unit body of heater outer periphery and links to each other with microwave tube, microwave tube is arranged on the furnace body outer wall, advancing extraction pipe is communicated with unit body of heater inner chamber, be communicated with vacuum extractor and shielding gas input unit by the band valve pipe, auger handling machinery axis and unit body of heater axis are installed in parallel in the unit body of heater, its two ends link to each other with the drive unit that is located at the outer both ends of the surface of unit body of heater respectively, vacuum tightness is surveyed probe, temperature measurement probe and pressure survey probe are installed in inboard wall of furnace body top, unit, are connected with the equipment control circuit corresponding circuits by data line; The parallel horizontal inclined layout of three cover unit stoves; the pitch angle is α; discharge port directly is communicated with opening for feed successively between the unit stove; opening for feed is communicated with pretreatment unit stove opening for feed near vertical by the charging air-exchanging chamber; pretreatment unit furnace discharge mouth directly is communicated with the opening for feed of presintering unit stove; the discharge port of presintering unit stove directly is communicated with the opening for feed of sintering unit stove; the discharge port of sintering unit stove is communicated with cool discharging mechanism and discharge port by the discharging air-exchanging chamber; each unit stove; the charging air-exchanging chamber; vacuum extractor; the shielding gas input unit; the discharging air-exchanging chamber; the discharging mechanism that cools is connected with the equipment control circuit corresponding circuits by data line.

7. the microwave heating according to claim 6 horizontal continuous production equipment that tilts, it is characterized in that: microwave source links to each other with certain group of number microwave tube in described each unit stove, every group by the parallel connection of some amount microwave tube, microwave tube is evenly arranged on the unit furnace body outer wall, or be evenly arranged in around the unit body of heater, wherein pretreatment unit stove, presintering unit stove microwave source power are 10～15kw, and sintering unit stove microwave source power is 30～100kw; Each unit body of heater is provided with a vapor pipe at least, is drawn into gas tube orifice and exhaust pipe mouth is equipped with microporous filter; Described each unit body of heater material is the optional one of silica glass or pottery, and the auger handling machinery is that silica glass, steel construction surface lining stupalith or stainless steel are optional wherein a kind of; Unit furnace discharge mouth is provided with unit furnace discharge valve, and the bleeder valve valve plate is the arc that mates with the unit body of heater; Sintering unit body of heater length is pretreatment unit body of heater, presintering unit body of heater length 3～5 times, and each unit stove parallel oblique arranges, unit body of heater axis downwards and the horizontal direction angle be inclined angle alpha, 0 °＜α≤30 °.

8. the microwave heating according to claim 6 horizontal continuous production equipment that tilts, it is characterized in that: described charging air-exchanging chamber, comprise that hopper, feed valve, bleeder valve, vacuum tightness survey probe and at least one and advance extraction pipe, the hopper upper port is communicated with opening for feed, lower port is communicated with pretreatment unit stove opening for feed, hopper upper and lower end portion is provided with feed valve and bleeder valve respectively, advance the extraction pipe opening and be arranged on the hopper upper inside wall, be communicated with vacuum extractor by the band valve pipe, vacuum tightness is surveyed probe and is installed in the hopper upper inside wall; Described discharging air-exchanging chamber, comprise that hopper, bleeder valve, vacuum tightness survey probe and at least one and advance extraction pipe, the hopper upper port is communicated with sintering unit furnace discharge mouth, lower port is communicated with the discharging mechanism that cools, bleeder valve is located at the hopper bottom, advance the extraction pipe opening and be arranged on the hopper upper inside wall, be communicated with vacuum extractor by the band valve pipe, vacuum tightness is surveyed probe and is installed in the hopper upper inside wall.

9. the described microwave heating horizontal continuous production equipment that tilts according to the arbitrary claim of claim 6～8, it is characterized in that: the described discharging mechanism that cools, comprise Material pipeline, the interlayer cover, water-in, water outlet, the auger handling machinery, bleeder valve, Material pipeline is a stainless steel, the interlayer cover is wrapped on the Material pipeline pipeline outer wall, the one end is provided with water-in, the other end is provided with water outlet, the auger handling machinery is installed in material conveying pipe inside, outer with being located at the outer both ends of the surface of the pipeline respectively auger handling machinery drive unit in its two ends links to each other, and bleeder valve is located at discharge port top.

10. the microwave heating according to claim 9 horizontal continuous production equipment that tilts, it is characterized in that: described equipment control circuit contains touch-screen, and touch-screen is communicated with pretreatment unit stove PLC pilot circuit, presintering unit stove PLC pilot circuit, sintering unit stove PLC pilot circuit, the charging ventilation/discharging discharging PLC pilot circuit of taking a breath/cool respectively by data bus; Described pretreatment unit stove PLC pilot circuit, presintering unit stove PLC pilot circuit, sintering unit stove PLC pilot circuit, contain unit stove PLC, PLC external circuits, unit stove signal acquisition circuit equally, auger drive control circuit, the microwave source pilot circuit, the air extractor pilot circuit; Described PLC external circuits, the manual switch that contains the some amount that links to each other with input terminus, the switch signal circuit of signal acquisition circuit, and the servo-driver that links to each other with output terminal, unit furnace discharge valve control ac contactor coil, shielding gas control ac contactor coil, venting control ac contactor coil, vacuum pump control ac contactor coil, microwave source control ac contactor coil and pilot lamp; Described unit stove signal acquisition circuit contains input terminus and links to each other with unit stove vacuum tightness probe, the vacuum meter that output terminal links to each other with unit stove PLC input terminus, input terminus links to each other with unit furnace temperature measuring sonde, the temperature controller that output terminal links to each other with unit stove PLC input terminus links to each other with unit furnace pressure power measuring sonde with input terminus, the pressure controller that output terminal links to each other with unit stove PLC input terminus; Described auger handling machinery drive unit driving circuit contains the servo-driver that an end links to each other with two-phase power supply, and servo-driver connects the output terminal of servomotor and unit stove PLC; Described microwave source pilot circuit, the microwave transformer that contains the some amount that links to each other with three-phase supply, hold the microwave tube circuit that links to each other with the microwave transformer, be in series with a contact of temperature control protection switch and multiple contact alternating current contactor on the former end input line of microwave transformer, the output terminal of the coil connector element stove PLC of alternating current contactor; Described air extractor pilot circuit contains the alternating current contactor that an end links to each other with three-phase supply, and the other end of alternating current contactor links to each other with the air extractor motor by isolating switch, the coil connector element stove PLC output terminal of alternating current contactor; Described touch-screen and pretreatment unit stove PLC pilot circuit, presintering unit stove PLC pilot circuit, sintering unit stove PLC pilot circuit, the charging ventilation/discharging discharging PLC pilot circuit of taking a breath/cool is communicated with by the RS422/485 bus.