CN101004331A - Energy transport system of bidirectional circulated heat pipe - Google Patents

Abstract

Translated fromChinese

本发明涉及一种能源工程技术领域冷或热能量输运系统，尤其是一种利用高效传热热管系统构成低能耗高密度的双向双循环热管能量输运系统，将分离式热管的两类换热器(蒸发器和冷凝器)分别放置在冷、热能量供应源和冷、热能量用户处两个不同地方，通过输气母管、回液母管、储液罐、气液分离母管、分液器、等长度均液管、四通阀、循环溶液泵、回液泵、压力调节阀、回液管及连接管道等，有机连接为一个气液相通的整体，构成双向双循环热管能量输运系统。本发明投资省，热交换力强，效率高，可实现多种供给模式，设备使用寿命长，安装使用操作方便，可广泛用于各种低温差场合的能量输运，也可用于太阳能热和各种余热回收场合。

The invention relates to a cold or heat energy transport system in the technical field of energy engineering, in particular to a bi-directional double-circulation heat pipe energy transport system that uses a high-efficiency heat transfer heat pipe system to form a low-energy consumption and high-density energy transport system. Heaters (evaporators and condensers) are placed in two different places, cold and heat energy supply sources and cold and heat energy users, through the gas transmission main pipe, liquid return main pipe, liquid storage tank, and gas-liquid separation main pipe , liquid separator, liquid equalizing pipe of equal length, four-way valve, circulating solution pump, liquid return pump, pressure regulating valve, liquid return pipe and connecting pipes, etc., are organically connected as a whole with gas and liquid communication, forming a two-way double circulation Heat pipe energy transport system. The invention has the advantages of low investment, strong heat exchange capacity, high efficiency, multiple supply modes, long service life of equipment, convenient installation, operation and operation, and can be widely used for energy transportation in various low-temperature difference occasions, and can also be used for solar thermal heating Various waste heat recovery occasions.

Description

A kind of energy transport system of bidirectional circulated heat pipe

Technical field:

The present invention relates to the cold or thermal energy transport system of a kind of energy project technical field, especially a kind of efficient heat transfer hot-pipe system that utilizes constitutes the highdensity energy transport system of bidirectional circulated heat pipe of low energy consumption.

Technical background:

The efficient utilization of the energy and power saving have become the key issue that can the decision human society long-term sustainable fast development, be subject to people's attention just day by day, and how to make good use of natural natural energy source, as marine energy, the soil energy or the underground water energy, how to make good use of people and will be discharged into waste water in the environment or the energy in the waste gas in life and production process, the efficient utilization and the power saving that the mankind are solved the energy have a very important role; Utilizing in the process of such hot and cold energy, usually need hot and cold energy transporting system.

In human real life and production process, usually occur to provide the place (calling hot and cold energy source of supply in the following text) of hot and cold energy and the place (calling hot and cold energy user place in the following text) of using hot and cold energy that one section longer-distance occasion is arranged, as the utilization of seawater (river or lake water) heat energy, seawater (river or lake water) present position and need between the user of its heat energy one section larger distance is often arranged; The and for example application of the soil energy or the underground water energy, the place that can obtain such hot and cold energy also often and needs use between the user of this energy and have one section larger distance; Hot and cold energy is recycled in the sanitary wastewater for another example, the exhaust position of waste water with need the position of energy that one segment distance is arranged; Also have the recycling of hot and cold energy in the industrial wastewater (gas), the exhaust position of industrial wastewater (gas) with need the customer location of energy that a segment distance far away is also usually arranged; In addition, such as cooling, the heat supply of central air conditioner system, the waste heat of solar thermal utilization, the recovery of air cold energy and utilization, all kinds of boiler or engine or the recovery of other used heat, nuclear energy heat utilization or the like field also usually exists place that hot and cold energy is provided and the place of using hot and cold energy that one section longer-distance occasion is arranged.At this moment hot and cold energy must be transported to another place from a place, promptly relate to the transport issues of hot and cold energy.

At present, the hot and cold energy transport method of human extensive use is to utilize certain liquid working substance to do media, after the place that hot and cold energy is provided obtains energy, with solution pump this liquid working substance is transported to the place that needs hot and cold energy, emits and be sent back to the place that hot and cold energy is provided again behind the hot and cold energy and obtain energy once more; So circulation continuously transports energy.

The shortcoming of this method is:

1, owing to is to utilize the sensible heat of liquid to carry heat, in the heat transfer process in two places of hot and cold energy source of supply and hot and cold energy user place, it is much smaller that its coefficient of heat transfer undergoes phase transition the coefficient of heat transfer of latent heat transport process of process, so under the same temperature difference, it is much bigger to transmit the required heat exchange area of same heat, and the initial cost of heat exchanger is increased.

2, because the sensible heat of liquid raises by temperature or reduces and carry energy, temperature raises just can carry heat energy, temperature reduces just can carry cold energy, for reducing the irreversible loss of the excessive generation of heat transfer temperature difference, the temperature of liquid working substance raises or the reduction value is not often wished excessive, and because the specific heat of liquid is less relatively, make and take away certain energy, need a large amount of liquid working substance circulations, this has not only increased pipeline, the initial cost of insulation material, and increased in the transport process energy loss that the heat exchange with external environment causes, and also increased the liquid solution pump, make its initial cost and the operating cost all bigger.

Usually energy to transport density big more, wait calorific value to transport cost low more, utilize the liquid working substance sensible heat to realize the method for energy transport, energy transport density is less relatively.Transport cost in order to reduce, expectation can be found a kind of big energy transporting system of density that transports.

Summary of the invention:

The objective of the invention is to overcome the shortcoming that exists in the prior art, solution utilizes the liquid sensible heat to realize the existing technical problem of energy transport, a kind of hot and cold energy transporting system method of low energy consumption high density of utilizing the high-efficiency heat pipe system formation of particular design is proposed, this system transports energy with the form of " latent heat ", so its energy transport density height, waiting under the condition that transports of calorific value, circular flow is littler than the circular flow that " sensible heat " form transports energy, can solve to have deficiency in the present hot and cold energy transport process.

To achieve these goals, the present invention is placed on two different places of hot and cold energy source of supply and hot and cold energy user place respectively with the two class heat exchangers (evaporimeter or condenser) of separate heat pipe, the organic integral body that a gas-liquid communicates, formation energy transport system of bidirectional circulated heat pipe of being connected to by gas transmission mother pipe, the female pipe of time liquid, fluid reservoir, air-liquid separating host tube, knockout, the equal liquid pipe of equal length, cross valve, circulation solution pump, time liquid pump, pressure-regulating valve, liquid back pipe and connecting pipe; By the organic assembling of solution circulation pump, knockout, the equal liquid pipe of equal length, evaporimeter and air-liquid separating host tube, pressure-regulating valve and liquid back pipe, formation has strong working solution carrying capacity and the uniformly relatively independent working solution circulation (partial circulatings in two circulations) of separatory.Its every class heat exchanger is one, or a plurality of being formed in parallel; Total system can be divided into condensate liquid feed flow and distribution, gas-liquid two-phase flows with separate, gas-phase transport collects and four subsystems of storage with distribution, liquid phase; Its running is: solution circulation pump extracts liquid refrigerant from fluid reservoir, be transported to knockout through the circulation solution carrier pipe, through knockout and the equal liquid pipe of equal length, equably liquid refrigerant is distributed to each the evaporation pipeline in the evaporimeter, in the evaporation pipeline, liquid refrigerant absorbs the heat of the medium that contacts with it, the partially liq gasification, enter gas-liquid separator through the two phase flow pipe and realize gas-liquid separation, subsequently, flow through pressure-regulating valve and liquid back pipe of liquid refrigerant flows to fluid reservoir, forms the liquid working substance partial circulating; Gas phase working medium then enters air-liquid separating host tube through the female pipe of gas transmission, deliver gas to by the uniform distribution pipe in each pipeline of condenser, in condenser pipe, after the realization total condensation, flow into the fluid reservoir of condenser, send back to the fluid reservoir of evaporimeter again by time liquid pump, form the heat-pipe working medium systemic circulation.Liquid working substance partial circulating and heat-pipe working medium systemic circulation organically combine and constitute energy transport system of bidirectional circulated heat pipe.The effect of partial circulating is control rationally or the internal circulating load that increases liquid working substance in the evaporimeter, has solved problems such as original separate heat pipe working solution carrying capacity is not enough, separatory is inhomogeneous, evaporimeter heat-transfer surface service efficiency is low; Systemic circulation then make heat from medium that evaporimeter contacts be sent to medium that condenser contacts in, finished the latent heat transport process of heat.The working medium of getting back in the fluid reservoir is sent in the evaporimeter once more through solution circulation pump, has begun latent heat transport process next time again; So move in circles, continuously realize transporting of energy.

The heat exchanger that hot and cold energy source of supply is placed among the present invention is an evaporimeter, or condenser; Equally, the heat exchanger that place at hot and cold energy user place is a condenser, or evaporimeter, is determined by the circulating direction of two cross valves in the system.Bidirectional energy propagation function of the present invention refers to utilize same system, both with the hot and cold energy user of the heat transferred of hot and cold energy source of supply, also the cold of hot and cold energy source of supply can be passed to and accept hot and cold energy user.

Hot and cold energy source of supply and hot and cold energy user are one among the present invention, or a plurality of; If both respectively are one, constitute one for a system; If hot and cold energy source of supply is a plurality of, and hot and cold energy user is one, constitutes many for a system; If hot and cold energy source of supply is one, and hot and cold energy user is a plurality of, constitutes one for multisystem; If it is a plurality of that hot and cold energy source of supply and hot and cold energy user all have respectively, then constitute many for multisystem.

The setting height(from bottom) of each evaporimeter and condenser is not limit among the present invention, and fluid reservoir separately is lower than two class heat exchangers respectively, guarantees that condensate liquid can be back to corresponding fluid reservoir smoothly.If heat exchanger must be installed in corresponding fluid reservoir bottom, install a small-sized fluid reservoir and a reflux solution pump additional in this heat exchanger bottom; Solution circulation pump and time liquid pump all are installed in the bottom of fluid reservoir, guarantee to have all the time in the course of work enough solution to use for pump, avoid cavitation, prolong the service life of pump.

The present invention is suitable for the energy transport occasion of the less occasions of the temperature difference such as recycling of hot and cold energy in the application, sanitary wastewater of utilization, soil heat source or the underground water thermal source of seawater (river or lake water) heat energy own; And by selecting rational heat-pipe working medium for use, also can be applicable to the occasion such as recovery, nuclear energy heat utilization of the waste heat of central air-conditioning, solar thermal utilization, the recovery of air cold energy and utilization, all kinds of boiler or engine or other used heat, easily realize maximizing, be convenient to be complementary with heavy construction.

The present invention compared with prior art, have the following advantages: the one, its energy transport density is higher than the mode that transports that the sensible heat that utilizes liquid carries energy, reduced the initial cost of pipeline, insulation material, also reduced in the transport process energy loss that the heat exchange with external environment produces, the liquid solution pump is reduced, and investment reduces; The 2nd, the coefficient of heat transfer is big in the heat transfer process in two places of hot and cold energy source of supply and hot and cold energy user place, and required heat exchange area is little, and the heat exchanger investment is little; The 3rd, system has the bidirectional energy propagation function; The 4th, system has one for one, how for one, one for how with supply various energy transport patterns such as many more; The 5th, need not liquid sucting core structure, simplified the inside heat pipe structure, easily realize maximizing and produce and use, reduced the heat pipe cost; The 6th, its evaporator section and condensation segment are independent respectively to form evaporimeter and condenser, but any-mode (level, vertical or by a certain inclination angle), places respectively at any relative position; The 7th, increased parts such as solution circulation pump, formed complete hot-pipe system, the working solution carrying capacity is big, separatory is even, the heat exchange efficiency height; The 8th, solution circulation pump and time liquid pump all are installed in the bottom of fluid reservoir, have enough solution to use for pump in the course of work all the time, have avoided cavitation, have prolonged the service life of pump; The 9th, realize the adjusting of energy transport amount easily by the control of solution circulation pump.

Description of drawings:

Fig. 1 is first kind of heat transportation workflow structural principle schematic diagram of the present invention.

Fig. 2 transports workflow structural principle schematic diagram for first kind of cold of the present invention.

Fig. 3 is second kind of heat transportation workflow structural principle schematic diagram of the present invention.

Fig. 4 transports workflow structural principle schematic diagram for second kind of cold of the present invention.

Fig. 5 is the third heat transportation workflow structural principle schematic diagram of the present invention.

Fig. 6 transports workflow structural principle schematic diagram for the third cold of the present invention.

Fig. 7 is the 4th a kind of heat transportation workflow structural principle schematic diagram of the present invention.

Fig. 8 is the 5th a kind of heat transportation workflow structural principle schematic diagram of the present invention.

The specific embodiment:

Critical piece in the invention process comprises cold, thermal energy source of supply A, cold, thermal energy user B, air-liquid separatinghost tube 1,9,28 and 39, even gas-distributingpipe 2,8,25 and 38, energy user place heat exchanger (evaporimeter or condenser) 3 and 26, the equalliquid pipe 4 of equal length, 6,27 and 36, thefemale pipe 5 of gas transmission, energy source of supply place heat exchanger (evaporimeter or condenser) 7 and 37, pressure-regulatingvalve 10,knockout 11,15,29 and 34,cross valve 12 and 14 returns thefemale pipe 13 of liquid, pressure-regulatingvalve 16,liquid back pipe 17 and 18,fluid reservoir 19 and 20, solution circulation pump (returning liquid pump) 21, circulation solution carrier pipe (liquid back pipe) 22 and 23, solution circulation pump (or returning liquid pump) 24,flow control valve 30,32,35 and 40,gas transmission arm 31 and 33.

The present invention includes 3,26 liang of class heat exchangers of energy source of supplyplace heat exchanger 7,37 and energy user place heat exchanger, every class heat exchanger may be 1 as required, also may be a plurality of (only drawing in the accompanyingdrawing 2, come to determine concrete quantity during practical application as required), each heat exchanger is evaporimeters according to cooling or the different operating conditions of heat supply, or condenser; Each heat exchanger and condensate liquid feed flow and distribution, gas-liquid two-phase flow and are respectively with the operation principle and the effect of separating, gas-phase transport and distribution, liquid phase are collected with four subsystems of storage:

Energy source of supplyplace heat exchanger 7,37: when energy source of supply place provides heat,heat exchanger 7,37 is an evaporimeter, byknockout 15,35 and the equalliquid pipe 6,36 of equal length, evenly obtain liquid refrigerant in each pipeline ofheat exchanger 7,37, these working medium absorb the heat of the medium that contacts with this heat exchanger and generating gasification, produce evaporation process, the two phase flow of formation enters air-liquid separatinghost tube 9,39 through even gas-distributingpipe 8,38; Its effect is: absorb the heat energy at energy source of supply place, and change this energy the phase transformation potential of cycle fluid into, be stored in the gaseous state cycle fluid.When energy source of supply place provides cold,heat exchanger 7,37 is a condenser, by air-liquid separatinghost tube 9,39 and even gas-distributingpipe 8,38, evenly obtain gaseous working medium in each pipeline ofheat exchanger 7,37, these working medium absorb the cold of the medium that contacts with this heat exchanger and undergo phase transition, produce condensation process, the liquid of formation entersfluid reservoir 20 through the equalliquid pipe 6,36 of equal length; Its effect is: absorb the cold energy at energy source of supply place, and change this energy the phase transformation potential of cycle fluid into, be stored in the liquid cycle fluid.

Energy userplace heat exchanger 3,26: when energy source of supply place provides heat,heat exchanger 3,26 is a condenser, by air-liquid separatinghost tube 1,28 and even gas-distributingpipe 2,25, evenly obtain gaseous working medium in each pipeline ofheat exchanger 3,26, these working medium contact heat transferred with this heat exchanger medium and undergoing phase transition, produce condensation process, the liquid of formation entersfluid reservoir 19 through the equalliquid pipe 4,27 of equal length; Its effect is: the heat of energy activity is offered the user, finish heat transportation process efficiently.When energy source of supply place provides cold,heat exchanger 3,26 is an evaporimeter, byknockout 11,29 and the equalliquid pipe 4,27 of equal length, evenly obtain liquid refrigerant in each pipeline ofheat exchanger 3,26, these working medium pass to the medium that contacts with this heat exchanger with cold and undergo phase transition, produce evaporation process, the two phase flow of formation enters air-liquid separatinghost tube 1,28 through even gas-distributingpipe 2,25; Its effect is: the cold at energy user place is offered the user, finish cold transmittance process efficiently.

Condensate liquid feed flow and assignment subsystem: at energy source of supply place,solution circulation pump 24 extracts liquid refrigerant fromfluid reservoir 20, transportingpipe 23 through circulation solution is transported in theknockout 15,35, throughknockout 15,35 and the equalliquid pipe 6,36 of equal length, equably liquid refrigerant is distributed to each pipeline in theheat exchanger 7,37; Its effect is: gas-liquid separator 9,39 isolated liquid refrigerants are delivered in theevaporimeter 7,37 once more equably evaporated, form partial circulating, to guarantee the efficient operation of evaporimeter; Simultaneously, the liquid working substance ofcondenser 3,26 condensations is also delivered in theevaporimeter 7,37, formed systemic circulation, finish the transportation work of the necessary liquid refrigerant of hot-pipe system from the condenser to the evaporimeter.At the energy user place,solution circulation pump 21 extracts liquid refrigerant fromfluid reservoir 19,transport pipe 22 through circulation solution and be transported in theknockout 11,29,, equably liquid refrigerant is distributed to each pipeline in theheat exchanger 3,26 throughknockout 11,29 and the equalliquid pipe 4,27 of equal length; Its effect is: gas-liquid separator 1,28 isolated liquid refrigerants are delivered in theevaporimeter 3,26 once more equably evaporated, form partial circulating, to guarantee the efficient operation of evaporimeter; Simultaneously, the liquid working substance ofcondenser 7,37 condensations is also delivered in theevaporimeter 3,26, formed systemic circulation, finish the transportation work of the necessary liquid refrigerant of hot-pipe system from the condenser to the evaporimeter.

Gas-liquid two-phase flows and isolated subsystem: at energy source of supply place, the two phase flow that comes out fromheat exchanger 7,37, under the pressure effect thatsolution circulation pump 24 provides, send into air-liquid separatinghost tube 9,39 by even gas-distributingpipe 8,38, after the gas-liquid separation, liquid is sent in thefluid reservoir 20, and gas enters in thefemale pipe 5 of gas transmission; Its effect is: in time collect the biphase gas and liquid flow that flows out from evaporimeter, the liquid refrigerant thickness of evaporimeter heat-transfer surface is kept within the specific limits, reach the effect of high efficient heat exchanging, simultaneously, finish the task of gas-liquid separation, form gas, two paths of liquid, constitute binary cycle system of the present invention.At the energy user place, the two phase flow that comes out fromheat exchanger 3,26 is under the pressure effect thatsolution circulation pump 21 provides, send into air-liquid separatinghost tube 1,28 by even gas-distributingpipe 2,25, after the gas-liquid separation, liquid is sent in thefluid reservoir 19, and gas enters in thefemale pipe 5 of gas transmission; Its effect is: in time collect the biphase gas and liquid flow that flows out from evaporimeter, the liquid refrigerant thickness of evaporimeter heat-transfer surface is kept within the specific limits, reach the effect of high efficient heat exchanging, simultaneously, finish the task of gas-liquid separation, form gas, two paths of liquid, constitute binary cycle system of the present invention.

Gas-phase transport and assignment subsystem: the gaseous state cycle fluid of separating from air-liquid separatinghost tube 9,39 has certain overbottom pressure, make gaseous working medium through thefemale pipe 5 ofgas transmission arm 33, gas transmission,gas transmission arm 31, enter air-liquid separatinghost tube 1,28, be assigned to each root heat exchanger tube in theheat exchanger 3,26 equably by even gas-distributingpipe 2,25; The effect of this subsystem is: the gas phase working medium that produces in theevaporimeter 7,37 is assigned in the every heat exchanger tube ofcondenser 3,26 equably, realizes condensing heat-exchange process efficiently.The gaseous state cycle fluid of separating from air-liquid separatinghost tube 1,28 has certain overbottom pressure, make gaseous working medium through thefemale pipe 5 ofgas transmission arm 31, gas transmission,gas transmission arm 33, enter air-liquid separatinghost tube 9,39, be assigned to each root heat exchanger tube in theheat exchanger 7,37 equably by even gas-distributingpipe 8,38; The effect of this subsystem is: the gas phase working medium that produces in theevaporimeter 3,26 is assigned in the every heat exchanger tube ofcondenser 7,37 equably, realizes condensing heat-exchange process efficiently.

Liquid phase is collected and storage subsystem: in the workflow diagram shown in accompanyingdrawing 1, accompanyingdrawing 3, the accompanyingdrawing 5, liquid phase is collected and divided two parts: a part is that the liquid refrigerant of condensation in the gas-liquid separator 9,39 flows intofluid reservoir 20 through pressure-regulatingvalve 16 andliquid back pipe 18, another part is the working medium under the condensation incondenser 3,26, after flowing intofluid reservoir 19, provide power by returningliquid pump 21, get back in thefluid reservoir 20 through circulationsolution carrier pipe 22,cross valve 12, thefemale pipe 13 of transfusion, cross valve 14.The effect of this subsystem is: collect and storing liquid working medium, by pressure-regulatingvalve 16, make two collecting loops reach pressure balance, the assurance system normally moves.

In the workflow diagram shown in the accompanyingdrawing 7, liquid phase is collected and divided two parts: a part is that the liquid refrigerant of condensation in the gas-liquid separator 9 flows intofluid reservoir 20 through pressure-regulatingvalve 16 andliquid back pipe 18, another part is the working medium under the condensation incondenser 3, after flowing intofluid reservoir 19, under the gravity effect,female pipe 13 flow back in thefluid reservoir 20 through infusing.The effect of this subsystem is: collect and storing liquid working medium, by pressure-regulatingvalve 16, make two collecting loops reach pressure balance, the assurance system normally moves.

In the workflow diagram shown in accompanyingdrawing 2, accompanyingdrawing 4, the accompanyingdrawing 6, liquid phase is collected and also divided two parts: a part is that the liquid refrigerant of condensation in the gas-liquid separator 1,28 flows intofluid reservoir 19 through pressure-regulatingvalve 10 andliquid back pipe 17, another part is the working medium under the condensation incondenser 7,37, after flowing intofluid reservoir 20, provide power by returningliquid pump 24, get back in thefluid reservoir 19 through circulationsolution carrier pipe 23,cross valve 14, thefemale pipe 13 of transfusion, cross valve 12.The effect of this subsystem is: collect and storing liquid working medium, by pressure-regulatingvalve 10, make two collecting loops reach pressure balance, the assurance system normally moves.

In the workflow diagram shown in the accompanyingdrawing 8, liquid phase is collected and also divided two parts: a part is that the liquid refrigerant of condensation in the gas-liquid separator 9 flows intofluid reservoir 20 through pressure-regulatingvalve 16 andliquid back pipe 18, another part is the working medium under the condensation incondenser 3,27, after flowing intofluid reservoir 19, under the gravity effect,female pipe 13 flow back in thefluid reservoir 20 through infusing.The effect of this subsystem is: collect and storing liquid working medium, by pressure-regulatingvalve 16, make two collecting loops reach pressure balance, the assurance system normally moves.

The present invention is described in further detail below in conjunction with example:

Embodiment 1:

Fig. 1 is a confession one a heat feed system for using the 1st kind of heat transportation workflow principle schematic of the present invention, and promptly a calorie source by the A place provides the user of heat to the B place; Its critical piece comprisesevaporimeter 7 andcondenser 3; Also comprise the condensate liquid feed flow and the assignment subsystem that constitute bysolution circulation pump 24, circulationsolution carrier pipe 23,knockout 15, the equalliquid pipe 6 of equal length etc.; The gas-liquid two-phase that is made of even gas-distributingpipe 8, air-liquid separatinghost tube 9 flows and isolated subsystem; By thefemale pipe 5 of gas transmission, air-liquid separatinghost tube 1, the even gas-phase transport and the assignment subsystem that constitute of gas-distributingpipe 2; Collect and storage subsystem by the liquid phase that pressure-regulatingvalve 16,liquid back pipe 18,fluid reservoir 19, timeliquid pump 21, thefemale pipe 13 of time liquid andfluid reservoir 20 constitute; Above-mentionedevaporimeter 7,condenser 3 and four organic connecting as one of subsystem, continuously with heat from medium thatevaporimeter 7 contacts be delivered in the medium that contacts withcondenser 3, finish one for one heat transportation process.

This system starts with running as follows: earlier system connectivity is installed, charge into the heat pipe cycle fluid after finding time, transfer twocross valves 12,14 to the heat transportation pattern again, startsolution circulation pump 24, make and form a certain amount of liquid refrigerant partial circulating in theevaporimeter 7, open the supplying heat source system ofevaporimeter 7 and the custom system ofcondenser 3 again, treat that liquid refrigerant in thefluid reservoir 19 after certain liquid level, starts backliquid pump 21; Behind the certain hour, this energy transporting system just enters normal work stage.In course of normal operation,solution circulation pump 24 extracts liquid refrigerant fromfluid reservoir 20, be transported to knockout 15 through circulationsolution carrier pipe 23, equalliquid pipe 6 throughknockout 15 and equal length, equably liquid refrigerant is distributed to each the evaporation pipeline in theevaporimeter 7, in the evaporation pipeline, liquid refrigerant absorbs the heat of the medium that contacts with it, the partially liq gasification enters air-liquid separatinghost tube 9 through even gas-distributingpipe 8 and realizes gas-liquid separations; Subsequently, flow throughcontrol valve 16 andliquid back pipe 18 of liquid refrigerant got back tofluid reservoir 20, formed the liquid working substance partial circulating, gas phase working medium then enters the air-liquid separatinghost tube 1 ofheat exchanger 3 through thefemale pipe 5 of gas transmission, gas evenly is transported in each pipeline ofcondenser 3 byuniform distribution pipe 2, in condenser pipe, after the realization total condensation, condensate liquid is sent intofluid reservoir 19 by the equalliquid pipe 4 of equal length, by returningliquid pump 21 liquid refrigerant is sent back in thefluid reservoir 20 again, form the heat-pipe working medium systemic circulation.Two circulations organically combine, and constitute of the present invention pair of circulating heat pipe system.The effect of partial circulating is control rationally or the internal circulating load that increases liquid working substance in theevaporimeter 7, solves problems such as original heat pipe working solution carrying capacity is not enough, separatory is inhomogeneous, evaporimeter heat-transfer surface service efficiency is low; Systemic circulation then make heat from medium thatevaporimeter 7 contacts be sent in the medium that contacts withcondenser 3, finish the latent heat transmittance process of heat.The working medium of getting back in thefluid reservoir 20 is sent in theevaporimeter 7 once more throughsolution circulation pump 24, has begun heat transfer process next time again, so moves in circles, and continuously realizes the transport process of heat.

Embodiment 2:

Fig. 2 is that the 1st kind of cold transports the workflow principle schematic, is a confession one cold feed system, and promptly a cold source by the A place provides the user of cold to the B place; Its critical piece comprisesevaporimeter 3 andcondenser 7; Also comprise the condensate liquid feed flow and the assignment subsystem that constitute bysolution circulation pump 21, circulationsolution carrier pipe 22,knockout 11, the equalliquid pipe 4 of equal length etc.; The gas-liquid two-phase that is made of even gas-distributingpipe 2, air-liquid separatinghost tube 1 flows and isolated subsystem; By thefemale pipe 5 of gas transmission, air-liquid separatinghost tube 9, the even gas-phase transport and the assignment subsystem that constitute of gas-distributingpipe 8; Collect and storage subsystem by the liquid phase that pressure-regulatingvalve 10,liquid back pipe 17,fluid reservoir 20, timeliquid pump 24, thefemale pipe 13 of time liquid andfluid reservoir 19 etc. constitute; Above-mentionedevaporimeter 3,condenser 7 and four organic connecting as one of subsystem, continuously with heat from medium thatevaporimeter 3 contacts be delivered in the medium that contacts withcondenser 7, finished one for one cold transport process.

Embodiment 2 is antikinesis processes ofembodiment 1, shows that system has the way traffic feature, promptly utilizes same system, can either finish transporting of heat, also can finish transporting of cold.

This system starts with running as follows: earlier system connectivity is installed, charge into the heat pipe cycle fluid after finding time, transfer twocross valves 12,14 to the cold transport mode again, start liquid workingmedium circulating pump 21, allowevaporimeter 3 form a certain amount of liquid refrigerant partial circulating, open the custom system ofevaporimeter 3 and the energy source of supply system ofcondenser 7 again, treat that liquid refrigerant in thefluid reservoir 20 after certain liquid level, starts backliquid pump 24; Behind the certain hour, energy transporting system just enters normal work stage.In course of normal operation,solution circulation pump 21 extracts liquid refrigerant fromfluid reservoir 19, be transported to knockout 11 through circulationsolution carrier pipe 22, throughknockout 11 and the equalliquid pipe 4 of equal length, equably liquid refrigerant is distributed to each the evaporation pipeline in theevaporimeter 3, in the evaporation pipeline, liquid refrigerant absorbs the heat of the medium that contacts with it, the partially liq gasification enters air-liquid separatinghost tube 1 through even gas-distributingpipe 2, realizes gas-liquid separation; Subsequently, flow throughcontrol valve 10 andliquid back pipe 17 of liquid refrigerant got back tofluid reservoir 19, formed the liquid refrigerant partial circulating, gas phase working medium then enters the air-liquid separatinghost tube 9 ofheat exchanger 7 through thefemale pipe 5 of gas transmission, gas evenly is transported in each pipeline ofcondenser 7 byuniform distribution pipe 8, in condenser pipe, after the realization total condensation, condensate liquid is sent in thefluid reservoir 20 by the equalliquid pipe 6 of equal length, by returningliquid pump 24 liquid two matter are sent back in thefluid reservoir 19 again, form the heat-pipe working medium systemic circulation.Two circulations organically combine, and constitute of the present invention pair of circulating energy transport system.The effect of partial circulating is control rationally or the internal circulating load that increases liquid working substance in theevaporimeter 3, solves problems such as original heat pipe working solution carrying capacity is not enough, separatory is inhomogeneous, evaporimeter heat-transfer surface service efficiency is low; Systemic circulation then make heat from medium thatevaporimeter 3 contacts be sent in the medium that contacts withcondenser 7, finish the latent heat transmittance process of cold.The working medium of getting back in thefluid reservoir 19 is sent in theevaporimeter 3 once more throughsolution circulation pump 21, has begun heat transfer process next time again, so moves in circles, and continuously realizes the transport process of heat.

Embodiment 3:

Fig. 3 is the 2nd a kind of heat transportation workflow principle schematic of system, is many heats of confession feed system, and promptly a calorie source by the A place provides a plurality of users of heat to the B place; Its critical piece comprises theevaporimeter 7 of energy activity and thecondenser 3,26 at user place; Also comprise the condensate liquid feed flow and the assignment subsystem that constitute bysolution circulation pump 24, circulationsolution carrier pipe 23,knockout 15, the equalliquid pipe 6 of equal length etc.; The gas-liquid two-phase that is made of even gas-distributingpipe 8, air-liquid separatinghost tube 9 flows and isolated subsystem; By thefemale pipe 5 of gas transmission,gas transmission arm 31, air-liquid separatinghost tube 1,28, the even gas-phase transport and the assignment subsystem that constitute such as gas-distributingpipe 2,25; Collect and storage subsystem by the liquid phase that pressure-regulatingvalve 16,liquid back pipe 18,fluid reservoir 19, timeliquid pump 21, thefemale pipe 13 of time liquid andfluid reservoir 20 etc. constitute; Subsystem is organic connects as one for above-mentionedevaporimeter 7,3,26 and four of condensers, continuously with heat from medium thatevaporimeter 7 contacts be delivered in the medium that contacts withcondenser 3,26, finished one for many heat transportation processes.

The condenser at user place only draws 3,26 two among Fig. 3, and the quantity of condenser without limits during practical application.Each user locates how much can being regulated byflow control valve 30,32 of condenser heating load.

The startup and the running of present embodiment are substantially the same manner as Example 1, just need the demand according to the user in running, suitably adjustflow control valve 30,32, and that satisfies each user uses the heat requirement.

Embodiment 4:

Fig. 4 is many colds of confession feed system for the 2nd kind of cold of system transports the workflow principle schematic, and promptly a cold source by the A place provides a plurality of users of cold to the B place; Its critical piece comprises theevaporimeter 3,26 that the user locates and thecondenser 7 of energy activity; Also comprise the condensate liquid feed flow and the assignment subsystem that constitute bysolution circulation pump 21, circulationsolution carrier pipe 22,knockout 11,29, the equalliquid pipe 4,27 of equal length etc.; The gas-liquid two-phase that is made of even gas-distributingpipe 2,25, air-liquid separatinghost tube 1,28 flows and isolated subsystem; By thefemale pipe 5 of gas transmission, air-liquid separatinghost tube 9, the even gas-phase transport and the assignment subsystem that constitute of gas-distributingpipe 8; Collect and storage subsystem by the liquid phase that pressure-regulatingvalve 10,liquid back pipe 17,fluid reservoir 20, timeliquid pump 24, thefemale pipe 13 of time liquid andfluid reservoir 19 etc. constitute; Above-mentionedevaporimeter 3,26 andcondenser 7 and four organic connecting as one of subsystem, continuously with heat from medium thatevaporimeter 3,26 contacts be delivered in the medium that contacts withcondenser 7, finish one for many cold transport processes.

The running ofembodiment 4 is the antikinesis process ofembodiment 2 just, shows that a system of the present invention has the way traffic feature, promptly utilizes same system, can either finish one of heat and supply to transport more, also can finish one of cold and supply to transport more.

The startup and the running of present embodiment are substantially the same manner as Example 2, just need the demand according to the user in running, suitably adjustflow control valve 30,32, and that satisfies each user uses the cold requirement.

Embodiment 5:

Fig. 5 is the 3rd a kind of heat transportation workflow principle schematic of system, and for many heats feed system, promptly a plurality of heat sources of supply by the A place provide a plurality of users of heat to the B place for many; Its critical piece comprises theevaporimeter 7,37 of energy activity and thecondenser 3,26 at user place; Also comprise the condensate liquid feed flow and the assignment subsystem that constitute bysolution circulation pump 24, circulationsolution carrier pipe 23,knockout 15,35, the equalliquid pipe 6,36 of equal length etc.; By even gas-distributingpipe 8,38, the gas-liquid two-phase that air-liquid separatinghost tube 9,39 constitutes flows and isolated subsystem; By thefemale pipe 5 of gas transmission,gas transmission arm 33,31, air-liquid separatinghost tube 1,28, the even gas-phase transport and the assignment subsystem that constitute such as gas-distributingpipe 2,25; Collect and storage subsystem by the liquid phase that pressure-regulatingvalve 16,liquid back pipe 18,fluid reservoir 19, timeliquid pump 21, thefemale pipe 13 of time liquid andfluid reservoir 20 etc. constitute; Subsystem is organic connects as one for 3,26 and four of above-mentionedevaporimeter 7,37 and condensers, continuously with heat from medium thatevaporimeter 7,37 contacts be delivered in the medium that contacts withcondenser 3,26, finish many for many heat transportation processes.

Only draw 3,26 two, the evaporimeter of heat activity of the condenser at user place also only draw 7,37 two among Fig. 5, and the quantity of condenser, evaporimeter without limits during practical application.Each user locate the condenser heating load what can regulate byflow control valve 30,32, what of each energy activity heating load can be regulated byflow control valve 34,40.

The startup and the running of present embodiment are substantially the same manner as Example 1, just in running, need demand, suitably adjustflow control valve 30,32, satisfy each user's heat requirement according to the user, simultaneously, regulateflow control valve 34,40 according to the various heat sources of energy activity.

Embodiment 6:

Fig. 6 transports the workflow principle schematic for the 3rd kind of cold of system, and for many colds feed system, promptly a plurality of colds source by the A place provides a plurality of users of cold to the B place for many; Its critical piece comprises theevaporimeter 3,26 that the user locates and thecondenser 7,37 of energy activity; Also comprise the condensate liquid feed flow and the assignment subsystem that constitute bysolution circulation pump 21, circulationsolution carrier pipe 22,knockout 11,29, the equalliquid pipe 4,27 of equal length etc.; The gas-liquid two-phase that is made of even gas-distributingpipe 2,25, air-liquidseparating host tube 1,28 flows and isolated subsystem; By thefemale pipe 5 of gas transmission,gas transmission arm 33,31, air-liquid separatinghost tube 9,39, the even gas-phase transport and the assignment subsystem that constitute such as gas-distributingpipe 8,38; Collect and storage subsystem by the liquid phase that pressure-regulatingvalve 10,liquid back pipe 17,fluid reservoir 20, timeliquid pump 24, thefemale pipe 13 of time liquid andfluid reservoir 19 etc. constitute; Subsystem is organic connects as one for 7,37 and four of above-mentionedevaporimeter 3,26 and condensers, continuously with heat from medium thatevaporimeter 3,26 contacts be delivered in the medium that contacts withcondenser 7,37, finished the many cold transport processes of many confessions.

Embodiment 6 is antikinesis processes ofembodiment 3, shows that system has the way traffic feature, promptly utilizes same system, and the many confessions that can either finish heat transport more, and the many confessions that also can finish cold transport more.

The startup and the running of present embodiment are substantially the same manner as Example 2, just in running, need demand, suitably adjustcontrol valve 30,32, satisfy each user's cold requirement according to the user, simultaneously, regulate 34,40 control valves according to the various heat sources of energy activity.

Embodiment 7:

Fig. 7 is the 4th a kind of heat transportation workflow principle schematic of system, is a confession one heat feed system, and promptly a calorie source by the A place provides the user of heat to the B place; The difference of this embodiment and embodiment 1 is that this embodiment is unidirectional heating system, so saved 2 cross valves that play the role of changing, simultaneously, considers that the position of B place fluid reservoir 19 is higher than the position of A place fluid reservoir 20, has also saved time liquid pump.Its critical piece comprises evaporimeter 7 and condenser 3; Also comprise the condensate liquid feed flow and the assignment subsystem that constitute by solution circulation pump 24, circulation solution carrier pipe 23, knockout 15, the equal liquid pipe 6 of equal length etc.; The gas-liquid two-phase that is made of even gas-distributing pipe 8, air-liquid separating host tube 9 flows and isolated subsystem; By the female pipe 5 of gas transmission, air-liquid separating host tube 1, the even gas-phase transport and the assignment subsystem that constitute of gas-distributing pipe 2; Collect and storage subsystem by the liquid phase that pressure-regulating valve 16, liquid back pipe 18, fluid reservoir 19, the female pipe 13 of time liquid and fluid reservoir 20 constitute; Above-mentioned evaporimeter 7, condenser 3 and four organic connecting as one of subsystem, continuously with heat from medium that evaporimeter 7 contacts be delivered in the medium that contacts with condenser 3, finished one for one heat transportation process.

The startup of present embodiment is identical withembodiment 1 with running, does not just have the step that starts back liquid pump.

Embodiment 8:

Fig. 8 is the 5th a kind of heat transportation workflow principle schematic of system, is many heats of confession feed system, and promptly a calorie source by the A place provides a plurality of users of heat to the B place; This embodiment and embodiment 3 comparatively roughly the same, its difference is that this embodiment is unidirectional heating system, so saved 2 cross valves that play the role of changing, simultaneously, considers that the position of B place fluid reservoir 19 is higher than the position of A place fluid reservoir 20, has also saved time liquid pump.Its critical piece comprises the evaporimeter 7 of energy activity and the condenser 3,26 at energy user place; Also comprise the condensate liquid feed flow and the assignment subsystem that constitute by solution circulation pump 24, circulation solution carrier pipe 23, knockout 15, the equal liquid pipe 6 of equal length etc.; The gas-liquid two-phase that is made of even gas-distributing pipe 8, air-liquid separating host tube 9 flows and isolated subsystem; By the female pipe 5 of gas transmission, gas transmission arm 31, air-liquid separating host tube 1,28, the even gas-phase transport and the assignment subsystem that constitute of gas-distributing pipe 2,25; Collect and storage subsystem by the liquid phase that pressure-regulating valve 16, liquid back pipe 18, fluid reservoir 19, the female pipe 13 of time liquid and fluid reservoir 20 constitute; Subsystem is organic connects as one for 3,26 and four of above-mentioned evaporimeter 7 and condensers, continuously with heat from medium that the evaporimeter 7 of energy activity contacts in be delivered in the medium that contacts with the condenser 3,26 of energy user, finished one for many heat transportation processes.The startup of present embodiment is identical with embodiment 2 with running, does not just have the step that starts back liquid pump.

Embodiment 9:

Be that 1000kW, temperature are 20 ℃ seawater cold energy to transport power summer below, to 10km energy user in addition, being used for central air conditioner system is example as the low-temperature receiver of taking away the condenser heat, and the difference of sensible heat energy transport and latent heat energy transport is adopted in concrete analysis.Air-conditioning system is if press 80W/m²Calculate with cold, this energy transporting system can satisfy 12500m²The Air-conditioning Engineering of area.If press 50W/m²Calculate with cold, this energy transporting system just can satisfy 20000m²The Air-conditioning Engineering of area.

Utilize green refrigerant R410A for the heat pipe cycle fluid, in hot-pipe system, the evaporation of cold-producing medium and condensation temperature are got 23 ℃, and under this temperature, saturation pressure is 15.564bar, and the density of liquid refrigerant is 1064.7kg/m³, the density of gaseous working medium is 58.275kg/m³, the latent heat of vaporization is 194.21kJ/kg.

By the law of conservation of energy analysis, for transporting the seawater energy of 1000kW, the cycle fluid amount of R410A is 18536.6kg/h, and the volume flow of saturated vapor is 318.09m in the female pipe of the gas transmission of this internal circulating load correspondence³/ h, the volume flow of returning saturated liquid in the female pipe of liquid is 17.41m³/ h.If the flow velocity of saturated vapor is got 1m/s (consider that this fluid density is bigger, the flow velocity of getting is very little, and the pipeline pressure drop is also very little like this) in the female pipe of gas transmission, then the internal diameter of the female pipe of gas transmission is that 336mm can meet the demands, and the internal diameter that rounds selection standard is the pipeline of 360mm.The R410A saturated vapor that in this flow velocity, this caliber, flows, its flow resistance is about: 2Pa/m, that is: and utilize this pipeline to realize the hot and cold energy transport 10km of 1000kW, pressure drop also only is 0.2bar, its phase transition temperature only changes 0.475 ℃, and is very little to the quality influence that is transported energy; If the flow velocity of saturated liquid is got 0.2m/s in the female pipe of transfusion, the internal diameter of female pipe of then infusing is that 176mm can meet the demands, and rounds the pipeline into internal diameter 180mm.

If adopt sensible heat to transport, be media with the aqueous water, suppose that the temperature variation of water in each heat exchanger is 4 degrees centigrade.By the law of conservation of energy analysis, for transporting the seawater energy of 1000kW, the flow of the aqueous water that needs is: 215310kg/h, because the density of water is 998.2kg/m³, can get: volume flow is 215.7 m³/ h, if the flow velocity of the female liquid in pipe of transfusion is also got 0.2m/s, the internal diameter of female pipe of then infusing should be 618mm, rounds the pipeline into internal diameter 630mm.

More above-mentioned data as can be seen, utilizing the required caliber of sensible heat energy transport is to utilize 1.75 times and 3.5 times of the required caliber of latent heat energy transporting system of the present invention, consider the wall thickness difference of different tube diameters, the pipeline material consumption of sensible heat energy transporting system will be the pipeline material consumption of 3-5 latent heat energy transporting system doubly.This initial cost that makes the initial cost of pipeline and pipe insulation material all equal proportion rises, and makes simultaneously that the energy loss to environment also increases considerably in the transport process.

In addition, the required aqueous water internal circulating load of sensible heat energy transport is 215.7/17.41=12.39 a times of latent heat energy transport process aqueous water internal circulating load of the present invention, and, liquid transport is back and forth a round trip during sensible heat energy transport, so its duct pressure loss is bigger than the duct pressure loss of latent heat energy transport of the present invention, required solution pump power will be 15-20 of the present invention times, and this has not only increased initial cost, and operating cost is also increased significantly.

Also can find out by top analysis, satisfy 12500-20000m²The seawater energy transporting system that the Air-conditioning Engineering of area is required, only needing internal diameter is the hot and cold energy transport task that two pipelines of 180mm, 360mm just can be finished 10km-20km or farther distance, and its operation energy consumption is very low.If the energy transport distance is 1km-2km only, required caliber is much smaller, and concrete caliber value can be calculated to determine by fluid resistance.The application of this energy transporting system will descend the condensation temperature and the condensing pressure of this air-conditioning system significantly, and Energy Efficiency Ratio increases substantially, and forms energy-efficient air-conditioning system.

Claims (5)

Translated fromChinese

1、一种双向双循环热管能量输运系统，其特征在于将分离式热管的两类换热器分别放置在冷、热能量供应源和冷、热能量用户处两个不同地方，通过输气母管、回液母管、储液罐、气液分离母管、分液器、等长度均液管、四通阀、循环溶液泵、回液泵、压力调节阀、回液管及连接管道有机连接为一个气液相通的整体构成能量输运系统；通过溶液循环泵、分液器、等长度均液管、蒸发器及气液分离母管、压力调节阀和回液管有机组合，形成具有强工作液输送力且分液均匀的相对独立的工作液小循环；整体系统分为冷凝液供液与分配、气液两相流动与分离、气相输送与分配、液相收集与储存四个子系统；其运行过程是：溶液循环泵从储液罐中抽取液态工质，经循环溶液输送管输送到分液器，经分液器和等长度均液管，均匀地将液态工质分配给蒸发器中的每个蒸发管路，在蒸发管路中，液态工质吸收与其相接触介质的热量，部分液体气化，经两相流管进入气液分离器实现气液分离，随后，液态工质流经压力调节阀和回液管流到储液罐，形成液体工质小循环；而气相工质则经输气母管进入气液分离母管，由均匀分配管将气体输送到冷凝器的每个管路中，在冷凝管路中实现完全冷凝后，流入冷凝器的储液罐，再由回液泵送回到蒸发器的储液罐，形成热管工质大循环；液体工质小循环和热管工质大循环有机结合实现双向双循环热管能量输运；小循环控制或增大蒸发器中液体工质的循环量；大循环使热量从与蒸发器接触的介质中传送到与冷凝器接触的介质中，实现热量的潜热输运过程；回到储液罐中的工质经溶液循环泵再次送入蒸发器中，开始下一次潜热输运过程。1. A two-way double-circulation heat pipe energy transport system, characterized in that the two types of heat exchangers of the separated heat pipe are respectively placed in two different places of the cold and heat energy supply source and the cold and heat energy user. Main pipe, liquid return main pipe, liquid storage tank, gas-liquid separation main pipe, liquid separator, liquid equalizing pipe of equal length, four-way valve, circulating solution pump, liquid return pump, pressure regulating valve, liquid return pipe and connecting pipes The energy transport system is organically connected as a whole with gas-liquid communication; through the organic combination of solution circulation pump, liquid separator, equal-length liquid pipe, evaporator, gas-liquid separation main pipe, pressure regulating valve and liquid return pipe, Form a relatively independent working fluid small cycle with strong working fluid delivery force and uniform liquid separation; the overall system is divided into four parts: condensate supply and distribution, gas-liquid two-phase flow and separation, gas phase transportation and distribution, and liquid phase collection and storage. It is a subsystem; its operation process is: the solution circulation pump extracts the liquid working medium from the liquid storage tank, transports it to the liquid separator through the circulating solution delivery pipe, and distributes the liquid working medium evenly through the liquid separator and equal-length equalizing pipes For each evaporation pipeline in the evaporator, in the evaporation pipeline, the liquid working fluid absorbs the heat of the medium in contact with it, and part of the liquid is vaporized, and enters the gas-liquid separator through the two-phase flow tube to achieve gas-liquid separation, and then, The liquid working medium flows through the pressure regulating valve and the liquid return pipe to the liquid storage tank, forming a small circulation of the liquid working medium; while the gas phase working medium enters the gas-liquid separation main pipe through the gas transmission main pipe, and the gas is transported to the gas-liquid separation main pipe by the uniform distribution pipe. In each pipeline of the condenser, after complete condensation in the condensing pipeline, it flows into the liquid storage tank of the condenser, and then is sent back to the liquid storage tank of the evaporator by the liquid return pump, forming a large circulation of the heat pipe working medium; the liquid The small cycle of working fluid and the large cycle of heat pipe working fluid are organically combined to realize the energy transport of bidirectional double cycle heat pipe; the small cycle controls or increases the circulation of the liquid working medium in the evaporator; the large cycle enables heat to be transferred from the medium in contact with the evaporator To the medium in contact with the condenser to realize the latent heat transport process of heat; the working fluid returned to the liquid storage tank is sent to the evaporator again through the solution circulation pump to start the next latent heat transport process.2、根据权利要求1所述的双向双循环热管能量输运系统，其特征在于所述的两类换热器是蒸发器或冷凝器，每类换热器使一个或多个并联，冷、热能量供应源放置的换热器是蒸发器或冷凝器；冷、热能量用户处放置的换热器是冷凝器或蒸发器；由系统中两个四通阀的流通方向确定双向能量传递功能，即利用同一个系统，将冷、热能量供应源的热量传递给冷、热能量用户，或将冷、热能量供应源的冷量传递给接受冷、热能量用户。2. The two-way double-circulation heat pipe energy transport system according to claim 1, characterized in that the two types of heat exchangers are evaporators or condensers, one or more of each type of heat exchangers are connected in parallel, cooling, The heat exchanger placed at the heat energy supply source is an evaporator or condenser; the heat exchanger placed at the cold and heat energy user is a condenser or an evaporator; the two-way energy transfer function is determined by the flow direction of the two four-way valves in the system , That is to use the same system to transfer the heat of the cold and hot energy supply source to the cold and hot energy user, or transfer the cold energy of the cold and hot energy supply source to the cold and hot energy user.3、根据权利要求1所述的双向双循环热管能量输运系统，其特征在于冷、热能量供应源及冷、热能量用户是一个或多个；两者各为一个构成一供一系统；冷、热能量供应源为多个，冷、热能量用户是一个而构成多供一系统；冷、热能量供应源为一个，冷、热能量用户为多个，则构成一供多系统；冷、热能量供应源与冷、热能量用户分别有多个，则构成多供多系统。3. The two-way double-circulation heat pipe energy transport system according to claim 1, characterized in that there are one or more cold and heat energy supply sources and one or more cold and heat energy users; each of them constitutes a one-supply system; There are multiple cold and hot energy supply sources, and one cold and hot energy user constitutes a multi-supply system; there is one cold and hot energy supply source, and there are multiple cold and hot energy users, which constitutes a multi-supply system; If there are multiple heat energy supply sources and cold and heat energy users respectively, then a multiple supply and multiple system is formed.4、根据权利要求1所述的双向双循环热管能量输运系统，其特征在于蒸发器与冷凝器的相对安装高度不限，各自的储液罐低于其换热器，使冷凝液能顺利回流到储液罐，换热器须安装在储液罐下部时，在回流管路安装一个回流溶液泵，溶液循环泵与回液泵都安装在储液罐的下部，工作过程中始终有足够的溶液供泵使用。4. The two-way double-circulation heat pipe energy transport system according to claim 1, characterized in that the relative installation heights of the evaporator and the condenser are not limited, and the respective liquid storage tanks are lower than their heat exchangers, so that the condensate can flow smoothly When the heat exchanger must be installed in the lower part of the liquid storage tank, a return solution pump is installed in the return line. Both the solution circulation pump and the liquid return pump are installed in the lower part of the liquid storage tank, and there is always sufficient solution for pump use.5、根据权利要求1所述的双向双循环热管能量输运系统，其特征在于该系统适于海水或江水或湖水热能的利用，土壤热源或地下水热源的应用，生活废水中冷、热能的回收利用场合；通过选用热管工质，用于中央空调、太阳能热利用、空气冷能回收与利用、锅炉或动力机的余热或废热的回收、核能热利用场合。5. The two-way double-circulation heat pipe energy transport system according to claim 1, characterized in that the system is suitable for the utilization of seawater or river water or lake water heat energy, the application of soil heat source or groundwater heat source, and the recovery of cold and heat energy in domestic wastewater Utilization occasions: through the selection of heat pipe working medium, it can be used in central air conditioning, solar heat utilization, air cooling energy recovery and utilization, boiler or power machine waste heat or waste heat recovery, and nuclear energy heat utilization occasions.

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