A cold machine for converting water hammer energy and water internal energy into mechanical energy
By designing a chiller structure, water hammer energy and the internal energy of water are converted into mechanical energy. By utilizing the rotation of centrifugal jet and annular reverse turbine, efficient energy conversion and output are achieved, solving the problem of low efficiency in the utilization of new energy sources and providing a highly efficient energy conversion method.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- 鄂雨松
- Filing Date
- 2026-03-24
- Publication Date
- 2026-06-12
Smart Images

Figure CN122190971A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of new energy technology, and in particular to a chiller that converts water hammer energy and the internal energy of water into mechanical energy. Background Technology
[0002] Water hammer is widely found in water pipes and, as a manifestation of the internal energy of water, has advantages such as being clean, efficient, and environmentally friendly.
[0003] In the search for and development of new energy engines, humanity is still following the heat engine model from 300 years ago. An engine is a type of heat engine. Where there is a heat engine, there must also be a cooling engine.
[0004] A chilled engine is a novel type of engine that uses water jets through small orifices to physically cool the air, creating a cold source that generates heat from the atmosphere. The chilled engine utilizes the water's hammer energy and internal energy release, which causes vaporization and physical cooling through the jets. Simultaneously, based on Kelvin's water-powered electricity experiment, excess energy is generated, producing electricity. This electricity can then be used to rotate the engine, converting the heat energy in the air into mechanical energy for external output. This represents a shift from exchanging matter for energy to exchanging energy for energy.
[0005] To address this, a chiller is proposed that converts water hammer energy and the internal energy of water into mechanical energy. Summary of the Invention
[0006] The purpose of this invention is to provide a chiller that converts water hammer energy and the internal energy of water into mechanical energy, aiming to solve urgent problems such as the energy crisis and the global greenhouse effect.
[0007] To achieve the above objectives, the present invention provides the following solution: The present invention provides a chiller that converts water hammer energy and the internal energy of water into mechanical energy, comprising: A sealed housing, wherein a flow guiding structure is provided at the bottom of the inner wall of the sealed housing; A central liquid outlet mechanism, comprising a central water collector and a check valve assembly, wherein the central water collector is installed in the middle section of the inner cavity of the sealed housing, and the check valve assembly is used to prevent liquid entering the central water collector from flowing back into the sealed housing; A rotating jet conduit mechanism includes a drive assembly and several sets of curved, twisted antelope horn-shaped conduits. The drive assembly drives the several sets of curved, twisted antelope horn-shaped conduits to rotate. The several sets of curved, twisted antelope horn-shaped conduits are arranged at equal intervals along the central axis of the sealed housing. The inner diameter of each curved, twisted antelope horn-shaped conduit has an egg-shaped cross-section that gradually decreases from the center outwards. One end is connected to the central liquid outlet mechanism, and the other end is equipped with a high-speed nozzle. The high-speed nozzle is located on the annular sleeve at the tip of the twisted antelope horn tube and integrates a nozzle and a duckbill cap. The annular inverted turbine is rotatably connected within the sealed housing. The nozzle of the high-speed nozzle has a certain tangential component facing the annular inverted turbine. The annular inverted turbine is driven by a power output mechanism. An external heat recovery mechanism is provided, with one end connected to the inner wall of the housing via a water pump and an outlet pipe, and the other end connected to a hot water return system, which is connected to the bottom of the inner cavity of the sealed housing. The outlet pipe is connected to the inner wall of the waist portion of the housing.
[0008] According to the present invention, a chiller that converts water hammer energy and the internal energy of water into mechanical energy is provided. The drive assembly includes an electric motor, the output shaft of which extends into the sealed housing, and the electric motor is connected to a plurality of the curved, twisted antelope horn-shaped conduits. A check valve is installed inside the curved, twisted antelope horn-shaped conduit, and the check valve is located near the central water collector.
[0009] According to the present invention, a chiller that converts water hammer energy and the internal energy of water into mechanical energy is provided. The sealed housing includes an upper housing and a lower housing, which are fixedly connected by a flange. The upper housing and the lower housing together form a flattened spherical structure. An upper fixed bracket, a vacuum gauge valve and a pressure regulating valve are installed on the top of the upper housing, and a heavy-duty insulating bracket is installed on the bottom of the lower housing. The output shaft of the motor extends into the inner cavity of the oblate spheroid structure, the flow guiding structure is provided on the inner wall of the lower shell, and the hot water return system is connected to the bottom of the inner cavity of the oblate spheroid structure.
[0010] According to the present invention, a chiller that converts water hammer energy and the internal energy of water into mechanical energy is provided. The power output mechanism includes a generator. The annular reverse turbine is composed of a plurality of turbine blades and a plurality of copper spokes. The plurality of copper spokes are fixedly connected to the outer bushing of the central shaft. The outer bushing is rotatably connected to the input shaft of the generator in a nested manner.
[0011] According to the present invention, a chiller that converts water hammer energy and the internal energy of water into mechanical energy is provided. The external heat energy recovery mechanism includes a liquid outlet pipe and a water pump. The liquid outlet pipe is connected to the inner cavity of the periphery of the oblate spheroid structure. The water pump is installed on the liquid outlet pipe. The end of the liquid outlet pipe away from the oblate spheroid structure is connected to the inner cavity of the external heat energy recovery mechanism.
[0012] According to the present invention, a chiller that converts water hammer energy and the internal energy of water into mechanical energy is provided. The high-speed nozzle has a duckbill cap structure similar to a duckbill, and several nozzles are arranged at the outlet end. The duckbill cap is a movable part used to open and close the high-speed nozzles. The diameter of each high-speed nozzle is less than 1 mm.
[0013] According to the present invention, a chiller that converts water hammer energy and the internal energy of water into mechanical energy is provided. The flow guiding structure includes a plurality of arc-shaped water guiding baffles, which are circumferentially and equally spaced on the inner wall of the lower shell.
[0014] According to the present invention, a chiller that converts water hammer energy and the internal energy of water into mechanical energy is provided, wherein the central water collector has a funnel-shaped structure.
[0015] According to the present invention, a chiller that converts water hammer energy and the internal energy of water into mechanical energy is provided. The curved, twisted antelope horn-shaped conduit is made of a diamagnetic copper-bismuth alloy and is internally silver-plated.
[0016] According to the present invention, a chiller that converts water hammer energy and the internal energy of water into mechanical energy is provided, wherein the number of the bent, twisted antelope horn-shaped conduits is 6n, where n is a natural number not less than 1.
[0017] The present invention discloses the following technical effects: This invention operates by filling the sealed shell with water and creating a vacuum. A drive component drives several sets of curved, twisted antelope horn-shaped conduits to rotate at high speed. This guides the water flow from the bottom of the sealed shell through a central water collector into the curved, twisted antelope horn-shaped conduits, where it rotates. The curved, twisted antelope horn-shaped conduits guide the water flow from axial to radial, forming a centrifugal jet. The direction of the jet is tangential to the annular inverted turbine at the edge, driving the annular inverted turbine to rotate and converting the hydraulic kinetic energy of the fluid into mechanical energy, which is output through a power output mechanism. When the high-pressure water jet is ejected from the slit of the high-speed nozzle, it instantly vaporizes, generating physical cooling. The water vapor is then pumped out through the liquid outlet pipe to an external heat recovery mechanism, where it is liquefied. The liquefied, warm water flows back to the bottom of the chiller, achieving recycling. The circulating water can repeatedly participate in the energy conversion and cooling process, increasing the total energy inside the device. This results in the output mechanical energy being much greater than the input mechanical energy, creating a self-circulating system. In this invention, when water impacts the annular inverted turbine, the rebounding water jet pushes the duckbill cap to close the high-speed nozzle. The water inside the bent, twisted antelope horn-shaped conduit generates a shock wave. Due to the closure of the one-way valve near the central water collector, the internal water instantly generates a water hammer effect, thereby accelerating the jet velocity and obtaining an ultra-high hydraulic pulse, resulting in a liquid-gas phase change of water. This invention converts water hammer energy into mechanical energy. By using small-hole injection to vaporize water and physically cool it, a low-temperature heat source is created. The atmosphere then becomes a high-temperature heat source, dissipating heat from the system. The machine obtains additional energy and can continue to operate. At the same time, it consumes heat from the atmosphere and obtains mechanical energy, resulting in an ultra-high energy conversion efficiency. Attached Figure Description
[0018] To more clearly illustrate the technical solutions in the embodiments of the present invention or the prior art, the drawings used in the embodiments will be briefly introduced below. Obviously, the drawings described below are only some examples of the present invention.
[0019] Figure 1 This is a schematic diagram of the structure of the present invention; Figure 2 This is a schematic diagram of the contact end structure between the curved, twisted antelope horn-shaped conduit and the annular inverted turbine in this invention. Figure 3 This is a schematic diagram of the annular inverted turbine in this invention.
[0020] The components include: 1. Sealed shell; 2. Curved, twisted antelope horn-shaped conduit; 3. Annular reverse turbine; 4. External heat recovery mechanism; 5. Electric motor; 6. Upper fixed bracket; 7. Heavy-duty insulating bracket; 8. Generator; 9. Liquid outlet pipe; 10. Water pump; 11. Hot water return system; 12. Arc-shaped water guide baffle plate; and 13. Central water collector. Detailed Implementation
[0021] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0022] To make the above-mentioned objects, features and advantages of the present invention more apparent and understandable, the present invention will be further described in detail below with reference to the accompanying drawings and specific embodiments.
[0023] Reference Figures 1-3 This invention provides a chiller that converts water hammer energy and the internal energy of water into mechanical energy, comprising: The sealing housing 1 has a flow guiding structure at the bottom of its inner wall; The central liquid outlet mechanism includes a central water collector 13 and a check valve assembly. The central water collector 13 is installed in the middle section of the inner cavity of the sealed housing 1, and the check valve assembly is used to prevent the backflow of liquid entering the central water collector 13. The rotating jet conduit mechanism includes a drive assembly and several sets of curved, twisted antelope horn-shaped conduits 2. The drive assembly drives the several sets of curved, twisted antelope horn-shaped conduits 2 to rotate. The several sets of curved, twisted antelope horn-shaped conduits 2 are arranged at equal intervals around the central axis of the sealed housing 1. The inner cross-section of the curved, twisted antelope horn-shaped conduits 2 is egg-shaped and gradually tapers from the center to the four sides. One end is connected to the central water collector 13, and the other end is equipped with a high-speed nozzle. The high-speed nozzle is a ring sleeve with a switch valve fitted around the tip of the twisted antelope horn tube. The annular inverted turbine 3 is rotatably connected inside the sealed housing 1, the high-speed nozzle faces the annular inverted turbine 3, and the annular inverted turbine 3 is driven by a power output mechanism. An external heat recovery mechanism 4 is provided. One end of the external heat recovery mechanism 4 is connected to the inner wall of the shell 1 via a water pump 10 and an outlet pipe 9. The other end is connected to a hot water return system 11, which is connected to the bottom of the inner cavity of the sealed shell 1. The outlet pipe is connected to the waist of the inner cavity of the shell 1. With this configuration, the present invention operates by filling the sealed shell with water and evacuating it. The drive component drives several sets of curved, twisted antelope horn-shaped conduits 2 to rotate at high speed, guiding the water flow at the bottom of the sealed shell through the central water collector into the several sets of curved, twisted antelope horn-shaped conduits 2 for rotation. The curved, twisted antelope horn-shaped conduits 2 guide the water flow from the axial direction to the radial direction, forming a centrifugal jet. The direction of the jet is tangential to the annular inverted turbine at the edge, driving the annular inverted turbine 3 to rotate, converting the kinetic energy of the fluid into mechanical energy, which is output through the power output mechanism. When the high-pressure water jet is ejected from the slit of the high-speed nozzle, it will produce physical cooling and vaporization. The vaporized water vapor is led out by the water pump through the liquid outlet conduit to the external radiator. The external radiator cools and liquefies the vaporized water. The liquefied warm water flows back to the bottom of the chiller, realizing recycling. The circulating water can repeatedly participate in the energy conversion and cooling process, increasing the total energy inside the device, so that the output mechanical energy is much greater than the input mechanical energy. In this invention, when the water jet impacts the annular reverse turbine 3, the rebounding water jet pushes the duckbill cap to close the high-speed nozzle. The water in the bent, twisted antelope horn-shaped conduit 2 instantly generates a water hammer effect, thereby accelerating the hydraulic overpressure of the water jet and accumulating the internal energy of the water to obtain an ultra-high hydraulic pulse. This invention converts water hammer energy into mechanical energy by vaporizing and absorbing heat after high-temperature, high-pressure water is injected through a small hole to create a low-temperature heat source. The atmosphere then becomes a high-temperature heat source, which spontaneously dissipates heat from the cooler, allowing the machine to operate continuously. At the same time, the heat consumed is from the atmosphere, and mechanical energy is obtained, resulting in high energy conversion efficiency.
[0024] This invention is a cold engine, also known as a traditional heat engine, which is the reverse of a traditional heat engine. A necessary condition for engine design is the need for two heat sources. A heat engine creates a high-temperature heat source from the combustion of fossil fuels, and a low-temperature heat source from the atmosphere. The engine of this invention creates a low-temperature heat source, making the atmosphere a high-temperature heat source. It can still operate. Any engine system cannot output excess energy without energy input; this is the ironclad law of energy conservation. This system not only utilizes water hammer energy but also recovers atmospheric heat energy through an external heat recovery mechanism, allowing the system to have external energy input. The new energy source that humans have been searching for for thousands of years is actually readily available atmospheric heat. Simultaneously, water flows within the antelope horn tube. Based on the Kelvin dripping power generation experiment, this cold engine structure forms a rotating Kelvin experimental machine with a voltage intensity reaching hundreds of millions of volts. In the Kelvin dripping power generator architecture, water is a polar molecule. When the negatively charged copper spokes come into close contact with the bent, twisted antelope horn-shaped conduit 2, the single bent, twisted antelope horn-shaped conduit 2 becomes positively charged, attracting the positively charged copper spokes to accelerate rotation. The pipe contains negatively charged water. The positively charged vanes of the annular inverted turbine 3 attract the negatively charged water, neutralizing the positive and negative charges and generating nuclear-level energy to accelerate the water's vaporization. The annular inverted turbine 3 gains additional rotation, reaching the next negatively charged vane region. The negatively charged water within the bent, twisted antelope horn-shaped conduit 2 repels and is pushed back. The water inside the pipe is compressed at the atomic level, like a spring, accumulating internal energy. Simultaneously, the duckbill nozzle, impacted by the rebounding water column, closes, generating a shock wave. The negatively charged water molecules in the antelope horn conduit flow back, pushing the positively charged water flowing towards the nozzle with centrifugal force, accumulating the water's internal energy and generating higher temperatures and ultra-high pressures. This builds energy for the next water hammer jet.
[0025] The high-voltage electrostatic field generated by the bent, twisted antelope horn-shaped conduit 2, when applied to different electric fields relative to the copper strip, forms a rarely used electrostatic motor structure. However, while electrostatic motors are repulsive structures, this one is an attractive structure. This causes the annular inverted turbine 3 to accelerate, thus achieving the operation of a refrigerated engine that extracts heat energy from the air. In a further optimized design, the drive assembly includes a motor 5, the output shaft of which extends into the sealed housing 1, and the motor 5 is connected to several curved, twisted antelope horn-shaped conduits 2. Each curved, twisted antelope horn-shaped conduit 2 is equipped with a check valve, which is located near the central water collector 13 to prevent liquid from flowing back under hydraulic pressure. During operation, the motor 5 is fixedly installed, with its output shaft extending into the sealed housing 1 and connected to several curved, twisted antelope horn-shaped conduits 2. After the device is started, the motor 5 is energized and operates, outputting stable power to drive several sets of curved, twisted antelope horn-shaped conduits 2 to rotate at high speed circumferentially along the central axis of the sealed housing 1. This attracts water from the bottom of the housing 1 and, through the central water collector 13, it flows upward along each twisted antelope horn tube, forming a uniform centrifugal jet. A check valve is installed inside the curved, twisted antelope horn-shaped conduit 2 near the central water collector 13, which enables unidirectional water flow and prevents backflow when the water hammer effect occurs. This ensures that the water flow can only flow from the central water collector 13 to the high-speed nozzle, preventing backflow from generating water hammer and interfering with jet stability. At the same time, it ensures that the pressure of the water in the tube can accumulate when the water hammer effect occurs, accelerating the water jet velocity, improving the water hammer energy conversion efficiency, and providing a continuous and stable impact force for the annular reverse turbine 3.
[0026] Further optimization of the scheme: the sealed housing 1 includes an upper housing and a lower housing, which are fixedly connected by a flange. The upper housing and the lower housing together form a flat spherical structure. The top of the upper housing is equipped with an upper fixed bracket 6, a vacuum gauge valve and a pressure regulating valve, and the bottom of the lower housing is equipped with a heavy-duty insulating bracket 7. The output shaft of the motor 5 extends into the inner cavity of the oblate spheroid structure, the flow guiding structure is located on the inner wall of the lower shell, and the hot water return system 11 is connected to the bottom of the inner cavity of the oblate spheroid structure. During operation, the upper and lower shells are fixedly connected by flanges, ensuring a tight seal and effectively guaranteeing the airtightness of the sealed shell 1. This meets the vacuum operation requirements after water filling and vacuuming, preventing energy loss due to air or water leakage. The upper and lower shells together form a flattened spherical structure, suitable for the rotation trajectory of the curved, twisted antelope horn-shaped guide tube 2 and the installation of the annular reverse turbine 3. This optimizes the internal space and ensures the stability of water flow rotation and jet impact. The upper fixed bracket 6 on the top of the upper shell is used to fix components such as the motor 5, ensuring secure installation. The vacuum gauge valve can monitor the vacuum level inside the sealed shell 1 in real time, and the pressure regulating valve can precisely adjust the internal pressure according to operational needs, ensuring the device operates under optimal pressure. The heavy-duty insulating bracket 7 at the bottom of the lower shell provides stable support, preventing shaking during operation and providing insulation to meet the operational requirements of the electrostatic acceleration structure. The flow guiding structure is located on the inner wall of the lower shell, guiding water flow and converging. The hot water return system 11 is connected to the bottom of the flattened spherical structure's internal cavity, ensuring smooth return of circulating water and improving water resource utilization.
[0027] The scheme is further optimized. The power output mechanism includes a generator 8 and an annular reverse turbine 3, which consists of several turbine blades and several copper spokes. The copper spokes are all fixedly connected to the outer bushing of the central shaft, and the outer bushing is fixedly connected to the input shaft of the generator 8. Under the high-speed rotation of the electric motor, and because the nozzle is only one millimeter wide, the water inside the pipe is compressed like a spring under the influence of the alternating electric field. This increases the internal energy at the atomic level. Upon re-ejection, the water instantly ionizes, and the vaporization temperature drops sharply.
[0028] During operation, several copper spokes of the annular inverted turbine 3 are fixedly connected to the outer bushing of the central shaft. The outer bushing is fixedly connected to the input shaft of the generator 8. When the water jet and water hammer effect drive the annular inverted turbine 3 to rotate, the turbine drives the input shaft of the generator 8 to rotate synchronously through the outer bushing, converting the rotational kinetic energy after the conversion of thermal energy and electrical energy into mechanical energy for efficient output, thus realizing the conversion from thermal energy in the air to mechanical energy.
[0029] The copper spokes not only serve to fix the turbine blades, but also act as an induction component for an electrostatic motor. They interact with the electrostatic field generated by the bent, twisted antelope horn-shaped conduit 2, utilizing electrostatic attraction and repulsion to further increase the rotational speed of the antelope horn tube and achieve a higher firing rate. Simultaneously, for the first time, electricity is generated from the air using the self-circulation of fluid, and the electrical energy generated from dripping water is directly converted into mechanical energy.
[0030] The scheme is further optimized. The external heat recovery mechanism includes an outlet pipe 9 and a water pump 10. The outlet pipe 9 is connected to the waist of the inner cavity of the flat spherical structure. The water pump 10 is installed on the outlet pipe 9. The end of the outlet pipe 9 away from the flat spherical structure is connected to the inner cavity of the external radiator 4 through the water pump 10. During operation, the liquid outlet pipe 9 is connected to the inner cavity of the sealed housing 1 with its flattened spherical structure. A water pump 10 is installed on the liquid outlet pipe 9, serving as the power source for water vapor condensation. When the high-pressure water jet produces physical cooling, the vaporized water inside the sealed housing 1 is rapidly discharged to the external radiator 4 through the liquid outlet pipe 9 under the drive of the water pump 10, ensuring that water vapor can be delivered to the heat dissipation area in a timely manner, providing efficient cooling for the liquid inside the chiller. The water pump 10 can precisely adjust the water vapor delivery efficiency according to the heat dissipation requirements and water circulation speed, avoiding delayed heat dissipation caused by the stagnation of vaporized water. The end of the liquid outlet pipe 9 furthest from the sealed housing 1 is connected to the inner cavity of the external radiator 4 through the water pump 10, ensuring that the cold air can completely enter the radiator for liquefaction. After liquefaction, the warm water flows back to the bottom of the sealed housing 1 through the hot water return system 11, forming a complete and smooth water circulation, thereby collecting heat energy from the air to replenish the energy of the device.
[0031] The design was further optimized so that the high-speed nozzle is a ring with a switch valve that fits around the tip of the twisted antelope horn tube, integrating a duckbill cap and a nozzle; the duckbill cap is used to open and close the high-speed nozzle, and the nozzle diameter of the high-speed nozzle is less than 1mm. During operation, the duckbill cap controls the opening and closing of the high-speed nozzle. When the water flow impacts the annular inverted turbine 3, the rebounding water jet pushes the duckbill cap to close the high-speed nozzle, causing a shock wave echo to be instantly generated within the curved, twisted antelope horn-shaped guide tube 2, accumulating pressure and increasing water pressure. When the pressure reaches a certain threshold, the duckbill cap opens, and the high-pressure, high-speed water jet is ejected and vaporized, realizing the conversion of water hammer energy. The design of multiple nozzles can disperse the water flow into multiple fine jets with a nozzle diameter of less than 1 mm, which can significantly increase the flow velocity and pressure of the water jet, forming a high-pressure water jet, enhancing the impact force on the annular inverted turbine 3, and improving the fluid kinetic energy conversion efficiency. At the same time, the vaporization of the high-pressure fine jet during ejection, and the physical cooling triggering of the water's gas-liquid phase change effect, can quickly generate a low-temperature heat source, forming a stable temperature difference with the atmosphere, providing more reliable support for the energy source of the chiller, and at the same time, as a maintenance cold source for the chiller, it can continuously extract energy from the atmosphere.
[0032] The scheme is further optimized, and the flow guiding structure includes several arc-shaped water guiding baffles 12, which are installed on the inner wall of the lower shell at equal intervals around the perimeter. During operation, several arc-shaped water-guiding baffles 12 are circumferentially and equally spaced on the inner wall of the lower shell. Their arc-shaped structure matches the flattened spherical shape of the sealing shell 1 and conforms to the direction of water flow rotation. After the sealing shell 1 is filled with water and evacuated, some unvaporized water flows to the bottom of the lower shell. The arc-shaped water-guiding baffles 12 can divert and guide the water flow, avoiding interference between waters of different polarities, and ensuring that the water flows orderly to the central water collector 13, providing a stable and sufficient water supply for the curved twisted antelope horn-shaped conduit 2. In addition, the flow guiding structure can also form a vortex to guide the warm water flow returning to the hot water return system 11, quickly integrating it into the circulation, improving water circulation efficiency, and ensuring the continuous and stable operation of the device.
[0033] The design was further optimized, with the central water collector 13 featuring a funnel-shaped structure. The bottom end of the funnel-shaped structure is in contact with the guide plate for conductive connection, enabling cross-connection for the Kelvin drip power generation experiment.
[0034] Further optimization of the design resulted in the curved, twisted antelope horn-shaped conduit 2 being made of copper-bismuth alloy. It follows a fractal geometric curve to undergo vortex twisting, with a cross-section approaching an egg-shaped concave corner structure, and the inner diameter gradually tapering from the center outwards.
[0035] During operation, the copper-bismuth alloy exhibits extremely strong diamagnetic properties, causing the internal energy of the water inside the pipe to accumulate and increase under an alternating electric field. This forms a high-temperature, high-pressure centrifugal jet, ensuring rapid cooling after vaporization through the nozzle, thus achieving physical cooling.
[0036] Further optimization of the design involves bending the geometric curve of the twisted antelope horn-shaped conduit 2 according to the golden curvature of fractal geometry, creating a double helix structure similar to that of the solar system, with an internal silver-plated structure. This guides water to flow internally with almost no friction, and the components are divided and grouped according to multiples of 3, 6, and 9 in the universe, similar to the three-phase winding of an electrostatic brushless motor.
[0037] The number of curved, twisted antelope horn-shaped ducts 2 is 6n, where n is a natural number not less than 1, such as 24, 36, etc., but no specific limitation is made in this embodiment.
[0038] In use, this invention first fills the casing with water and then evacuates it until the water level reaches the upper outlet pipe. The switch brake valve is opened, and the motor is started to rotate the antelope horn tube water jet wheel. Water from the bottom of the lower casing enters the check valve of each antelope horn tube through the central water collector, undergoing centrifugal motion from axial to radial. Because the nozzle outlet is less than 1 mm, a large amount of water accumulates inside the tube and cannot be discharged quickly. Some of the discharged water impacts the inverted inner blades of the inverted turbine disc, causing the inverted turbine to rotate. This drives the generator to output kinetic energy. Thus, the work obtained by the generator, transmitted through the hydraulic impact of the water, is almost equal to the work done by the jet kinetic energy of the fluid in the antelope horn tube water jet wheel driven by the motor. In this device that converts water hammer energy into mechanical energy, the generator can obtain several additional power outputs.
[0039] In this invention, because each curved, twisted antelope horn-shaped conduit 2 descends from axial to radial direction, forming a siphon structure from bottom to top, the water flow within the siphon is gravity-fed and requires no manual work. A slight rotation of the antelope horn-shaped water jet impeller impacts the reverse-mounted turbine disk, recovering energy with almost equal work done by an electric motor. The energy transfer efficiency, similar to a hydraulic torque converter, is nearly 100%.
[0040] The overall structure of this invention circulates water within a rotating Kelvin dripping electrostatic generator (KEDG) system. KEDGGs have been publicly available for over a century, generating electricity simultaneously as water drips downwards. This rotating KEDGG system generates electricity exponentially as the water velocity increases and the temperature decreases. The voltage can reach hundreds of millions of volts. These hundreds of millions of volts, combined with the spokes of the inverted turbine disc, form an electrostatic motor, thus enabling the water-to-electricity rotation. The addition of Kelvin electricity provides the system with additional power output. This electricity is obtained by the system from sensing the cosmic electric field and is considered free energy.
[0041] The water jet impact on the inner flange of the inverted turbine disk of this invention causes the inverted turbine disk to rotate. The water pressure generated by the motor drives the water to move the pressure transmission from the center position to the periphery with a certain torque from the axial to the radial direction. According to the principle of force × torque, the work recovered on the radial inverted turbine disk is amplified and recovered. This makes the power obtained by the generator in the axial direction greater than the power output of the motor, which also outputs in the axial direction.
[0042] This invention utilizes a secondary impact of water rebounding from the inverted turbine disc's flaps onto the baffle cap of a duckbill nozzle, closing the small-hole injection nozzle. With the nozzle closed, the water inside the twisted antelope horn tube experiences a water hammer effect, thus gaining overpressure and internal energy. Upon injection through the small hole, a gas-liquid phase change occurs, resulting in a lower physical cooling. This allows for the extraction of more excess heat energy. In this invention, because the outlet of the pinhole jet nozzle is only one millimeter, and the water has a high pressure, temperature, and velocity in each antelope horn tube, the water is atomized and physically cooled after being sprayed through the pinhole jet nozzle. This temperature reduction allows the entire system to benefit from the ambient temperature, thus providing energy to the device for continuous operation. The heat energy is then transported to an external heat recovery device radiator for cooling and collection of atmospheric heat energy, which is then condensed into additional mechanical energy for the chiller within the system.
[0043] In this invention, the overall structure is a rotating Kelvin dripping starter, characterized by a rotatable starter system. This system creates an electrostatic motor structure between the twisted antelope horn tube and the copper spokes. The electrostatic motor drives the twisted antelope horn tube to rotate, which in turn drives the inverted turbine disk to rotate, converting it into mechanical energy. Thus, in a flowing liquid state, this energy can be converted into electricity, then into mechanical energy, and based on the law of conservation of energy, continuously obtain heat energy from the atmosphere to achieve self-sustaining operation. In the description of this invention, it should be understood that the terms "longitudinal", "lateral", "up", "down", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings, and are only for the convenience of describing this invention, and are not intended to indicate or imply that the refrigeration unit or component referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this invention.
[0044] Obviously, the above embodiments of the present invention are merely examples for clearly illustrating the present invention, and are not intended to limit the implementation of the present invention. For those skilled in the art, other variations or modifications can be made based on the above description. It is neither necessary nor possible to exhaustively describe all embodiments here. Any modifications, equivalent substitutions, and improvements made within the spirit and principles of the present invention should be included within the scope of protection of the claims of the present invention.
Claims
1. A chiller that converts water hammer energy and the internal energy of water into mechanical energy, characterized in that, include: A sealing housing (1) has a flow guiding structure at the bottom of its inner wall; The central liquid outlet mechanism includes a central water collector (13) and a check valve assembly. The central water collector (13) is installed in the middle section of the inner cavity of the sealing housing (1). The check valve assembly is used to prevent the backflow of liquid entering the central water collector (13). A rotating jet conduit mechanism, comprising a drive assembly and several sets of curved, twisted antelope horn-shaped conduits (2), wherein the drive assembly is used to drive the several sets of curved, twisted antelope horn-shaped conduits (2) to rotate, the several sets of curved, twisted antelope horn-shaped conduits (2) are arranged at equal intervals along the central axis of the sealing housing (1), one end of the curved, twisted antelope horn-shaped conduit (2) is connected to the central water collector (13), and the other end is equipped with a high-speed nozzle; An annular inverted turbine (3) is rotatably connected inside the sealed housing (1), and the high-speed nozzle faces the annular inverted turbine (3). The annular inverted turbine (3) is driven by a power output mechanism. An external heat recovery mechanism (4) is provided. One end of the external heat recovery mechanism (4) is connected to the inner wall of the shell (1) via a water pump (10) and a liquid outlet pipe (9). The other end is connected to a hot water return system (11), which is connected to the bottom of the inner cavity of the sealed shell (1).
2. The chiller according to claim 1, which converts water hammer energy and the internal energy of water into mechanical energy, is characterized in that: The drive assembly includes an electric motor (5), the output shaft of which extends into the sealed housing (1), and the electric motor (5) is connected in drive to a plurality of the curved, twisted antelope horn-shaped conduits (2); A check valve is installed inside the curved, twisted antelope horn-shaped conduit (2), and the check valve is located near the central water collector (13).
3. The chiller according to claim 2, which converts water hammer energy and the internal energy of water into mechanical energy, is characterized in that: The sealed housing (1) includes an upper housing and a lower housing. The upper housing and the lower housing are fixedly connected by a flange. The upper housing and the lower housing together form a flat spherical structure. An upper fixed bracket (6), a vacuum gauge valve and a pressure regulating valve are installed on the top of the upper housing. A heavy-duty insulating bracket (7) is installed on the bottom of the lower housing. The output shaft of the motor (5) extends into the inner cavity of the oblate spheroid structure, the flow guiding structure is provided on the inner wall of the lower shell, and the hot water return system (11) is connected to the bottom of the inner cavity of the oblate spheroid structure.
4. The chiller according to claim 1, which converts water hammer energy and the internal energy of water into mechanical energy, is characterized in that: The power output mechanism includes a generator (8), and the annular reverse turbine (3) consists of several turbine blades and several copper spokes. The copper spokes are fixedly connected to the outer bushing of the central shaft, and the outer bushing is fixedly connected to the input shaft of the generator (8).
5. The chiller according to claim 3, which converts water hammer energy and the internal energy of water into mechanical energy, is characterized in that: The external heat recovery mechanism (4) includes an outlet pipe (9) and a water pump (10). The outlet pipe (9) is connected to the inner cavity of the oblate spheroid structure. The water pump (10) is installed on the outlet pipe (9). The end of the outlet pipe (9) away from the oblate spheroid structure is connected to the inner cavity of the external heat recovery mechanism (4).
6. The chiller according to claim 1, which converts water hammer energy and the internal energy of water into mechanical energy, is characterized in that: The duckbill cap on the nozzle is used to open and close the high-speed nozzle, and the nozzle diameter of the high-speed nozzle is less than 1 mm.
7. The chiller according to claim 3, which converts water hammer energy and the internal energy of water into mechanical energy, is characterized in that: The flow guiding structure includes several arc-shaped water guiding baffles (12), which are installed circumferentially at equal intervals on the inner wall of the lower shell.
8. The chiller according to claim 1, which converts water hammer energy and the internal energy of water into mechanical energy, is characterized in that: The central water collector (13) has a funnel-shaped structure.
9. The chiller according to claim 1, which converts water hammer energy and the internal energy of water into mechanical energy, is characterized in that: The curved, twisted antelope horn-shaped conduit (2) is made of diamagnetic materials such as copper-bismuth alloy.
10. The chiller according to claim 1, which converts water hammer energy and the internal energy of water into mechanical energy, is characterized in that: The number of the curved, twisted antelope horn-shaped ducts (2) is 6n, where n is a natural number not less than 1.