TWI700432B - Supersonic shock wave dual-cycle drive power generation system - Google Patents

Abstract

The present invention is a dual-cycle supersonic shock wave drive power generation system, including a high-pressure air source, a first shock wave generator and a second shock wave generator, a first ratchet, a second ratchet, a magnetic idler, and a first magnetic generator , The second magnetic energy generator, a power control unit, a power output unit, a signal acquisition control unit and a monitoring host, the seismic wave generator is input by a high-pressure air source, and the two sets of seismic wave generators interact to generate seismic waves to drive The ratchet wheel and the magnetic energy idler rotate to drive the generator to generate electricity, thereby providing a power generation system that can generate electricity with high efficiency.

Description

Supersonic shock wave dual-cycle drive power generation system

The present invention is a supersonic shock wave dual-cycle drive power generation system, especially a power generation system capable of high-efficiency power generation.

Due to the depletion of petrochemical energy and the demand for sustainable environmental management, the development and promotion of renewable energy has become an important energy policy of all countries. In terms of power generation, although nuclear power and thermal power can provide electricity quickly and conveniently, they will produce waste and environmental pollution. At present, most countries in the world use wind power or solar power as renewable energy sources. Get power.

However, because wind power generation uses wind turbine rotation to drive the generator, its cost is high, the electromechanical facilities are complex, the blades are difficult to optimize the design, and the conditions of its installation location are harsh, so the overall cost of wind power generation is higher than that of thermal power generation. Wind energy is expensive, making it difficult to popularize wind energy; while solar power generation must have a considerable area to install solar power panels to collect enough power, and solar energy will be affected by climate, day and night, which makes it necessary to install storage devices, and improve The overall construction cost, and the semiconductors used in solar cells will also pollute the environment during the manufacturing process, making solar power generation still difficult.

However, because high-pressure air has the advantages of rapid formation, easy storage, and no environmental pollution, it creates a low-pressure area before the high-pressure air, and when all gas molecules are guided into the low-pressure area, a shock wave will be generated, and when the speed of the shock wave More than 1 Mach (that is, double the speed of sound, about 340.3m/s) At this time, the shock wave can be called a supersonic shock wave; and the use of the supersonic shock wave to drive a mechanical device to generate mechanical energy, and then generate electrical energy, is indeed a subject for the industry to use renewable energy.

The purpose of the present invention is to improve the above-mentioned deficiencies of renewable energy power generation, so as to provide a power generation system capable of high-efficiency power generation.

To achieve the above objective, the supersonic shock wave dual-cycle drive power generation system of the present invention includes a high-pressure air source, a first shock wave generator and a second shock wave generator, a first ratchet, a second ratchet, a magnetic idler, and a first Magnetic energy generator, second magnetic energy generator, a power control unit, a power output unit, a signal acquisition control unit and a monitoring host; among them:

The high-pressure gas source is used to store high-pressure gas, and the high-pressure gas source is respectively connected with the first seismic wave generator and the second seismic wave generator;

The first shock wave generator is connected to a high-pressure gas source through an inlet pressure controller, which is connected to the signal acquisition control unit to control the high-pressure gas source to input high-pressure gas into the first shock wave generator In a high-pressure storage tank; the first shock wave generator is provided with a balanced valve stem and a nozzle, the first shock wave generator is also provided with a valve stem controller and a position detection switch, the valve stem controller and a position detection switch Both are connected to the signal capture control unit, the valve stem controller is used to control the balanced valve stem, and the position detection opening relationship is used to detect whether the balanced valve stem is in position; and the first shock wave generator is provided There is a pressure detector which is connected to the signal acquisition control unit and detects the gas pressure in the high pressure storage tank of the first shock wave generator. The first shock wave generator is provided with a shock wave starter. The starter is connected with the signal capture control unit to control the first shock wave generator to generate supersonic shock waves. The first shock wave generator is provided with a sealed box, which is a retractable stainless steel corrugated container. Filled with water quality fluid, in front of the sealed box The end system is connected with the nozzle of the first shock wave generator, the front end of the sealed box is provided with a diaphragm, and the back end of the sealed box is connected with a reciprocating connecting rod; and the first shock wave generator is also provided with a pressure discharge controller , The pressure discharge controller is connected with the signal acquisition control unit to quickly eliminate the gas pressure remaining after the first shock wave generator generates the supersonic shock wave;

The second shock wave generator is connected to a high-pressure gas source through an inlet pressure controller, and the inlet pressure controller is connected to the signal acquisition control unit for controlling the high-pressure gas source to input high-pressure gas into the second shock wave generator In the high-pressure storage tank; the second shock wave generator is provided with a balanced valve stem and nozzle, the second shock wave generator is also provided with a valve stem controller and a position detection switch, the valve stem controller and a position detection switch Both are connected to the signal acquisition control unit, the valve stem controller is used to control the balanced valve stem, and the position detection on relationship is used to detect whether the balanced valve stem is in position; and the second shock wave generator is provided There is a pressure detector which is connected to the signal acquisition control unit and detects the gas pressure in the high-pressure storage tank of the second shock wave generator. The second shock wave generator is provided with a shock wave activator. The starter is connected to the signal acquisition control unit to control the second shock wave generator to generate supersonic shock waves. The second shock wave generator is provided with a sealed box, which is a retractable stainless steel corrugated container. The front end of the sealed box is connected with the nozzle of the second shock wave generator, the front end of the sealed box is provided with a diaphragm, and the back end of the sealed box is connected with a reciprocating connecting rod; and, the second shock wave generates The device is also provided with a discharge pressure controller, which is connected to the signal acquisition control unit to quickly eliminate the gas pressure remaining after the second shock wave generator generates the supersonic shock wave;

The first ratchet is connected to the reciprocating link provided in the sealing box in the first shock wave generator. The first ratchet can be converted into a rotary motion by the pushing of the reciprocating link. The axis of the first ratchet is provided with A coaxially penetrating rotating link, one end of the rotating link is connected to the first magnetic energy generator Connected, the other end of the rotating link is coaxially penetrated through the magnetic idler and connected to the second ratchet;

The second ratchet wheel is connected with the reciprocating link provided in the sealing box in the second shock wave generator. The second ratchet wheel can be converted into a rotary motion by the pushing of the reciprocating link rod. The axis of the second ratchet wheel is provided with A coaxially penetrating rotating link, one end of the rotating link is connected to the second magnetic generator, and the other end of the rotating link is coaxially penetrating through the magnetic idler and connected to the first ratchet;

The magnetic idler wheel is connected to the first ratchet wheel and the second ratchet wheel respectively by a coaxially penetrating rotating link. The magnetic idler wheel can extend the rotation time of the rotating link and increase its rotation speed by using magnetism;

The first magnetic energy generator uses the rotation of the rotating connecting rod to drive the first magnetic energy generator to generate electricity;

The second magnetic energy generator uses the rotation of the rotating connecting rod to drive the second magnetic energy generator to generate electricity;

The power control unit is connected to the first magnetic energy generator and the second magnetic energy generator, and is used to provide the electric energy generated by the first magnetic energy generator and the second magnetic energy generator to the power output unit for use; and the power control unit can Measure the voltage signal of the generated electric energy, and the power control unit is connected with the signal acquisition control unit to transmit the voltage signal;

The power output unit is connected to the power control unit. It can be a load that directly consumes electrical energy, or a battery that stores electrical energy, or a modulating device that can convert the generated electrical energy into room electricity and send it to the grid;

The signal acquisition control unit is connected with each inlet pressure controller, valve stem controller, position detector, pressure detector, shock wave starter and discharge controller to receive each position detector and pressure detector The signal of the detector, and to control the pressure controller, valve stem controller, shock wave The opening and closing of the starter and the discharge controller; the signal captures the control unit and connects with the power control unit to receive the voltage signal measured by the power control unit and send it to the monitoring host for processing;

The monitoring host is connected to the signal capture control unit to receive the signal sent by the signal capture control unit, and after processing and determination, the monitoring host can send the control signal to the signal capture control unit to perform power generation and overall control program;

In this way, a power generation system that can generate power with high efficiency is provided.

10: High pressure gas source

20A: The first shock wave generator

20B: Second shock wave generator

201A, 201B: high pressure storage tank

202A, 202B: Balanced stem

203A, 203B: nozzle

21A, 21B: pressure controller

22A, 22B: Stem controller

23A, 23B: position detection switch

24A, 24B: pressure detector

25A, 25B: shock wave starter

26A, 26B: sealed box

261A, 261B: diaphragm

262A, 262B: reciprocating link

27A, 27B: exhaust pressure controller

30A: First ratchet

30B: second ratchet

31: Rotating link

40: Magnetic energy idler

50A: The first magnetic energy generator

50B: The second magnetic energy generator

60: Power control unit

70: Power output unit

80: signal acquisition control unit

90: Monitoring host

Figure 1 is a diagram of the device of the present invention.

Figure 2 is the monitoring flow chart of the present invention.

Regarding the technical means and structure used by the present invention to achieve the purpose, I would like to cooperate with the embodiments shown in Figures 1 to 2, and the detailed description is as follows:

As shown in Figure 1, the supersonic shock wave dual-cycle drive power generation system of the present invention includes a high-pressure air source 10, a first shock wave generator 20A and a second shock wave generator 20B, a first ratchet 30A, a second ratchet 30B, A magnetic energy idler 40, a first magnetic energy generator 50A, a second magnetic energy generator 50B, a power control unit 60, a power output unit 70, a signal acquisition control unit 80 and a monitoring host 90; among them:

The high-pressure gas source 10 (see Figure 1) is used to store high-pressure gas, and the high-pressure gas source 10 is connected to the first seismic wave generator 20A and the second seismic wave generator 20B, respectively.

The first shock wave generator 20A (please refer to Figure 1) is connected to the high-pressure air source 10 through an in-pressure controller 21A. The in-pressure controller 21A is also connected to the signal acquisition control unit 80 connection, used to control the high-pressure gas source 10 to input high-pressure gas into the high-pressure storage tank 201A of the first shock wave generator 20A; the first shock wave generator 20A is provided with a balanced valve stem 202A and a nozzle 203A, the first shock wave The generator 20A is also provided with a valve stem controller 22A and a position detection switch 23A. The valve stem controller 22A and the position detection switch 23A are both connected to the signal capture control unit 80. The valve stem controller 22A is used to control Balanced valve stem 202A, the position detection switch 23A is used to detect whether the balanced valve stem 202A is in position; in addition, the first shock wave generator 20A is provided with a pressure detector 24A, the pressure detector 24A is It is connected to the signal acquisition control unit 80 and detects the gas pressure in the high-pressure storage tank 201A of the first shock wave generator 20A. The first shock wave generator 20A is provided with a shock wave starter 25A. The shock wave starter 25A and the signal capture The control unit 80 is connected to control the first shock wave generator 20A to generate supersonic shock waves. The first shock wave generator 20A is provided with a sealed box 26A. The sealed box 26A is a retractable stainless steel corrugated container. The sealed box 26A Filled with water quality fluid, the front end of the sealed box 26A is connected with the nozzle 203A provided by the first shock wave generator 20A, the front end of the sealed box 26A is provided with a diaphragm 261A, and the rear end of the sealed box 26A is connected with a reciprocating connecting rod 262A; In addition, the first shock wave generator 20A is also provided with a discharge pressure controller 27A. The discharge pressure controller 27A is connected to the signal capture control unit 80 for quickly eliminating the supersonic shock wave generated by the first shock wave generator 20A. The remaining gas pressure.

The second shock wave generator 20B (please refer to Figure 1) is connected to the high-pressure gas source 10 through an in-pressure controller 21B, and the in-pressure controller 21B is also connected to the signal acquisition control unit 80 for The high-pressure gas source 10 is controlled to input the high-pressure gas into the high-pressure storage tank 201B of the second shock wave generator 20B; the second shock wave generator 20B is provided with a balanced valve stem 202B and a nozzle 203B, and the second shock wave generator 20B is arranged in parallel There is a valve stem controller 22B and a position detection switch 23B. The valve stem controller 22B and the position detection switch 23B are both connected to the signal capture control unit 80. The valve The rod controller 22B is used to control the balanced valve stem 202B, and the position detection switch 23B is used to detect whether the balanced valve stem 202B is in position; in addition, the second shock wave generator 20B is provided with a pressure detector 24B The pressure detector 24B is connected to the signal acquisition control unit 80 and detects the gas pressure in the high-pressure storage tank 201B of the second shock wave generator 20B. The second shock wave generator 20B is provided with a shock wave starter 25B. The shock wave starter 25B is connected with the signal capture control unit 80 to control the second shock wave generator 20B to generate supersonic shock waves. The second shock wave generator 20B is provided with a sealed box 26B, which is made of retractable stainless steel A corrugated container, the sealed box 26B is filled with water quality fluid, the front end of the sealed box 26B is connected with the nozzle 203B of the second shock wave generator 20B, the front end of the sealed box 26B is provided with a diaphragm 261B, and the rear end of the sealed box 26B A reciprocating link 262B is connected; and the second shock wave generator 20B is also provided with a discharge pressure controller 27B. The discharge pressure controller 27B is connected to the signal acquisition control unit 80 to quickly eliminate the second shock wave generation The gas pressure remaining after the device 20B generates a supersonic shock wave.

The first ratchet 30A (see Figure 1) is connected to the reciprocating link 262A provided in the sealed box 26A in the first shock wave generator 20A. The first ratchet 30A is pushed by the reciprocating link 262A. It can be converted into a rotary motion. The axis of the first ratchet 30A is provided with a coaxially penetrating rotary link 31. One end of the rotary link 31 is connected to the first magnetic energy generator 50A, and the other end of the rotary link 31 is coaxially penetrating through The magnetic idler 40 is connected to the second ratchet 30B.

The second ratchet 30B (please refer to Figure 1) is connected to the reciprocating link 262B provided in the sealed box 26B of the second shock wave generator 20B. The second ratchet 30B is pushed by the reciprocating link 262B. It can be converted into a rotary motion. The shaft of the second ratchet 30B is provided with a coaxially penetrating rotary link 31. One end of the rotary link 31 is connected to the second magnetic energy generator 50B, and the other end of the rotary link 31 is coaxially penetrating through The magnetic idler 40 is connected to the first ratchet 30A.

The magnetic idler 40 (please refer to Figure 1) is connected to the first ratchet 30A and the second ratchet 30B by a coaxially penetrating rotating link 31. The magnetic idler 40 can extend the rotating connecting rod by magnetic action 31 rotation time, and can increase its rotation speed.

The first magnetic energy generator 50A (please refer to FIG. 1) uses the rotation of the rotating connecting rod 31 to drive the first magnetic energy generator 50A to generate electricity.

The second magnetic energy generator 50B (see FIG. 1) uses the rotation of the rotating link 31 to drive the second magnetic energy generator 50B to generate electricity.

The power control unit 60 (please refer to Figure 1) is connected to the first magnetic energy generator 50A and the second magnetic energy generator 50B to connect the power generated by the first magnetic energy generator 50A and the second magnetic energy generator 50B. The electrical energy is provided to the power output unit 70 for use; and the power control unit 60 can measure the voltage signal of the generated electrical energy. The power control unit 60 is connected to the signal acquisition control unit 80 to transmit the voltage signal.

The power output unit 70 (please refer to Figure 1) is connected to the power control unit 60 and can be a load that directly consumes electrical energy (such as various electrical appliances), a battery that stores electrical energy, or a kind of modulation Device, which can convert the generated electric energy into room electricity and send it to the grid.

The signal capture control unit 80 (please refer to Figure 1) is connected to the input pressure controllers 21A, 21B, valve stem controllers 22A, 22B, position detectors 23A, 23B, and pressure detectors 24A, 24B , The shock wave starter 25A, 25B and the discharge controller 27A, 27B are connected to receive the signals of the position detectors 23A, 23B and the pressure detectors 24A, 24B, and thereby control the pressure controllers 21A, 21B , Valve stem controllers 22A, 22B, shock wave starters 25A, 25B and discharge pressure controllers 27A, 27B to open and close, the signal capture control unit 80 and connected to the power control unit 60 to receive the power control unit 60 Measure the voltage signal and send it to the monitoring host 90 deal with.

The monitoring host 90 (please refer to Figure 1) is connected to the signal capture control unit 80 to receive the signal transmitted by the signal capture control unit 80, and after processing and determination, the monitoring host 90 can transmit control The signal is sent to the signal acquisition control unit 80 to execute power generation and overall control procedures, while monitoring the voltage signal measured by the power control unit 60; the monitoring host 90 can be a computer running LabVIEW monitoring software.

With the above device, the monitoring flow chart shown in Figure 2 includes the following steps:

Use the monitoring host 90 to pre-set the pressure setting value P _{S of the} high pressure storage tanks 201A, 201B, the lower limit setting value of the output voltage V _LS , and set the completion conditions of the first and second shock wave generators 20A, 20B to determine G _AReady and G _BReady as False, then set the condition that the peak voltage of the power generation energy is too low to determine V _Low as False, and then automatically set the working flag Flag to A, which means that the first seismic wave generator 20A is the first to obtain the right to generate seismic waves.

The monitoring host 90 transmits control signals through the signal acquisition control unit 80 according to the LabVIEW monitoring software and its set parameters, so that the first shock wave generator 20A and the second shock wave generator 20B simultaneously start the preparation process and power generation detection Then, confirm whether the position detection signal S _PA of the position detection switch 23A of the first shock wave generator 20A is home (ON), if the position detection signal S _PA is not home, then the first shock wave is activated The valve stem controller 22A of the generator 20A controls the balanced valve stem 202A to return the balanced valve stem 202A. When the position detection signal S _PA is in the return position (ON), check the first shock wave generator 20A Whether the pressure detection value P _{TA of the} high pressure storage tank 201A is greater than the preset pressure setting value P _S , if the pressure detection value P _{TA of the} high pressure storage tank 201A is less than the preset pressure setting value P _S , the first shock wave generator is activated The 20A inlet pressure controller 21A allows the high pressure gas from the high pressure gas source 10 to enter the high pressure storage tank 201A of the first shock wave generator 20A. When the pressure detection value P _{TA of} the high pressure storage tank 201A is greater than (or equal to) the preset after setting the pressure setpoint P _S, the first shock wave generator is about to complete the conditional _G aReady 20A is set to True. At the same time, confirm whether the position detection signal S _PB of the position detection switch 23B of the second shock wave generator 20B is home (ON), if the position detection signal S _PB is not home, start the second shock wave generation The valve stem controller 22B of the device 20B controls the balanced valve stem 202B to return the balanced valve stem 202B. When the position detection signal S _PB is in the return position (ON), check the high pressure of the second shock wave generator 20B Whether the pressure detection value P _{TB of the} storage tank 201B is greater than the preset pressure setting value P _S , if the pressure detection value P _{TB of the} high pressure storage tank 201B is less than the preset pressure setting value P _S , the second shock wave generator 20B is activated The inlet pressure controller 21B allows the high-pressure gas from the high-pressure gas source 10 to enter the high-pressure storage tank 201B of the second shock wave generator 20B, when the pressure detection value P _{TB of} the high-pressure storage tank 201B is greater than (or equal to) a preset after the pressure setpoint P _S, is about to complete a second shock wave generator 20B determines the condition _G BReady is set to True.

Then, when the peak voltage V _{P of the} electric energy generated by the system is lower than the set value V _LS (V _P ≦V _LS ) of the lower limit of the output voltage, the condition of the power generation peak voltage is too low V _{Low is} set to True. At this time, because the pre-set working flag Flag of this system is A, the first seismic wave generator 20A will start generating the seismic waves first; and if the completion condition of the first seismic wave generator 20A is judged to be not G _AReady or the peak voltage of power generation If V _{Low is} not True, the condition determination procedure of power generation detection and position and pressure detection must be restarted. Only when G _AReady and V _{Low are} both established (True), will it enter the first The seismic wave generation program of the seismic wave generator 20A.

After the first shock wave generator 20A enters the process of generating shock waves, the first shock wave generator 20A will be activated through the shock wave starter 25A to generate the shock waves. The shock waves generated by the first shock wave generator 20A will hit the sealed box 26A at high speed. Set the diaphragm 261A, the water quality fluid in the sealed box 26A will transmit the shock wave hitting the diaphragm 261A to the reciprocating link 262A. The reciprocating link 262A can push the first ratchet wheel 30A to rotate at high speed and high pressure to make the first The ratchet wheel 30A drives the rotating connecting rod 31 to rotate, thereby driving the first magnetic energy generator 50A and the second magnetic energy generator 50B to generate electricity synchronously. At the same time, the rotating connecting rod 31 also synchronously drives the magnetic idler 40 to extend the rotation of the rotating connecting rod 31 Time, and increase the rotation speed; then, set the completion condition judgment G _{AReady of the} first shock wave generator 20A and the condition judgment V _{Low of the} peak voltage of power generation to False, and set the working flag Flag of the system to B , That is, the second shock wave generator 20B enters the procedure of preparing to generate shock waves. At this time, start the discharge pressure controller 27A of the first shock wave generator 20A to eliminate the residual gas pressure in the first shock wave 20A, and then restart to confirm the position detection of the position detection switch 23A of the first shock wave generator 20A _Detect whether the signal S _PA is in position (ON) and inflate the first shock wave generator 20A to prepare for the procedure of generating shock waves and generating electricity again.

And when the working flag Flag of this system is set to B, if the completion condition of the second shock wave generator 20B judges that G _BReady is not True or the condition judges that the peak voltage of power generation is too low, V _Low must be restarted. The condition judgment procedure of detection and position and pressure detection; and when the completion condition judgment G _{BReady of the} second shock wave generator 20B and the condition judgment V _{Low of the} peak voltage of power generation are both True at the same time, the second shock wave starts The generator 20B enters the process of generating shock waves. At this time, the second shock wave generator 20B can be activated through the shock wave starter 25B to generate the shock waves. The shock waves generated by the second shock wave generator 20B will hit the diaphragm set in the sealed box 26B at high speed. 261B, the water quality fluid in the sealed box 26B will transmit the shock wave hitting the diaphragm 261B to the reciprocating link 262B, which can push the second ratchet wheel 30B to rotate at high speed and high pressure, and drive the second ratchet wheel 30B to rotate The connecting rod 31 rotates to drive the first and second magnetic energy generators 50A, 50B to generate electricity synchronously. At the same time, the rotating connecting rod 31 will also synchronously drive the magnetic idler 40 to extend the rotation time of the rotating connecting rod 31 and increase the rotation speed; Then, set the completion condition judgment G _{AReady of the} second shock wave generator 20B and the condition judgment V _{Low of the} peak voltage of the power generation energy to be False, and set the working flag Flag of the system to A, that is, the first shock wave The generator 20A enters the program of preparing to generate shock waves. At this time, the discharge pressure controller 27B of the second shock wave generator 20B is activated to eliminate the residual gas pressure in the second shock wave 20B, and then restart to confirm the position detection of the position detection switch 23B of the second shock wave generator 20B _Detect whether the signal S _PB is in position (ON) and inflate the second shock wave generator 20B to prepare for the procedure of generating shock waves and generating electricity again.

In this way, the first shock wave generator 20A and the second shock wave generator 20B generate shock waves in sequence, and drive the first ratchet wheel 30A and the second ratchet wheel 30B to rotate and drive the rotating link 31 to rotate, so that the rotating link 31 can drive the first magnetic energy generator 50A and the second magnetic energy generator 50B to generate electricity, and the first shock wave generator 20A (or the second shock wave generator 20B) that generates shock waves and generates power will remove the residual gas in them, namely Then enter the valve stem return, fill the storage tank, complete the preparation procedures for the judgment of each condition, and the second shock wave generator 20B (or the first shock wave generator 20A) starts to generate shock waves and generate electricity at this time; then, wait for the second After the shock wave generator 20B (or the first shock wave generator 20A) completes the power generation operation and removes the remaining gas, it then enters the valve stem return, the storage tank is filled, and the preparation procedures for determining various conditions are completed, and the first shock wave generator 20A (Or the second shock wave generator 20B) starts to generate shock waves and generate electricity at this time. In this way, the system can alternately and cyclically generate shock waves to generate electricity by arranging two sets of shock wave generators 20A and 20B. At the same time, the magnetic idler 40 extends the rotation time of the rotating link 31 and increases its rotation speed. Drive two sets of magnetic energy generators 50A and 50B to generate electricity to achieve high-efficiency power generation.

In addition, the electric energy generated by the first and second magnetic energy generators 50A, 50B can be The power control unit 60 transmits to the power output unit 70 for operation.

Therefore, it can be seen from the above that the present invention has the following advantages:

(1) Since the first and second shock wave generators 20A, 20B of the present invention can generate supersonic shock waves, that is, high-pressure air can generate shock wave pressure with a hundredfold magnification, which can effectively drive the first and second magnetic energy generators 50A, 50B power generation, improve power generation efficiency.

(2) Since the shock wave pressure generated by the first and second shock wave generators 20A and 20B of the present invention will hit the diaphragms 261A and 261B of the sealed boxes 26A and 26B, the shock waves are transmitted by the water quality fluid to drive the first and second shock waves. The ratchet wheels 30A, 30B and the rotating connecting rod 31 drive the first and second magnetic energy generators 50A, 50B to generate electricity. The present invention uses high-voltage, high-speed shock waves to drive power generation. It has the characteristics of small size and easy operation. The equipment is obviously simpler than that of wind power generation. This invention clearly can effectively reduce the construction cost.

(3) Since the present invention is equipped with the first and second shock wave generators 20A, 20B to drive the first and second ratchet wheels 30A, 30B and the magnetic idler 40, respectively, so as to drive the first and second magnetic energy generators 50A, 50B to generate electricity. The principle that the two sets of magnetic energy generators 50A and 50B are cyclically and alternately driven by the above two sets of equipment to generate electricity, and the magnetic idler 40 is continuously rotated through magnetic action, which can overcome the thermal energy consumption of friction and thereby improve the power generation efficiency of the generator.

(4) Since the system of the present invention is equipped with position detectors 23A, 23B, pressure detectors 24A, 24B, it can control the positions of the balanced valve stems 202A, 202B in the first and second shock wave generators 20A, 20B and The pressure of high-pressure storage tanks 201A, 201B can be monitored, and the peak voltage of power generation can be measured to achieve the benefits of operational safety. At the same time, the inlet pressure controllers 21A, 21B, valve stem controllers 22A, 22B, and shock starters can be used 25A, 25B, exhaust pressure controller 27A, 27B to automatically control gas input, valve stem return, start shock wave and remove residual gas and other operations, can achieve automatic The goal of chemical operation, and has the advantages of simple and fast operation.

Therefore, this invention clearly has significant progress, and its overall structure is indeed unprecedented, and sincerely it has met the requirements of an invention patent. Yan filed a patent application in accordance with the law, and prayed for the patent as a prayer.

However, the foregoing is only a feasible embodiment of the present invention. The embodiment is mainly used to illustrate the technical means and structure used by the present invention to achieve the purpose, so it cannot limit the protection scope of the present invention. Any equivalent changes or modifications made according to the specification of the present invention and the scope of the patent application shall still fall within the scope of protection covered by the present invention.

10: High pressure gas source

20A: The first shock wave generator

20B: Second shock wave generator

201A, 201B: high pressure storage tank

202A, 202B: Balanced stem

202A, 202B: nozzle

21A, 21B: pressure controller

22A, 22B: Stem controller

23A, 23B: position detection switch

24A, 24B: pressure detector

25A, 25B: shock wave starter

26A, 26B: sealed box

261A, 261B: diaphragm

262A, 262B: reciprocating link

27A, 27B: exhaust pressure controller

30A: First ratchet

30B: second ratchet

31: Rotating link

40: Magnetic energy idler

50A: The first magnetic energy generator

50B: The second magnetic energy generator

60: Power control unit

70: Power output unit

80: signal acquisition control unit

90: Monitoring host

Claims (1)

A supersonic shock wave dual-cycle drive power generation system, comprising a high-pressure air source, a first shock wave generator and a second shock wave generator, a first ratchet, a second ratchet, a magnetic idler, a first magnetic generator, and a second magnetic energy Generator, a power control unit, a power output unit, a signal acquisition control unit and a monitoring host; among them: The high-pressure gas source is used to store high-pressure gas, and the high-pressure gas source is respectively connected with the first seismic wave generator and the second seismic wave generator; The first shock wave generator is connected to a high-pressure gas source through an inlet pressure controller, which is connected to the signal acquisition control unit to control the high-pressure gas source to input high-pressure gas into the first shock wave generator In a high-pressure storage tank; the first shock wave generator is provided with a balanced valve stem and a nozzle, the first shock wave generator is also provided with a valve stem controller and a position detection switch, the valve stem controller and a position detection switch Both are connected to the signal capture control unit, the valve stem controller is used to control the balanced valve stem, and the position detection opening relationship is used to detect whether the balanced valve stem is in position; and the first shock wave generator is provided There is a pressure detector which is connected to the signal acquisition control unit and detects the gas pressure in the high pressure storage tank of the first shock wave generator. The first shock wave generator is provided with a shock wave starter. The starter is connected with the signal acquisition control unit to control the first shock wave generator to generate supersonic shock waves. The first shock wave generator is provided with a sealed box filled with water quality fluid. The front end of the sealed box is connected with the first shock wave generator. The nozzle of a shock wave generator is connected, the front end of the sealed box is provided with a diaphragm, and the back end of the sealed box is connected with a reciprocating connecting rod; in addition, the first shock wave generator is also provided with a discharge pressure controller, the discharge pressure The controller is also connected to the signal acquisition control unit to quickly eliminate the gas pressure remaining after the first shock wave generator generates the supersonic shock wave; The second shock wave generator is connected to a high-pressure gas source through an in-pressure controller, and the in-pressure controller is connected to the signal acquisition control unit for controlling the high-pressure gas source to input high-pressure gas into the first shock wave generator In the high-pressure storage tank; the second shock wave generator is provided with a balanced valve stem and nozzle, the second shock wave generator is also provided with a valve stem controller and a position detection switch, the valve stem controller and a position detection switch Both are connected to the signal acquisition control unit, the valve stem controller is used to control the balanced valve stem, and the position detection on relationship is used to detect whether the balanced valve stem is in position; and the second shock wave generator is provided There is a pressure detector which is connected to the signal acquisition control unit and detects the gas pressure in the high-pressure storage tank of the second shock wave generator. The second shock wave generator is provided with a shock wave activator. The starter is connected with the signal acquisition control unit to control the second shock wave generator to generate supersonic shock waves. The second shock wave generator is provided with a sealed box filled with water quality fluid. The front end of the sealed box is connected to the second The nozzle of the shock wave generator is connected, the front end of the sealed box is provided with a diaphragm, and the back end of the sealed box is connected with a reciprocating connecting rod; in addition, the second shock wave generator is also provided with a discharge pressure controller, the discharge pressure control The device is also connected to the signal acquisition control unit to quickly eliminate the gas pressure remaining after the second shock wave generator generates the supersonic shock wave; The first ratchet is connected to the reciprocating link provided in the sealing box in the first shock wave generator. The first ratchet can be converted into a rotary motion by the pushing of the reciprocating link. The axis of the first ratchet is provided with A coaxially penetrating rotating link, one end of the rotating link is connected to the first magnetic energy generator, and the other end of the rotating link is coaxially penetrating through the magnetic idler and connected to the second ratchet; The second ratchet wheel is connected with the reciprocating link provided in the sealing box in the second shock wave generator. The second ratchet wheel can be converted into a rotary motion by the pushing of the reciprocating link rod. The axis of the second ratchet wheel is provided with A coaxially penetrating rotating link, one end of the rotating link is connected to the second magnetic energy generator, The other end of the rotating link coaxially penetrates the magnetic idler wheel and is connected to the first ratchet wheel; The magnetic idler wheel is connected to the first ratchet wheel and the second ratchet wheel respectively by a coaxially penetrating rotating link. The magnetic idler wheel can extend the rotation time of the rotating link and increase its rotation speed by using magnetism; The first magnetic energy generator uses the rotation of the rotating connecting rod to drive the first magnetic energy generator to generate electricity; The second magnetic energy generator uses the rotation of the rotating connecting rod to drive the second magnetic energy generator to generate electricity; The power control unit is connected to the first magnetic energy generator and the second magnetic energy generator, and is used to provide the electric energy generated by the first magnetic energy generator and the second magnetic energy generator to the power output unit for use; and the power control unit can Measure the voltage signal of the generated electric energy, and the power control unit is connected with the signal acquisition control unit to transmit the voltage signal; The power output unit is connected to the power control unit. It can be a load that directly consumes electrical energy, a battery that stores electrical energy, or a modulating device that can convert the generated electrical energy into room electricity and send it to the grid; The signal acquisition control unit is connected with each inlet pressure controller, valve stem controller, position detector, pressure detector, shock wave starter and discharge controller to receive each position detector and pressure detector The signal of the detector, and used to control the opening and closing of each inlet pressure controller, valve stem controller, shock wave starter and discharge pressure controller; the signal captures the control unit and connects with the power control unit to receive the power control unit Measure the voltage signal and send it to the monitoring host for processing; The monitoring host is connected to the signal capture control unit to receive the signal sent by the signal capture control unit, and after processing and determination, the monitoring host can send control signals to the signal capture The control unit is used to execute power generation and overall control procedures.

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