CN210536354U - Coupling induction power generation energy-saving circuit - Google Patents

Abstract

The utility model discloses a coupling induction power generation energy-saving circuit, concretely relates to generating circuit technical field, coupling induction power generation energy-saving circuit includes first winding coil, the second winding coil, the diode, the triode, rectifier bridge and can rechargeable battery, first winding coil and second winding coil adopt double-wire duplex winding mode, the positive end of power is connected to the upper end of first winding coil, the collecting electrode of triode is connected to the lower extreme, the negative pole of power is connected to the projecting pole of triode, the anodal parallel winding coil's of diode lower extreme, negative pole parallel power is anodal, the ac input end of rectifier bridge is connected at the both ends of second winding coil, the rechargeable battery of ability is connected to the dc output end of rectifier bridge. The system can be applied to all devices with winding coils inside and with power-on and power-off functions, is particularly suitable for the field of motors, and has wide application conditions and obvious energy-saving effect.

Description

Coupling induction power generation energy-saving circuit

Technical Field

The utility model relates to a power generation circuit technical field, concretely relates to coupling induction power generation energy-saving circuit.

Background

In order to deal with the shortage of petroleum energy, the new energy is vigorously developed, and in the technical field of motors, the research is efficient, the progress of energy-saving motors is slow, and the advancing pace of developing new energy is tired to a certain extent.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a not enough to current energy-conserving motor inefficiency, provide one kind through with the coupled coil induction electricity generation of motor stator winding coil double-wire duplex winding to the electric energy that gets off the response is gone into the coupling induction electricity generation energy-saving circuit that can rechargeable battery store.

The utility model discloses specifically adopt following technical scheme:

the utility model provides a coupling induction power generation energy-saving circuit, including first winding coil, the second winding coil, the diode, the triode, rectifier bridge and can rechargeable battery, first winding coil and second winding coil adopt two-wire duplex winding mode, the power positive pole is connected to the upper end of first winding coil, the collecting electrode of triode is connected to the lower extreme, the negative pole of power is connected to the projecting pole of triode, the positive pole of diode connects the lower extreme of winding coil in parallel, the negative pole connects the power positive pole in parallel, the AC input end of rectifier bridge is connected at the both ends of second winding coil, the DC output end of rectifier bridge connects can rechargeable battery.

Preferably, the base of the triode is connected with a signal sensor for controlling the conduction and the cut-off of the triode.

Preferably, the first winding coil and the second winding coil are wound in a bifilar winding manner, that is, two wires are wound together to form a coil and wound on the iron core.

Preferably, the rectifier bridge is a full bridge rectifier bridge.

Preferably, the diode is a normal diode or a fast recovery diode.

Preferably, the triode is a common triode, a field effect transistor or an IGBT bipolar transistor.

Preferably, the rechargeable battery is a storage battery, a lithium battery, a rechargeable capacitor, a rechargeable battery or a capacitor.

Preferably, each element in the system is connected by a copper wire.

The utility model discloses following beneficial effect has:

this coupling induction power generation energy-saving circuit can use in all inside have the winding coil, and the winding coil has the equipment of circular telegram outage function in the middle of, especially is suitable for in the middle of the motor field, the utility model discloses the circuit application condition is extensive, and energy-conserving effect is obvious, no matter is with exchange mode drive or direct current mode drive, the utility model discloses the circuit all can be under the condition that does not influence motor normal operating, and the electric energy that the at utmost used the motor operation, the coupling coil through with motor stator winding coil double-line duplex winding induction gets off to the electric energy that gets off of response is gone into can rechargeable battery and is stored, reaches energy-efficient for the purpose.

Drawings

FIG. 1 is a schematic diagram of a coupled induction power generation energy-saving circuit;

fig. 2 is a schematic diagram of the circuit applied to a three-phase brushless motor driving circuit.

Wherein, 1 is the first winding coil, 2 is the second winding coil, 3 is the rectifier bridge, 4 is the diode, 5 is the triode, and 6 is the rechargeable battery.

Detailed Description

The following description of the embodiments of the present invention will be made with reference to the accompanying drawings:

as shown in figure 1, a coupling induction power generation energy-saving circuit comprises a first winding coil 1, a second winding coil 2, a diode 4, a triode 5, a rectifier bridge 3 and a rechargeable battery 6, wherein the first winding coil 1 and the second winding coil 2 adopt a double-wire parallel winding mode, the base electrode of the triode 5 is connected with a signal sensor for controlling the conduction and the cut-off of the triode, the rectifier bridge 3 is a full-bridge rectifier bridge, the diode 4 is a common diode or a fast recovery diode, the triode is a common triode, a field effect transistor or an IGBT, the rechargeable battery 6 is a storage battery, a lithium battery, a rechargeable capacitor or a rechargeable battery or a capacitor, all elements in the system are connected through copper wires, the upper end of the first winding coil 1 is connected with the positive pole of a power supply, the lower end of the first winding coil is connected with the collector electrode of the triode 5, the emitter electrode of the, the anode of the diode 4 is connected with the lower end of the winding coil in parallel, the cathode is connected with the anode of the power supply in parallel, two ends of the second winding coil 2 are connected with the alternating current input end of the rectifier bridge 3, and the direct current output end of the rectifier bridge 3 is connected with the rechargeable battery.

The first winding coil 1 and the second winding coil 2 are wound in a double-wire winding manner, i.e. two wires are wound together into a coil and wound on an iron core.

A coupling induction power generation energy-saving method adopts the coupling induction power generation energy-saving circuit, and comprises the following steps:

the triode 5 is in a cut-off state when flat, the circuit does not work, when the base electrode of the triode 5 receives a signal from the signal sensor, the triode 5 is in a conducting state at the moment, the circuit starts to work, and power supply current flows to the negative electrode of the power supply through the first winding coil 1 and the collector and emitter of the triode 5;

when a signal applied to the base electrode of the triode by the signal sensor is interrupted, the triode is cut off, the circuit stops working, the first winding coil generates back electromotive force, the voltage of the back electromotive force is opposite to the voltage direction of a power supply and has the same direction with the diode, the back electromotive force flows through the diode, dynamic magnetic energy is generated in the first winding coil due to the fact that the first winding coil is in double-wire parallel winding and the second winding coil is powered on and powered off, the second winding coil converts the magnetic energy of the first winding coil into electric energy through coupling induction according to the dynamic magnetic electricity generation principle, the rechargeable battery is charged through the rectifier bridge, the rechargeable battery is continuously charged through continuous repetition of the actions, and the rechargeable battery stores the electric energy.

As shown in fig. 2, in order to apply the coupled induction power generation energy-saving circuit to a common three-phase brushless motor driving circuit,

the left part is a circuit of a common three-phase brushless motor, and the right part is the coupling induction power generation energy-saving system when a driving circuit of the three-phase brushless motor operates normally. The A, B and C three-phase winding coils are continuously electrified and powered off according to a certain sequence to generate corresponding magnetic poles, the magnetic poles interact with the permanent magnet on the rotor, and homopolar repulsion and heteropolar attraction are realized, so that the rotor rotates. And simultaneously, according to the moving magnetic electricity generating principle, the induced magnetic energy is converted into electric energy through coupling induction with an induction coil wound in a double-wire mode with the A, B and C three-phase winding coils, the electric energy is rectified through a rectifier bridge, and finally the electric energy is transmitted to a rechargeable battery for charging.

Of course, the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and the changes, modifications, additions or substitutions made by those skilled in the art within the scope of the present invention should also belong to the protection scope of the present invention.

Claims (8)

1. The utility model provides a coupling induction power generation energy-saving circuit, a serial communication port, including first winding coil, the second winding coil, the diode, the triode, rectifier bridge and can rechargeable battery, first winding coil and second winding coil adopt the double-wire and wind the mode, the positive pole of power is connected to the upper end of first winding coil, the collecting electrode of triode is connected to the lower extreme, the negative pole of power is connected to the projecting pole of triode, the positive pole of diode connects the lower extreme of winding coil in parallel, the negative pole connects the power in parallel, the AC input end of rectifier bridge is connected at the both ends of second winding coil, the DC output end of rectifier bridge connects can rechargeable battery.

2. The coupled induction power generation energy-saving circuit as claimed in claim 1, wherein the base of the triode is connected with a signal sensor for controlling the conduction and the cut-off of the triode.

3. The coupled induction power-generation energy-saving circuit as claimed in claim 2, wherein the first winding coil and the second winding coil are wound in a bifilar winding manner, i.e. two wires are wound together to form a coil and wound on the iron core.

4. The coupled induction power generation energy-saving circuit as claimed in claim 2, wherein the rectifier bridge is a full-bridge rectifier bridge.

5. The coupled induction power-generation energy-saving circuit as claimed in claim 2, wherein the diode is a normal diode or a fast recovery diode.

6. The coupled induction power generation energy-saving circuit as claimed in claim 2, wherein the triode is a common triode, a field effect transistor or an IGBT (insulated gate bipolar transistor).

7. The coupled induction power generation energy-saving circuit as claimed in claim 2, wherein the rechargeable battery is a storage battery, a lithium battery, a rechargeable capacitor, a rechargeable battery or a capacitor.

8. The coupled induction power-generation energy-saving circuit as claimed in claim 2, wherein each element in the system is connected through a copper wire.

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