KR20190139094A - composition for thermistor - Google Patents

Abstract

The present invention relates to a composition for a thermistor and the thermistor using the same. According to the present invention, in a cubic spinel complex oxide consisting of Mn3O4 : 50-72mol%, NiO : 10-26mol%, CuO : 10-40mol% and CoO : 5-40mol%, Sc : 0.01-10mol% is substituted with at least one of Mn, Ni, Cu, and Co to form a chemical equilibrium (AB2O4).

Description

Composition for thermistor {composition for thermistor}

The present invention relates to a thermistor composition and thermistor using the same.

Thermistors are heat-sensitive semiconducting resistors and electronic components that use a property of changing the resistance of a material with temperature.

Such thermistors are classified into positive temperature coefficient thermistors (PTC), which increase resistance when temperature increases, and negative temperature coefficient thermistors (NTC), which decrease resistance when temperature rises.

The higher the B constant, the better the sensitivity to temperature changes. Since the B constant has a correlation with the resistivity, the higher the B constant, the higher the specific resistance.

The importance of developing a thermistor that is sensitive to high B constant and can be used even at low resistance is highlighted.

An object of the present invention is to provide a composition that can lower the specific resistance and improve the B constant value.

The present invention has been made to provide a composition for a thermistor of a novel composition design that can overcome the characteristic limitations of existing general-purpose thermistor materials, and to provide a thermistor using the same.

To this end, one object of the present invention is mol (mol), Mn 3 O 4: 50-72%, NiO: 10-26%, CuO: 10-40% and CoO: 5-40% SiO 2: 1-20% In the cubic spinel-based composite oxide made, the composition is achieved by providing a composition for thermistors having a chemical equilibrium (AB2O4) by replacing SC with 0.01 to 10% at least one of Mn, Ni, Cu, and Co. do.

The composition for thermistors according to the present invention may have a wide specific resistivity control and high B constant characteristics through a composition design for controlling Mn-Ni-Cu-Co castings at a predetermined ratio and substituting a small amount of Sc 2 O 3.

According to the present invention, it is possible to manufacture a low-resistance or high-resistance thermistor having a high B constant using the composition for thermistors, and improve the temperature sensing ability of these thermistors.

The present embodiment relates to a composition for a thermistor including a trace substituent Sc and an additive SiO 2 in the castability of the Mn-Ni-Cu-Co-based composite oxide.

That is, the composition for a thermistor of this embodiment is a composition in which a small amount of Sc is substituted for a Mn-Ni-Cu-Co-based cubic spinel-based composite oxide at least one of the metals contained in the composite oxide. With the additive SiO2.

Specifically, the composition for the thermistor of the present embodiment is mol (mol)%, Mn 3 O 4: 50-72%, NiO: 10-26%, CuO: 10-40% and CoO: 5-40% SiO 2: 1-20% In the cubic spinel-based composite oxide consisting of, SC is substituted by 0.01 to 10% at least one of Mn, Ni, Cu, and Co to have a chemical equilibrium (AB 2 O 4).

The composition for thermistors of the above composition is composed of 3d transition metals such as Mn, Ni, Cu, Co are castable to form a negative temperature coefficient (NTC) thermistor composition.

The composition for a thermistor having the above composition has a spinel structure chemically represented by AB 2 O 4, wherein some of the trivalent cations are occupied at the A-site and trivalent and divalent cations are occupied at the B-site. This corresponds to an intermediate mixed-spinel structure.

Hereinafter, the role and content of each component included in the thermistor composition of the present embodiment will be described.

[Mn]

In this embodiment, Mn is a main component of the thermistor composition, and serves as electron hopping to divalent or trivalent cations.

Such Mn is preferably added in an amount of 50 mol% to 72 mol% based on the total content of the composition for thermistor in the form of Mn3O4 oxide.

In this case, it is suitable to maintain a single crystal phase in the crystal structure of the cubic spinel structure, and the electron hopping action of the divalent, trivalent or tetravalent Mn cation can be sufficiently used on the stable crystal structure, which is advantageous for resistance control.

In the above, if the content of Mn 3 O 4 is less than 50 mol% relative to the total content of the composition for thermistor, it may cause oxygen deficiency to properly perform the role of thermistor material. On the other hand, when the content of Mn3O4 exceeds 72 mol% of the total content of the thermistor composition, Mn2O3, which is a secondary phase in crystal structure, may be generated to lower resistance and B constant.

On the other hand, throughout this specification, the B constant means a value calculated by the following equation (1), where T0 is 25 ℃, T was based on 85 ℃.

(Where B is thermistor constant, R is the resistance of temperature T, R0 is the resistance of temperature T0, T is the absolute temperature and T0 is any reference absolute temperature near room temperature)

[Cu]

In this embodiment, Cu mainly serves to control the sintered density.

Such Cu is in the form of CuO oxide, it is preferably added in an amount of 10 mol% to 40 mol% relative to the total content of the thermistor composition.

On the other hand, if the content of CuO is out of the above range, the sintered density control effect is insufficient to reduce the resistance and B constant.

[Ni, Co]

In this embodiment, Ni or Co is a 3d transition metal so that the electrons are balanced in the thermistor composition.

In other words, Ni or Co in the thermistor composition serves to maintain the equilibrium of the atomic molar ratio forming the cubic spinel structure.

Such Ni is preferably added in an amount of 20 mol% to 26 mol% based on the total content of the thermistor composition in the form of NiO oxide.

In addition, Co is in the form of CoO oxide, preferably added in an amount of 5 mol% to 40 mol% based on the total content of the thermistor composition.

In the present embodiment, the content of Ni or Co oxide is a factor that is determined depending on the content of Mn and Cu oxide, but can be freely adjusted within the above range as long as the equilibrium of the molar ratio of atoms in the thermistor composition is maintained.

However, when the content of CoO exceeds 40 mol% relative to the total content of the thermistor composition, the magnetic properties may be stronger than the electrical properties, resulting in deterioration of device characteristics due to signal interference or electromagnetic interference.

[Sc]

In this embodiment, Sc is a substitution component substituted at least one position of the metal contained in the Mn-Ni-Cu-Co-based cast product.

The purpose of substituting such Sc is to improve the B constant by easily controlling the thermistor resistance.

Specifically, Sc was substituted in this example. This is because the tetravalent cation electron valence is exhibited at 4f orbital, so that the electron hopping between atoms becomes good when substituted at the castable Mn, Ni, Cu, and Co sites, thereby promoting resistance control. When Sc is substituted, the composition for thermistor has a high B constant value when the resistance is well controlled.

At this time, if the content of Sc2O3 is less than 0.01 mol% relative to the total content of the thermistor composition, the B water purification improvement effect may be insignificant or insufficient. On the other hand, when the content of ScO2 exceeds 10 mol% relative to the total content of the thermistor composition, a secondary phase of the crystal structure may be generated, thereby lowering the resistance and the B constant characteristics.

[SiO2]

In this embodiment, SiO 2 is an additive added to improve thermal shock resistance and stability.

At this time, if the content of SiO2 is 16 mol% or more relative to the total content of the thermistor composition, the thermal shock resistance and stability improving effect may be insignificant or insufficient.

The thermistor composition of this embodiment having such a configuration can control the resistivity from several hundred Ωcm to several hundred kΩcm through a composition design that controls the Mn-Ni-Cu-Co cast product at a constant ratio and replaces a small amount of ScO2. , B constant could be increased to more than 3300K. This is due to the smoothing of electron hopping between atoms through the substitution of Sc metal to increase the resistance control effect.

As a result, the composition for thermistors of this embodiment has a specific resistance of 10 kΩcm to 70 kΩcm and a B25 / 85 constant of 3000K to 4700K, preferably 3700K or more.

The composition for thermistors of this embodiment is applicable to high resistance thermistor products having a resistivity of 10 kΩcm or more at a B25 / 85 constant of 3700K or more.

As such, when Mn, Ni, Cu and Co oxide raw materials are used as casting products and Mn-Ni-Cu-Co-based spinel oxide powders substituted with a small amount of Sc2O3 are used, the resistivity control and the B constant characteristics in a wide range are remarkable. Can be improved. In this case, the temperature sensing capability of the device can be further improved in the device manufactured using the specific resistance of the material and the B constant value.

Example

Hereinafter, the configuration and operation of the present invention through the preferred embodiment of the present invention will be described in more detail. However, this is presented as a preferred example of the present invention and in no sense can be construed as limiting the present invention.

Details that are not described herein will be omitted since those skilled in the art can sufficiently infer technically.

1. Preparation of Sample

Specimens 1-11 of NTC thermistor compositions according to Examples 1-5 were prepared with the compositions shown in Table 1.

Example 1

Thermistor raw material was weighed to the composition shown in Table 1. Then, the weighed raw materials were mixed and then calcined at 700 ° C. for 2 hours to obtain calcined powder. Thereafter, a PVA (Polyvinyl Alcohol) binder solution was added to the powder, and then pressed at a pressure of 611 kg / cm 2 to prepare a specimen for sintering of a disk type of 10 mm in diameter. Finally, the prepared specimen was sintered at 1200 ° C. to complete the final specimen.

division

Psalter
Chemical composition Main ingredient (mol%) Additive (mol%) Mn3O4 CuO CoO NiO SiO2 Sc2O3 Example 1 One 55.92 11.5 8 20 4.5 0.08

2. Property evaluation

After measuring the density of the specimens 1 to 3 according to Example 1 and the resistance of each specimen at 25 ℃ and 80 ℃, the specific resistance and B constant was calculated, the results are shown in Table 2.

division Temperature (℃) Resistance value (kΩ) Temperature (℃) Resistance value (kΩ) B constant (K) Resistivity
(kΩcm) sample 1 25 11.1 72 1.61 4223.327 40.408 sample 2 25 10.19 73 1.82 3700.225 35.852 sample 3 25 3.01 78 0.5 3542.689 16.348

Referring to Tables 1 and 2, Example 1 satisfying the thermistor composition range of the present invention satisfied the B constant 3500K to 4200K range characteristics.

In addition, in Examples 1 to 3, while the B constant is 3000K or more, it was confirmed that the specific resistance is controlled in the range of 16kΩcm to 40.5kΩcm.

Specifically, Examples 1 to 3 in which Sc is substituted for the Mn-Cu-Co-based thermistor composition, the B constant is 3700K band while the specific resistance is several tens of kΩcm, and thus it is applicable to thermistor products having a high B constant of 3700K or more. And it was found.

In conclusion, according to the present invention, it is possible to design a thermistor composition which is possible for product application at B constant 3000K or more, preferably 3500K or more.

Preferred embodiments of the present invention described above are disclosed for the purpose of illustration, and various substitutions, modifications, and changes within the scope without departing from the spirit of the present invention for those skilled in the art to which the present invention pertains. It will be possible, but such substitutions, changes and the like should be regarded as belonging to the following claims.

Claims (1)

In the mol%, in the cubic spinel-based composite oxide consisting of Mn 3 O 4: 50-72%, NiO: 10-26%, CuO: 10-40% and CoO: 5-40%, Mn, Ni , The composition for thermistors Sc is substituted with 0.01 to 10% at least one position of Cu and Co to form a chemical equilibrium (AB2O4).
Claim 2
The composition for a thermistor according to claim 1, wherein the composition for thermistors has a B25 / 85 integer of 3000K to 4700K.
Claim 3
The thermistor composition according to claim 2, wherein the composition for thermistor has a B25 / 85 integer of 4000K or more.
Claim 4
The composition for a thermistor according to claim 1, wherein the composition for thermistor has a specific resistance of 100 Ωcm to 200 kΩcm at 25 ° C.
Claim 5
The thermistor composition of claim 1, wherein the thermistor composition has negative temperature coefficient characteristics.
Claim 7
The composition for thermistor is Mn in the cubic spinel-based composite oxide consisting of mol%, Mn3O4: 50-72%, NiO: 10-26%, CuO: 10-40% and CoO: 5-40%. Thermistor having a composition for a thermistor which Sc is substituted with 0.01 to 10% at least one of Ni, Cu and Co to form a chemical equilibrium (AB 2 O 4).
Claim 8
The thermistor is a B25 / 85 constant 3000K to 3700K, thermistor having a specific resistance of 10kΩcm to 200kΩcm at 25 ℃.
Claim 9
The thermistor of claim 7, wherein the composition for thermistor has a negative temperature coefficient characteristic.
Claim 10
The method of claim 7, wherein
The thermistor is a temperature sensor.