JP2010184845A - Mn-Zn-Ni-BASED FERRITE - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a ferrite wherein the minimum value of iron loss lies in the temperature range of 120-140°C, the saturation magnetic flux density at 130°C is high, and the absolute value of iron loss is small. <P>SOLUTION: An Mn-Zn-Ni-based ferrite comprises a basic component composition comprising 52.5-54.0 mol% Fe<SB>2</SB>O<SB>3</SB>, 5.0-10.0 mol% ZnO, 0.01-0.16 mol% NiO and the balance MnO and unavoidable impurities, and contains as additive components, based on the ferrite, 50-500 mass ppm SiO<SB>2</SB>, 200-2,000 mass ppm CaO, 50-500 mass ppm Nb<SB>2</SB>O<SB>5</SB>, and 10-100 ppm mass BeO, wherein the saturation magnetic flux density as measured at 130°C and a magnetizing force of 1,200 A/m is 400 mT or higher, and the iron loss at 130°C is 400 kW/m<SP>3</SP>or smaller. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a Mn—Zn—Ni-based ferrite with low energy iron loss, and particularly exhibits high saturation magnetic flux density and low iron loss in a temperature range higher than 100 ° C. suitable for use in a magnetic core such as a transformer for a switching power supply. The present invention relates to a Mn—Zn—Ni based ferrite.

  Oxide magnetic materials are generally collectively referred to as “ferrites”. This ferrite is classified into hard magnetic materials such as Ba ferrite and Sr ferrite and soft magnetic materials such as Mn—Zn ferrite and Ni—Zn ferrite. Among these, the soft magnetic material is a material that is sufficiently magnetized even with a small magnetic field, and is therefore used in a wide range of fields such as power supply equipment, communication equipment, measurement control equipment, magnetic recording, and computers. Properties required for this soft magnetic material include a low coercive force, a high magnetic permeability, a high saturation magnetic flux density, and a low iron loss.

  In addition to the oxide ferrite, the soft magnetic material includes a metal material. Although this metal-based soft magnetic material has a feature that the saturation magnetic flux density is higher than that of an oxide-based material, it has a small electric resistance, so when used in a high frequency region, it is caused by an eddy current generated. There is a problem that iron loss becomes large. Therefore, in recent years when the frequency of use has been increased due to the demand for downsizing and higher density of electronic devices, it is not possible to use metallic magnetic materials for switching power supplies used in a high frequency band of about 100 kHz. Almost impossible.

  Against this background, Mn—Zn-based ferrite with low iron loss (less heat generation) has been conventionally used as a magnetic core material for power transformers used in high frequency bands. However, this material also has a low electrical resistivity of about 0.01 to 0.05 Ω · m, so by further increasing the electrical resistance and reducing eddy current loss, the overall iron loss is reduced and the amount of heat generated The development of a magnetic material that suppresses this problem has been desired.

For such requirements, for example, Patent Document 1, the Mn-Zn ferrite, by segregating at the grain boundaries of the oxide such as SiO ₂ or CaO as an auxiliary component added trace, grain boundary resistance And a technique for suppressing heat generation by increasing the resistivity to several Ω · m or more is disclosed.

  In addition, when ferrite is used for power transformers, consideration must be given to the temperature (operating temperature) when using a device incorporating ferrite and the temperature rise due to heat generation due to the iron loss of the ferrite itself. is there. For example, if the temperature at which the iron loss of ferrite is at a minimum is near room temperature, the core loss increases as the temperature of the magnetic core rises due to heat generation, and the heat generation further increases accordingly. This is because there is a risk of causing a so-called thermal runaway.

  Conventionally, the operating temperature of the transformer has been around 50 to 70 ° C. Therefore, in order to avoid the risk of thermal runaway, the conventional ferrite has a temperature at which the iron loss becomes a minimum of about 100 ° C., the temperature coefficient of the iron loss near room temperature is negative, and the iron loss decreases with increasing temperature. The material design was made. However, in the case of a material having a minimum iron loss temperature of about 100 ° C., if the temperature rises to 100 ° C. or higher for some reason, the iron loss increases and there is a risk of causing thermal runaway.

  In particular, recently, in order to cope with the downsizing of electronic devices, the loading density of electronic components has been increased, and the temperature rise due to heat generation during use tends to be larger. As a result, recent electronic components are sometimes used in a high temperature range of 120 to 140 ° C. exceeding 100 ° C., which has not been assumed so far. Therefore, it has been studied that the design minimum iron loss temperature is 120 ° C. or more, for example, about 120 to 140 ° C. from around 100 ° C. so far. To that end, the temperature dependence of the iron loss of the ferrite core must also correspond to these design changes.

  Even if the minimum temperature of the core loss is set to 120 to 140 ° C so as to operate in a high temperature range, the saturation magnetic flux density decreases as the temperature rises. It becomes impossible to maintain the designed value at the temperature. For example, the saturation magnetic flux density at 100 ° C. of a conventional low-loss transformer material is about 390 to 400 mT for a general-purpose material, but decreases to about 320 to 350 mT at a temperature of 130 ° C. Accordingly, it is necessary to change the design such as increasing the shape of the core, which increases the manufacturing cost. Therefore, a ferrite material used in a high temperature range of about 120 to 140 ° C. is required to have a saturation magnetic flux density in the same temperature range of 400 mT or more, which is the same as the value at 100 ° C.

By the way, one of the factors governing the core loss of ferrite, and magnetic anisotropy constant K _1. The iron loss changes with the temperature change of the magnetic anisotropy constant K ₁ and becomes minimum at a temperature where K ₁ = 0. Therefore, in order to change the temperature dependence of the iron loss, it is necessary to change the temperature dependence (iron loss temperature coefficient) of the magnetic anisotropy constant K ₁ and its absolute value.

The magnetic anisotropy constant K ₁ is almost determined by the type of elements constituting the spinel compound, which is the main phase of ferrite. In the case of Mn—Zn ferrite, the temperature dependence is reduced by introducing Co ions. The absolute value of the iron loss temperature coefficient can be reduced (see, for example, Non-Patent Documents 1 and 2). Thereby, it is possible to obtain a material having a small iron loss in the vicinity of 100 ° C. and a relatively small iron loss in the temperature range before and after that. However, adding Co causes another problem that the iron loss minimum temperature decreases, or the iron loss temperature coefficient and the minimum temperature fluctuate greatly due to slight fluctuations in the firing temperature and oxygen concentration in the firing atmosphere. Occurs.

For example, Patent Document 2 discloses that a Mn—Zn—Co-based ferrite containing Fe ₂ O ₃ , ZnO, and MnO as main components and having CoO added in an amount of 0.01 mol% or more and less than 0.5 mol% has a wider temperature than conventional. It is disclosed that K ₁ = 0 in the range, and high magnetic permeability and low loss can be realized in a wide temperature range. However, the ferrite described in Patent Document 2 has a high temperature of 120 to 140 ° C. in recent years because the minimum temperature of the core loss has shifted to the low temperature side as shown in FIG. At the operating temperature, it cannot be said that the risk of thermal runaway due to accelerated temperature rise has been eliminated.

Japanese Patent Publication No. 36-002283 Japanese Patent Publication No. 04-033755

“The effect of cobalt subsidiaries on some properties of manganese zinc ferrites”, A. D. Giles and F.M. F. Westendorp: J.M. Phys. D: Appl. Phys, 9 (1976) 2117 “Low-Loss Power Ferrites for Frequency up to 500 kHz”, T.M. G. W. Stijintjes and J.M. J. et al. Roelofsma; Adv. Cer. 16 (1986) 493

  As described above, none of the prior art ferrites has a temperature at which the minimum value of power loss is 100 ° C. or less, and no iron loss has a minimum value in a high temperature range of 120 to 140 ° C. . In addition, the saturation magnetic flux density decreases as the iron loss minimum temperature increases to 100 ° C or higher, so even if thermal runaway at 100 ° C or higher is suppressed, the critical loss value increases, so the heat generation problem is still solved. Is in a situation that is not.

  Therefore, the present invention has been made in view of the situation in which recent electronic components have come to be used in a high temperature range that has not been envisaged so far, and its purpose is higher than 100 ° C. The object is to provide a ferrite having a minimum value of iron loss in a temperature range of 120 to 140 ° C., a high saturation magnetic flux density at 130 ° C., and a small absolute value of iron loss.

In order to solve the above-mentioned problems of the prior art, the inventors have determined that the contents of MnO, ZnO and Fe ₂ O ₃ which are the basic components of the Mn—Zn ferrite are reduced to the core loss of the final core and its minimum temperature. In addition to investigating the effects, various studies have been conducted on the effects of various metal oxides added to improve the characteristics on the saturation magnetic flux density and iron loss in the temperature range of 100 ° C. or higher. As a result, in addition to the basic components of MnO, ZnO and Fe ₂ O ₃ , NiO is further added as a basic component to optimize their composition range, and furthermore, SiO ₂ , CaO and Nb ₂ O ₅ are appropriate as additive components By adding the amount, the minimum temperature of the iron loss can be shifted to the high temperature side and the saturation magnetic flux density can be increased, and by adding an appropriate amount of BeO as an additional component to this, 120 can be more stably added. The inventors have found that a ferrite having a high saturation magnetic flux density and a low loss can be obtained in a high temperature range of ℃ or higher, and completed the present invention.

That is, the present invention includes Fe ₂ O ₃ : 52.5 to 54.0 mol%, ZnO: 5.0 to 10.0 mol%, NiO: 0.01 to 0.16 mol%, and the balance from MnO and inevitable impurities. In the Mn—Zn—Ni-based ferrite having the basic component composition, the additive components are SiO ₂ : 50 to 500 massppm, CaO: 200 to 2000 massppm, Nb ₂ O ₅ : 50 to 500 massppm, and BeO: 10 to the ferrite. A Mn—Zn—Ni-based ferrite containing 100 mass ppm and having a saturation magnetic flux density of 400 mT or more when measured at 130 ° C. and a magnetizing force of 1200 A / m.

The Mn—Zn—Ni ferrite of the present invention has a maximum magnetic flux density of 200 mT, a minimum iron loss temperature at a frequency of 100 kHz in a temperature range of 120 to 140 ° C., and an iron loss at 130 ° C. of 400 kW / m ³ or less. It is characterized by.

Further, the Mn—Zn—Ni ferrite of the present invention has a maximum magnetic flux density of 200 mT, a minimum iron loss temperature at a frequency of 100 kHz in a temperature range of 120 to 140 ° C., and an iron loss at 130 ° C. of 350 kW / m ³ or less. It is characterized by being.

  According to the present invention, it is possible to provide a Mn—Zn—Ni ferrite having a high saturation magnetic flux density and low iron loss even in a high temperature range of 100 ° C. or higher and 120 to 140 ° C. Therefore, this Mn—Zn—Ni-based ferrite can be suitably used for a transformer core material such as a switching power supply whose operating temperature is increased.

The basic component composition of the Mn—Zn—Ni ferrite according to the present invention will be described.
From the viewpoint of optimizing the saturation magnetic flux density, the Curie temperature, and the minimum iron loss temperature, the basic component composition of the Mn—Zn—Ni ferrite of the present invention is Fe ₂ O ₃ : 52.5 to 54.0 mol%, ZnO : 5.0-10.0 mol%, NiO: 0.01-0.16 mol%, the balance being MnO.

Fe ₂ O _3: 52.5~54.0mol%
Fe ₂ O ₃ needs to be contained in an amount of 52.5 mol% or more in order to make the minimum iron loss temperature 120 ° C. or higher and further increase the saturation magnetic flux density at 130 ° C. However, if the content exceeds 54.0 mol%, the iron loss near room temperature becomes too large, so the upper limit is made 54.0 mol%. Preferably, it is the range of 53.0-53.5 mol%.

ZnO: 5.0-10.0 mol%
As described above, the magnetic properties required for soft magnetic ferrite include a high saturation magnetic flux density, a high Curie temperature, a low iron loss, and a high magnetic permeability. Of these, the saturation magnetic flux density and the Curie temperature are almost determined by the ratio of the basic components MnO, ZnO, and Fe ₂ O ₃ , and the ZnO content increases in a region where the amount of ZnO is relatively small. At the same time, the saturation magnetic flux density at room temperature increases monotonously, but the Curie temperature decreases. Therefore, in order to increase the saturation magnetic flux density in a high temperature range of about 130 ° C., it is necessary to increase the Curie temperature.

  Therefore, in the present invention, the ZnO content is determined from the balance between the Curie temperature and the saturation magnetic flux density. That is, when ZnO is less than 5.0 mol%, the Curie temperature is high but the saturation magnetic flux density is low, the iron loss value is high, and the magnetic permeability is low. On the other hand, when there is more ZnO than 10.0 mol%, the saturation magnetic flux density in 130 degreeC will fall to 400 mT or less. Therefore, in order to set the saturation magnetic flux density at 130 ° C. to 400 mT or more and the minimum iron loss temperature to 120 to 140 ° C., ZnO is set to a range of 5.0 to 10.0 mol%. In order to realize a higher saturation magnetic flux density and a Curie point, it is preferable to make ZnO in a range of 6.0 to 9.0 mol%.

NiO: 0.01-0.16 mol%
NiO constitutes the spinel phase of Mn—Zn ferrite, and is an effective component for realizing high saturation magnetic flux density and low loss by affecting magnetic anisotropy together with ZnO and MnO. That is, when the iron loss minimum temperature is set to 120 ° C. or higher and the saturation magnetic flux density at 130 ° C. is increased, when the composition of Fe ₂ O ₃ and ZnO is within the above range, the absolute value of the core loss is larger than the other composition ranges. Inevitably, it is necessary to add NiO as a basic component to suppress the increase in core loss. Addition of 0.01 mol% or more is necessary for NiO to exhibit the above effects in the composition range of Fe ₂ O ₃ and ZnO. On the other hand, if it exceeds 0.16 mol%, the iron loss minimum temperature is in the range of 120 to 140 ° C. and low loss cannot be realized. Accordingly, NiO is in the range of 0.01 to 0.16 mol%. Preferably, it is the range of 0.05-0.12 mol%.

MnO: Remaining Basic Component The ferrite of the present invention is a quaternary system of Fe ₂ O ₃ —ZnO—MnO—NiO, and the remaining basic component other than the Fe ₂ O ₃ , ZnO, and NiO is MnO.

The Mn—Zn—Ni ferrite of the present invention needs to contain the following additive components in addition to the above basic components. Fe ₂ O ₃ , ZnO, MnO and NiO, which are basic components of the ferrite of the present invention, form a spinel structure, and SiO ₂ , CaO, Ta ₂ O ₅ , ZrO ₂ , Nb that do not form a spinel on the spinel structure. By adding a small amount and an appropriate amount of additive components such as ₂ O ₅ and V ₂ O _{5, a} high-performance Mn—Zn—Ni-based ferrite material with little iron loss can be obtained. In the ferrite of the present invention, it has been found that a remarkable effect can be obtained by adding SiO ₂ , CaO and Nb ₂ O ₅ in the following ranges among the above-mentioned additive components.

SiO _2: 50~500massppm
SiO ₂ contributes to reducing iron loss by forming a high resistance phase at the grain boundary together with CaO. However, if the amount of SiO ₂ added is less than 50 massppm, the effect is small. On the other hand, if it exceeds 500 massppm, abnormal grain growth may occur during sintering, which may significantly increase iron loss. Thus, SiO ₂ is in the range of 50～500Massppm. The range of 50 to 300 massppm is preferable for stably realizing low loss.

CaO: 200-2000 massppm
When CaO coexists with SiO _2, it forms a high resistance phase at the grain boundary and contributes to lower iron loss. However, if the amount of CaO added is less than 200 massppm, the effect is small, while if it exceeds 2000 massppm, the iron loss increases conversely. Therefore, the addition amount of CaO is added in the range of 200 to 2000 massppm. In order to realize low loss more stably, the range of 200 to 1500 mass ppm is preferable.

Nb ₂ O _5: 50~500massppm
Nb ₂ O ₅ effectively contributes to an increase in specific resistance in the presence of SiO ₂ and CaO. However, if the content is less than 50 massppm, the effect of addition is poor, whereas if it exceeds 500 massppm, the iron loss is reversed. Increase. Thus, _Nb 2 _{O 5} is added in the range of 50～500Massppm. In order to obtain a lower loss, the range of 50 to 300 mass ppm is preferable.

BeO: 10-100 massppm
In the Mn—Zn—Ni based ferrite of the present invention, the composition of the basic components Fe ₂ O ₃ , ZnO, MnO and NiO is set within an appropriate range, and further, SiO ₂ , CaO and Nb ₂ O ₅ are added to the above appropriate values. It is necessary to add in a complex range. However, in the present invention, in order to more stably realize a high saturation density and a low iron loss in a high temperature range of 100 ° C. or higher, an appropriate amount of BeO is added as an additional component in addition to the above. Newly found that is effective. Although the mechanism by which the magnetic properties of the final sintered body are improved by the addition of BeO has not yet been clearly clarified, BeO is an oxide having a high specific resistance and low dielectric constant and dielectric loss. It is considered that this has a positive influence on the properties of the final sintered body, particularly the iron loss and permeability in a high temperature range of 100 ° C. or higher. If the addition amount of BeO is less than 10 massppm, the above effect cannot be obtained sufficiently. On the other hand, if it is added more than 100 massppm, it causes abnormal grain growth and causes a significant increase in iron loss. Add in the range of ~ 100 massppm. In order to surely prevent the occurrence of abnormal grain growth, it is preferable to add in the range of 10 to 50 massppm.

Next, a method for producing Mn—Zn—Ni ferrite according to the present invention will be described.
In the Mn—Zn—Ni ferrite of the present invention, first, the powder raw materials of Fe ₂ O ₃ , ZnO, MnO and NiO were weighed so that the basic component composition had a predetermined ratio defined by the present invention, and these were sufficiently mixed. After calcining, the calcined powder obtained is pulverized. Next, the above-mentioned calcined powder is added with a small amount of additive components such as SiO ₂ , CaO, Nb ₂ O ₅ and BeO so as to have a predetermined ratio defined by the present invention, and further pulverized. In this pulverization operation, it is necessary to homogenize sufficiently so that the concentration of the added component is not biased. Thereafter, an organic binder such as polyvinyl alcohol is added to the powder of the pulverized calcined powder, granulated, formed into a predetermined shape by applying pressure, and then fired under appropriate conditions to obtain a sintered body. .

The Mn—Zn—Ni ferrite of the present invention thus obtained has a minimum iron loss in a high temperature range of 120 to 140 ° C., which is impossible with the conventional Mn—Zn ferrite, and at 130 ° C. A ferrite having extremely excellent magnetic properties with a saturation magnetic flux density of 400 mT and an iron loss of 400 kW / m ³ or less is obtained.

The ferrite raw materials are mixed so that the basic components of the final sintered body (ferrite) have the compositions shown in Table 1-1 and Table 1-2, and calcined at 930 ° C. for 3 hours. In addition, BeO, SiO ₂ , CaO and Nb ₂ O ₅ in the amounts shown in Table 1-1 and Table 1-2 were added as additive components, and pulverization was performed for 10 hours using a ball mill. Thereafter, it was molded into a ring shape having an outer diameter of 31 mm, an inner diameter of 19 mm, and a height of 7 mm. Firing was performed for 3 hours. In this case, the rate of temperature increase from 500 ° C. to 1300 ° C. was 650 ° C./hr.
Next, the fired ring-shaped sample obtained as described above was subjected to winding of 5 turns on the primary side and 5 turns on the secondary side, and was excited at a frequency of 100 kHz and a magnetic flux density of 200 mT using an AC BH loop tracer. The iron loss was measured in a temperature range of 25 to 140 ° C. In addition, the saturation magnetic flux density at 1200 A / m at 130 ° C. was also measured.

The results of the above measurements are shown together in Table 1-1 and Table 1-2. Here, No. in Table 1-1. Examples 1 to 24 are invention examples suitable for the component composition of the present invention, and No. 1 in Table 1-1 and Table 1-2. Examples 25-61 show comparative examples deviating from the component composition of the present invention. From these tables, the basic composition of Fe ₂ O ₃ , ZnO, MnO and NiO and the composition of additive components of SiO ₂ , CaO and Nb ₂ O ₅ are controlled within an appropriate range, and further BeO is 10 to 100 massppm. The ferrite of the added invention example has a minimum magnetic loss temperature in a temperature range of 120 to 140 ° C. when measured at a maximum magnetic flux density of 200 mT and a frequency of 100 kHz under any conditions, and a saturation magnetic flux density at 130 ° C. Is 400 mT or more, and the iron loss at 130 ° C. is 400 kW / m ³ or less, and further shows excellent characteristics of 350 kW / m ³ or less. From the above results, it was confirmed that according to the present invention, a Mn—Zn—Ni ferrite exhibiting a low loss at a high saturation magnetic flux density even at a high temperature of 100 ° C. or higher was obtained.

  Since the ferrite of the present invention has characteristics of high saturation magnetic flux density and low iron loss in a high temperature range of 100 ° C. or higher, various power transformer cores and chokes for automobiles whose operating temperature is higher than that of normal electronic devices. It can be suitably used for a coil or the like.

Claims (3)

Fe ₂ O ₃ : 52.5 to 54.0 mol%, ZnO: 5.0 to 10.0 mol%, NiO: 0.01 to 0.16 mol%, the balance having a basic component composition consisting of MnO and inevitable impurities In the Mn—Zn—Ni-based ferrite, the additive contains SiO ₂ : 50 to 500 massppm, CaO: 200 to 2000 massppm, Nb ₂ O ₅ : 50 to 500 massppm, and BeO: 10 to 100 massppm with respect to the ferrite, 130 A Mn—Zn—Ni-based ferrite having a saturation magnetic flux density of 400 mT or more as measured at ° C. and a magnetizing force of 1200 A / m. 2. The Mn—Zn according to claim 1, wherein an iron loss minimum temperature at a maximum magnetic flux density of 200 mT and a frequency of 100 kHz is in a temperature range of 120 to 140 ° C., and an iron loss at 130 ° C. is 400 kW / m ³ or less. -Ni-based ferrite. 2. The Mn—Zn according to claim 1, wherein an iron loss minimum temperature at a maximum magnetic flux density of 200 mT and a frequency of 100 kHz is in a temperature range of 120 to 140 ° C., and an iron loss at 130 ° C. is 350 kW / m ³ or less. -Ni-based ferrite.