CN109163468B - Heat supply method utilizing water molecule high-frequency oscillation - Google Patents

Abstract

The invention provides a heat supply method by utilizing high-frequency oscillation of water molecules, which comprises a negative pressure exciter, a hot water outlet, a high-frequency oscillation bin of water molecules, a connecting flange, a negative pressure feedback pipe, a water inlet pipe, a water outlet valve, a water return pipe, a pressurizing pump, a heat storage tank and a hot water pipe; by utilizing a specially designed water flow accelerating structure, water in a high-pressure state instantaneously changes the flow speed and excites stronger negative pressure, the negative pressure effect can lead water molecules to generate strong high-frequency oscillation, the oscillation frequency of the water molecules is instantaneously increased and severe collision is generated, so that the temperature of the water molecules is increased, and the water heating function is realized. The water temperature is gradually increased to the temperature required by heat supply by circularly heating the water in the heating process for a plurality of times, so that low-cost heat energy can be continuously provided for heating and heat supply users. Compared with the traditional heat supply technology, the invention has the advantages of simple structure, low manufacturing and running cost, energy conservation, consumption reduction, safe and reliable running, lower fault rate and maintenance cost and capability of realizing unattended operation.

Description

Heat supply method utilizing water molecule high-frequency oscillation

Technical Field

The invention belongs to the technical field of thermal engineering, and particularly relates to a heating method for heating by utilizing water molecules through high-frequency oscillation.

Background

Currently, in the field of thermal engineering, water is used as the most widely used heating medium in various heating modes, including heating methods such as coal heating, gas heating, fuel heating, and heating by electric heating materials. The traditional water heating method has the defects of high energy consumption, high running cost, low thermal efficiency, serious equipment scaling, high failure rate, high labor and maintenance cost and the like. With the continuous development of economy and the rapid promotion of living standard, no matter the demands of industry, agriculture and residents on heat supply are higher and higher, the popularization of a heating and heat supply system from north to south and from cities to villages and towns has become a great trend, and the market is in need of new unattended heating technology with smaller energy consumption, higher heat efficiency, low pollution and zero emission, lower running cost and higher automation degree, and the limitation of the traditional heating technology is difficult to meet the demands of market development. Especially for the demands of decentralized, miniaturized heating systems in special industries and modern agriculture, traditional heating techniques are problematic. Aiming at the defects existing in the traditional heat supply technology, the novel technology for fully utilizing the characteristics of water molecules needs to be developed, and the problem can be better solved without directly heating water by utilizing the traditional heating energy or electric heating materials. Similar technical solutions are not currently seen.

Disclosure of Invention

The invention aims at providing a heat supply method by utilizing high-frequency oscillation of water molecules, wherein a water molecule high-frequency oscillation heat supply device involved in the method consists of a negative pressure exciter, a hot water outlet, a water molecule high-frequency oscillation bin, a connecting flange, a negative pressure feedback pipe, a water inlet pipe, a water outlet valve, a water return pipe, a booster pump, a heat storage tank and a hot water pipe; by utilizing a specially designed water flow accelerating structure, water in a high-pressure state instantaneously changes the flow speed and excites stronger negative pressure, the negative pressure effect can lead water molecules to generate strong high-frequency oscillation, the oscillation frequency of the water molecules is instantaneously increased and severe collision is generated, so that the temperature of the water molecules is increased, and the water heating function is realized. The water temperature is gradually increased to the temperature required by heat supply by circularly heating the water in the heating process for a plurality of times, so that low-cost heat energy can be continuously provided for heating and heat supply users. Compared with the traditional heat supply technology, the invention has the advantages of simple structure, incomparable manufacturing and running cost, more importantly, the invention can provide wide prospect for realizing the construction of green heat supply in the aspects of energy conservation, consumption reduction, emission reduction, environmental pollution and the like.

The invention relates to a heating method utilizing water molecule high-frequency oscillation, wherein a water molecule high-frequency oscillation heating device involved in the method consists of a negative pressure exciter (1), a hot water outlet (2), a water molecule high-frequency oscillation bin (3), a connecting flange (4), a negative pressure feedback pipe (5), a water inlet pipe (6), a water outlet valve (7), a water return valve (8), a water return pipe (9), a booster pump (10), a heat storage tank (13) and a hot water pipe (14); the water inlet end of the pressure pump (10) is communicated with a water return port of the heat storage tank (13) through a water return pipe (9), and the water outlet end of the pressure pump (10) is communicated with the water inlet pipe (6); the water inlet pipe (6) is communicated with the water molecule high-frequency oscillation bin (3) through the flange (4), a negative pressure exciter (1) with the diameter identical to the aperture of the flange hole is arranged in the flange hole of the connecting flange (4), a plurality of vertical through accelerating holes (11) are uniformly formed in the negative pressure exciter (1), and a concave negative pressure excitation cavity (12) with the diameter larger than the aperture of the accelerating holes (11) is arranged between the upper port and the lower port of the accelerating holes (11); the bottom of the water molecule high-frequency oscillation bin (3) is communicated with a water inlet pipe (6) of the pressurizing pump (10) through a negative pressure feedback pipe (5), a hot water outlet (2) is arranged at the top of the water molecule high-frequency oscillation bin (3), the water outlet is communicated with a water inlet end of the heat storage box (13) through a hot water pipe (14), and a water return valve (8) and a water outlet valve (7) are respectively and correspondingly arranged at the water inlet end and the water outlet end of the pressurizing pump (10); the specific operation is carried out according to the following steps:

a. opening a water outlet valve (7) and a water return valve (8), starting a pressurizing pump (10), and enabling the pressurizing pump (10) to pressurize backwater to a certain water pressure to achieve a flow rate required by exciting negative pressure, and conveying the pressurized backwater to a water molecule high-frequency oscillation bin (3) through a water inlet pipe (6);

b. the flow velocity of water is changed instantaneously when the water flow passes through the negative pressure exciter (1), a high-pressure cyclone is generated in the negative pressure excitation cavity (12), and water molecules are excited to generate stronger negative pressure;

c. the negative pressure of water molecules is enhanced through a negative pressure feedback structure;

d. the water molecules with very strong negative pressure release negative pressure in the water molecule high-frequency oscillation bin (3), and trigger the water molecules to generate high-frequency oscillation to generate collision friction and temperature rise, so that the water is heated;

e. the hot water heated in the water molecule high-frequency oscillation bin (3) is conveyed to the heat storage box (13) through the hot water pipe (14), the heat storage box (13) returns to be circularly heated through the water return pipe (9), the temperature is raised in a gradient manner, and the heating is continuously carried out for a plurality of times, so that the water temperature is gradually raised to the temperature required by heat supply;

f. the heat energy accumulated in the heat storage tank (13) is transmitted to a user through a circulation system.

The invention relates to a heating method utilizing water molecule high-frequency oscillation, which comprises a negative pressure exciter, a water molecule high-frequency oscillation bin, a negative pressure feedback pipe and a pressurizing pump, wherein an accelerating hole is formed in the negative pressure exciter, and a negative pressure excitation cavity is arranged in the accelerating hole. The water flow pressurized by the pressurizing pump generates stronger negative pressure after passing through the negative pressure exciter, and the negative pressure triggers water molecules to generate high-frequency oscillation when the water molecule high-frequency oscillation bin is released, so that the water is collided, rubbed and warmed, and the water is heated.

The heat supply method utilizing the high-frequency oscillation of the water molecules realizes a revolution of water heating technology in the thermal engineering field, does not directly consume traditional petrochemical energy sources such as coal, oil and gas, does not use electric heating materials which consume large power and are easy to scale, does not need laying a network pipeline for central heat supply, does not generate high pressure in the operation process, does not scale equipment, is safe and reliable, has lower failure rate and maintenance cost, and can realize unattended operation. Compared with the traditional heat supply technology, the invention has the advantages of simple structure, incomparable manufacturing and running cost, more importantly, the invention can provide wide prospect for realizing the construction of green heat supply in the aspects of energy conservation, consumption reduction, emission reduction, environmental pollution and the like.

Drawings

FIG. 1 is a schematic diagram of a water molecule high-frequency oscillation heating device;

FIG. 2 is a cross-sectional view of a negative pressure actuator;

fig. 3 is an external view structure diagram of the upper and lower surfaces of the negative pressure actuator.

Legend: 1. a negative pressure exciter 2, a hot water outlet 3, a water molecule high-frequency oscillation bin 4, a connecting flange 5, a negative pressure feedback pipe 6, a water inlet pipe 7, a water outlet valve 8 and a water return valve, 9, a return water pipe, 10, a booster pump, 11, an acceleration hole, 12, a negative pressure excitation cavity, 13, a heat storage tank, 14, a hot water pipe, 15, a hot water output port, 16 and a return water input port.

Detailed Description

The present invention is not limited by the following examples, and specific embodiments can be determined according to the technical scheme and practical situation of the present invention.

Examples

The invention relates to a heating method utilizing water molecule high-frequency oscillation, wherein a water molecule high-frequency oscillation heating device involved in the method consists of a negative pressure exciter 1, a hot water outlet 2, a water molecule high-frequency oscillation bin 3, a connecting flange 4, a negative pressure feedback pipe 5, a water inlet pipe 6, a water outlet valve 7, a water return valve 8, a water return pipe 9, a booster pump 10, a heat storage box 13 and a hot water pipe 14; the water inlet end of the booster pump 10 is communicated with a water return port of the heat storage tank 13 through a water return pipe 9, and the water outlet end of the booster pump 10 is communicated with the water inlet pipe 6; the water inlet pipe 6 is communicated with the water molecule high-frequency oscillation bin 3 through the flange 4, a negative pressure exciter 1 with the diameter identical to the aperture of the flange hole is arranged in the flange hole of the connecting flange 4, a plurality of vertically through accelerating holes 11 are uniformly formed in the negative pressure exciter 1, and a concave negative pressure excitation cavity 12 with the diameter larger than the aperture of the accelerating holes 11 is arranged between the upper port and the lower port of the accelerating holes 11; the bottom of the water molecule high-frequency oscillation bin 3 is communicated with a water inlet pipe 6 of a pressurizing pump 10 through a negative pressure feedback pipe 5, a hot water outlet 2 is arranged at the top of the water molecule high-frequency oscillation bin 3 and is communicated with a water inlet end of a heat storage box 13 through a hot water pipe 14, and a water return valve 8 and a water outlet valve 7 are respectively and correspondingly arranged at the water inlet end and the water outlet end of the pressurizing pump 10; the specific operation is carried out according to the following steps:

a. opening the water outlet valve 7 and the water return valve 8, starting the pressurizing pump 10, pressurizing the water return to a certain water pressure by the pressurizing pump 10 to reach the flow rate required by exciting the negative pressure, and conveying the pressurized water return to the water molecule high-frequency oscillation bin 3 through the water inlet pipe 6;

b. the flow velocity of water is changed instantaneously when the water flow passes through the negative pressure exciter 1, a high-pressure cyclone is generated in the negative pressure exciting cavity 12, and water molecules are excited to generate stronger negative pressure;

c. the negative pressure of water molecules is enhanced through a negative pressure feedback structure;

d. the water molecules with very strong negative pressure release negative pressure in the water molecule high-frequency oscillation bin 3, and trigger the water molecules to generate high-frequency oscillation to generate collision friction and temperature rise so as to heat the water;

e. the hot water heated in the water molecule high-frequency oscillation bin 3 is conveyed to the heat storage tank 13 through the hot water pipe 14, the heat storage tank 13 returns to be circularly heated through the water return pipe 9, the temperature is raised in a echelon manner, and the heating is continuously carried out for a plurality of times, so that the water temperature is gradually raised to the temperature required by heat supply;

f. the heat energy accumulated in the heat storage tank 13 is delivered to the user through the circulation system;

as shown in fig. 1, the high-frequency oscillation heating device consists of a negative pressure exciter 1, a hot water outlet 2, a water molecule high-frequency oscillation bin 3, a connecting flange 4, a negative pressure feedback pipe 5, a water inlet pipe 6, a water outlet valve 7, a water return valve 8, a water return pipe 9, a booster pump 10, a heat storage box 13 and a hot water pipe 14; the water molecule high-frequency oscillation bin 3 has the function of enabling water molecules to release negative pressure to trigger the water molecules to generate high-frequency oscillation temperature rise, realizing the heating temperature rise of water, and processing a bin body into a cylindrical, square or spherical tank body, wherein the processing of stainless steel materials is optimized for enhancing the rust prevention and heat preservation effects, and meanwhile, a heat preservation layer is additionally arranged; the function of the booster pump 10 is to increase the water pressure so that the water flow speed in the water inlet pipe 6 reaches the flow speed required by the negative pressure exciter 1 to excite the negative pressure of water molecules; the water inlet end of the booster pump 10 is communicated with a water return port of the heat storage tank 13 through a water return pipe 9, and the water outlet end of the booster pump is communicated with the water inlet pipe 6; a water return valve 8 is arranged at the water inlet end of the booster pump 10, and a water outlet valve 7 is arranged at the water outlet end of the booster pump; in order to further accelerate the water flow at the water inlet end of the water molecule high-frequency oscillation bin 3 and further strengthen the negative pressure value of the water molecule through negative pressure feedback, a negative pressure feedback pipe 5 is arranged between the water inlet ends of the water molecule high-frequency oscillation bin 3 and the pressurizing pump 10 to communicate the water molecule high-frequency oscillation bin 3 and the pressurizing pump 10; the port of the negative pressure feedback pipe 5, which is communicated with the water molecule high-frequency oscillation bin 3, is arranged at the position which is close to the port of the water inlet pipe 6 of the water molecule high-frequency oscillation bin 3 as much as possible, so that the effects of increasing the flow speed and enhancing the negative pressure are better; a hot water outlet 2 is arranged at the top of the water molecule high-frequency oscillation bin 3 and is communicated with the water inlet end of the heat storage box 13 through a hot water pipe 14, so that the hot water heated and warmed in the water molecule high-frequency oscillation bin 3 is sent into the heat storage box 13 and is matched with backwater to form cyclic heating, and the temperature rise is carried out in a echelon manner; the hot water in the heat storage tank 13 is conveyed to a user needing heat through a circulating system; in order to ensure rust prevention and heating effects, the components such as the pipe, the valve, the connecting flange and the like in the device are preferably made of stainless steel materials and are additionally provided with heat insulation materials for heat insulation;

as shown in fig. 1, 2 and 3, a water inlet pipe 6 is communicated with a water molecule high-frequency oscillation bin 3 through a connecting flange 4, a negative pressure exciter 1 with the diameter identical with the aperture of the flange hole is arranged in the flange hole of the connecting flange 4, a plurality of vertical through accelerating holes 11 are uniformly formed on the negative pressure exciter 1, and a concave negative pressure exciting cavity 12 with the diameter larger than the aperture of the accelerating holes 11 is processed between the upper port and the lower port of the accelerating holes 11; the height of the negative pressure exciter 1 can be selected to be consistent with the depth of a flange hole on the flange plate, and the negative pressure exciter 1 is connected and fixed with threads processed in the flange hole through threads processed at the outer edge of the negative pressure exciter; the manufacture of the negative pressure exciter 1 preferably adopts a 3D additive printing manufacturing process, and the material is preferably processed by high-strength tungsten, manganese alloy or stainless steel materials; the sizes and corresponding parameters of the negative pressure exciter 1, the accelerating hole 11 and the negative pressure exciting cavity 12 are determined according to the power parameters required by the heating system; the negative pressure exciter 1 is a core component of the invention, and has the function of mainly enabling water flow to instantaneously change the flow velocity of water when passing through, and simultaneously generating a high-pressure cyclone in the negative pressure excitation cavity 12 to excite water molecules to generate stronger negative pressure.

According to the heat supply method utilizing the high-frequency oscillation of the water molecules, the specially designed water flow accelerating structure is utilized, so that the water in a high-pressure state instantaneously changes the flow speed and generates stronger negative pressure, the negative pressure effect can lead the water molecules to generate strong high-frequency oscillation, collision, friction and temperature rise, and the water heating function is realized. The water temperature is gradually increased to the temperature required by heat supply by circularly heating the water in the heating process for a plurality of times, so that low-cost heat energy can be continuously provided for heating and heat supply users.

The heat supply method utilizing the high-frequency oscillation of the water molecules has the advantages that experimental operation is carried out, through multiple measurement and calculation on operation data obtained through actual operation, the result is that the power consumption is required to be 38 ℃ on average for heating 1 ton of water to 55 ℃, and the power consumption is required to be 124 ℃ on average for heating 1 ton of water to 55 ℃ in the traditional electric heating method, so that the method is 70% more energy-saving than the traditional electric heating method. The unit operation cost of the heating system adopting the method is reduced by 70-80% compared with the unit operation cost of the central heating system.

In conclusion, compared with the traditional energy heating method or the electric heating method, the method has obvious advantages in the aspects of energy conservation and consumption reduction of heat supply. And simultaneously, the method has obvious technical progress in the aspects of environmental protection, operation and maintenance cost, manufacturing cost and safe production. Provides a good foundation for realizing unattended heating and green heating, and has very good social and economic benefits.

The technical characteristics form the optimal embodiment of the invention, have stronger adaptability and optimal implementation effect, and can increase or decrease unnecessary technical characteristics according to actual needs so as to meet the needs of different situations.

Claims (1)

1. A heat supply method utilizing water molecule high-frequency oscillation is characterized in that a water molecule high-frequency oscillation heat supply device involved in the method consists of a negative pressure exciter (1), a hot water outlet (2), a water molecule high-frequency oscillation bin (3), a connecting flange (4), a negative pressure feedback pipe (5), a water inlet pipe (6), a water outlet valve (7), a water return valve (8), a water return pipe (9), a pressurizing pump (10), a heat storage box (13) and a hot water pipe (14); the water inlet end of the pressure pump (10) is communicated with a water return port of the heat storage tank (13) through a water return pipe (9), and the water outlet end of the pressure pump (10) is communicated with the water inlet pipe (6); the water inlet pipe (6) is communicated with the water molecule high-frequency oscillation bin (3) through the flange (4), a negative pressure exciter (1) with the diameter identical to the aperture of the flange hole is arranged in the flange hole of the connecting flange (4), a plurality of vertical through accelerating holes (11) are uniformly formed in the negative pressure exciter (1), and a concave negative pressure excitation cavity (12) with the diameter larger than the aperture of the accelerating holes (11) is arranged between the upper port and the lower port of the accelerating holes (11); the bottom of the water molecule high-frequency oscillation bin (3) is communicated with a water inlet pipe (6) of the pressurizing pump (10) through a negative pressure feedback pipe (5), a hot water outlet (2) is arranged at the top of the water molecule high-frequency oscillation bin (3), the water outlet is communicated with a water inlet end of the heat storage box (13) through a hot water pipe (14), and a water return valve (8) and a water outlet valve (7) are respectively and correspondingly arranged at the water inlet end and the water outlet end of the pressurizing pump (10); the specific operation is carried out according to the following steps:

a. opening a water outlet valve (7) and a water return valve (8), starting a pressurizing pump (10), and enabling the pressurizing pump (10) to pressurize backwater to a certain water pressure to achieve a flow rate required by exciting negative pressure, and conveying the pressurized backwater to a water molecule high-frequency oscillation bin (3) through a water inlet pipe (6);

b. the flow velocity of water is changed instantaneously when the water flow passes through the negative pressure exciter (1), a high-pressure cyclone is generated in the negative pressure excitation cavity (12), and water molecules are excited to generate stronger negative pressure;

c. the negative pressure of water molecules is enhanced through a negative pressure feedback structure;

d. the water molecules with very strong negative pressure release negative pressure in the water molecule high-frequency oscillation bin (3), and trigger the water molecules to generate high-frequency oscillation to generate collision friction and temperature rise, so that the water is heated;

e. the hot water heated in the water molecule high-frequency oscillation bin (3) is conveyed to the heat storage box (13) through the hot water pipe (14), the heat storage box (13) returns to be circularly heated through the water return pipe (9), the temperature is raised in a gradient manner, and the heating is continuously carried out for a plurality of times, so that the water temperature is gradually raised to the temperature required by heat supply;

f. the heat energy accumulated in the heat storage tank (13) is transmitted to a user through a circulation system.