KR101525216B1 - A hybrid reactor - Google Patents

Abstract

A hybrid reactor according to the present invention includes: a core portion having a plurality of core modules having magnetism; And a winding part surrounding the core part, wherein the core modules have mutually different magnetic materials.

Description

[0001] The present invention relates to a hybrid reactor,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a reactor, and more particularly, to a hybrid reactor constructed by mixing and assembling two or more types of cores having different block shapes.

In general, reactors are used not only for solar inverters, air conditioner inverters, but also for power converters required for the entire industry. The reactor is a part that converts electric energy into magnetic energy and stores it. It plays a role of smoothing the fluctuating current by using the property that the current flowing in the reactor does not change suddenly.

However, since the conventional reactor uses a core made of one kind of material, it has been inevitable to use it within a limited range in accordance with L-I characteristics (inductance and current correlation characteristics) and frequency loss characteristics of the material. In recent years, in order to solve the problem that handling power increases and size must be reduced in the renewable energy field, the operating frequency tends to be higher than 50 to 100 [kHz]. Therefore, in order to cope with a power conversion product having a high operating frequency, it is burdensome to use an expensive core material having a low core loss at a high frequency.

The present invention is directed to a hybrid reactor capable of meeting a large capacity and various functions of electric power products, having size and price competitiveness, and varying the inductance according to the load capacity.

A hybrid reactor for solving the above problems includes a core portion having a plurality of core modules having magnetism; And a winding part surrounding the core part, wherein the core modules have at least two or more different magnetic materials.

The core module in which the magnetic flux is generated in the winding portion, that is, the core module positioned at the winding portion of the winding uses a magnetic core having a relatively high frequency loss characteristic of a predetermined standard or more, That is, the portion where the winding is not wound, is characterized in that heat generated due to core loss is dispersed while achieving cost competitiveness by using the above-mentioned core having a relatively low cost, although the high frequency loss characteristic is not good.

The present invention is characterized in that the core modules having different magnetic materials are appropriately combined, the cross-sectional area of each core is adjusted to have a variable inductance according to the capacity, and the slope thereof is adjusted to improve the efficiency and control characteristics of the power converter.

The core module in which the winding is wound over the predetermined reference is characterized by using at least one of permalloy, sendust, amorphous, iron, silicon and iron alloy.

At least one of ferrite, iron, silicon, and an iron alloy is used as a core module in a portion where the winding is not wound below the predetermined standard.

And the core modules are used in combination in order to adjust the inductance saturation slope according to the magnitude of the input current.

According to the present invention, a reactor having an optimal price / performance ratio can be realized by using a core combining various magnetic materials.

Also, since the current saturation characteristics of the respective magnetic materials are different, it is possible to vary the inductance according to the severity of the load, thereby realizing a reactor having a competitive price and size.

In addition, when such a hybrid reactor is used in an inverter, it is possible to design an inverter optimized to increase the efficiency.

1 is a reference diagram of an embodiment for explaining a hybrid reactor according to the present invention.
2 is an exemplary graph for comparing LI characteristics according to the types of core modules.
3 is a reference graph illustrating a change in the current flowing in the reactor in accordance with the variation of the load (the magnitude of the output current) in the inverter using the hybrid reactor.
4 is a graph for comparing output characteristics of an inverter using a single core module and an inverter using a hybrid reactor.

Hereinafter, a hybrid reactor according to the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a reference diagram of an embodiment for explaining a hybrid reactor according to the present invention, and includes core parts 100 and 200 and a winding part 300.

The core portion has a plurality of core modules 100, 200 having magnetism. The core modules 100 and 200 have mutually different magnetic materials.

The magnetic material constituting each of the core modules 100 and 200 is implemented by adjusting the mixing ratio optimized for winding, frequency, and temperature conditions. In the present invention, a hybrid reactor is realized by combining two or more kinds of magnetic materials of the core modules 100 and 200 to construct a reactor.

The winding portion 300 includes a winding surrounding a portion of the core portions 100 and 200.

In the present invention, the core module located at the portion where the magnetic flux is generated in the winding portion 300 has a frequency characteristic higher than a predetermined standard, and the core module located in the path through which the magnetic flux of the winding portion passes do.

As shown in FIG. 1, the core module located at the portion where the magnetic flux is generated in the winding portion 300 is a core module corresponding to the identification symbol 100, and the core module located in the path through which the magnetic flux passes, Is a core module.

Here, when the frequency characteristic is above a certain standard, it means an expensive magnetic material having a good frequency loss characteristic, and when the frequency characteristic is below a certain standard, it means a magnetic material having a relatively low frequency loss characteristic.

For example, at least one of Permalloy, Sendust, Amorphous, iron, silicon and an iron alloy is used as a core module having a frequency characteristic of a predetermined standard or higher. Table 1 below is a table illustrating the types of magnetic materials constituting the core module whose frequency characteristics are equal to or higher than a certain standard and the power devices in which such core modules are used.

Reactor type Reactor magnetic material Power equipment used a Permalloy:
Fe-Ni Power Supply Unit (Small Size Coil) b Sendust:
Fe-Si-Al Power Supply Unit (Small Size Coil) c Amorphous:
Fe-Si-B Power Supply Unit (Small Size Coil) d Silicon and Iron Alloys:
Fe 3.5 [%] - Si Aircon / Power Inv.
UPS / Automotive e Pure Iron:
Fe Aircon / Power Inv.
UPS / Automotive f Silicon and Iron Alloys:
Fe 6.5 [%] - Si Power Inverter

Further, at least one of ferrite, iron, silicon, and an iron alloy is used as a core module whose frequency characteristics are below a certain standard.

The core units 100 and 200 use core modules for adjusting the inductance saturation gradient according to the magnitude of the input current.

FIG. 2 (a) shows the LI characteristics of a reactor composed of one type of core module, and FIG. 2 (b) shows the characteristics of two types of reactors The LI characteristics of the reactor consisting of the above core modules are shown.

The reactor functions as a filter that suppresses a rapidly varying current to obtain a desired current waveform. Therefore, the greater the inductance, the greater the suppression capability, and the fluctuation (ripple) of the current flowing through the reactor becomes smaller. Generally, when the current flowing through the reactor increases, the inductance is maintained to a certain degree according to the inherent permeability of the core module. However, when the current increases further, it is usually not saturated and falls rapidly. Even though the same inductance is maintained at no load, the saturation point increases with the increase of the current in proportion to the reactor capacity. Therefore, a large-capacity reactor is required to cope with the large current.

As shown in FIG. 2 (a), in the case of a reactor using one type of core module, the inductance is maintained at a constant current (for example, 6 [A]) for an increasing current, , The inductance is generally decreased rapidly. In order to control the inductance, the slope of the gap has been adjusted by forming a gap between the core modules. However, when the gap becomes large, various losses such as eddy current loss occur, and it is difficult to make the desired inductance slope with only the gap.

2B shows a case in which a reactor having two or more types of core modules having different permeabilities has a smooth gradient of inductance. In particular, when the current is higher than a constant current (for example, 6 [A]) The inductance does not drop sharply but gradually decreases. Thus, by properly combining the core modules, the inductance saturation slope can be adjusted.

Conventionally, it has been considered desirable to maintain the inductance value constant even if the current flowing through the reactor increases. However, due to the nature of the power converter using the reactor, the same inductance is not required depending on the output current. Especially in the case of inverters among power converters. The ripple current of the power converter is designed to be around 10% to 20% based on the rated output. Since the inductance of the reactor is kept constant, a ripple current of approximately the same magnitude as the rated output occurs under light load, A relatively large ripple current flows in comparison with the magnitude of the output current, which is a great burden to the control for maintaining stable output at light load. Furthermore, in order to maintain a constant inductance, it is necessary to keep the core cross-sectional area or the number of turns of the core, which implies a burden on the cost of raw materials.

3 is a reference graph illustrating current fluctuation according to a load (magnitude of an output current) in an inverter using a hybrid reactor. As shown in FIG. 3, it can be seen that the ripple current is relatively small due to the high inductance at the time of light load, and the current fluctuation is relatively low at the rated load (rated output current) due to the rated inductance It can be confirmed that it is large. Even if the ripple current increases somewhat at the rated output, it is still a small value in terms of the ratio to the rated current, so it does not follow a great deal of control. Therefore, the hybrid reactor according to the present invention reflects such inductance characteristics and can be designed optimally in terms of size, efficiency, and price.

4 is a graph for comparing output characteristics of an inverter using a single core module and an inverter using a hybrid reactor. Fig. 4 (a) shows the output voltage / current waveform of the inverter when a reactor designed only with a ferrite core module is used, and Fig. 4 (b) shows the output voltage / current waveform of the inverter when using a hybrid reactor combining ferrite and sentust core modules Voltage / current waveform.

The yellow waveform in Fig. 4 (a) and the yellow waveform in Fig. 4 (b) indicate the output voltage waveform output from the inverter. The blue waveform in Fig. 4 (a) and the green waveform in Fig. 4 (b) indicate output current waveforms output from the respective inverters. The green waveform in Fig. 4 (a) and the blue waveform in Fig. 4 (b) are ripple current waveforms flowing through the reactor.

Referring to the output current waveform of FIG. 4 (a), it can be seen that the ripple current is almost constant regardless of the current size. This is because the L value is constant in accordance with the current I in the L-I characteristic curve as shown in Fig. 2 (a). On the other hand, the output current waveform of FIG. 4 (b) shows that the ripple current is relatively small when the current size is small, and the ripple current is large when the current size is large. This is because, as shown in FIG. 2 (b), when the current becomes large in the L-I characteristic curve, the L value becomes low.

Although the hybrid reactor of the present invention has been described with reference to the embodiments shown in the drawings for the sake of understanding, the hybrid reactor is merely an example, and those skilled in the art can make various modifications and other equivalent embodiments I will understand the point. Accordingly, the true scope of the present invention should be determined by the appended claims.

100, 200: Core modules
300:

Claims (5)

A core portion having a plurality of core modules having magnetism; And
And a winding portion surrounding a portion of the core portion,
Wherein the core portion includes a core module positioned at a portion where magnetic flux is generated in the winding portion and a core module positioned in a path through which the magnetic flux passes,
Wherein the core modules have at least two or more different magnetic materials,
Wherein the core module located at a portion where the magnetic flux is generated in the winding portion uses a frequency characteristic of a predetermined standard or more and a core module located in a path through which the magnetic flux passes passes the magnetic core,
Wherein the core module is combined such that the inductance does not abruptly decrease but gradually decreases even when the current increases by a constant current or more. delete The method according to claim 1,
Wherein at least one of Permalloy, Sendust, Amorphous, iron, silicon and an iron alloy is used as the core module having the predetermined standard or more. The method according to claim 1,
Wherein at least one of ferrite, iron, silicon and an iron alloy is used as the core module below the predetermined standard. delete

Images