CN107999763A - A kind of method that powder hotforging prepares Fe-6.5%Si bands with diffusion-sintering - Google Patents
A kind of method that powder hotforging prepares Fe-6.5%Si bands with diffusion-sintering Download PDFInfo
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- CN107999763A CN107999763A CN201711369221.6A CN201711369221A CN107999763A CN 107999763 A CN107999763 A CN 107999763A CN 201711369221 A CN201711369221 A CN 201711369221A CN 107999763 A CN107999763 A CN 107999763A
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F3/00—Manufacture of workpieces or articles from metallic powder characterised by the manner of compacting or sintering; Apparatus specially adapted therefor ; Presses and furnaces
- B22F3/17—Manufacture of workpieces or articles from metallic powder characterised by the manner of compacting or sintering; Apparatus specially adapted therefor ; Presses and furnaces by forging
-
- B22F1/0003—
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F1/00—Metallic powder; Treatment of metallic powder, e.g. to facilitate working or to improve properties
- B22F1/10—Metallic powder containing lubricating or binding agents; Metallic powder containing organic material
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F3/00—Manufacture of workpieces or articles from metallic powder characterised by the manner of compacting or sintering; Apparatus specially adapted therefor ; Presses and furnaces
- B22F3/10—Sintering only
- B22F3/1003—Use of special medium during sintering, e.g. sintering aid
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F3/00—Manufacture of workpieces or articles from metallic powder characterised by the manner of compacting or sintering; Apparatus specially adapted therefor ; Presses and furnaces
- B22F3/18—Manufacture of workpieces or articles from metallic powder characterised by the manner of compacting or sintering; Apparatus specially adapted therefor ; Presses and furnaces by using pressure rollers
-
- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22C—ALLOYS
- C22C33/00—Making ferrous alloys
- C22C33/02—Making ferrous alloys by powder metallurgy
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- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22C—ALLOYS
- C22C38/00—Ferrous alloys, e.g. steel alloys
- C22C38/02—Ferrous alloys, e.g. steel alloys containing silicon
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F3/00—Manufacture of workpieces or articles from metallic powder characterised by the manner of compacting or sintering; Apparatus specially adapted therefor ; Presses and furnaces
- B22F3/17—Manufacture of workpieces or articles from metallic powder characterised by the manner of compacting or sintering; Apparatus specially adapted therefor ; Presses and furnaces by forging
- B22F2003/175—Manufacture of workpieces or articles from metallic powder characterised by the manner of compacting or sintering; Apparatus specially adapted therefor ; Presses and furnaces by forging by hot forging, below sintering temperature
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F2998/00—Supplementary information concerning processes or compositions relating to powder metallurgy
- B22F2998/10—Processes characterised by the sequence of their steps
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- Metallurgy (AREA)
- Organic Chemistry (AREA)
- Powder Metallurgy (AREA)
- Manufacture Of Metal Powder And Suspensions Thereof (AREA)
Abstract
A kind of method that powder hotforging prepares Fe 6.5%Si bands with diffusion-sintering, chooses reduction Fe powder and water atomization Fe powder, according to 4:6~6:4 ratio mixing, then the HIGH-PURITY SILICON iron powder that Si contents are 70~80% is added, form Fe Si mixed powders.It is molded squarely base; it is heated to 950~1020 DEG C and realizes Fe phase austenitizings; final forging temperature is 850~920 DEG C after repeatedly forging; so that then powder hotforging base is carried out vacuum at 1060~1160 DEG C or protection of reducing atmosphere sinters, multiple cold rolling, low-temperature sintering by pressed compact close to full densification; sintered in 1250~1320 DEG C of High temperature diffusions; realize homogeneous alloy, obtain 0.1~0.5mm thickness containing 4.5~6.7%Si, density >=7.39g/cm3High silicon steel band.
Description
Technical field
Preparation and manufacture field the invention belongs to metal material, and in particular to the powder hotforging of high silicon steel thin belt material and roll
The method for making deformation.
Technical background
Remanent magnetism and coercive force all very littles of soft magnetic material, i.e. hysteresis curve is very narrow, it and fundamental magnetization curve are almost
Overlap, be mainly used for the iron core of inductance coil, transformer, relay and motor.Fe-Si alloys maximum permeability is sent out with Si contents
Changing, respectively Si mass percent it is (the same below) for 2% and 6.5% nearby there is the peak of two maximum permeabilities
Value, respectively reaches 10000 and 25000.The maximum permeability of Fe-Si alloys does not have absolute predominance, such as slope in soft magnetic materials
The maximum permeability of alloy can not reach 200000.But the Fe-Si lattens of Si < 4.5% manufacture cost is low, therefore
Silicon steel sheet is also known as electrical sheet or silicon steel thin slice, is a kind of very important magnetic material.
And Si>When 4.5%, below 540 DEG C of temperature B can occur for Fe-Si alloys2The eutectoid decomposition reaction of ordered phase, it is raw
Into the unordered phases of α-Fe and DO3Ordered phase so that alloy becomes fragile and is difficult to deform.
For iron Si system alloy of the Si contents between 4.5~6.7%, commonly referred to as high silicon steel, wherein silicone content 6.5%
High silicon steel it is mostly important.Its reason is Fe-Si alloy grains edge<100>The magnetostriction coefficient in direction is with the increase of Si contents
And reduce, disappear substantially at about 6.3%, and<111>The magnetostriction coefficient in direction increases and increases with Si contents, about
When 6.1% with<100>The magnetostriction coefficient in direction is equal so that high silicon steel shows excellent low in higher frequency operation
Iron loss characteristic.
The transformer of normal operation can occur continuous uniform " drone " sound, this is because alternating current by transformer around
Group when, in the core between generate periodically variable alternating flux, cause iron core magnetostriction and shake the sound sent.Greatly
The sound that amount or large-scale iron core are sent in vibrations not only causes the loss of energy, also creates noise pollution.Especially
It is to play particularly important role in the military aviation such as spacecraft, submarine and guided missile field, Fe-Si systems alloy.20th century 60
Age Mo, the alloy of Si contents 6.5% are appeared on No. 11 airships of Apollo as transformer material, are completed the mankind and are landed on the moon first
Heroic undertaking.As it can be seen that high silicon steel is the environment-friendly type soft magnetic materials of a kind of consumption reduction of function admirable, noise reduction.
Compared to other alloys, the research and development process of high silicon steel is relatively very long.Late 1920s
A.Schulze studies discovery first, and the iron Si system alloy of silicone content 6.5% has the almost nil characteristic of magnetostriction coefficient.
In the 1980s, professor K.I.Arail etc. has found the high silicon steel alloy low compared to traditional Si content in exchange dynamic magnetic field
In there is the magnetic conductivity of lower iron loss and higher.Hereafter between many decades, in order to overcome the brittleness of high silicon steel, in technology of preparing side
There are many trials in face.As the special rolled method of jacket or temperature control, rapid solidification method, chemical vapour deposition technique (CVD method),
Plasma chemical vapor deposition (PCVD methods), hot dipping ooze a diffusion annealing method, powder metallurgic method, microalloying and are modified
Etc. various methods.
Wherein CVD is the successful example of comparison.NKK companies of Japan in 1988 have produced thickness for the first time using CVD technology
It is the No yield point 6.5%Si steel discs of 400mm to spend for 0.1~0.5mm, width.Phase early 1990s, global first commercialization
Can realize that the CVD production lines of continuous siliconising are developed, the product size of production can reach 0.1~0.3mm ×
600mm。
The principle of CVD is:Under specific temperature conditions, silicon-containing gas (SiCl4) can react generation Fe- with silicon strip
Si compounds, and alloy is reached required content to alloy diffusion inside by elevated furnace temperature.Although oneself uses this
Technology realizes small-scale industrialized production, but its scale and yield all can not much meet the need in international soft magnetic materials market
Ask, and this preparation method technical process is sufficiently complex, energy consumption and of high cost, operating environment and its severe, it is impossible to meet ring
Guaranteed request.
High silicon steel is " the steel art work ", its technology of preparing is all always and everywhere state-of-the-art steel and iron manufacturing technology, and
It is the hot spot of development and exploitation.For 6.5%Si high silicon steel, its excellent magnetic performance and wide application prospect are even more to inhale
Draw scientific worker and carry out substantial amounts of research-and-development activity.The development of preparation process and ripe and can be cost-effectively
Production, is that 6.5%Si high silicon steel move towards to be commercialized widely applied key, also the always emphasis of research work.Once grope
Go out simple, economic, effective, ripe preparation process, will just produce huge economic benefit and social benefit.
The content of the invention
The object of the present invention is to provide the side that a kind of powder hotforging and High temperature diffusion sintering prepare Fe-6.5%Si thin strips
Method, the problem of being difficult to shape for Fe-4.5~6.7%Si alloy thin band materials, using industrial Fe powder and with Si contents as 70~80%
HIGH-PURITY SILICON iron powder uniformly mix, be molded into hot forging green compact after adding binder, then prepared necessarily using powder hotforging method
The slab of thickness, is acted on using the large deformation of powder hotforging and causes green density raising, structure refinement, and under thermal diffusion effect
Realize partially-alloyed, the α-Fe crystal grain of poor Si and the heterogeneous structure of brittleness high Si phase of the formation with plastic deformation ability.Afterwards
It is continuous to obtain thin plate after multi-pass cold rolling-sintering, finally sintered using High temperature diffusion and obtain the high silicon steel band of homogeneous single phase.
The present invention is achieved by the following technical solutions:Reduction Fe powder and two kinds of Industrial iron powders of water atomization Fe powder are chosen,
According to 4:6~6:4 ratio mixing, forms technical pure Fe powder basic materials, then it is 70~80% to add fine Si contents
HIGH-PURITY SILICON iron powder is raw material, forms Fe-4.5~6.7%Si mixed powders.Will be fine by suitable bonding agent, dispersant
HIGH-PURITY SILICON iron powder is adhered in mixed process in Industrial iron powder surface or hole.Since industrial Fe powder is with high-compressibility
Big particle, occupies larger volume ratio in mixed powder, its plastic deformation ability is not significantly reduced after adding ferrosilicon powder, can be with
By being molded squarely base.It is heated to 950~1020 DEG C and realizes Fe phase austenitizings, then places into closed mould hot forging,
Repeatedly final forging temperature is 850~920 DEG C after forging so that pressed compact is close complete fine and close, about 6.87~7.19g/cm3.Then will
Powder hotforging base carries out vacuum or protection of reducing atmosphere sintering in 1060~1160 DEG C of temperature ranges, makes Fe powder particles metallurgical junctions
Close, and ferrosilicon powder particles realized with Fe it is partially-alloyed, formed densification, have the poor Si of plastic deformation ability α-Fe crystal grain and
The high silicon steel blank of heterogeneous structure of the high Si phases of brittleness.Sintered subsequently through multiple cold rolling, low temperature diffusion, the density rise of slab,
Plate thickness is reduced, and the alloying level of Si is also continuously improved.Finally vacuum or and Primordial Qi in 1250~1320 DEG C of temperature ranges
Atmosphere protection sintering, realizes the homogeneous alloy of high silicon steel with the help of thermal diffusion, obtain containing 4.5~6.7%Si 0.1~
0.5mm is thick, density >=7.39g/cm3High silicon steel band.
The method of the present invention specifically comprises the following steps:
(1) raw material powder prepares
Using -100 mesh reduced iron powders, Fe >=98.5% in Fe powder is reduced, remaining is Si, Mn, P, S and other are inevitable
Impurity, using -100 mesh water-atomized iron powders, Fe >=99.0% in water atomization Fe powder, remaining for Si, Mn, P, S and other can not
The impurity avoided, by reduction Fe powder and water atomization Fe powder according to 4:6~6:4 ratio is prepared, and is mixed using conical mixer, V-arrangement
Material machine or drum mixer are mixed to form technical pure Fe powder basic materials, and incorporation time is 2~6h.
Si contents are used as 70~80% HIGH-PURITY SILICON iron powder, the ferrosilicon powder of particle diameter≤10 μm, this ferrosilicon powder except containing
Have beyond 70~80%Si, major impurity is~0.25%Al ,~0.08%Ca and~0.02%C, remaining is Fe.
Reduced iron powder is a kind of widely used Industrial iron powder, has irregular porous pattern, micro- beneficial to storing, adhering to
Fine silica powder, and in follow-up powder extrusion process also being mutually twisted for powder easy to implement and improve the intensity of pressed compact, be conducive to
The stabilization of powder extrusion process.Water atomization Fe powder is also a kind of widely used Industrial iron powder, has subsphaeroidal pattern, and impurity contains
Amount is less than reduction Fe powder, compressibility and mobility with higher, is conducive to the uniform flow of powder extrusion process course powder
Dynamic, low impurity content is favourable to the soft magnetic characteristic of high silicon steel in water atomization Fe powder.Will two kinds of reduction Fe powder and water atomization Fe powder
Industrial iron powder, according to 4:6~6:4 ratio mixing, forms technical pure Fe powder basic materials, and it is each to be conducive to two kinds of straight iron powders of performance
From advantage, be also relatively common method in industrial production iron-base part.
Fe-70~80%Si high purity ferrosilicons are in process of setting in addition to primary silicon crystal grain, and at 1207 DEG C, there are eutectic
Reaction, forms the β-FeSi with tP3 structures2It is very crisp with Si phase eutectic structures, this tissue, it is easy to pass through Mechanical Crushing
Technique refines.Fe-70~80%Si high purity ferrosilicons are crushed to≤10 μm of ferrosilicon powder, the Si phases in its actual tissue, FeSi2
It is mutually more tiny, be conducive to the thermal diffusion homogenization of Si elements during subsequent high temperature sintering, it is single-phase to form homogeneous Fe-4.5~6.7%Si
Alloy.Meanwhile 20~30%Fe present in powder can effectively reduce the degree of oxidation of Si, be conducive to improve the production of high silicon steel
Quality.
By Fe-70~80%Si high purity ferrosilicons Mechanical Crushing to particle diameter≤10 μm, be conducive to it and be adhered to industrial Fe powder
Surface, tiny Si, FeSi2The mutually Dispersed precipitate in blank, plays the role of the Strengthening and Toughening of structure refinement, is conducive to improve follow-up
Blank toughness, do not easily cause cracking in densification process is rolled.But still suffered from Fe-70~80%Si high purity ferrosilicons more
Si phases, Si is easily absorbing oxygen, and SiO is formed in exposed Si phase surfaces2Film, therefore in Fe-70~80%Si HIGH-PURITY SILICONs
In the preparation of iron powder, storage and transfer process, and inert gas shielding, institute should be used in follow-up batch mixing, hot forging, the operation of rolling
The instrument used must also take dehydration, drying process in advance.
On the premise of oxygen content is controlled, influence of the impurity such as other Al, Ca, Mn to alloy magnetic property is little, during
The possibility for introducing other alloying elements is also little.
(2) powder mixes
According to the ratio of Fe-4.5~6.7%Si, Fe powder and fine Fe-70~80%Si HIGH-PURITY SILICONs iron powder are weighed;Lazy
Property protective atmosphere under using low energy mixer mix, mixing velocity and time regarding mixing uniformity depending on, should try one's best mitigation Fe
Processing hardening occurs in mixed process for powder.
(3) powder hotforging
Square pressed compact is prepared using compression-moulding methods, the green density of acquisition is 6.49~6.66g/cm3;Before hot forging
Molding square billet is heated to 950~1020 DEG C under nitrogen protective effect, keeps the temperature 2~4h, the hot forging densification in square dies,
Repeatedly final forging temperature is 850~920 DEG C after forging, and pressed compact is close complete fine and close, and density reaches 6.87~7.19g/cm3。
Under impact force action, hot forging pressed compact is close complete fine and close.Make the plasticity of plate after hot forging in order to avoid alloying
Decline, relatively low heating-up temperature is have selected before hot forging.Fe phase and complexity FeSi phase composition of the alloy structure for high-ductility after hot forging
Complex tissue, which possesses the high-ductility characteristic of simple substance Fe.
(4) cold rolling-sintering
By above-mentioned hot forged plate cold rolling-sintering, progressively it is thinned.
Single pass rolling reduction≤8%, after multi- pass rolling reaches 30~50% to total reduction, then in sintering furnace in
1060~1160 DEG C of 0.5~2h of heat preservation sintering, after multiple cold rolling-sintering, the thickness of plate reaches 0.1~0.5mm, with Si's
Alloying is gradually completing, and strip density improves, and reaches 7.38~7.52g/cm3。
There are a large amount of deformable Fe phases in blank, slab can bear cold-rolling deformation.But there is also more in slab
High Si phases, its performance is more crisp, therefore amount cannot be too high under every time rolling, and accumulation total reduction reaches 30~50%, takes around 8
~25 passages.
Since existing hard crisp phase, cold deformation process can form some micro-cracks.In order to realize the closing of pores and crackle
Repair, and the homogenization diffusion of a degree of Si elements.Cold rolling reduction accumulation needs to sinter 1 again to a certain extent afterwards
It is secondary, 0.1~0.5mm is rolled down to from 36~54mm hot forging plates, takes around and sinters 12~20 times again.
Sintering temperature is too low, is unfavorable for metallurgical binding and the Si element thermal diffusions of Fe powder particles;And sintering temperature is excessive then
Si elements can be caused quickly to spread, cause crystal grain excessive high hardness, embrittlement, follow-up rolling deformation is difficult to realize.
Take reproducibility, inert gas shielding or vacuum-sintering.W, Mo, heat resisting steel etc. can be used during sintering as support
Plate (or burning boat), can also use the ceramic wafers such as corundum, zirconium oxide, but metallic plate thermal conductivity is good, and be beneficial to Even Sintering.
The texture of coarse crystal containing the second phase is formed after sintering.X-ray diffraction Discriminating materials are heterogeneous Fe (Si)
Phase, body-centred cubic several characteristic peaks have obvious separating phenomenon, illustrate there are 2 kinds of different Fe phases of Si solid solubility, wherein must
There are the Si contents in a kind of Fe phases low, there is plastic deformation ability.
(5) full alloying high temperature sintering
Vacuum or restitutive protection 1~4h of atmosphere sintering in 1250~1320 DEG C of temperature ranges, in the effect of thermal diffusion
Under, to realize the full alloyings of Si, form single-phase alloy, obtain the high silicon steel of homogeneous, the thickness of plate is almost unchanged after densification sintering,
For 0.1~0.5mm, density reaches 7.39~7.53g/cm3。
The HIGH-PURITY SILICON iron powder of particle diameter≤10 μm is by high-energy ball milling or rushes the acquisition of rotation method.
The low energy mixer is conical mixer, V-arrangement batch mixer or drum mixer.
The square pressed compact prepared in step (3), length and width are respectively 100~300mm, are highly 40~60mm, using table
The pressure that surface pressure is 400~600MPa is suppressed.The thickness of blank is 36~54mm after hot forging, and three point bending test shows to mould
Property, bending strength reaches 108~198MPa.
Step (2) adds cellulose, paraffin micro mist when mixing or zinc stearate is water-insoluble adds as binder, binder
Dosage total amount is no more than the 0.8% of mixed-powder gross mass, while adds grease and absolute ethyl alcohol does passivator, plays passivation Si
Powder, bonding Fe-Si powder, the effect for strengthening powder flowbility and compact strength, the additive amount total amount of passivator are no more than mixed powder
The 2% of last gross mass.
Support plate described in step (4) uses molybdenum plate, W plates, heat resisting steel, corundum or zirconia ceramics plate.
During high temperature sintering described in step (6), overlapping places sintering plate, and interlayer is laid with MgO powder, and plate tiling is placed,
Tablet weight is placed on plate, prevents from deforming in sintering process.
In addition to Si contents, content of element such as grain size, crystal grain orientation, C etc. also has the magnetic behavior of high silicon steel
Large effect, can subsequently be annealed, the technological means such as normalizing treatment is controlled by by wet hydrogen.
Essence of the invention is by with the addition of fine Fe-70 in the industrial Fe powder of the big volumetric portion with good plasticity
~80%Si HIGH-PURITY SILICON iron powders, form Fe-4.5~6.7%Si alloys basis powder.Using powder hotforging into slab, obtain high
Green density.Since hot forging is organized as incomplete alloying tissue, in tissue in addition to small part richness Si phases, main constituent
For yielding Fe phases, therefore subsequently structural homogenity and compactness, then high temperature can be improved by multi-pass cold rolling and sintering
Diffusion technique, realizes the homogenization of Si, so as to obtain the single-phase high silicon steel band of high quality.This method is set by technique and equipment
Meter, realizes Technics Process Automation, continuous production, and can be mass-produced 0.1~0.5mm thickness, density >=7.39g/cm3Height
Silicon steel band.
Brief description of the drawings
Fig. 1 be the embodiment of the present invention 1 powder hotforging after blank three-point bending curve map.
Fig. 2 is metallographic structure figure after powder hotforging-cold rolling-sintering of the embodiment of the present invention 2;
Fig. 3 is XRD diffraction curve figures after powder hotforging-cold rolling-sintering of the embodiment of the present invention 2;
Fig. 4 is XRD diffraction curve figures after powder hotforging-cold rolling-high temperature sintering of the embodiment of the present invention 4.
Embodiment
The present invention is described in further detail with reference to the accompanying drawings and detailed description.
Embodiment 1
By the water atomization Fe powder of the reduction Fe powder of -100 mesh and -100 mesh according to 5:5 ratio is prepared, and is mixed using drum-type
Material machine is mixed to form technical pure Fe powder raw materials, incorporation time 6h, is added in mixed process according to 500ml/ tons of ratio anhydrous
Ethanol.
By well pre-mixed technical pure Fe powder and the Fe-80%Si high-purity powders of granularity≤10 μm according to 91.625:8.375
Ratio mixing, form the mixed-powder of Fe-6.7%Si.The paraffin micro mist of addition raw material total amount 0.6% during mixing, 0.1%
Machine oil.Absolute ethyl alcohol is added according to 200ml/ tons of amount.Using V-arrangement batch mixer by above-mentioned powder mixing 4h.
Square pressed compact is prepared using compression-moulding methods, and pressed compact size is 100 × 100 × 40mm, surface pressing
600MPa, green density 6.49g/cm3。
Molding square billet is heated to 950 DEG C under nitrogen protective effect, keeps the temperature 4h.Using power forging machine, in square dies
Middle hot forging densification, repeatedly final forging temperature is 920 DEG C after forging, and the thickness of blank is about 36mm, and density reaches 6.87g/cm3。
Three point bending test shows plasticity, sees Fig. 1, and bending strength reaches 108MPa.
By above-mentioned hot forged plate cold rolling-sintering, progressively it is thinned.Specifically pressure-annealing schedule is:36mm→24mm→17mm→
12mm → 9.5mm → 7.2mm → 5mm → 3.5mm → 2.4mm → 1.6mm → 1.02mm → 1.02mm → 0.71mm → 0.49mm,
Sintered through 13 cold rollings and 12 times.
Multi-pass cold rolling is thick in 1060 DEG C of heat preservation sintering 2h, plate to after 30~50%, then in vacuum sintering furnace
Degree is thinned to 0.49mm, and density reaches 7.38g/cm3。
4h is sintered in 1320 DEG C of Temperature Vacuums, realizes the full alloyings of Si, forms single-phase alloy, thickness 0.5mm, density reaches
7.39g/cm3, Si contents are 6.7%.
Embodiment 2
By the water atomization Fe powder of the reduction Fe powder of -100 mesh and -100 mesh according to 6:4 ratio is prepared, and is mixed using drum-type
Material machine is mixed to form technical pure Fe powder raw materials, incorporation time 4h, is added in mixed process according to 500ml/ tons of ratio anhydrous
Ethanol.
By well pre-mixed technical pure Fe powder and the Fe-70%Si high-purity powders of granularity≤10 μm according to 93.57:6.42
Ratio mixes, and forms the mixed-powder of Fe-4.5%Si.The zinc stearate of raw material total amount 0.7%, 0.1% machine are added during mixing
Oil.Absolute ethyl alcohol is added according to 400ml/ tons of amount.Using drum mixer by above-mentioned powder mixing 6h.
Square pressed compact is prepared using compression-moulding methods, and pressed compact size is 300 × 300 × 60mm, surface pressing
600MPa, green density 6.66g/cm3。
Molding square billet is heated to 1020 DEG C under nitrogen protective effect, keeps the temperature 2h.Using power forging machine, in square dies
Middle hot forging densification, repeatedly final forging temperature is 920 DEG C after forging, and the thickness of blank is about 54mm, and density reaches 7.19g/cm3。
Three point bending test shows plasticity, and bending strength reaches 198MPa.
By above-mentioned hot forged plate cold rolling-sintering, progressively it is thinned.Specifically pressure-annealing schedule is:54mm→36mm→36mm→
24mm→17mm→12mm→9.5mm→7.2mm→5mm→3.5mm→2.4mm→1.6mm→1.02mm→1.02mm→
0.71mm → 0.49mm → 0.39mm → 0.25mm → 0.17mm → 0.13mm → 0.10mm, i.e., burn through 20 cold rollings and 19 times
Knot.
Multi-pass cold rolling is to after 30~50% total reductions, then is burnt in hydrogen shield sintering furnace in 1160 DEG C of insulations
0.5h is tied, sheet metal thickness is thinned to 0.10mm, and density reaches 7.52g/cm3。
The texture of coarse crystal containing the second phase is formed after sintering, sees Fig. 2.X-ray diffraction Discriminating materials are heterogeneous Fe
(Si) phase, as seen in Figure 3, body-centred cubic several characteristic peaks have obvious separating phenomenon, illustrate there are Si solid solubility it is different 2
Kind Fe phases, wherein must have the Si contents in a kind of Fe phases low, have plastic deformation ability.
4h is sintered in 1250 DEG C of Temperature Vacuums, realizes the full alloyings of Si, forms single-phase alloy, thickness 0.1mm, density reaches
7.53g/cm3, Si contents are 4.5%.
Embodiment 3
By the water atomization Fe powder of the reduction Fe powder of -100 mesh and -100 mesh according to 5:6 ratio is prepared, and is mixed using drum-type
Material machine is mixed to form technical pure Fe powder raw materials, incorporation time 3h, is added in mixed process according to 400ml/ tons of ratio anhydrous
Ethanol.
By well pre-mixed technical pure Fe powder and the Fe-76%Si high-purity powders of granularity≤10 μm according to 91.45:8.55
Ratio mixes, and forms the mixed-powder of Fe-6.5%Si.The paraffin micro mist of raw material total amount 0.4%, 0.2% first are added during mixing
Base cellulose, 0.1% machine oil.Absolute ethyl alcohol is added according to 400ml/ tons of amount.Using drum mixer by above-mentioned powder
Mix 6h.
Square pressed compact is prepared using compression-moulding methods, and pressed compact size is 200 × 200 × 50mm, surface pressing
500MPa, green density 6.53g/cm3。
Molding square billet is heated to 960 DEG C under nitrogen protective effect, keeps the temperature 2h.Using power forging machine, in square dies
Middle hot forging densification, repeatedly final forging temperature is 860 DEG C after forging, and the thickness of blank is about 46mm, and density reaches 6.90g/cm3。
Three point bending test shows plasticity, and bending strength reaches 110MPa.
By above-mentioned hot forged plate cold rolling-sintering, progressively it is thinned.Specifically pressure-annealing schedule is:46mm→36mm→24mm→
17mm→12mm→9.5mm→7.2mm→5mm→3.5mm→2.4mm→1.6mm→1.02mm→1.02mm→0.71mm→
0.49mm → 0.39mm → 0.27mm, i.e., sinter through 16 cold rollings and 15 times.
Multi-pass cold rolling is to after 30~50% total deformations, then is burnt in nitrogen protective sintering stove in 1100 DEG C of insulations
1h is tied, sheet metal thickness is thinned to 0.27mm, and density reaches 7.39g/cm3。
2h is sintered in 1300 DEG C of Temperature Vacuums, realizes the full alloyings of Si, forms single-phase alloy, thickness 0.27mm, density reaches
To 7.40g/cm3, Si contents are 6.5%,
Embodiment 4
By the water atomization Fe powder of the reduction Fe powder of -100 mesh and -100 mesh according to 4:6 ratio is prepared, and is mixed using drum-type
Material machine is mixed to form technical pure Fe powder raw materials, incorporation time 2h, is added in mixed process according to 200ml/ tons of ratio anhydrous
Ethanol.
By well pre-mixed technical pure Fe powder and the Fe-72%Si high-purity powders of granularity≤10 μm according to 91.05:8.95
Ratio mixes, and forms the mixed-powder of Fe-5.8%Si.The paraffin micro mist of raw material total amount 0.6%, 0.2% machine are added during mixing
Oil.Absolute ethyl alcohol is added according to 400ml/ tons of amount.Using drum mixer by above-mentioned powder mixing 3h.
Square pressed compact is prepared using compression-moulding methods, and pressed compact size is 220 × 220 × 55mm, surface pressing
450MPa, green density 6.50g/cm3。
Molding square billet is heated to 980 DEG C under nitrogen protective effect, keeps the temperature 2h.Using power forging machine, in square dies
Middle hot forging densification, repeatedly final forging temperature is 880 DEG C after forging, and the thickness of blank is about 52mm, and density reaches 6.92g/cm3。
Three point bending test shows plasticity, and bending strength reaches 130MPa.
By above-mentioned hot forged plate cold rolling-sintering, progressively it is thinned.Specifically pressure-annealing schedule is:52mm→39mm→26mm→
18mm→13mm→10.5mm→8.2mm→5mm→3.2mm→2.4mm→2.0mm→1.3mm→0.90mm→0.63→
0.43mm→0.32mm→0.21mm.Sintered through 17 cold rollings and 16 times.
Multi-pass cold rolling is to after 30~50% total deformations, then is burnt in hydrogen shield sintering furnace in 1150 DEG C of insulations
1h is tied, sheet metal thickness is thinned to 0.21mm, and density reaches 7.41g/cm3。
2h is sintered in 1300 DEG C of Temperature Vacuums, realizes the full alloyings of Si, forms single-phase alloy, thickness 0.21mm, density reaches
To 7.42g/cm3, Si contents are 5.8%, and the XRD analysis figure of its final plate is shown in Fig. 4, is the high silicon steel of single-phase homogeneous.
Claims (8)
1. a kind of method that powder hotforging prepares Fe-6.5%Si thin strips with High temperature diffusion sintering, it is characterised in that including as follows
Step:
(1) raw material powder prepares
Using -100 mesh reduced iron powders, Fe >=98.5% in Fe powder is reduced, remaining is Si, Mn, P, S and other are inevitably miscellaneous
Matter, using -100 mesh water-atomized iron powders, Fe >=99.0% in water atomization Fe powder, remaining is Si, Mn, P, S and other are inevitable
Impurity, will reduction Fe powder and water atomization Fe powder according to 4:6~6:4 ratio is prepared, using conical mixer, V-arrangement batch mixer
Or drum mixer is mixed to form technical pure Fe powder basic materials, incorporation time is 2~6h;
Si contents are used as 70~80% HIGH-PURITY SILICON iron powder, the ferrosilicon powder of particle diameter≤10 μm, major impurity is~0.25%Al,
~0.08%Ca and~0.02%C, remaining is Fe;
(2) powder mixes
According to the ratio of Fe-4.5~6.7%Si, Fe powder and Fe-70~80%Si HIGH-PURITY SILICON iron powders are weighed;Gas is protected in inertia
Mixed under atmosphere using low energy mixer;
(3) powder hotforging
Square pressed compact is prepared using compression-moulding methods, green density is 6.49~6.66g/cm3;Square billet will be molded before hot forging
950~1020 DEG C are heated under nitrogen protective effect, keeps the temperature 2~4h, repeatedly final forging temperature is 850~920 DEG C after forging, pressure
Base reaches 6.87~7.19g/cm close to full densification, density3;
(4) cold rolling-sintering
By above-mentioned hot forged plate cold rolling-sintering, progressively it is thinned, single pass rolling reduction≤8%, is reached through multi- pass rolling to total reduction
To after 30~50%, then in sintering furnace after 1060~1160 DEG C of 0.5~2h of heat preservation sintering, multiple cold rolling-sintering, plate
Thickness reaches 0.1~0.5mm, and after the completion of the alloying of Si, strip density brings up to 7.38~7.52g/cm3;
(5) full alloying high temperature sintering
Vacuum or restitutive protection 1~4h of atmosphere sintering in 1250~1320 DEG C of temperature ranges, it is real under the action of thermal diffusion
The existing full alloyings of Si, form single-phase alloy, obtain the high silicon steel of homogeneous, and the thickness of plate is 0.1~0.5mm after densification sintering,
Density brings up to 7.39~7.53g/cm3。
2. the method that powder hotforging as claimed in claim 1 prepares Fe-6.5%Si bands with diffusion-sintering, it is characterised in that:
Iron powder per ton adds 200~500ml absolute ethyl alcohols in step (1) mixed process.
3. the method that powder hotforging as claimed in claim 1 prepares Fe-6.5%Si bands with diffusion-sintering, it is characterised in that:
The HIGH-PURITY SILICON iron powder of particle diameter≤10 μm is by high-energy ball milling or rushes the acquisition of rotation method.
4. the method that powder hotforging as claimed in claim 1 prepares Fe-6.5%Si bands with diffusion-sintering, it is characterised in that:
The low energy mixer is conical mixer, V-arrangement batch mixer or drum mixer.
5. the method that powder hotforging as claimed in claim 1 prepares Fe-6.5%Si bands with diffusion-sintering, it is characterised in that:
It is characterized in that:The square pressed compact prepared in step (3), length and width are respectively 100~300mm, are highly 40~60mm, adopt
Suppressed with the pressure that surface pressing is 400~600MPa;The thickness of blank is 36~54mm after hot forging, and three point bending test shows
Go out plasticity, bending strength reaches 108~198MPa.
6. the method that powder hotforging as claimed in claim 1 prepares Fe-6.5%Si bands with diffusion-sintering, it is characterised in that:
Add cellulose, paraffin micro mist or zinc stearate water-insoluble binder during mixing, the additive amount total amount of binder is no more than mixing
The 0.8% of powder gross mass, while add grease and absolute ethyl alcohol does passivator, play passivation Si powder, bonding Fe-Si powder, enhancing
The effect of powder flowbility and compact strength, the additive amount total amount of passivator are no more than the 2% of mixed-powder gross mass.
7. the method that powder hotforging as claimed in claim 1 prepares Fe-6.5%Si bands with diffusion-sintering, it is characterised in that:
Support plate described in step (4) uses molybdenum plate, W plates, heat resisting steel, corundum or zirconia ceramics plate.
8. the method that powder hotforging as claimed in claim 1 prepares Fe-6.5%Si bands with diffusion-sintering, it is characterised in that:
During high temperature sintering described in step (6), overlapping places sintering plate, and interlayer is laid with MgO powder, and plate tiling is placed, on plate
Tablet weight is placed, prevents from deforming in sintering process.
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Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2000192186A (en) * | 1998-12-25 | 2000-07-11 | Daido Steel Co Ltd | Manufacture of soft magnetic alloy sheet, and magnetic core member using this sheet |
CN1273611A (en) * | 1998-05-29 | 2000-11-15 | 住友特殊金属株式会社 | Method for producing high silicon steel and silicon steel |
CN1528921A (en) * | 2003-09-25 | 2004-09-15 | 武汉理工大学 | High-silica silicon-steel sheet heat treatment and multiple cold-rolling method |
CN102658367A (en) * | 2012-05-16 | 2012-09-12 | 上海大学 | Method and device for preparing high-silicon silicon steel sheet in static magnetic field with powder sintering method |
CN106808159A (en) * | 2015-11-27 | 2017-06-09 | 安徽中龙节能科技有限公司 | A kind of preparation method of high-silicon silicon steel sheet |
-
2017
- 2017-12-18 CN CN201711369221.6A patent/CN107999763A/en not_active Withdrawn
Patent Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN1273611A (en) * | 1998-05-29 | 2000-11-15 | 住友特殊金属株式会社 | Method for producing high silicon steel and silicon steel |
JP2000192186A (en) * | 1998-12-25 | 2000-07-11 | Daido Steel Co Ltd | Manufacture of soft magnetic alloy sheet, and magnetic core member using this sheet |
CN1528921A (en) * | 2003-09-25 | 2004-09-15 | 武汉理工大学 | High-silica silicon-steel sheet heat treatment and multiple cold-rolling method |
CN102658367A (en) * | 2012-05-16 | 2012-09-12 | 上海大学 | Method and device for preparing high-silicon silicon steel sheet in static magnetic field with powder sintering method |
CN106808159A (en) * | 2015-11-27 | 2017-06-09 | 安徽中龙节能科技有限公司 | A kind of preparation method of high-silicon silicon steel sheet |
Non-Patent Citations (7)
Title |
---|
傅祖铸: "《有色金属板带材生产》", 1 April 2009, 中南大学出版社 * |
员文杰: "粉末轧制法制备高硅硅钢片的工艺及过程原理的研究", 《中国博士学位论文全文数据库工程科技Ⅰ辑》 * |
员文杰等: "粉末轧制法制备Fe-6.5%Si硅钢片的研究", 《粉末冶金技术》 * |
周勇: "铁、硅复合粉末的轧制成型与后续热处理", 《中国优秀博硕士学位论文全文数据库 (硕士) 工程科技Ⅰ辑》 * |
张翔: "粉末冶金法制备高硅硅钢片的轧制和热处理工艺研究", 《中国博士学位论文全文数据库 工程科技Ⅰ辑》 * |
李然: "粉末压延技术制备高硅铁硅合金", 《中国优秀博硕士学位论文全文数据库 (硕士) 工程科技Ⅰ辑》 * |
莱内尔: "《粉末冶金原理和应用》", 30 November 1989, 冶金工业出版社 * |
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