KR100624257B1 - Electric power saver using regulation of 3 phase distribution line - Google Patents

Abstract

A three-phase constant voltage power saver, comprising: first to third input terminals externally powered to reduce reactive power by reducing power factor by improving power factor; First to third output terminals for supplying a voltage to the load; First to third cores provided corresponding to three input terminals; Five winding groups provided in each of the first to third core, wherein the first winding of the first core is the second winding of the third core, the third winding of the first core, the fourth winding of the first core, It is connected to the neutral point through the fifth winding of the second core in order, and the first winding of the second core is the second winding of the first core, the third winding of the second core, the fourth winding of the second core, and the third Connected to the neutral point in order through the fifth winding of the core, the first winding of the third core being the second winding of the second core, the third winding of the third core, the fourth winding of the third core, of the first core The fifth winding was connected to the neutral point in order, and the first to third output terminals were drawn out at respective connection points of the third and fourth windings of the first to third cores, respectively.

By such a configuration, the inrush current has a smoothing function and the second induced voltage balance, thereby preventing the flicker caused by the inrush current and reducing the power loss of the load. .

Three-phase constant voltage saver, core, winding, neutral point, input terminal, output terminal.

Description

Electric power saver using regulation of 3 phase distribution line}

1 is a connection diagram of a conventional three-phase four-wire power saver transformer,

2 is a structural diagram showing a connection relationship between a conventional three-phase automatic transformer,

3 is a plan view showing an embodiment of a three-phase constant voltage power saver according to the present invention;

4 is a circuit diagram illustrating a concept according to the present invention.

Explanation of symbols on the main parts of the drawings

100: three-phase constant voltage power saver 110: first core

120: second core 130: third core

111: first winding 112: second winding

113: third winding 114: fourth winding

115: fifth winding n: neutral point

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a three-phase constant voltage power saver supplied to a load, and more particularly, to a constant voltage power saver that reduces power loss due to unbalance of voltage and current of each phase in three-phase power.

In general, a transformer is an inductive coupling of two electrical circuits by two or more windings or by a single winding with a tab, with and without windings.

As used in such a transformer, reactive power refers to power that does not actually do anything and consumes no heat since the inflow and reception of energy from a power source is repeated every half cycle when an alternating current flows through an inductor and a capacitor. It refers to power that doesn't actually work. If the effective values of AC voltage and current are V and I, respectively, and the phase angle is θ, the apparent power becomes VI, and the active power and reactive power are represented by VIcosψ and VIsinψ respectively.

In addition, the effective power is a quantity given by VIcosθ when the effective value of voltage is V, the effective value of current is I, and the phase difference between them is θ. This is the power that changes from the load to the actual effective one, as opposed to reactive power or apparent power.

Power factor refers to the effective power divided by the apparent power, and the circuit resistance divided by the circuit impedance at the operating frequency. If the circuit currents are all sine waves, the power factor is the cosine of the phase difference between voltage and current.

The supply voltage from the utility company varies somewhat depending on the location of the transformer and the length of the wiring, and the voltage drop rate may also vary from customer to customer. That is, the electricity is supplied from the power distribution transformer of one bank to each customer, and the supply voltage is set such that the voltage at the end of the power supply transformer tab is maintained at 220V. However, the customer near the power distribution transformer receives a supply voltage higher than 200V, causing overheating and malfunction of the electric equipment, blackening of the lighting equipment, etc., resulting in excessive power consumption and shortening the life of the electric equipment.

Accordingly, in the case of electric equipment using a rated voltage of 220V or 380V, there should be no abnormality in use within the voltage range of 198 to 242V and ± 342% and 342 to 418V, which are ± 10%. By using the allowable voltage characteristic that should be no problem for the normal operation of the equipment within the specified range, the power supply is reduced to the minimum rated voltage of the load to reduce the power consumption, thereby saving power.

An example of a technique for obtaining the power saving effect as described above is disclosed in Korean Utility Model Publication No. 20-343827.

1 is a connection diagram of a three-phase four-wire power saving transformer disclosed in the above publication.

The power saving transformer shown in FIG. 1 includes a neutral wire 300 having an input terminal N and an output terminal n. The current coil includes R phase, S phase and T phase current coils 302, 304 and 306. The R phase current coil 302 includes an output side r connected in series with the input side R and the input side R and having the same potential as the input side R. The S phase current coil 304 includes an output side s connected in series with the input side S and the input side S and having the same potential as the input side S. The T-phase current coil 306 includes an output side t connected in series with the input side T and the input side T and having the same potential as the input side T.

The voltage coil includes R phase, S phase and T phase voltage coils 308, 310 and 312. The R phase voltage coil 308 includes primary and secondary side lines L1 and L1, and the S phase voltage coil 310 includes primary and secondary side lines L2 and L2, and the T phase voltage coil. 312 includes primary and secondary side lines L3 and l3. The primary and secondary lines L1 and L1 of the R-phase voltage coil 308 are connected to the input side R and the N-phase output side n of the R-phase current coil 302, respectively, and the S-phase voltage coil 310 The primary side and secondary side lines L2 and L2 of) are connected to the input side S and the N phase output side n of the S phase current coil 304, respectively, and the primary side and 2 of the T phase voltage coil 312. The difference side lines L3 and L3 are connected to the input side T and the N phase output side n of the T-phase current coil 306, respectively.

The secondary lines L1, L2, and L3 are commonly connected to the input terminal N or the output terminal n of the midline 300 so that the voltage coils 308, 310, 312 are Y-connected. The midline provides a transformer for the energy-saving device that can simultaneously use the three-phase 380V power supply and single-phase 220V power supply by jointly connecting the input side and the output side.

However, in the technique disclosed in the above publication, the power consumption can be reduced by reducing the constant voltage to supply the electric power such as a motor by reducing the fluctuation range of the input voltage to reduce the power consumption, but the imbalance between the three phases is not considered at all. It is not.

That is, in a distribution transformer, the three-phase output stage is connected to the three-phase input stage through the distribution line, each winding is connected to the neutral point, and the output stage is connected to the motor that is the load, the voltage at the output stage due to the resistance of the distribution line It causes a drop.

Thus, an unbalance between the voltages of the three-phase output stages occurs like an unbalance between the currents, which adversely affects the load.

Accordingly, the torque of the motor as a load is reduced and the efficiency is also reduced to shorten or destroy the life of the motor.

The structure of the three-phase automatic transformer proposed to solve this problem is shown in FIG.

Figure 2 is a structural diagram showing the connection of the three-phase automatic transformer disclosed in Republic of Korea Patent Publication No. 1995-13002.

In the three-phase autotransformer illustrated in FIG. 2, the U-phase series winding includes a coil 10, a W-phase coil 11, a U-phase coil 12 and a coil 19, a W-phase coil 20, and a U-phase coil ( It is connected to the neutral point N via 21, and the structure which draws out the output terminal u at the connection point of the coil 12 and the coil 19 is carried out.

In addition, the series winding of the V phase is connected to the neutral point N via the coil 13, the U phase 14 coil, the V phase coil 15 and the coil 22, the U phase coil 23, and the V phase coil 24. And the output terminal v is drawn out at the connection point between the coil 15 and the coil 22, and the W-phase serial winding is the coil 16, the V-phase coil 17, the W-phase coil 18, and the coil ( 25), it is connected to the neutral point N via the coil 26 of the V phase and the coil 27 of the W phase, and has the structure which draws out the output terminal w from the connection point of the coil 18 and the coil 25. FIG.

However, in the structure shown in Fig. 2, the number of windings wound around the core has six stages, and there is a problem that the manufacturing is complicated and the manufacturing cost is expensive.

An object of the present invention is to solve the problems of the prior art as described above, and to provide a three-phase constant voltage power saver that can reduce the power loss by reducing the reactive power by improving the power factor.

Another object of the present invention is to provide a three-phase constant voltage power saver that can easily perform winding winding of a core for a three-phase constant voltage power saver.

In order to achieve the above object, the three-phase constant voltage power saver according to the present invention comprises: a three-phase constant voltage power saver supplied to a load, the first to third input terminals receiving external power; First to third output terminals for supplying a voltage to the load; First to third cores provided corresponding to the three input terminals; And five winding groups provided in each of the first to third cores, wherein the first winding of the first core includes a second winding of the third core, a third winding of the first core, and the first core. A fourth winding of, a fifth winding of the second core in order to a neutral point, wherein the first winding of the second core is a second winding of the first core, a third winding of the second core, A fourth winding of the second core and a fifth winding of the third core are connected to the neutral point in the order, the first winding of the third core being the second winding of the second core, the third core A third winding, a fourth winding of the third core, and a fifth winding of the first core in order to be connected to the neutral point, and the first to third output ends of the first to third cores respectively. It is characterized in that drawn out at each connection point of the third winding and the fourth winding.

In the three-phase constant voltage power saver according to the present invention, the fourth and fifth windings of the first to third cores are wound in opposite directions.

In the three-phase constant voltage power saver according to the present invention, each of the first to third windings of the first to third cores is wound in the same direction.

In the three-phase constant voltage power saver according to the present invention, each of the first to third windings of the first to third cores functions as a series reactor.

In the three-phase constant voltage power saver according to the present invention, the number of turns of the first to fifth windings is different from each other.

In the three-phase constant voltage power saver according to the present invention, the first to third cores are made of silicon steel sheet or iron.

The above and other objects and novel features of the present invention will become more apparent from the description of the specification and the accompanying drawings.

EMBODIMENT OF THE INVENTION Hereinafter, the structure of this invention is demonstrated according to drawing.

In addition, in description of this invention, the same code | symbol is attached | subjected to the same part and the repeated description is abbreviate | omitted.

3 is a plan view showing an embodiment of a three-phase constant voltage power saver 100 according to the present invention.

In FIG. 3, R, S, and T are three-phase input terminals supplied from a power supply, and r, s, and t are output terminals for supplying a constant voltage to a load such as a motor through a three-phase constant voltage power saver according to the present invention.

Reference numeral 110 is a first core for the R terminal, 120 is a second core for the S terminal, and 130 is a third core for the T terminal.

The first to third cores 110, 120, and 130 are conventional shell cores, which are made of iron or silicon steel sheets. That is, the core material may be an iron or silicon steel sheet depending on the use of the load.

As shown in FIG. 3, the first winding 111 on the first core 110 for the R terminal is connected to the R terminal and is connected in series to the second winding 132 of the third core 130. In addition, the second winding 132 of the third core 130 is connected in series to the third winding 113 of the first core 110. That is, in the three-phase constant voltage power saver 100 according to the present invention, the first winding, the second winding and the third winding are all wound in the same direction.

In addition, the third winding 113 of the first core 110 is connected to the fourth winding 114 of the first core 110, at the connection point of the third winding 113 and the fourth winding 114. The output terminal r of the R terminal is drawn out.

The fourth winding 114 of the core 110 for the R terminal is connected in series to one end of the fifth winding 125 of the second core 120 for the S terminal, and the other end of the fifth winding 125 is the neutral point. is connected to (n).

In addition, the first winding 121 on the second core 120 for the S terminal is connected to the S terminal and connected in series to the second winding 112 of the first core 110, as shown in FIG. In addition, the second winding 112 of the first core 112 is connected in series to the third winding 123 of the second core 120. That is, in the three-phase constant voltage power saver 100 according to the present invention, all the windings for the S terminal are wound in the same direction.

In addition, the third winding 123 of the second core 120 is connected to the fourth winding 124 of the second core 120, and at the connection point of the third winding 123 and the fourth winding 124. The output terminal s of the S terminal is drawn out.

The fourth winding 124 of the second core 120 for the S terminal is connected in series to one end of the fifth winding 135 of the third core 130 for the T terminal, and the other end of the fifth winding 135. Is connected to the neutral point n.

In addition, the first winding 131 on the third core 130 for the T terminal is connected to the T terminal and connected in series to the second winding 122 of the second core 120, as shown in FIG. In addition, the second winding 122 of the second core 120 is connected in series to the third winding 133 of the third core 130. That is, in the three-phase constant voltage power saver 100 according to the present invention, all the windings for the T terminal are wound in the same direction.

In addition, the third winding 133 of the third core 130 is connected to the fourth winding 134 of the third core 130, and at the connection point of the third winding 133 and the fourth winding 134 The output terminal t of the T terminal is drawn out.

The fourth winding 134 of the third core 130 for the T terminal is connected in series to one end of the fifth winding 115 of the first core 110 for the R terminal, and the other end of the fifth winding 115. Is connected to the neutral point n.

That is, in the three-phase constant voltage power saver 100 according to the present invention, the other end of the fifth winding 125 of the winding for the R, S, T terminals, the other end of the fifth winding 135 and the fifth winding 115 The other end of is commonly connected to the neutral point n.

In addition, in the present invention, as shown in FIG. 3, each of the fourth windings 114 and 124 wound around the first core 110, the second core 120, and the third core 130, 134 and respective fifth windings 115, 125, and 135 are wound in opposite directions to equalize and cancel out the phase of the image current.

Further, the first windings 111, 121, 131, and second windings 112, 122 wound around the first core 110, the second core 120, and the third core 130, respectively. ), 132, and the third windings 113, 123, and 133, as a series reactor, balance the inrush current smoothing function and the secondary induced voltage.

That is, the feedback effect according to the present invention is shown in Figure 4, for example, the current flowing in the primary winding n1 in the R phase

This is because the load current of I3 increases by the value of I1. Here, n1 is the number of turns of the primary winding, n2 is the number of turns of the secondary winding, I1 is the current flowing in the primary winding, I2 is the current at the R input terminal, and I3 is the current through the secondary winding.

As described above, in the present invention, the secondary current coil is induced in a reverse phase voltage stimulatively with respect to the primary voltage coil by the electromagnetic induction of the primary voltage coil connected in parallel with the power supply to provide a voltage drop to the load. The secondary coil connected in series reduces the input current by the power feedback action by the electromagnetic induction action on the primary coil by the load current amount. In addition, the two windings at the bottom shown in FIG. 3 are wound in opposite directions to offset the harmonic image currents in the same phase, thereby improving the power factor and reducing the power loss.

In addition, in the three-phase constant voltage power saver 100 according to the present invention, the number of turns of the first winding 111 and the second winding 112 of the first core 110 are different from each other, for example, 1: 2. The ratio may be set.

As mentioned above, although the invention made by this inventor was demonstrated concretely according to the said Example, this invention is not limited to the said Example and can be variously changed in the range which does not deviate from the summary.

That is, in the above embodiment, the three-phase constant voltage power saver 100 has been described, but the present invention is not limited thereto, and of course, the present invention can also be applied to a single-phase transformer or a troidle three-phase transformer.

As described above, according to the three-phase constant voltage power saver according to the present invention, since the upper three windings act as a series reactor on the load side, it has a smoothing function of the inrush current and the balance of the secondary induced voltage and flickers due to the inrush current. The effect of being able to prevent the phenomenon of is obtained.

In addition, according to the three-phase constant voltage power saver according to the present invention, since excessive loss can be prevented in a load such as a motor, the effect of reducing the power loss required for the load is also obtained.

Claims (7)

In the three-phase constant voltage power saver supplied to the load, First to third input terminals receiving external power; First to third output terminals for supplying a voltage to the load; First to third cores provided corresponding to the three input terminals; 5 winding groups provided in each of the first to third cores, The first winding of the first core is a neutral point through the second winding of the third core, the third winding of the first core, the fourth winding of the first core, and the fifth winding of the second core in this order. Connected to, The first winding of the second core is passed through the second winding of the first core, the third winding of the second core, the fourth winding of the second core, and the fifth winding of the third core in this order. Connected to the neutral point, The first winding of the third core is passed through the second winding of the second core, the third winding of the third core, the fourth winding of the third core, and the fifth winding of the first core in this order. Connected to the neutral point, And the first to third output terminals are drawn at respective connection points of the third and fourth windings of the first to third cores, respectively. The method of claim 1, And each of the fourth and fifth windings of the first to third cores are wound in opposite directions to each other. The method of claim 1, Wherein each of the first to third windings of the first to third cores is wound in the same direction. The method of claim 1, Wherein each of the first to third windings of the first to third cores functions as a series reactor. The method of claim 1, Three-phase constant voltage power saver, characterized in that the number of turns of the first to fifth windings are different from each other. The method of claim 1, The first to third cores are three-phase constant voltage power saver, characterized in that made of silicon steel sheet. The method of claim 1, The first to third cores are three-phase constant voltage power saver, characterized in that made of iron.

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