The present invention relates to a transformer.
In a commercial AC transmission and distribution system, a transformer is used. Just near a consumer's house, a pole transformer is used which transforms, for example, 6600 V (50 Hz or 60 Hz) to 200 V (see NON PATENT LITERATURE 1). Such a pole transformer has a thick coil as a conductive wire wound around an iron core, and therefore has a considerable weight. For example, a pole transformer with a diameter of 40 cm and a height of 80 cm has a weight of about 200 kg, including an insulating oil and a case.
On the other hand, for realizing a smart grid which is a next-generation power system, studies of an SST (Solid-State Transformer) are being conducted. For the SST, a high-frequency transformer is used (for example, see NON PATENT LITERATURE 2).
A conventional pole transformer is heavy, and therefore is not easy to handle. In addition, an attachment space that is large enough to contain the outer dimension of the transformer is needed on the pole.
On the other hand, a high-frequency transformer cannot avoid an influence of a parasitic capacitance, and has a difficulty in designing.
Considering such conventional problems, an object of the present invention is to provide an innovative next-generation transformer with a small size and a light weight, which does not need a coil, an iron core, and the like for magnetic coupling, electromagnetic induction, or mutual inductance as used in a conventional transformer.
The present invention is a transformer provided between a power supply, and a load with a resistance value R, the transformer including a two-terminal pair circuit composed of n-number of reactance elements that are mutually connected, where n is a natural number equal to or greater than 4, wherein, with respect to any value of the resistance value R of the load, an input impedance Zin of the two-terminal pair circuit has a real number component of k·R, where k is a constant, and an imaginary number component of 0.
It is noted that a reactance element is an inductor having an inductive reactance or a capacitor having a capacitive reactance.
Using the transformer of the present invention as a power transformer makes it unnecessary to use a conventional transformer including a coil, an iron core, and the like. Therefore, it becomes possible to realize drastic size reduction and weight reduction of a transformer, and thereby realize cost reduction.
Summary of embodiments of the present invention includes at least the following.
(1) A transformer is provided between a power supply, and a load with a resistance value R, and includes a two-terminal pair circuit composed of n-number of reactance elements that are mutually connected, where n is a natural number equal to or greater than 4. With respect to any value of the resistance value R of the load, an input impedance Zin of the two-terminal pair circuit has a real number component of k·R, where k is a constant, and an imaginary number component of 0.
The transformer as described above can obtain output voltage proportional to input voltage regardless of the resistance value R of the load. That is, the transformer that transforms input voltage to output voltage with a constant voltage transformation ratio (1/k)1/2 can be obtained. Using the above transformer as transformers makes it unnecessary to use a conventional commercial-frequency transformer or high-frequency transformer. Therefore, drastic size reduction and weight reduction of a transformer can be realized, and as a result, cost reduction can be realized. Further, problems of parasitic capacitance and occurrence of magnetic field leakage, which arise in a high-frequency transformer, are also solved, and thus a transformer with low loss can be realized.
(2) In the transformer of (1), preferably, in the case where reactances of four reactance elements are X1, X2, X3, and X4, the two-terminal pair circuit is composed of, starting from an input side, X1 present on one line of the two-terminal pair circuit, X2 present between two lines thereof, X3 present on the one line, and X4 present between the two lines, and the following condition is satisfied.
(1/X1)+(1/X2)+(1/X3)=0X2+X3+X4=0
In this case, the input impedance Zin is represented as Zin=(X22/X42)·R, and is proportional to the resistance value R of the load, and thus output voltage proportional to input voltage is obtained.
It is noted that the symbol “” denotes a logical conjunction or AND (hereafter, the same applies).
(3) In the transformer of (1), preferably, in the case where reactances of four reactance elements are X1, X2, X3, and X4, the two-terminal pair circuit is composed of, starting from an input side, X1 present between two lines of the two-terminal pair circuit, X2 present on one line thereof, X3 present between the two lines, and X4 present on the one line, and the following condition is satisfied.
X1+X2+X3=0(1/X2)+(1/X3)+(1/X4)=0
In this case, the input impedance Zin is represented as Zin=(X12/X32)·R, and is proportional to the resistance value R of the load, and thus output voltage proportional to input voltage is obtained.
(4) In the transformer of (1), preferably, in the case where reactances of four reactance elements are X1, X2, X3, and X4, the two-terminal pair circuit is composed of: starting from an input side, a T-shaped circuit formed by X1 present on one line of the two-terminal pair circuit, X2 present between two lines thereof, and X3 present on the one line; and X4 present in parallel with a series unit of X1 and X3, and the following condition is satisfied.
X1+X3+X4=0(1/X1)+(1/X2)+(1/X3)=0
In this case, the input impedance Zin is represented as Zin=(X12/X32)·R, and is proportional to the resistance value R of the load, and thus output voltage proportional to input voltage is obtained.
(5) In the transformer of (1), preferably, in the case where reactances of four reactance elements are X1, X2, X3, and X4, the two-terminal pair circuit is composed of, starting from an input side, a first series unit of X1 and X2 present between two lines of the two-terminal pair circuit, and a second series unit of X3 and X4 present between the two lines, such that a mutual connection point in the first series unit and a mutual connection point in the second series unit are output terminals, and the following condition is satisfied.
X1+X2+X3+X4=0(1/X1)+(1/X2)+(1/X3)+(1/X4)=0
In this case, the input impedance Zin is represented as Zin={(X1+X2)2/(X1−X2)2}·R, and is proportional to the resistance value R of the load, and thus output voltage proportional to input voltage is obtained.
(6) In the transformer of (1), preferably, in the case where reactances of five reactance elements are XA, XB, XC, XD, and XE, the two-terminal pair circuit is composed of, starting from an input side, XA present on one line of the two-terminal pair circuit, XB present between two lines thereof, XC present on the one line, XD present between the two lines, and XE present on the one line, and the following relationship is satisfied.
XA=−XBXE−XDXC=XA+XE
In this case, the input impedance Zin is represented as Zin=(XA2/XE2)·R, and is proportional to the resistance value R of the load, and thus output voltage proportional to input voltage is obtained.
(7) In the transformer of (1), preferably, in the case where reactances of five reactance elements are XA, XB, XC, XD, and XE, the two-terminal pair circuit is composed of, starting from an input side, XA present between two lines of the two-terminal pair circuit, XB present on one line thereof, XC present between the two lines, XD present on the one line, and XE present between the two lines, and the following relationship is satisfied.
XA=−XBXE=−XDXC=XA·XE/(XA+XE)
In this case, the input impedance Zin is represented as Zin=(XA2/XE2)·R, and is proportional to the resistance value R of the load, and thus output voltage proportional to input voltage is obtained.
(8) In the transformer of (1), preferably, in the case where reactances of six reactance elements are XA, XB, XC, XD, XE, and XF, the two-terminal pair circuit is composed of, starting from an input side, XA present on one line of the two-terminal pair circuit, XB present between two lines thereof, XC present on the one line, XD present between the two lines, XE present on the one line, and XF present between the two lines, and the following relationship is satisfied.
XA=XC=−XBXD=XF=−XE
In this case, the input impedance Zin is represented as Zin=(XA2/XF2)·R, and is proportional to the resistance value R of the load, and thus output voltage proportional to input voltage is obtained.
(9) In the transformer of (1), preferably, in the case where reactances of six reactance elements are XA, XB, XC, XD, XE, and XF, the two-terminal pair circuit is composed of, starting from an input side, XA present between two lines of the two-terminal pair circuit, XB present on one line thereof, XC present between the two lines, XD present on the one line, XE present between the two lines, and XF present on the one line, and the following relationship is satisfied.
XA=XC=−XBXD=XF=−XE
In this case, the input impedance Zin is represented as Zin=(XA2/XF2)·R, and is proportional to the resistance value R of the load, and thus output voltage proportional to input voltage is obtained.
(10) A transformer may include: a circuit configured to perform switching; and the transformer of any one of (1) to (9), which is interposed in the circuit.
In this case, it is possible to utilize a transformer having a lumped constant circuit, using an environment in which switching is performed.
(11) In the transformer of any one of (1) to (9), a capacitance of a cable and an inductance of a cable may be used as the reactance elements.
In this case, the cable can easily ensure voltage withstanding performance and the cost thereof is low.
(12) In the transformer of (10), preferably, a frequency of the switching is at least 1 MHz.
In this case, it is possible to utilize a transformer having a lumped constant circuit, using an environment in which switching is performed at a high frequency.
<Transformer Using Lumped Constant Circuit>
Next, the details of a transformer using a lumped constant circuit according to embodiments of the present invention will be described.
<<Outline>>
Zin=k·R(k is a constant)
Thus, the input impedance Zin linearly varies with respect to load variation, and the voltage transformation ratio is constant. In addition, the input impedance Zin does not have a reactance component. That is, the input impedance Zin needs to have a real number component of k·R and an imaginary number component of 0. The transformer 200 having such an input impedance Zin is referred to as an LILT (Load-Invariant Linear Transformer).
The transformer 200 as described above can obtain output voltage proportional to input voltage regardless of the resistance value R of the load. That is, the transformer 200 that transforms input voltage to output voltage with a constant voltage transformation ratio (1/k)1/2 can be obtained. Using such a transformer 200 as transformers makes it unnecessary to use a conventional commercial-frequency transformer or high-frequency transformer. Therefore, drastic size reduction and weight reduction of a transformer can be realized, and as a result, cost reduction can be realized. Further, problems of parasitic capacitance and occurrence of magnetic field leakage, which arise in a high-frequency transformer, are also solved, and thus a transformer with low loss can be realized.
Although an infinite number of circuit configurations as an LILT are conceivable, it is desirable that an element number n of reactance elements is small. The present inventors have performed full search while changing the value of n to 1, 2, 3, 4, . . . , starting from 1, and as a result, have found that the minimum element number n is 4.
In the following expression, “j” denotes an imaginary number (−1)1/2.
That is, when the parameter condition satisfies (1/X1)+(1/X2)+(1/X3)=0X2+X3+X4=0, in other words, when (1/X1)+(1/X2)+(1/X3)=0 and X2+X3+X4=0 are satisfied, Zin=(X22/X42)·R is satisfied, and thus output voltage proportional to input voltage is obtained. It is noted that, in order to exert this function, the input voltage needs to be AC.
That is, when the parameter condition satisfies X1+X2+X3=0(1/X2)+(1/X3)+(1/X4)=0, Zin=(X12/X32)·R is satisfied, and thus output voltage proportional to input voltage is obtained. It is noted that, in order to exert this function, the input voltage needs to be AC.
That is, when the parameter condition satisfies X1+X3+X4=0(1/X1)+(1/X2)+(1/X3)=0, Zin=(X12/X32)·R is satisfied, and thus output voltage proportional to input voltage is obtained. It is noted that, in order to exert this function, the input voltage needs to be AC.
That is, when the parameter condition satisfies X1+X2+X3+X4=0(1/X1)+(1/X2)+(1/X3)+(1/X4)=0, Zin={(X1+X2)2/(X1−X2)2}·R is satisfied, and thus output voltage proportional to input voltage is obtained. It is noted that, in order to exert this function, the input voltage needs to be AC.
Next, the circuit configuration with the element number n=5 will be described. Although the element number increases by one from the case of n=4, this circuit configuration is practical.
In
On the other hand, in
In the case of T-shaped circuit, since R is present in the denominator, an LILT is not obtained. However, if the T-shaped circuit is configured in a two-stage form, Zin=k·R is satisfied, and thus output voltage proportional to input voltage is obtained. Considering this, in the case where reactances of the five reactance elements in the circuit shown in (a) of
XA=−XBXE=−XDXC=XA+XE
In this case, the input impedance Zin is represented as Zin=(XA2/XE2)·R, and is proportional to the resistance value R of the load, and thus output voltage proportional to input voltage is obtained. It is noted that, in order to exert this function, the input voltage needs to be AC.
In
On the other hand, in
In the case of π-shaped circuit, since R is present in the denominator, an LILT is not obtained. However, if the π-shaped circuit is configured in a two-stage form, Zin=k·R is satisfied, and thus output voltage proportional to input voltage is obtained. Considering this, in the case where reactances of the five reactance elements in the circuit shown in (a) of
XA=−XBXE=−XDXC=XA·XE/(XA+XE)
In this case, the input impedance Zin is represented as Zin=(XA2/XE2)·R, and is proportional to the resistance value R of the load, and thus output voltage proportional to input voltage is obtained. It is noted that, in order to exert this function, the input voltage needs to be AC.
Next, the circuit configuration with the element number n=6 will be described. Although the element number increases by two from the case of n=4, this circuit configuration is practical.
In
As described above, in either case of T-shaped circuit or π-shaped circuit, since R is present in the denominator, an LILT is not obtained. However, if the T-shaped circuit and the π-shaped circuit are combined, Zin=k·R is satisfied, and thus output voltage proportional to input voltage is obtained. Considering this, in the case where reactances of the six reactance elements in the circuit shown in (a) of
XA=XC=−XBXD=XF=−XE
In this case, the input impedance Zin is represented as Zin=(XA2/XE2)·R, and is proportional to the resistance value R of the load, and thus output voltage proportional to input voltage is obtained. It is noted that, in order to exert this function, the input voltage needs to be AC.
In
As described above, in either case of π-shaped circuit or T-shaped circuit, since R is present in the denominator, an LILT is not obtained. However, if the π-shaped circuit and the T-shaped circuit are combined, Zin=k·R is satisfied, and thus output voltage proportional to input voltage is obtained. Considering this, in the case where reactances of the six reactance elements in the circuit shown in (b) of
XA=XC=−XBXD=XF=−XE
In this case, the input impedance Zin is represented as Zin=(XA2/XE2)·R, and is proportional to the resistance value R of the load, and thus output voltage proportional to input voltage is obtained. It is noted that, in order to exert this function, the input voltage needs to be AC.
The transformer 200 using a lumped constant circuit as described above may be used in combination with a transformer having another configuration. The following are examples of such a transformer having another configuration.
<Transformer Using Switching by Reactance Element>
The switches Sr1, Sr2, Sb1, and Sb2 and the switching control section 3 form a switch device 4 which switches the state of circuit connection of the transformer 1. The switches Sr1 and Sr2 operate in synchronization with each other, and the switches Sb1 and Sb2 operate in synchronization with each other. The pair of switches Sr1 and Sr2 and the pair of switches Sb1 and Sb2 operate so as to be alternately turned on exclusively from each other. The switches Sr1, Sr2, Sb1, and Sb2 are semiconductor switching elements formed by an SiC element or a GaN element, for example. An SiC element or a GaN element allows faster switching than an Si element, for example. In addition, sufficient withstand voltage (which can be even 6 kV per element, for example) can be obtained without connecting multiple stages of such elements.
In
The pair of inductors L1 and L2 are connected in series to each other via a connection point P2. Between both ends of this series unit, input voltage Vm is applied via the capacitors C1 and C2, so that input current Im flows. When one of the switches Sr1 and Sb2 is ON, current flows in the load R. Here, voltage applied to the load R is Vout, and output current flowing from the transformer 1 to the load R is Iout.
In
On the other hand, in
While the states in
In this case, it is possible to utilize the transformer 200 having a lumped constant circuit, using an environment in which switching is performed at a high frequency of 1 MHz, for example. It is noted that, even if the AC power supply 2 is replaced with a DC power supply, a switching waveform based on switching at the preceding stage in the transformer 1 is inputted to the transformer 200, and therefore the transformer 200 can be used (hereafter, the same applies).
<<Others>>
As the above reactance elements, a capacitance of a cable and an inductance of a cable may be used.
In this case, there is an advantage that the cable can easily ensure voltage withstanding performance and the cost thereof is low.
It is noted that the embodiments disclosed herein are merely illustrative in all aspects and should not be recognized as being restrictive. The scope of the present invention is defined by the scope of the claims, and is intended to include meaning equivalent to the scope of the claims and all modifications within the scope.
Number | Date | Country | Kind |
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2013-178494 | Aug 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2014/070967 | 8/8/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2015/029744 | 3/5/2015 | WO | A |
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4635005 | Kaminsky | Jan 1987 | A |
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0412568 | Feb 1991 | EP |
755219 | Aug 1956 | GB |
0755219 | Aug 1956 | GB |
H08-305450 | Nov 1996 | JP |
10-174436 | Jun 1998 | JP |
2002-049428 | Feb 2002 | JP |
2002-095241 | Mar 2002 | JP |
2002-272127 | Sep 2002 | JP |
Entry |
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Homepage of Chuba Electric Power Co., Inc., [Pole Transformer], Internet <URL:http://www.chuden.co.jp/kids/kids_denki/home/hom_kaku/> corresponding to previous <URL:http://www.chuden.co.jp/e-museum/guide/3floor/exhibit_c23.html> [searched on Jul. 19, 2013]. |
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Number | Date | Country | |
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20160211760 A1 | Jul 2016 | US |