CN104091675A - Barium titanate-based rare earth ferromagnetic core material - Google Patents
Barium titanate-based rare earth ferromagnetic core material Download PDFInfo
- Publication number
- CN104091675A CN104091675A CN201410241596.4A CN201410241596A CN104091675A CN 104091675 A CN104091675 A CN 104091675A CN 201410241596 A CN201410241596 A CN 201410241596A CN 104091675 A CN104091675 A CN 104091675A
- Authority
- CN
- China
- Prior art keywords
- mol
- core material
- barium titanate
- rare earth
- barium
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Withdrawn
Links
Landscapes
- Soft Magnetic Materials (AREA)
- Hard Magnetic Materials (AREA)
Abstract
The invention discloses a barium titanate-based rare earth ferromagnetic core material which comprises a main material and an additive, wherein the main material comprises the components according to a mole ratio: 64-76.5 mol of Fe2O3, 25.5-30 mol of manganese oxide, 4-6.5 mol of zinc oxide and 2.5-4 mol of molybdenum trioxide; the additive comprises the components in percentage by weight of the ferromagnetic core material: 300-400 ppm of vanadium pentoxide, 600-700 ppm of zirconium dioxide and 800-1,000 ppm of a barium titanate-based rare earth composite magnetic powder body. The rare earth composite magnetic powder body added into the ferromagnetic core material disclosed by the invention is high in magnetic energy product and stable in magnetism; the mechanical property of the ferromagnetic core material can be obviously improved, and the porosity is reduced.
Description
Technical field
The present invention relates generally to oxidate magnetic material and manufactures field, relates in particular to a kind of barium phthalate base Rare-earth Iron core material.
Background technology
Along with the communication technology and the digitized development of electronic product; soft magnetic ferrite and element have been proposed to new requirement; high-performance high magnetic permeability magnetic core is widely used in each type telecommunications and information stock, as the fields such as common-mode filter, pulsactor, current transformer, earth leakage protective device, insulating transformer, signal and pulse transformer are widely applied.Telecommunications industry needs FERRITE CORE to have low core loss and high magnetic permeability now, and to meet microminiaturization and the high efficiency requirement of present electric equipment, existing magnetic core is difficult to meet above-mentioned requirements;
Its magnetic energy product of the permanent magnetic material that rare earth makes can reach 150 times of carbon steel, 3~5 times of aluminium barium titanate cobalt permanent magnetic material, 8~10 times of permanent-magnet ferrite, and temperature coefficient is low, magnetic stability, coercive force is up to 800 kilo-ampere/rice.Be mainly used in the magnetic system of low speed torque motor, actuating motor, transducer, magnetic bearing etc.Nd-Fe-Bo permanent magnet material is third generation rare earth permanent-magnetic material, and its remanent magnetism, coercive force and maximum magnetic energy product are higher than the former, non-friable, has good mechanical performance, and alloy density is low, is conducive to lightness, slimming, the small-sized and subminaturization of magnetic element.
Summary of the invention
The object of the invention is exactly the defect in order to make up prior art, and a kind of barium phthalate base Rare-earth Iron core material is provided.
The present invention is achieved by the following technical solutions:
A kind of barium phthalate base Rare-earth Iron core material, it comprises major ingredient and additive, described major ingredient comprises according to mol ratio: the zinc oxide of the Fe2O3 of 64-76.5 mol, the manganese oxide of 25.5-30 mol, 4-6.5 mol, the molybdenum trioxide of 2.5-4 mol; Additive comprises according to the weight ratio meter that accounts for described ferromagnetic core material: the barium phthalate base rare earth compounded magnetic conductive powder of the vanadic oxide of 300-400ppm, the zirconium dioxide of 600-700ppm, 800-1000ppm;
The preparation of described barium phthalate base rare earth compounded magnetic conductive powder comprises the following steps:
(1) preparation of barium titanate colloidal sol:
APES is joined in cyclohexane, after stirring, add pentaerythrite, 60-100 rev/min of dispersed with stirring 10-12 minute;
It is 60-100 μ m that barium titanate is ground to fineness, joins in 4-5 times of water, stirs;
Above-mentioned each raw material after treatment is mixed, and 500-600 rev/min of dispersed with stirring 10-12 minute, obtains described barium titanate emulsion;
(2) polyvinylpyrrolidone is joined in lanthanum chloride solution, at 60-80 DEG C, be uniformly mixed 10-20 minute, add ammonium bicarbonate aqueous solution, insulation 3-5h, adds above-mentioned barium titanate emulsion, is stirred to normal temperature, centrifugal dehydration, 200 DEG C of dry 30-40 minute of 100-, calcine 6-10 hour at 500-600 DEG C, obtain described rare earth compounded magnetic conductive powder;
The concentration of described lanthanum chloride solution is 0.8-2mol/L; The concentration of ammonium bicarbonate aqueous solution is that 20-30%, consumption are the 30-40% of lanthanum chloride solution weight;
Described polyvinylpyrrolidone and the mol ratio of lanthanum chloride are 1-2:1;
Described barium titanate and the mass ratio of lanthanum chloride are 40-60:1;
The mass ratio of described APES, cyclohexane, pentaerythrite, barium titanate is 1-2:30-50:2-3:100.
A preparation method for barium phthalate base Rare-earth Iron core material, comprises the following steps:
(1) above-mentioned major ingredient is sent into blending tank, 2500-3000 rev/min is stirred mixed 2-4 hour, sends into rotary furnace pre-burning, control 400 DEG C of temperature 300-, the pre-burning time is 2-4 hour, sends into grinding pot, adopt the alcohol water blend that abrasive media is 15-20%, being ground to fineness is 40-100 μ m;
(2) additive is sent into grinding pot, adopt the alcohol water blend that abrasive media is 15-20%, be wherein added with and be equivalent to the alum powder of weight of additive 1-2%, the polyurethanes of 0.4-1%, being ground to fineness is 40-50 μ m;
(3) above-mentioned each raw material after treatment is mixed, spraying is dry, is pressed into base, and sintering, obtains described barium phthalate base Rare-earth Iron core material.
Advantage of the present invention is:
Barium phthalate base rare earth compounded magnetic conductive powder good weatherability, magnetic energy product that ferromagnetic core material of the present invention adds are high, and magnetic stability can obviously improve the mechanical performance of ferromagnetic core material, reduces the porosity.
Embodiment
Embodiment 1
A kind of barium phthalate base Rare-earth Iron core material, is characterized in that it comprises major ingredient and additive, and described major ingredient comprises according to mol ratio: the zinc oxide of the Fe2O3 of 76.5 mol, the manganese oxide of 25.5 mol, 6.5 mol, the molybdenum trioxide of 2.5 mol; Additive comprises according to the weight ratio meter that accounts for described ferromagnetic core material: the barium phthalate base rare earth compounded magnetic conductive powder of the vanadic oxide of 300ppm, the zirconium dioxide of 700ppm, 1000ppm;
The preparation of described barium phthalate base rare earth compounded magnetic conductive powder comprises the following steps:
(1) preparation of barium titanate colloidal sol:
APES is joined in cyclohexane, after stirring, add pentaerythrite, 100 revs/min of dispersed with stirring 12 minutes;
It is 100 μ m that barium titanate is ground to fineness, joins in 4 times of water, stirs;
Above-mentioned each raw material after treatment is mixed, and 600 revs/min of dispersed with stirring 12 minutes, obtain described barium titanate emulsion;
(2) polyvinylpyrrolidone is joined in lanthanum chloride solution, at 80 DEG C, be uniformly mixed 20 minutes, add ammonium bicarbonate aqueous solution, insulation 3h, adds above-mentioned barium titanate colloidal sol, is stirred to normal temperature, centrifugal dehydration, 200 DEG C dry 40 minutes, calcine 10 hours at 500 DEG C, obtain described rare earth compounded magnetic conductive powder;
The concentration of described lanthanum chloride solution is 0.8mol/L; The concentration of ammonium bicarbonate aqueous solution is 30%, consumption is 40% of lanthanum chloride solution weight;
Described polyvinylpyrrolidone and the mol ratio of lanthanum chloride are 1:1;
Described barium titanate and the mass ratio of lanthanum chloride are 60:1;
The mass ratio of described APES, cyclohexane, pentaerythrite, barium titanate is 1:50:3:100.
A preparation method for barium phthalate base Rare-earth Iron core material, comprises the following steps:
(1) above-mentioned major ingredient is sent into blending tank, 3000 revs/min are stirred mixed 2 hours, send into rotary furnace pre-burning, control 400 DEG C of temperature, and the pre-burning time is 4 hours, sends into grinding pot, adopts the alcohol water blend that abrasive media is 20%, and being ground to fineness is 100 μ m;
(2) additive is sent into grinding pot, adopt the alcohol water blend that abrasive media is 20%, be wherein added with and be equivalent to the alum powder of weight of additive 1%, 0.4% polyurethanes, being ground to fineness is 50 μ m;
(3) above-mentioned each raw material after treatment is mixed, spraying is dry, is pressed into base, and sintering, obtains described barium phthalate base Rare-earth Iron core material.
Through detection, the basic mechanical design feature index that the product of above-described embodiment 1 gained reaches:
The saturation induction density of magnetic core of the present invention can reach 15000 Gausses, and saturation flux rate density is 480mT, and Curie temperature is higher than 240 DEG C, resistivity 6.6 Ω .m.
Claims (2)
1. a barium phthalate base Rare-earth Iron core material, it is characterized in that it comprises major ingredient and additive, described major ingredient comprises according to mol ratio: the zinc oxide of the Fe2O3 of 64-76.5 mol, the manganese oxide of 25.5-30 mol, 4-6.5 mol, the molybdenum trioxide of 2.5-4 mol; Additive comprises according to the weight ratio meter that accounts for described ferromagnetic core material: the barium phthalate base rare earth compounded magnetic conductive powder of the vanadic oxide of 300-400ppm, the zirconium dioxide of 600-700ppm, 800-1000ppm;
The preparation of described barium phthalate base rare earth compounded magnetic conductive powder comprises the following steps:
(1) preparation of barium titanate colloidal sol:
APES is joined in cyclohexane, after stirring, add pentaerythrite, 60-100 rev/min of dispersed with stirring 10-12 minute;
It is 60-100 μ m that barium titanate is ground to fineness, joins in 4-5 times of water, stirs;
Above-mentioned each raw material after treatment is mixed, and 500-600 rev/min of dispersed with stirring 10-12 minute, obtains described barium titanate emulsion;
(2) polyvinylpyrrolidone is joined in lanthanum chloride solution, at 60-80 DEG C, be uniformly mixed 10-20 minute, add ammonium bicarbonate aqueous solution, insulation 3-5h, adds above-mentioned barium titanate colloidal sol, is stirred to normal temperature, centrifugal dehydration, 200 DEG C of dry 30-40 minute of 100-, calcine 6-10 hour at 500-600 DEG C, obtain described rare earth compounded magnetic conductive powder;
The concentration of described lanthanum chloride solution is 0.8-2mol/L; The concentration of ammonium bicarbonate aqueous solution is that 20-30%, consumption are the 30-40% of lanthanum chloride solution weight;
Described polyvinylpyrrolidone and the mol ratio of lanthanum chloride are 1-2:1;
Described barium titanate and the mass ratio of lanthanum chloride are 40-60:1;
The mass ratio of described APES, cyclohexane, pentaerythrite, barium titanate is 1-2:30-50:2-3:100.
2. a preparation method for barium phthalate base Rare-earth Iron core material as claimed in claim 1, is characterized in that comprising the following steps:
(1) above-mentioned major ingredient is sent into blending tank, 2500-3000 rev/min is stirred mixed 2-4 hour, sends into rotary furnace pre-burning, control 400 DEG C of temperature 300-, the pre-burning time is 2-4 hour, sends into grinding pot, adopt the alcohol water blend that abrasive media is 15-20%, being ground to fineness is 60-100 μ m;
(2) additive is sent into grinding pot, adopt the alcohol water blend that abrasive media is 15-20%, be wherein added with and be equivalent to the alum powder of weight of additive 1-2%, the polyurethanes of 0.4-1%, being ground to fineness is 40-50 μ m;
(3) above-mentioned each raw material after treatment is mixed, spraying is dry, is pressed into base, and sintering, obtains described barium phthalate base Rare-earth Iron core material.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201410241596.4A CN104091675A (en) | 2014-06-03 | 2014-06-03 | Barium titanate-based rare earth ferromagnetic core material |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201410241596.4A CN104091675A (en) | 2014-06-03 | 2014-06-03 | Barium titanate-based rare earth ferromagnetic core material |
Publications (1)
Publication Number | Publication Date |
---|---|
CN104091675A true CN104091675A (en) | 2014-10-08 |
Family
ID=51639383
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201410241596.4A Withdrawn CN104091675A (en) | 2014-06-03 | 2014-06-03 | Barium titanate-based rare earth ferromagnetic core material |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN104091675A (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN111747745A (en) * | 2020-05-20 | 2020-10-09 | 四会市康荣新材料有限公司 | Dielectric powder for 5G filter and preparation method thereof |
CN114907106A (en) * | 2022-03-30 | 2022-08-16 | 电子科技大学 | Preparation method of high-mechanical-strength wide-temperature wide-band MnZn power ferrite |
-
2014
- 2014-06-03 CN CN201410241596.4A patent/CN104091675A/en not_active Withdrawn
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN111747745A (en) * | 2020-05-20 | 2020-10-09 | 四会市康荣新材料有限公司 | Dielectric powder for 5G filter and preparation method thereof |
CN114907106A (en) * | 2022-03-30 | 2022-08-16 | 电子科技大学 | Preparation method of high-mechanical-strength wide-temperature wide-band MnZn power ferrite |
CN114907106B (en) * | 2022-03-30 | 2023-06-02 | 电子科技大学 | Preparation method of high-mechanical-strength wide-temperature broadband MnZn power ferrite |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN104045337B (en) | A kind of vanadium based ferrite core material for transformer | |
CN104091671A (en) | Titanium-based rare earth ferromagnetic core material | |
CN104051106B (en) | A kind of boron oxide based ferrite core material for transformer | |
CN104051108B (en) | A kind of nickel oxide-base ferrite core material for transformer | |
CN104051109B (en) | A kind of molybdenio ferrite core material for transformator | |
CN104091675A (en) | Barium titanate-based rare earth ferromagnetic core material | |
CN104051112A (en) | Manganese-based ferrite core material used for transformer | |
CN104051113B (en) | A kind of Ni-based ferrite core material for transformator | |
CN104361969A (en) | Cerium-based ferrite core material for transformer | |
CN104078186A (en) | Zinc-base ferrite core material | |
CN104045334B (en) | A kind of rare-earth ferrite core material for transformer | |
CN104051115B (en) | A kind of niobium based ferrite core material for transformer | |
CN104124027B (en) | A kind of cobalt silicon base lanthanon ferromagnetic core material | |
CN104051110A (en) | Cobalt-based ferrite core materials | |
CN104058739B (en) | Tantalum-based ferrite magnetic core material used for transformer | |
CN104124025A (en) | Silicon-based rare earth ferromagnetic core material | |
CN104269240A (en) | Tungsten ferrite core material for transformer | |
CN104051114B (en) | A kind of transformer chromium based ferrite core material | |
CN104091677A (en) | Iron silicon-based rare earth ferromagnetic core material | |
CN104134507A (en) | Vanadium-based rare earth ferromagnetic core material | |
CN104051107A (en) | Titanium-based ferrite core material used for transformer | |
CN104124023A (en) | Lithium-based rare earth ferromagnetic core material | |
CN104091674A (en) | Rare earth ferromagnetic core material | |
CN104124024A (en) | Magnesium-based rare earth ferromagnetic core material | |
CN104078185A (en) | Cobaltous oxide based ferrite core material |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
C06 | Publication | ||
PB01 | Publication | ||
SE01 | Entry into force of request for substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
WW01 | Invention patent application withdrawn after publication |
Application publication date: 20141008 |
|
WW01 | Invention patent application withdrawn after publication |