Patent Application
20240067568
The present application belongs to the field of magnetic materials for microwave communication, and relates to a two-component microwave ferrite material, a preparation method therefor and an application thereof.
Microwave ferrite devices occupy an important position in microwave technology and have wide applications in the fields of aerospace, satellite communication, electronic countermeasures, mobile communication and medical treatment. As the core of the devices, microwave ferrite materials are largely used in microwave ferrite circulators and isolators and implement technical processing in terms of isolation of microwave transmission in microwave systems.
With the rapid development of microwave technology, the systems have increasingly urgent requirements on the miniaturization of components. A ferrite component has a much larger volume than other components, so the task of miniaturizing and lightweight ferrite component is particularly important.
A circulator works in two types of magnetic field regions: a high field region and a low field region. Working in the low field region means that a working internal field of a ferrite is below a resonance field at such a working frequency, where the resonance field is determined by Hr=ω/γ, the working internal field is Hi<Hr, a normalization internal field is expressed as σ=Hi/Hr. During working in a low field, σ<<1, the ferrite works substantially in a zero field (generally σ=0-0.2), and when σ is increased, μe<0 enters an abnormal mode. A circulator working in the low field is generally applicable to a high frequency band typically having a frequency of 1 GHz or above. Both a high field and the low field can be used in S and L wavebands. At a higher frequency, the circulator is not suitable for working in the high field because magnetic saturation is not easily reached due to too high a magnetizing field, especially in a waveguide system. It is also difficult to work in the low field at too low a frequency due to the increased zero field loss. The circulator design of a low-field circulator relating high field has the characteristics of an ultra-wideband, a small applied magnetic field and a required low saturation of ferrite.
Some patent documents have already been provided on a microwave ferrite material and a preparation method therefor. For example, CN102584200A discloses a microwave ferrite material with an ultra-low loss and a small linewidth and preparation thereof. The material has a chemical formula of Y3−2x−yCa2x+yFe5−x−y−zVxZryAlzO12. A preparation method includes calculating and weighing raw materials according to stoichiometry, vibratory ball-milling, pre-sintering, vibratory grinding for coarse pulverization, sand grinding for fine pulverization, spray granulating, press molding and sintering. This technical solution can be used in the fields of microwave communication and magnetic materials. This method discloses that the microwave ferrite material has a ferromagnetic resonance linewidth ΔH≤1.27 KA/m and a dielectric loss tgδc≤0.5×10−4 and provides the microwave ferrite material with an ultra-low loss and a small linewidth. A relatively high pre-sintering temperature and a relatively high sintering temperature are required in the preparation process, which is unfavorable for production and environmental protection.
CN103833347A discloses a microwave ferrite material with a small linewidth and a high Curie temperature and a preparation method therefor. The material has a chemical formula of Y3-xCaxSnxMnyFe5-x-y-zO12. The preparation method includes calculating and weighing raw materials according tostoichiometry, primary wet ball milling, pre-sintering, secondary wet ball milling, dry granulating, press molding and sintering. The microwave ferrite material obtained by this technical solution has a relatively small resonance linewidth and a relatively high Curie temperature.
CN111285673A discloses a microwave ferrite material with a high dielectric constant, a preparation method and a microwave communication device. The material has a chemical formula of Bi1.25Ca0.25+2xY1.5−2xZr0.25AlxMnyFe4.75−x−y. The preparation method includes calculating and weighing raw materials according to stoichiometry, wet ball milling and mixing, drying and sieving, pre-sintering, wet ball milling for fine pulverization, spray granulating, press molding and sintering. The microwave ferrite material obtained by this technical solution has a high dielectric constant.
The above patents provide microwave ferrite materials having different characteristics, but which have relatively high saturation magnetic moments and are unsuitable for working in the low field. Therefore, it is necessary to further improve the performance of a microwave ferrite material. It has already become a tendency to provide a microwave ferrite material having a low loss, a low saturation magnetic moment, a small linewidth and a high Curie temperature.
An object of the present application is to provide a two-component microwave ferrite material, a preparation method therefor and an application thereof. The two-component microwave ferrite material provided in the present application has the characteristics of a small linewidth, a high Curie temperature, a low saturation magnetic moment and a low loss, thereby greatly improving the stability and reliability of the microwave ferrite material.
To achieve the object, the present application adopts the technical solutions described below.
In a first aspect, the present application provides a two-component microwave ferrite material, where raw materials for preparing the two-component microwave ferrite material include a first microwave ferrite material and a second microwave ferrite material.
The first microwave ferrite material is Y(3−2a−c−d−e)Ca(2a+c+d+e)Fe(5−a−b−c−d−e)VaAlbZrcSndMneO12, where a+b=0.5;
The second microwave ferrite material is Gd(3−2A−C−D)Ca(2A+C+D)Fe(5−A−B−C−D−E)VAAlBGeCInDTiEO12, where A+B=0.4;
Optionally, a mass ratio of the first microwave ferrite material to the second microwave ferrite material is (1-3):(1-3), for example, the mass ratio may be 1:1, 1:2, 1:3, 2:3, 3:2 or 3:1, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
A pure yttrium iron garnet ferrite has a relatively low power carrying capability, a relatively large ferromagnetic resonance linewidth and a relatively large dielectric loss, requires a relatively high sintering temperature, and is relatively simple in performance. In the present application, the replacement of part of octahedral Fe3+ with Zr3+ can reduce the magnetocrystalline anisotropy constant so that the ferromagnetic resonance linewidth decreases. However, Zr3+ cannot be too much, and too much Zr3+ will cause the ferromagnetic resonance linewidth to rapidly increase. The replacement of part of Fe3+ with V5+ can reduce saturation magnetization intensity and maintain a relatively high Curie temperature. Ca2+ and V5+ are substances with low melting points, and the doping of Ca2+ and V5+ can reduce the sintering temperature. The replacement of part of Fe3+ with a small amount of Mn2+ can reduce the ferromagnetic resonance linewidth and dielectric loss of the material. The replacement of V3+ with Gd3+ ions can improve a temperature coefficient of Ms, thus maintaining a relatively high Curie temperature. In the present application, the composition of the microwave ferrite material is adjusted so that the microwave ferrite material having a relatively low saturation magnetization intensity 4πMs, a relatively small ferromagnetic resonance linewidth ΔH, a relatively low dielectric loss tgδe and a relatively high Curie temperature Tc is obtained through the combination of electromagnetic characteristics of various elements.
In a second aspect, the present application provides a preparation method for the two-component microwave ferrite according to the first aspect. The method includes the following steps:
Optionally, the wet ball milling in step (1) includes mixing raw materials, grinding balls and a dispersion medium at a mass ratio of 1:(4-7.5):(0.6-2.5) and performing wet ball milling, for example, the mass ratio may be 1:4:0.6, 1:5:0.8, 1:6:1.2, 1:7:1.5, 1:7.5:2, 1:6.5:1.5, 1:4.5:2.5 or 1:5.5:2.5, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the wet ball milling in step (1) is performed at a rotational speed of 20-80 r/min, for example, the rotational speed may be 20 r/min, 30 r/min, 40 r/min, 50 r/min, 60 r/min, 70 r/min or 80 r/min, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the wet ball milling in step (1) is performed for 10-30 h, for example, the time may be 10 h, 15 h, 20 h, 25 h or 30 h, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the grinding balls include zirconium balls or steel balls.
Optionally, the grinding balls include large-diameter grinding balls and small-diameter grinding balls.
Optionally, a mass ratio of the large-diameter grinding balls to the small-diameter grinding balls is (0.8-3):1, for example, the mass ratio may be 0.8:1, 1:1, 1.2:1, 1.4:1, 1.6:1, 1.8:1, 2:1, 2.2:1, 2.4:1, 2.6:1, 2.8:1 or 3:1, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the large-diameter grinding balls have a diameter of 5-10 mm, for example, the diameter may be 5 mm, 6 mm, 7 mm, 8 mm, 9 mm or 10 mm, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable; and the small-diameter grinding balls have a diameter of 1-4 mm, for example, the diameter may be 1 mm, 2 mm, 3 mm or 4 mm, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the dispersion medium includes any one or a combination of at least two of deionized water, alcohol, acetone, n-propanol or aqueous ammonia.
Optionally, the ball-milled material has particle size ranges of D50=0.005-2 μm and D90=0.05-4 μm, for example, the particle size ranges may include D50=0.005 μm, 0.01 μm, 0.05 μm, 0.1 μm, 0.5 μm, 1 μm, 1.5 μm or 2 μm, and D90=0.05 μm, 0.1 μm, 0.5 μm, 1 μm, 1.5 μm, 2 μm, 3 μm or 4 μm, but are not limited to the numerical values listed, and other unlisted numerical values within the numerical ranges are also applicable.
Optionally, the drying in step (2) is performed at 100-250° C., for example, the temperature may be 100° C., 120° C., 150° C., 180° C., 200° C., 220° C. or 250° C., but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the drying in step (2) ends when a moisture content decreases to 0.01-10%, for example, the moisture content may be 0.01%, 0.1%, 1%, 3%, 5%, 7%, 9% or 10%, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, a sieve for the sieving in step (2) has a size of 30-100 mesh, for example, the mesh size may be 30, 40, 50, 60, 70, 80, 90 or 100, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the granulating in step (2) includes mixing the sieved ball-milled material with a binder uniformly and sieving under pressure to obtain the granulated particles.
Optionally, the binder includes an aqueous solution of polyvinyl alcohol.
Optionally, the solution of polyvinyl alcohol has a concentration of 5-20 wt %, for example, the concentration may be 5 wt %, 10 wt %, 15 wt % or 20 wt %, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, a mass of the solution of polyvinyl alcohol is 5-10% of a mass of powder, for example, the percentage may be 5%, 6%, 7%, 8%, 9% or 10%, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the sieving is performed under a pressure of 300-1200 kg/cm2, for example, the pressure may be 300 kg/cm2, 500 kg/cm2, 700 kg/cm2, 900 kg/cm2, 1100 kg/cm2 or 1200 kg/cm2, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, a sieve for the sieving has a size of 30-100 mesh, for example, the mesh size may be 30, 40, 50, 60, 70, 80, 90 or 100, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the molding in step (3) includes placing the granulated particles in step (2) into a mold and pressing the particles into a green body in a specified shape.
Optionally, the green body has a molding density of 3.0-4.0 g/cm3, for example, the molding density may be 3.0 g/cm3, 3.2 g/cm3, 3.4 g/cm3, 3.6 g/cm3, 3.8 g/cm3 or 4.0 g/cm3, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the sintering in step (3) is performed at 1200-1500° C., for example, the temperature may be 1200° C., 1250° C., 1300° C., 1350° C., 1400° C., 1450° C., 1480° C. or 1500° C., but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, a heat preservation time for the sintering is 5-30 h, for example, the heat preservation time may be 5 h, 6 h, 8 h, 10 h, 12 h, 14 h, 16 h, 18 h, 20 h, 22 h, 24 h, 26 h, 28 h or 30 h. but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, a heating rate of the sintering is 0.4-5° C./min, for example, the heating rate may be 0.4° C./min, 1° C./min, 1.5° C./min, 2° C./min, 2.5° C./min, 3° C./min, 3.5° C./min, 4° C./min, 4.5° C./min or 5.5° C./min, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, during the sintering, oxygen introduction begins at 1-6 h before heat preservation ends, for example, the time may be 1 h, 2 h, 3 h, 4 h, 5 h or 6 h, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, during the sintering, oxygen introduction ends at 100-500° C. lower than the sintering temperature, for example, the temperature may be 100° C. lower than the sintering temperature, 300° C. lower than the sintering temperature or 500° C. lower than the sintering temperature, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, a preparation method for the first microwave ferrite material in step (1) includes:
The first microwave ferrite material is Y(3−2a−c−d−e)Ca(2a+c+d+e)Fe(5−a−b−c−d−e)VaAlbZrcSndMneO12, where 0≤a≤0.6, 0≤b≤0.6, 0≤c≤0.7, 0≤d≤0.7, 0≤e≤0.7, and a+b=0.5.
Optionally, the raw materials for preparing the first microwave ferrite material in step (a) are Y2O3, CaCO3, Fe2O3, V2O5, Al2O3, ZrO2, SnO2 and MnCO3, respectively.
Optionally, the wet ball milling in step (a) includes mixing the raw materials, grinding balls, a dispersion medium and a dispersant at a mass ratio of 1:(4-7.5):(0.6-2.5):(0.003-0.01) and performing wet ball milling, for example, the mass ratio may be 1:4:0.6:0.003, 1:5:0.8:0.004, 1:6:1.2:0.005, 1:7:1.5:0.006, 1:7.5:2:0.007, 1:5:1.5:0.008, 1:6:2.5:0.009 or 1:6.5:2.5:0.01, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the grinding balls in step (a) include zirconium balls.
Optionally, the grinding balls in step (a) include large-diameter grinding balls and small-diameter grinding balls.
Optionally, a mass ratio of the large-diameter grinding balls to the small-diameter grinding balls in step (a) is (0.8-3):1, for example, the mass ratio may be 0.8:1, 1:1, 1.2:1, 1.4:1, 1.6:1, 1.8:1, 2:1, 2.2:1, 2.4:1, 2.6:1, 2.8:1 or 3:1, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the large-diameter grinding balls in step (a) have a diameter of 5-10 mm, for example, the diameter may be 5 mm, 6 mm, 7 mm, 8 mm, 9 mm or 10 mm, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable; and the small-diameter grinding balls in step (a) have a diameter of 1-4 mm, for example, the diameter may be 1 mm, 2 mm, 3 mm or 4 mm, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the dispersion medium in step (a) includes any one or a combination of at least two of deionized water, alcohol, acetone, n-propanol or aqueous ammonia.
Optionally, the dispersant in step (a) includes ammonium citrate and/or aqueous ammonia.
Optionally, the wet ball milling in step (a) is performed at a rotational speed of 20-80 r/min, for example, the rotational speed may be 20 r/min, 30 r/min, 40 r/min, 50 r/min, 60 r/min, 70 r/min or 80 r/min, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the wet ball milling in step (a) is performed for 10-30 h, for example, the time may be 10 h, 15 h, 20 h, 25 h or 30 h, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the ball-milled material has particle size ranges of D50=0.005-2 μm and D90=0.05-4 μm, for example, the particle size ranges may include D50=0.005 μm, 0.01 μm, 0.05 μm, 0.1 μm, 0.5 μm, 1 μm, 1.5 μm or 2 μm and D90=0.05 μm, 0.1 μm, 0.5 μm, 1 μm, 1.5 μm, 2 μm, 3 μm or 4 μm, but are not limited to the numerical values listed, and other unlisted numerical values within the numerical ranges are also applicable.
Optionally, the drying in step (b) is performed at 100-250° C., for example, the temperature may be 100° C., 120° C., 150° C., 180° C., 200° C., 220° C. or 250° C., but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the drying in step (b) ends when a moisture content decreases to 0.01-10%, for example, the moisture content may be 0.01%, 0.1%, 1%, 3%, 5%, 7%, 9% or 10%, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, a sieve for the sieving in step (b) has a size of 30-100 mesh, for example, the mesh size may be 30, 40, 50, 60, 70, 80, 90 or 100, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the pre-sintering in step (b) is performed at 1100-1350° C., for example, the temperature may be 1100° C., 1120° C., 1160° C., 1200° C., 1240° C., 1280° C., 1320° C. or 1350° C., but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, a heat preservation time for the pre-sintering in step (b) is 6-15 h, for example, the heat preservation time may be 6 h, 8 h, 10 h, 12 h, 14 h or 14 h, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, a heating rate for the pre-sintering in step (b) is 0.3-4° C./min, for example, the heating rate may be 0.3° C./min, 1.5° C./min, 2.5° C./min or 4° C./min, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, during the pre-sintering in step (b), oxygen introduction begins when the pre-sintering temperature is reached.
Optionally, during the pre-sintering in step (b), oxygen introduction ends at 100-500° C. lower than the pre-sintering temperature, for example, the temperature may be 100° C. lower than the pre-sintering temperature, 300° C. lower than the pre-sintering temperature or 500° C. lower than the pre-sintering temperature, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
In the present application, the pre-sintering can reduce the non-uniformity of the chemical activity of the dried ball-milled material and can also reduce the shrinkage rate and deformation of the subsequent sintered product.
Optionally, a preparation method for the second microwave ferrite material in step (1) includes:
The second microwave ferrite material is Gd(3−2A−C−D)Ca(2A+c+D)Fe(5−A−B−C−D−E)VAAlBGeCInDTiEO12, where 0≤A≤0.5, 0≤B≤0.5, 0≤C≤0.7, 0≤D≤0.7, 0≤E≤0.7, and A+B=0.4.
Optionally, the raw materials for preparing the second microwave ferrite material in step (I) are Gd2O3, CaCO3, Fe2O3, V2O5, Al2O5, GeO2, InO2 and TiO2, respectively.
Optionally, the wet ball milling in step (I) includes mixing the raw materials, grinding balls, a dispersion medium and a dispersant at a mass ratio of 1:(4-7.5):(0.6-2.5):(0.003-0.01) and performing wet ball milling, for example, the mass ratio may be 1:4:0.6:0.008, 1:5:0.8:0.009, 1:6:1.2:0.01, 1:7:1.5:0.003, 1:7.5:2:0.004, 1:1.5:1.5:0.005, 1:1:2.5:0.006 or 1:5:2.5:0.007, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the grinding balls in step (I) include zirconium balls.
Optionally, the grinding balls in step (I) include large-diameter grinding balls and small-diameter grinding balls.
Optionally, a mass ratio of the large-diameter grinding balls to the small-diameter grinding balls in step (I) is (0.8-3):1, for example, the mass ratio may be 0.8:1, 1:1, 1.2:1, 1.4:1, 1.6:1, 1.8:1, 2:1, 2.2:1, 2.4:1, 2.6:1, 2.8:1 or 3:1, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the large-diameter grinding balls in step (I) have a diameter of 5-10 mm, for example, the diameter may be 5 mm, 6 mm, 7 mm, 8 mm, 9 mm or 10 mm, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable; and the small-diameter grinding balls in step (I) have a diameter of 1-4 mm, for example, the diameter may be 1 mm, 2 mm, 3 mm or 4 mm, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the dispersion medium in step (I) includes any one or a combination of at least two of deionized water, alcohol, acetone, n-propanol or aqueous ammonia.
Optionally, the dispersant in step (I) includes ammonium citrate and/or aqueous ammonia.
Optionally, the wet ball milling in step (I) is performed at a rotational speed of 20-80 r/min, for example, the rotational speed may be 20 r/min, 30 r/min, 40 r/min, 50 r/min, 60 r/min, 70 r/min or 80 r/min, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the wet ball milling in step (I) is performed for 10-30 h, for example, the time may be 10 h, 15 h, 20 h, 25 h or 30 h, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the ball-milled material has particle size ranges of D50=0.005-2 μm and D90=0.05-4 μm, for example, the particle size ranges may include D50=0.005 μm, 0.01 μm, 0.05 μm, 0.1 μm, 0.5 μm, 1 μm, 1.5 μm or 2 μm and D90=0.05 μm, 0.1 μm, 0.5 μm, 1 μm, 1.5 μm, 2 μm, 3 μm or 4 μm, but are not limited to the numerical values listed, and other unlisted numerical values within the numerical ranges are also applicable.
Optionally, the drying in step (II) is performed at 100-250° C., for example, the temperature may be 100° C., 120° C., 150° C., 180° C., 200° C., 220° C. or 250° C., but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the drying in step (II) ends when a moisture content decreases to 0.01-10%, for example, the moisture content may be 0.01%, 0.1%, 1%, 3%, 5%, 7%, 9% or 10%, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, a sieve for the sieving in step (II) has a size of 30-100 mesh, for example, the mesh size may be 30, 40, 50, 60, 70, 80, 90 or 100, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, the pre-sintering in step (b) is performed at 1100-1400° C., for example, the temperature may be 1100° C., 1140° C., 1180° C., 1220° C., 1260° C., 1300° C., 1340° C., 1380° C. or 1400° C., but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, a heat preservation time for the pre-sintering in step (II) is 8-20 h, for example, the heat preservation time may be 8 h, 10 h, 12 h, 14 h, 16 h, 18 h or 20 h, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, a heating rate for the pre-sintering in step (II) is 0.3-4° C./min, for example, the heating rate may be 0.3° C./min, 2° C./min, 3° C./min or 4° C./min, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
Optionally, during the pre-sintering in step (II), oxygen introduction begins when the pre-sintering temperature is reached.
Optionally, during the pre-sintering in step (II), oxygen introduction ends at 100-500° C. lower than the pre-sintering temperature, for example, the temperature may be 100° C. lower than the pre-sintering temperature, 300° C. lower than the pre-sintering temperature or 500° C. lower than the pre-sintering temperature, but is not limited to the numerical values listed, and other unlisted numerical values within the numerical range are also applicable.
As an optional technical solution of the method of the present application, the method includes the following steps:
A preparation method for the first microwave ferrite material in step (1) includes:
A preparation method for the second microwave ferrite material in step (1) includes:
Any numerical range in the present application includes not only the listed point values but also any unlisted point values within the numerical range. Due to the limitation of space and the consideration of simplicity, specific point values included in the range are not exhaustively listed in the present application.
Compared with the existing art, the present application has the beneficial effects described below.
After tests, the two-component microwave ferrite provided in the present application has a ferromagnetic resonance linewidth ΔH≤18 Oe, a saturation magnetic moment 4πMs≤1260 Gs, a dielectric loss tgδe≤5.4×10−4, and a Curie temperature Tc≥260° C. Therefore, the material of the present application has a relatively small resonance linewidth, a relatively low saturation magnetic moment, a relatively low dielectric loss and a relatively high Curie temperature, greatly improving the stability and reliability of the microwave ferrite material, thereby expanding the application range of a two-component microwave ferrite.
Technical solutions of the present application are further described below through specific examples. Those skilled in the art are to understand that the examples described herein are used to facilitate the understanding of the present application and are not to be construed as specific limitations to the present application.
This example provides a preparation method for a two-component microwave ferrite material, where the two-component microwave ferrite includes a first microwave ferrite material and a second microwave ferrite material.
The first microwave ferrite material is Y(3−2a−c−d−e)Ca(2a+c+d+e)Fe(5−a−b−c−d−e)VaAlbZrcSndMneO12, where a=0.35, b=0.15, c=0.2, d=0.1, and e=0.04.
The second microwave ferrite material is Gd(3−2A−C−D)Ca(2A+C+D)Fe(5−A−B−C−D−E)VAAlBGeCInDTiEO12, where A=0.35, B=0.05, C=0.1, D=0.1, and E=0.05.
The preparation method for the two-component microwave ferrite material includes the steps described below.
A preparation method for the first microwave ferrite material in step (1) includes the steps described below.
A preparation method for the second microwave ferrite material in step (1) includes the steps described below.
The magnetic properties measured after the obtained sample was ground are shown in Table 1.
This example provides a preparation method for a two-component microwave ferrite material, where the two-component microwave ferrite includes a first microwave ferrite material and a second microwave ferrite material.
The first microwave ferrite material is Y(3−2a−c−d−e)Ca(2a+c+d+e)Fe(5−a−b−c−d−e)VaAlbZrcIndMneO12, where a=0.25, b=0.25, c=0.1, d=0.2, and e=0.05.
The second microwave ferrite material is Gd(3−2A−C−D)Ca(2A+C+D)Fe(5−A−B−C−D−E)VAAlBGeCInDTiEO12, where A=0.25, B=0.05, C=0.2, D=0.3, and E=0.1.
The preparation method for the two-component microwave ferrite material includes the steps described below.
A preparation method for the first microwave ferrite material in step (1) includes the steps described below.
A preparation method for the second microwave ferrite material in step (1) includes the steps described below.
The magnetic properties measured after the obtained sample was ground are shown in Table 1.
This example provides a preparation method for a two-component microwave ferrite material, where the two-component microwave ferrite includes a first microwave ferrite material and a second microwave ferrite material.
The first microwave ferrite material is Y(3−2a−c−d−e)Ca(2a+c+d+e)Fe(5−a−b−c−d−e)VaAlbZrcSndMneO12, where a=0.3, b=0.2, c=0.05, d=0.25, and e=0.1.
The second microwave ferrite material is Gd(3−2A−C-D)Ca(2A+c+D)Fe(5−A−B−C−D−E)VAAlBGeCInDTiEO12, where A=0.1, B=0.3, C=0.05, D=0.5, and E=0.2.
The preparation method for the two-component microwave ferrite material includes the steps described below.
A preparation method for the first microwave ferrite material in step (1) includes the steps described below.
A preparation method for the second microwave ferrite material in step (1) includes the steps described below.
The magnetic properties measured after the obtained sample was ground are shown in the table below.
This example provides a preparation method for a two-component microwave ferrite material, where the two-component microwave ferrite includes a first microwave ferrite material and a second microwave ferrite material.
The first microwave ferrite material is Y(3−2a−c−d−e)Ca(2a+c+d+e)Fe(5−a−b−c−d−e)VaAlbZrcSndMneO12, where a=0.4, b=0.1, c=0.35, d=0.05, and e=0.5.
The second microwave ferrite material is Gd(3−2A−C−D)Ca(2A+C+D)Fe(5−A−B−C−D−E)VAAlBGeCInDTiEO12, where A=0.15, B=0.25, C=0.4, D=0.2, and E=0.4.
The preparation method for the two-component microwave ferrite material includes the steps described below.
A preparation method for the first microwave ferrite material in step (1) includes the steps described below.
A preparation method for the second microwave ferrite material in step (1) includes the steps described below.
The magnetic properties measured after the obtained sample was ground are shown in Table 1.
This example provides a preparation method for a two-component microwave ferrite material, where the two-component microwave ferrite includes a first microwave ferrite material and a second microwave ferrite material.
The first microwave ferrite material is Y(3−2a−c−d−e)Ca(2a+c+d+e)Fe(5−a−b−c−d−e)VaAlbZrcSndMneO12, where a=0.25, b=0.25, c=0.7, d=0.1, and e=0.35.
The second microwave ferrite material is Gd(3−2A−C−D)Ca(2A+C+D)Fe(5−A−B−C−D−E)VAAlBGeCInDTiEO12, where A=0.05, B=0.35, C=0.3, D=0.45, and E=0.3.
The preparation method for the two-component microwave ferrite material includes the steps described below.
A preparation method for the first microwave ferrite material in step (1) includes the steps described below.
A preparation method for the second microwave ferrite material in step (1) includes the steps described below.
The magnetic properties measured after the obtained sample was ground are shown in Table 1.
This example provides a preparation method for a two-component microwave ferrite material, where the two-component microwave ferrite includes a first microwave ferrite material and a second microwave ferrite material.
The preparation method in this example was the same as that in Example 1 except that in step (1), the first microwave ferrite material and the second microwave ferrite material were mixed uniformly at a mass ratio of 3:1 rather than 1:1.
The magnetic properties measured after the obtained sample was ground are shown in Table 1.
This example provides a preparation method for a two-component microwave ferrite material, where the two-component microwave ferrite includes a first microwave ferrite material and a second microwave ferrite material.
The preparation method in this example was the same as that in Example 1 except that in step (1), the first microwave ferrite material and the second microwave ferrite material were mixed uniformly at a mass ratio of 3:2 rather than 1:1.
The magnetic properties measured after the obtained sample was ground are shown in Table 1.
This example provides a preparation method for a two-component microwave ferrite material, where the two-component microwave ferrite includes a first microwave ferrite material and a second microwave ferrite material.
The preparation method in this example was the same as that in Example 1 except that in step (1), the first microwave ferrite material and the second microwave ferrite material were mixed uniformly at a mass ratio of 1:2 rather than 1:1.
The magnetic properties measured after the obtained sample was ground are shown in Table 1.
According to an ion substitution mechanism, this comparative example provides a microwave ferrite material: Y1.5Ca1.5Fe3.9V0.6Al0.2Sn0.3.
A preparation method for the microwave ferrite material includes the steps described below.
The magnetic properties measured after the obtained sample was ground are shown in Table 1.
According to an ion substitution mechanism, this comparative example provides a microwave ferrite material: Y2.65Ca0.35Fe4.6Sn0.35Mn0.05.
A preparation method for the microwave ferrite material includes the steps described below.
The magnetic properties measured after the obtained sample was ground are shown in Table 1.
According to an ion substitution mechanism, this comparative example provides a microwave ferrite material: Y2.6Ca0.4Fe4.2Al0.4Zr0.4.
A preparation method for the microwave ferrite material includes the steps described below.
The magnetic properties measured after the obtained sample was ground are shown in Table 1.
According to an ion substitution mechanism, this comparative example provides a microwave ferrite material: Y1.85Ca1.15Fe4.1V0.2Al0.05Sn0.2Zr0.35Mn0.1Ge0.2.
A preparation method for the microwave ferrite material includes the steps described below.
The magnetic properties measured after the obtained sample was ground are shown in Table 1.
According to an ion substitution mechanism, this comparative example provides a microwave ferrite material: Y2.3Ca0.7Fe4.1Sn0.4Zr0.3Mn0.2Ti0.05.
A preparation method for the microwave ferrite material includes the steps described below.
The magnetic properties measured after the obtained sample was ground are shown in Table 1.
The magnetic performance parameters of the microwave ferrites obtained in the examples and comparative examples are shown in Table 1.
As can be seen from Table 1, the two-component microwave ferrite provided in the present application has a ferromagnetic resonance linewidth ΔH≤18 Oe, a saturation magnetic moment 4πMs≤1260 Gs, a dielectric loss tgδe≤2×10−4, and a Curie temperature Tc≥260° C. As can be seen from the analysis of Comparative Examples 1 to 5, a one-component microwave ferrite material has a relatively large ferromagnetic resonance linewidth, a relatively high dielectric loss and a relatively low Curie temperature, thus greatly affecting the stability and reliability of the microwave ferrite material and affecting the use of a microwave communication device.
To sum up, after tests, the two-component microwave ferrite provided in the present application has a ferromagnetic resonance linewidth ΔH≤18 Oe, a saturation magnetic moment 4πMs≤1260 Gs, a dielectric loss tgδe≤2×10−4, and a Curie temperature Tc≥260° C. Therefore, the material of the present application has a relatively small resonance linewidth, a relatively low saturation magnetic moment, a relatively low dielectric loss and a relatively high Curie temperature, thereby greatly improving the stability and reliability of the microwave ferrite material and expanding the application range of a two-component microwave ferrite.
The objects, technical solutions and beneficial effects of the present application are described in more detail through the preceding specific examples. It is to be understood that the above are only specific examples of the present application and are not intended to limit the present application.
| Number | Date | Country | Kind |
|---|---|---|---|
| 202110436445.4 | Apr 2021 | CN | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/CN2021/103496 | 6/30/2021 | WO |
