CN212390449U - Swirl integrated heat source station for radio energy storage - Google Patents

Abstract

The utility model discloses an swirl radio energy storage integration heat source station, including outlet pipe way, return water pipeline and controlling means, its characterized in that still includes air inlet pipeline, interior heating pipeline and air water siphon mixing arrangement, temperature sensor, pressure sensor and electric heating element, interior heating pipeline one end is connected with the return water pipeline, and the other end is connected with outlet pipe way, air inlet pipeline is located interior heating pipeline top, air inlet pipeline gas outlet is linked together through connecting pipe and air water siphon mixing arrangement, and the air inlet is connected with the air supply, air water siphon mixing arrangement establishes on interior heating pipeline, the utility model discloses owing to adopt above-mentioned structure, have simple structure, compactness, energy saving, heat fast, heating efficiency is high, equipment cost is low, the investment is little, small, convenient to use, the installation is swift simple, intelligent degree is high, Safe operation, unattended operation and the like.

Description

Swirl integrated heat source station for radio energy storage

Technical Field

The utility model relates to a heating equipment technical field, specific swirl radio energy storage integrated heat source station that says so.

Background

With the development of society and the improvement of requirements of human beings on living environment, the requirements of heating in winter on energy and quality requirements are gradually more and more urgent for replacing pollution emissions such as combustible coal and heavy oil by clean energy, the energy price of clean energy electricity and natural gas is 5-7 times of that of coal to become a bottleneck of transformation, and the bottleneck contradiction is solved by improving the energy efficiency of clean energy through a scientific and technological method.

At present, the market electric boiler has low energy efficiency, various heat pump heating devices are difficult to meet the constant index of heating efficiency due to large environmental temperature difference in winter in the application of cold regions, and the device use environment and the installation auxiliary facilities are complex; the direct-heating type electric energy efficiency ratio is very low, and a matched machine room and a boiler room for power distribution are required to be constructed during application and installation, so that the investment is large and the auxiliary engineering is complex.

Disclosure of Invention

The utility model aims at solving the not enough of above-mentioned prior art, provide a simple structure, compactness, energy saving, heat fast, heating efficiency is high, equipment cost is low, the investment is little, small, convenient to use, installation are swiftly simple, intelligent degree is high, the operation is safe, the swirl radio energy storage integration heat source station of unmanned on duty's intelligent teletransmission management.

The utility model provides a technical scheme that its technical problem adopted is:

an swirl radio energy storage integrated heat source station comprises a water outlet pipeline (1), a water return pipeline (2) and a control device, wherein a transmission and distribution circulating pump (3) and a first electronic flowmeter (4) are sequentially installed on the water return pipeline (2), the transmission and distribution circulating pump (3) and the first electronic flowmeter (4) are connected with the control device, the station is characterized by further comprising an air inlet pipeline (5), an inner heating pipeline (6), an air-water siphon mixing device (7), a temperature sensor (8), a pressure sensor (9), an electric heating element (10) and a water drain valve, one end of the inner heating pipeline (6) is connected with the water return pipeline (2), the other end of the inner heating pipeline is connected with the water outlet pipeline (1), the air inlet pipeline (5) is positioned above the inner heating pipeline (6), an air outlet of the air inlet pipeline (5) is communicated with the air-water siphon mixing device (7) through a connecting pipe, the air inlet is connected with an air source, the air-water siphon mixing device is arranged on the inner heating pipeline (6) to facilitate the change of heating water into an elastic fluid medium through the air-water siphon mixing device (7), namely, an elastic heating medium with bubbles is generated by wrapping air with a bubble film through an swirl jet principle, the inner heating pipeline (6) is provided with a temperature sensor (8), a pressure sensor (9) and an electric heating element (10), the temperature sensor (8), the pressure sensor (9), the electric heating element (10) and a water drain valve are respectively connected with the control device, the fluid medium is attached to the electric heating element (10) when passing through the electric heating element (10) to form a plurality of bubbles wrapped by water films of gasification points, water around the boundaries of the bubbles is continuously gasified to form water envelopes, when the internal tension of the water bubbles wrapping the gas is greater than the adhesive force of the heating element, a large amount of monomolecular bubble bodies are further generated in the elastic flow medium, the elastic flow medium is further fully mixed with the air and the water by an air-water siphon mixing device (7) to increase the flow rate and do work by inertia, the elastic flow medium continuously generates heat by mutual friction in the flow process of the internal heating pipeline, meanwhile, the heat supply resistance is changed into friction in the heat supply process, the driving energy consumption is converted into a friction energy heating body in the heat supply pipeline, a large amount of friction heat and electric energy are generated by the elastic flow medium to heat and superpose to manufacture heat energy, in the heat supply process, when the pressure reaches a set upper limit value, the control device instructs the water drain valve to open to release the fluid in the internal heating pipeline, when the pressure reaches a set lower limit value, the control device instructs the water drain valve to close, when the temperature detected by the control device reaches the set upper limit value, the control device instructs the electric heating, not only saves energy, but also achieves the effects of small volume, compact structure, convenient use, quick and simple installation,

the utility model discloses can be equipped with inner loop pipeline (11) between return water pipeline (2) and outlet conduit (1), inner loop pipeline (11) one end is linked together through tee bend pipeline (39) and interior heating pipeline (6) and outlet conduit, and the other end is linked together with the interior heating pipeline other end, return water pipeline and inner loop pipeline communicate, be equipped with aerodynamic energy mixing pump (22), second electronic flowmeter (23) on interior heating pipeline (6), aerodynamic energy mixing pump (22) and second electronic flowmeter (23) are installed respectively on interior heating pipeline (6), aerodynamic energy mixing pump (22), second electronic flowmeter (23) are connected with controlling means respectively to make a part of elastic flow medium in the inner loop pipeline under the power of aerodynamic energy mixing pump, mix the acceleration rate once more through the heating gasification of electrical heating element on interior heating pipeline and the heating element's of interior heating pipeline and gas-water siphon mixing arrangement once more and make The heat energy stored by the elastic circulating medium is further remarkably improved, when energy is stored, due to the elastic expansion of the elastic circulating medium, the pressure in the internal circulation pipeline and the internal heating pipeline is increased, the pressure sensor uploads the sensed pressure information to the control device in real time, the temperature sensor uploads the temperature information to the control device in real time, when the temperature detected by the control device reaches a set upper limit value, the control device instructs the electric heating element to stop heating, and the effects of intelligent control, energy conservation and safe operation are further achieved.

The utility model discloses can be equipped with thermal cycle medium energy storage equipment (12) on interior heating pipeline (6), it includes medium expansion tank (13) and at least one unit heat accumulation barrel (14), be equipped with feed liquor chamber (15), heat-retaining chamber (16) and play liquid chamber (17) in proper order in unit heat accumulation barrel (14), be equipped with a plurality of heat storage pipes (18) in heat storage chamber (16), heat storage chamber (16) are linked together through oil circuit and medium expansion tank (13), it has heat accumulation medium (19) to fill in the clearance of heat storage chamber (16) and heat storage pipe (18), heat storage pipe (18) one end is linked together with feed liquor chamber (15), and the other end is linked together with play liquid chamber (17), feed liquor chamber (15) and the feed liquor end of interior heating pipeline (6) are linked together, it is linked together with the heat accumulation end of interior heating pipeline (6) to go out liquid chamber (17) to do benefit to carry out heat preservation heat accumulation through the elastic fluid of liquid medium (19) in heat accumulation pipe (18) and hold The elastic flow medium flowing through the internal circulation pipeline (11) and the internal heating pipeline (6) and entering the heat storage pipe (18) is subjected to heat preservation and heat storage, so that the effect of further saving energy is achieved.

When unit heat accumulation barrel (14) are more than two, end to end connection between adjacent unit heat accumulation barrel (14) to do benefit to the circulation route of extension elasticity circulation medium, increase bubble medium collides each other and the friction heat energy that forms.

The utility model discloses also can feed liquor chamber (15) and play liquid chamber (17) axle center are equipped with heat accumulation medium passageway (37) respectively, heat accumulation medium passageway (37) are linked together with heat storage chamber (16) to reach the abundant heat retaining effect of heat accumulation of elastic fluid medium.

The electric heating element (10) can be arranged on the unit heat storage barrel body (14) to achieve the effects of heat storage, heat preservation, heat energy superposition and heat efficiency ratio increase.

The utility model discloses can heat the pipeline within a definite time at return water pipeline and be equipped with the moisturizing case, moisturizing case (21) is linked together through moisturizing pipeline (24) and interior heating pipeline (6), be equipped with the liquid level detection switch on moisturizing case (21), the water source is connected in moisturizing case (21), be equipped with control switch valve (25) on moisturizing pipeline (24), control switch valve (25) and liquid level detection switch are connected with controlling means respectively to when the flow of the water in second electronic flowmeter detects interior heating pipeline (6) is not enough, open through controlling means instruction control switch valve (25), the water in moisturizing case (21) is supplemented to interior heating pipeline (6) promptly, reaches the stable effect of heat supply.

Tee bend tube coupling inner loop pipeline's an interface diameter is less than the interface diameter of connecting water outlet pipe way to do benefit to and shunt the elasticity circulation medium, and will further compress the elasticity circulation medium through inner loop pipeline's minor diameter pipeline, deposit the energy, and then produce a large amount of friction heat.

The utility model discloses can be equipped with tubaeform built-in pipeline (38) between inner loop pipeline and tee bend pipeline, tubaeform built-in pipeline path end is connected with the inner loop pipeline, big footpath end is connected with the tee bend pipeline, so that tubaeform built-in pipeline path end exerts the resistance collision once more to the part circulation of elasticity medium through the reducer energy storage, make it produce more heat energy, the path end secondary compression energy storage of circulation of elasticity medium after the collision once more through tubaeform built-in pipeline, further accelerate the velocity of flow of circulation of elasticity medium, increase the friction of bubble and rise power, in order to reach the effect of further energy storage.

The gas-water siphon mixing device of the utility model comprises an expansion cavity (26), a water inlet pipe (27) and a reducer (28), wherein the water inlet pipe (27) is horizontally arranged in the inner cavity of the expansion cavity (26), one end of the expansion cavity (26) is fixedly connected with an inner heating pipeline (6) in a sealing way, the other end of the expansion cavity is fixedly communicated with the reducer (28), a gas circulation cavity 29 is formed between the expansion cavity (26) and the water inlet pipe 26, the gas circulation cavity 29 of the expansion cavity (26) is communicated with an air inlet pipeline (5) above through a connecting pipe,

the reducer (28) is formed by coaxially connecting a left conical pipe (29), a connecting pipe (30) and a right conical pipe (31), the left end of the connecting pipe (30) is connected with the small-diameter end of the left conical pipe (29), the right end of the connecting pipe is connected with the small-diameter end of the right conical pipe (31), the large-diameter end of the right conical pipe (31) is connected with an expansion cavity (26), the left end of the left conical pipe (29) is communicated with a three-way valve on an internal circulation pipeline (11), a third interface of the three-way valve is communicated with a water outlet pipeline (1),

the left end of the water inlet pipe (27) is inserted into the right conical pipe (31), the periphery of the water inlet pipe and the right conical pipe (31) form a gas circulation gap (32), the right end of the water inlet pipe is fixedly communicated with the small diameter end of the funnel-shaped reducing pipe (33), the large diameter end of the funnel-shaped reducing pipe (33) is communicated with the inner heating pipeline (6),

so that gas is sucked into the gas circulation gap through the gas inlet pipeline (5) under the siphon physical action and enters the reducer (28) along with the rotational flow of the side wall of the expansion cavity, meanwhile, real water forms high-pressure jet flow in the water inlet pipe through the gradual reduction of the diameter of the funnel-shaped reducer, the gas which is rotated out of the gas circulation gap (32) is jetted and sucked into the reducer (28), so that the water and the gas change the incompressible real water into a bubble elastic circulation medium which is formed by mixing the water and the gas and then changing the mixture into compressible micro bubbles in a gas-in-water form under the action of swirl jet flow, when the fluid which is mixed with the water passes through the right conical pipe, the fluid which is mixed with the water is scattered through the resistance collision of the right conical pipe to generate more bubble elastic circulation media, the bubble elastic circulation media collide with each other to generate heat energy, and the bubble elastic circulation media are released in the reducer (28) through the diameter changing action of the connecting pipe and increase the flow, so that the mixed bubble elastic flow medium further collides violently and rubs to generate heat energy again, and then the bubble elastic flow medium is further mixed fully and flows out through the taper of the left taper pipe.

The electric heating element adopts a semiconductor MCH electric heating element to achieve the effect of high energy efficiency.

The utility model discloses still can be equipped with tubaeform intake pipe (34) between air intake pipeline (5) and air supply, tubaeform intake pipe (34) path end is connected with air intake pipeline (5), and the air supply is connected to the path end to do benefit to and form gas compression through tubaeform intake pipe and enter into the gas circulation chamber with high-pressure gas, the siphon effect of rivers in the high-pressure gas recycle intake pipe enters into the reducing ware and mixes.

The utility model discloses still can install stop valve (35) and check valve (36) on air inlet pipeline (5), stop valve (35) are connected with controlling means.

The water drain valve is communicated with the water replenishing tank (21) through a connecting pipeline so as to achieve the effect of saving water source.

The utility model discloses a reach safe operation, can set up the alarm, the alarm is connected with controlling means, works as the utility model discloses temperature sensor or first electronic flowmeter, or second electronic flowmeter, or pneumatic energy mixing pump, or control switch valve, or the information of draining the valve and uploading are unusual that controlling means received, and alarm signal is sent to the alarm to reach the stable effect of heat supply.

Controlling means can adopt PLC controller, display screen and power module, the PLC controller is connected with power module and display screen respectively, gathers the information that first electron flowmeter, second electron flowmeter, pressure sensor, temperature sensor, pressure detection switch, liquid level detection switch uploaded through the PLC controller, then instruction transmission joins in marriage circulating pump and/or automatic can the hybrid pump and/or control switch valve and/or stop the valve action, reaches intelligent control's effect.

The utility model discloses still can be in be equipped with communication module in the PLC controller, communication module transmits the data information of gathering in with the PLC controller to cell-phone or computer through cloud ware or internet to reach long-range intelligent control, unmanned on duty's effect.

By adopting the above structure, the utility model, in the electric heating circulation operation in-process, swirl through air water siphon mixing arrangement penetrates the principle and makes thermal cycle medium elastic energy storage, the bore change through tubaeform built-in pipeline makes medium elasticity release increase flow rate form inertia force again in the inner loop pipeline, make the interior production elasticity of elasticity circulation medium change, the friction produces heat energy, and it is effectual with electric energy heat stack heat energy, and has simple structure, compact, energy saving, the heat production is fast, the heating efficiency is high, equipment cost is low, the investment is little, small, high durability and convenient use, the installation is swift simple, intelligent degree is high, the operation is safe, advantages such as unmanned on duty.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present invention.

Fig. 2 is a cross-sectional view of the thermal cycle media energy storage device of the present invention.

Fig. 3 is a left side view of fig. 2.

Fig. 4 is an enlarged view of the middle air-water siphon mixing device of the present invention.

Reference numerals: the device comprises a water outlet pipeline (1), a water return pipeline (2), a transmission and distribution circulating pump (3), a first electronic flowmeter (4), an air inlet pipeline (5), an internal heating pipeline (6), an air-water siphon mixing device (7), a temperature sensor (8), a pressure sensor (9), an electric heating element (10), an internal circulating pipeline (11), a heat circulating medium energy storage device (12), a medium expansion tank (13), a unit heat storage cylinder (14), a liquid inlet cavity (15), a heat storage cavity (16), a liquid outlet cavity (17), a heat storage pipe (18), a heat storage medium (19), a water supplementing tank (21), a pneumatic energy mixing pump (22), a second electronic flowmeter (23), a water supplementing pipeline (24), a control switch valve (25), an expansion cavity (26), a water inlet pipe (27), a diameter reducer (28), a left conical pipe (29), a connecting pipe (30), a right conical pipe (31), The device comprises a gas circulation gap (32), a funnel-shaped reducing pipe (33), a horn-shaped gas inlet pipe (34), a stop valve (35), a one-way valve (36), a heat storage medium channel (37), a horn-shaped built-in pipeline (38) and a three-way pipeline (39).

Detailed Description

The present invention will be described with reference to the accompanying drawings and examples.

As shown in the attached drawing, the swirl radio energy storage integrated heat source station comprises a water outlet pipeline (1), a water return pipeline (2) and a control device, wherein a transmission and distribution circulating pump (3) and a first electronic flow meter (4) are sequentially installed on the water return pipeline (2), the transmission and distribution circulating pump (3) and the first electronic flow meter (4) are connected with the control device, the station is characterized by further comprising an air inlet pipeline (5), an internal heating pipeline (6), an air-water siphon mixing device (7), a temperature sensor (8), a pressure sensor (9), an electric heating element (10) and a water drain valve, one end of the internal heating pipeline (6) is connected with the water return pipeline (2), the other end of the internal heating pipeline is connected with the water outlet pipeline (1), the air inlet pipeline (5) is positioned above the internal heating pipeline (6), an air outlet of the air inlet pipeline (5) is communicated with the air-water siphon mixing device (7) through a connecting pipe, the air inlet is connected with an air source, the air-water siphon mixing device is arranged on the inner heating pipeline (6) to facilitate the change of heating water into an elastic fluid medium through the air-water siphon mixing device (7), namely, an elastic heating medium with bubbles is generated by wrapping air with a bubble film through an swirl jet principle, the inner heating pipeline (6) is provided with a temperature sensor (8), a pressure sensor (9) and an electric heating element (10), the temperature sensor (8), the pressure sensor (9), the electric heating element (10) and a water drain valve are respectively connected with the control device, the fluid medium is attached to the electric heating element (10) when passing through the electric heating element (10) to form a plurality of bubbles wrapped by water films of gasification points, water around the boundaries of the bubbles is continuously gasified to form water envelopes, when the internal tension of the water bubbles wrapping the gas is greater than the adhesive force of the heating element, a large amount of monomolecular bubble bodies are further generated in the elastic flow medium, the elastic flow medium is further fully mixed with the air and the water by an air-water siphon mixing device (7) to increase the flow rate and do work by inertia, the elastic flow medium continuously generates heat by mutual friction in the flow process of the internal heating pipeline, meanwhile, the heat supply resistance is changed into friction in the heat supply process, the driving energy consumption is converted into a friction energy heating body in the heat supply pipeline, a large amount of friction heat and electric energy are generated by the elastic flow medium to heat and superpose to manufacture heat energy, in the heat supply process, when the pressure reaches a set upper limit value, the control device instructs the water drain valve to open to release the fluid in the internal heating pipeline, when the pressure reaches a set lower limit value, the control device instructs the water drain valve to close, when the temperature detected by the control device reaches the set upper limit value, the control device instructs the electric heating, not only saves energy, but also achieves the effects of small volume, compact structure, convenient use, quick and simple installation,

the utility model discloses can be equipped with inner loop pipeline (11) between return water pipeline (2) and outlet conduit (1), inner loop pipeline (11) one end is linked together through tee bend pipeline (39) and interior heating pipeline (6) and outlet conduit, and the other end is linked together with the interior heating pipeline other end, return water pipeline and inner loop pipeline communicate, be equipped with aerodynamic energy mixing pump (22), second electronic flowmeter (23) on interior heating pipeline (6), aerodynamic energy mixing pump (22) and second electronic flowmeter (23) are installed respectively on interior heating pipeline (6), aerodynamic energy mixing pump (22), second electronic flowmeter (23) are connected with controlling means respectively to make a part of elastic flow medium in the inner loop pipeline under the power of aerodynamic energy mixing pump, mix the acceleration rate once more through the heating gasification of electrical heating element on interior heating pipeline and the heating element's of interior heating pipeline and gas-water siphon mixing arrangement once more and make The heat energy stored by the elastic circulating medium is further remarkably improved, when energy is stored, due to the elastic expansion of the elastic circulating medium, the pressure in the internal circulation pipeline and the internal heating pipeline is increased, the pressure sensor uploads the sensed pressure information to the control device in real time, the temperature sensor uploads the temperature information to the control device in real time, when the temperature detected by the control device reaches a set upper limit value, the control device instructs the electric heating element to stop heating, and the effects of intelligent control, energy conservation and safe operation are further achieved.

The utility model discloses can be equipped with thermal cycle medium energy storage equipment (12) on interior heating pipeline (6), it includes medium expansion tank (13) and at least one unit heat accumulation barrel (14), be equipped with feed liquor chamber (15), heat-retaining chamber (16) and play liquid chamber (17) in proper order in unit heat accumulation barrel (14), be equipped with a plurality of heat storage pipes (18) in heat storage chamber (16), heat storage chamber (16) are linked together through oil circuit and medium expansion tank (13), it has heat accumulation medium (19) to fill in the clearance of heat storage chamber (16) and heat storage pipe (18), heat storage pipe (18) one end is linked together with feed liquor chamber (15), and the other end is linked together with play liquid chamber (17), feed liquor chamber (15) and the feed liquor end of interior heating pipeline (6) are linked together, it is linked together with the heat accumulation end of interior heating pipeline (6) to go out liquid chamber (17) to do benefit to carry out heat preservation heat accumulation through the elastic fluid of liquid medium (19) in heat accumulation pipe (18) and hold The elastic flow medium flowing through the internal circulation pipeline (11) and the internal heating pipeline (6) and entering the heat storage pipe (18) is subjected to heat preservation and heat storage, so that the effect of further saving energy is achieved.

When unit heat accumulation barrel (14) are more than two, end to end connection between adjacent unit heat accumulation barrel (14) to do benefit to the circulation route of extension elasticity circulation medium, increase bubble medium collides each other and the friction heat energy that forms.

The utility model discloses also can feed liquor chamber (15) and play liquid chamber (17) axle center are equipped with heat accumulation medium passageway (37) respectively, heat accumulation medium passageway (37) are linked together with heat storage chamber (16) to reach the abundant heat retaining effect of heat accumulation of elastic fluid medium.

The electric heating element (10) can be arranged on the unit heat storage barrel body (14) to achieve the effects of heat storage, heat preservation, heat energy superposition and heat efficiency ratio increase.

The utility model discloses can heat the pipeline within a definite time at return water pipeline and be equipped with the moisturizing case, moisturizing case (21) is linked together through moisturizing pipeline (24) and interior heating pipeline (6), be equipped with the liquid level detection switch on moisturizing case (21), the water source is connected in moisturizing case (21), be equipped with control switch valve (25) on moisturizing pipeline (24), control switch valve (25) and liquid level detection switch are connected with controlling means respectively to when the flow of the water in second electronic flowmeter detects interior heating pipeline (6) is not enough, open through controlling means instruction control switch valve (25), the water in moisturizing case (21) is supplemented to interior heating pipeline (6) promptly, reaches the stable effect of heat supply.

Tee bend tube coupling inner loop pipeline's an interface diameter is less than the interface diameter of connecting water outlet pipe way to do benefit to and shunt the elasticity circulation medium, and will further compress the elasticity circulation medium through inner loop pipeline's minor diameter pipeline, deposit the energy, and then produce a large amount of friction heat.

The utility model discloses can be equipped with tubaeform built-in pipeline (38) between inner loop pipeline and tee bend pipeline, tubaeform built-in pipeline path end is connected with the inner loop pipeline, big footpath end is connected with the tee bend pipeline, so that tubaeform built-in pipeline path end exerts the resistance collision once more to the part circulation of elasticity medium through the reducer energy storage, make it produce more heat energy, the path end secondary compression energy storage of circulation of elasticity medium after the collision once more through tubaeform built-in pipeline, further accelerate the velocity of flow of circulation of elasticity medium, increase the friction of bubble and rise power, in order to reach the effect of further energy storage.

The gas-water siphon mixing device of the utility model comprises an expansion cavity (26), a water inlet pipe (27) and a reducer (28), wherein the water inlet pipe (27) is horizontally arranged in the inner cavity of the expansion cavity (26), one end of the expansion cavity (26) is fixedly connected with an inner heating pipeline (6) in a sealing way, the other end of the expansion cavity is fixedly communicated with the reducer (28), a gas circulation cavity 29 is formed between the expansion cavity (26) and the water inlet pipe 26, the gas circulation cavity 29 of the expansion cavity (26) is communicated with an air inlet pipeline (5) above through a connecting pipe,

the reducer (28) is formed by coaxially connecting a left conical pipe (29), a connecting pipe (30) and a right conical pipe (31), the left end of the connecting pipe (30) is connected with the small-diameter end of the left conical pipe (29), the right end of the connecting pipe is connected with the small-diameter end of the right conical pipe (31), the large-diameter end of the right conical pipe (31) is connected with an expansion cavity (26), the left end of the left conical pipe (29) is communicated with a three-way valve on an internal circulation pipeline (11), a third interface of the three-way valve is communicated with a water outlet pipeline (1),

the left end of the water inlet pipe (27) is inserted into the right conical pipe (31), the periphery of the water inlet pipe and the right conical pipe (31) form a gas circulation gap (32), the right end of the water inlet pipe is fixedly communicated with the small diameter end of the funnel-shaped reducing pipe (33), the large diameter end of the funnel-shaped reducing pipe (33) is communicated with the inner heating pipeline (6),

so that gas is sucked into the gas circulation gap through the gas inlet pipeline (5) under the siphon physical action and enters the reducer (28) along with the rotational flow of the side wall of the expansion cavity, meanwhile, real water forms high-pressure jet flow in the water inlet pipe through the gradual reduction of the diameter of the funnel-shaped reducer, the gas which is rotated out of the gas circulation gap (32) is jetted and sucked into the reducer (28), so that the water and the gas change the incompressible real water into a bubble elastic circulation medium which is formed by mixing the water and the gas and then changing the mixture into compressible micro bubbles in a gas-in-water form under the action of swirl jet flow, when the fluid which is mixed with the water passes through the right conical pipe, the fluid which is mixed with the water is scattered through the resistance collision of the right conical pipe to generate more bubble elastic circulation media, the bubble elastic circulation media collide with each other to generate heat energy, and the bubble elastic circulation media are released in the reducer (28) through the diameter changing action of the connecting pipe and increase the flow, so that the mixed bubble elastic flow medium further collides violently and rubs to generate heat energy again, and then the bubble elastic flow medium is further mixed fully and flows out through the taper of the left taper pipe.

The electric heating element adopts a semiconductor MCH electric heating element to achieve the effect of high energy efficiency.

The utility model discloses still can be equipped with tubaeform intake pipe (34) between air intake pipeline (5) and air supply, tubaeform intake pipe (34) path end is connected with air intake pipeline (5), and the air supply is connected to the path end to do benefit to and form gas compression through tubaeform intake pipe and enter into the gas circulation chamber with high-pressure gas, the siphon effect of rivers in the high-pressure gas recycle intake pipe enters into the reducing ware and mixes.

The utility model discloses still can install stop valve (35) and check valve (36) on air inlet pipeline (5), stop valve (35) are connected with controlling means.

The water drain valve is communicated with the water replenishing tank (21) through a connecting pipeline so as to achieve the effect of saving water source.

The utility model discloses a reach safe operation, can set up the alarm, the alarm is connected with controlling means, works as the utility model discloses temperature sensor or first electronic flowmeter, or second electronic flowmeter, or pneumatic energy mixing pump, or control switch valve, or the information of draining the valve and uploading are unusual that controlling means received, and alarm signal is sent to the alarm to reach the stable effect of heat supply.

Controlling means can adopt PLC controller, display screen and power module, the PLC controller is connected with power module and display screen respectively, gathers the information that first electron flowmeter, second electron flowmeter, pressure sensor, temperature sensor, pressure detection switch, liquid level detection switch uploaded through the PLC controller, then instruction transmission joins in marriage circulating pump and/or automatic can the hybrid pump and/or control switch valve and/or stop the valve action, reaches intelligent control's effect.

The utility model discloses still can be in be equipped with communication module in the PLC controller, communication module transmits the data information of gathering in with the PLC controller to cell-phone or computer through cloud ware or internet to reach long-range intelligent control, unmanned on duty's effect.

The utility model discloses before the heat accumulation heat supply, under the initial condition, outlet pipe way, return water pipeline, inner loop pipeline and interior heating pipeline all are full of real water, usually set up according to the nominal pressure of building earlier the utility model discloses a pressure value is nominal pressure's 40-70% scope.

When heat storage and heat supply are carried out, a PLC (programmable logic controller) is connected with a power supply through a power supply module, a start key on a display screen is clicked or touched, a transmission and distribution circulating pump (3), a first electronic flowmeter (4), a pneumatic energy mixing pump (22), a second electronic flowmeter (23) and an electric heating element (10) are started, real water is heated through the electric heating element (10) and enters a transition funnel-shaped reducer pipe 32 of a gas-water siphon mixing device (7), high-pressure jet flow is formed in the real water in a water inlet pipe through reduction of a funnel-shaped reducer pipe, gas which flows out in a swirling mode from a gas circulation gap (32) is jetted and sucked into a reducer (28), non-compressible real water is changed into a bubble elastic circulation medium of tiny bubbles in a compressible gas-in-water form after the real water and the gas are mixed through jet flow of the water and the gas under the action of swirl, the fluid mixed with the gas and the water collide through the resistance, the method comprises the steps of scattering fluid mixed with gas and water to generate more bubble elastic circulating media, wherein the bubble elastic circulating media collide with each other to generate heat energy, the bubble elastic circulating media are released in a diameter reducer (28) through the diameter reducing action of a connecting pipe and increase the flow rate to form inertia force, the friction tension of bubbles is further increased under the diameter reducing compression of the connecting pipe, the heat energy is generated again, then the bubble elastic circulating media are further and fully mixed to flow into a three-way pipeline through the taper of a left tapered pipe, when the elastic circulating media with the heat supply temperature flow through the three-way pipeline (39), most of the elastic circulating media enter a water outlet pipeline (1) to supply heat to a heat supply pipe network, and a small part of the elastic circulating media flow into an internal circulating pipeline (11) through the three-way pipeline (39), and the taper of a horn-shaped internal pipeline (38) on the internal circulating pipeline (11) faces a part for storing energy through the diameter reducer The elastic circulating medium exerts resistance again to enable the bubbles in the elastic circulating medium to generate mutual collision again to generate more heat energy, the elastic circulating medium after secondary collision is compressed again for energy storage through the small-diameter end of the trumpet-shaped built-in pipeline to further accelerate the flow rate of the elastic circulating medium and increase the frictional tension of the bubbles to further compress again for energy storage, and under the power action of the pneumatic energy mixing pump, the elastic circulating medium and the backwater in the backwater pipeline (2) enter the internal heating pipeline (6), the bubbles wrapped by a plurality of water films of more gasification points are formed again through the electric heating element (10) in the internal heating pipeline (6), water around the bubble boundary is continuously gasified to form a water envelope, when the internal tension of the bubbles wrapped by gas in the water envelope is larger than the adhesive force of the heating element, a large amount of single-molecule bubbles are further generated in the elastic circulating medium, and then the gas and the water are fully mixed by the gas-water siphon mixing device (7) and the flow rate is increased, the inertia work is done, the elastic circulating medium continuously generates heat by mutual friction in the flowing process of the internal circulating pipeline (11) and the internal heating pipeline (6), the heat supply resistance is changed into friction force in the heat supply process, the driving energy consumption is converted into a friction energy heating body in the heat supply pipeline, a large amount of friction heat and electric energy heating and superposition integrated heat are generated by the elastic circulating medium, most of the elastic circulating medium flows into the water outlet pipeline (1) again for heat supply, and a small part of the elastic circulating medium enters the internal circulating pipeline (11), so that the processes are repeatedly circulated, and the energy is continuously stored.

In the circulation process, when the pressure sensors sense that the pressures in the internal circulation pipeline and the internal heating pipeline are higher than the set maximum value, the PLC automatically opens the water drain valve, and the heat supply fluid flows into the water replenishing tank.

In the circulation process, when the pressure sensor senses that the pressure in the internal circulation pipeline and the internal heating pipeline is lower than a set minimum value and the flow values detected by the first electronic flowmeter and the second electronic flowmeter are also lower than a set value, the PLC controller instructs the control switch valve (25) to be opened, water in the water supplementing tank (21) is supplemented into the internal heating pipeline (6), and when the normal values set by the pressure sensor, the first electronic flowmeter and the second electronic flowmeter are reached, the control switch valve is closed by the control device, so that the heat supply stabilizing effect is achieved.

The utility model discloses a make the energy storage heat keep at the optimum temperature, the circulation medium energy storage device heat preservation heat accumulation that sets up in the utilization in-heating pipeline, when the elastic flow medium that produces a large amount of friction heat in the circulation operation in-process in inner loop pipeline and in-heating pipeline gets into the heat storage pipe in the unit heat storage barrel promptly, heat energy in the heat storage pipe keeps warm through the heat storage medium in the unit heat storage barrel to further heat the elastic flow medium through electric heating element, this embodiment the heat storage medium adopts hot oil that holds, has not only improved greatly and has heated efficiency, moreover because simple structure, compactness, is showing and is reducing investment cost, has satisfied cold region because of the big heating demand of the ambient temperature difference in winter.

In the heat storage circulation process, the temperature of hot water flowing back from the water return pipeline is detected through the temperature sensor, when the water return temperature is higher than the set upper limit water temperature, the electric heating element is closed, and when the water return temperature is lower than the set lower limit water temperature, the PLC starts the electric heating element to heat.

The utility model discloses a reach intelligent remote control or modify the parameter, through cell-phone APP or computer web page remote operation, reached intelligent automatic control's effect.

In the heat accumulation heating heat supply in-process, work as the utility model discloses when the information that temperature sensor or first electron flowmeter, or second electron flowmeter, or pneumatic energy mixing pump, or control switch valve, or the valve that drains uploaded of controlling means received is unusual, alarm signal is sent to the alarm to reach real time monitoring, the effect that the heat supply operation is stable.

The upper limit temperature of temperature is the highest temperature of setting for promptly, and the lower limit temperature is the minimum temperature of setting for promptly, and upper limit temperature and lower limit temperature can set up according to scene and the demand of difference.

By adopting the above structure, the utility model, in the electric heating circulation operation in-process, swirl through air water siphon mixing arrangement penetrates the principle and makes thermal cycle medium elastic energy storage, the bore change through tubaeform built-in pipeline makes medium elasticity release increase flow rate form inertia force again in the inner loop pipeline, make the interior production elasticity of elasticity circulation medium change, the friction produces heat energy, and it is effectual with electric energy heat stack heat energy, and has simple structure, compact, energy saving, the heat production is fast, the heating efficiency is high, equipment cost is low, the investment is little, small, high durability and convenient use, the installation is swift simple, intelligent degree is high, the operation is safe, advantages such as unmanned on duty.

Claims (16)

1. An swirl radio energy storage integrated heat source station comprises a water outlet pipeline (1), a water return pipeline (2) and a control device, wherein a transmission and distribution circulating pump (3) and a first electronic flow meter (4) are sequentially installed on the water return pipeline (2), the transmission and distribution circulating pump (3) and the first electronic flow meter (4) are connected with the control device, the station is characterized by further comprising an air inlet pipeline (5), an internal heating pipeline (6), an air-water siphon mixing device (7), a temperature sensor (8), a pressure sensor (9) and an electric heating element (10), one end of the internal heating pipeline (6) is connected with the water return pipeline (2), the other end of the internal heating pipeline is connected with the water outlet pipeline (1), the air inlet pipeline (5) is positioned above the internal heating pipeline (6), and an air outlet of the air inlet pipeline (5) is communicated with the air-water siphon mixing device (7) through a connecting pipe, the air inlet is connected with an air source, the air-water siphon mixing device is arranged on the inner heating pipeline (6), the inner heating pipeline (6) is provided with a temperature sensor (8), a pressure sensor (9) and an electric heating element (10), and the temperature sensor (8), the pressure sensor (9) and the electric heating element (10) are respectively connected with a control device.

2. The swirl radio energy storage integrated heat source station according to claim 1, wherein an internal circulation pipeline (11) is disposed between the water return pipeline (2) and the water outlet pipeline (1), one end of the internal circulation pipeline (11) is connected to the internal heating pipeline (6) and the water outlet pipeline through a three-way pipeline, the other end of the internal circulation pipeline is connected to the other end of the internal heating pipeline, the water return pipeline is connected to the internal circulation pipeline, a pneumatic energy mixing pump (22), a second electronic flow meter (23) and a water drain valve are disposed on the internal heating pipeline (6), the pneumatic energy mixing pump (22) and the second electronic flow meter (23) are respectively mounted on the internal heating pipeline (6), and the pneumatic energy mixing pump (22), the second electronic flow meter (23) and the water drain valve are respectively connected to the control device.

3. An swirl radio energy storage integrated heat source station according to claim 2, wherein the inner heating pipeline (6) is provided with a thermal circulation medium energy storage device (12), which comprises a medium expansion tank (13) and at least one unit heat accumulation barrel (14), wherein a liquid inlet cavity (15), a heat accumulation cavity (16) and a liquid outlet cavity (17) are sequentially arranged in the unit heat accumulation barrel (14), a plurality of heat storage pipes (18) are arranged in the heat storage cavity (16), the heat storage cavity (16) is communicated with the medium expansion tank (13) through an oil way, a heat storage medium (19) is filled in the gap between the heat storage cavity (16) and the heat storage pipe (18), one end of the heat storage pipe (18) is communicated with the liquid inlet cavity (15), the other end is communicated with the liquid outlet cavity (17), the liquid inlet cavity (15) is communicated with the liquid inlet end of the inner heating pipeline (6), the liquid outlet cavity (17) is communicated with the liquid outlet end of the inner heating pipeline (6).

4. An swirl radio energy storage integrated heat source station according to claim 3, wherein when there are more than two unit heat storage cylinders (14), the adjacent unit heat storage cylinders (14) are connected end to end.

5. An swirl radio energy storage integrated heat source station as claimed in claim 3 or 4, wherein the axial centers of the liquid inlet chamber (15) and the liquid outlet chamber (17) are respectively provided with a heat storage medium channel (37), and the heat storage medium channel (37) is communicated with the heat storage chamber (16).

6. An swirl radio energy storage integrated heat source station according to claim 5, characterized in that the electric heating element (10) is provided on the unit heat storage drum (14).

7. The swirl radio energy storage integrated heat source station according to claim 2, 3, 4 or 6, wherein a water replenishing tank is disposed between the water returning pipeline and the internal heating pipeline, the water replenishing tank (21) is communicated with the internal heating pipeline (6) through a water replenishing pipeline (24), the water replenishing tank (21) is provided with a liquid level detection switch, the water replenishing tank (21) is connected to a water source, the water replenishing pipeline (24) is provided with a control switch valve (25), and the control switch valve (25) and the liquid level detection switch are respectively connected to a control device.

8. The integrated swirl radio energy storage and heat source station of claim 7, wherein the diameter of a port of the tee pipe connecting the internal circulation pipe is smaller than the diameter of a port connecting the water outlet pipe.

9. The swirl storing energy as claimed in claim 8, wherein a flared tube (38) is provided between the internal circulation tube and the tee tube, the flared tube is connected to the internal circulation tube at its small diameter end and to the tee tube at its large diameter end.

10. The swirl radio energy storage integrated heat source station of claim 1, 2, 3, 4, 6, 8, or 9, wherein the air-water siphon mixing device includes an expansion chamber (26), a water inlet pipe (27), and a reducer (28), the water inlet pipe (27) is horizontally disposed in the inner chamber of the expansion chamber (26), one end of the expansion chamber (26) is fixedly connected with the inner heating pipeline (6) in a sealing manner, the other end is fixedly connected with the reducer (28), a gas circulation chamber 29 is formed between the expansion chamber (26) and the water inlet pipe (26), the gas circulation chamber 29 of the expansion chamber (26) is connected with the upper air inlet pipeline (5) through a connecting pipe, the reducer (28) is formed by coaxially connecting a left conical pipe (29), a connecting pipe (30), and a right conical pipe (31), the left end of the connecting pipe (30) is connected with the small diameter end of the left conical pipe (29), the right-hand member is connected with the path end of right conical tube (31), the path end of right conical tube (31) is connected with inflation chamber (26), left side conical tube (29) left end is linked together with the three-way valve on inner loop pipeline (11), three-way valve third interface and outlet conduit (1) intercommunication, insert in right conical tube (31) inlet tube (27) left end and its periphery and right conical tube (31) form gas circulation clearance (32), and the right-hand member is fixed with funnel-shaped reducing pipe (33) path end and is linked together, funnel-shaped reducing pipe (33) path end is linked together with interior heating pipeline (6).

11. The swirl radio energy storage integrated heat source station according to claim 10, wherein a flared inlet pipe (34) is provided between the inlet pipe (5) and the air source, the flared inlet pipe (34) has a small diameter end connected to the inlet pipe (5) and a large diameter end connected to the air source.

12. An swirl radio energy storage and integration heat source station, according to claim 2, 3, 4, 6, 8, 9, 11, characterized in that the air inlet pipe (5) is equipped with a stop valve (35) and a check valve (36), the stop valve (35) is connected with a control device.

13. An swirl radio energy storage integrated heat source station, according to claim 12, characterized in that the water discharge valve is connected to the water supply tank (21) through a connecting pipe.

14. An swirl radio energy storage integrated heat source station, according to claim 13, wherein an alarm is provided, said alarm being connected to the control means.

15. An swirl radio energy storage integrated heat source station, according to claim 1, 2, 3, 4, 6, 8, 9, 11, 13, 14, wherein the control device employs a PLC controller, a display screen and a power module, the PLC controller is connected with the power module and the display screen respectively.

16. The swirl radio energy storage integrated heat source station of claim 15, wherein a communication module is provided in the PLC controller, and the communication module transmits data information collected in the PLC controller to a mobile phone or a computer through a cloud server or the internet.

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