CN205619604U - Hydrophily ground heat compensator and high low temperature integral type hydrophily ground heat compensator - Google Patents

Abstract

The utility model provides a hydrophily ground heat compensator and high low temperature integral type hydrophily ground heat compensator, including heat exchange section and deferent segment, the heat exchange section has the first end and the second end of relative setting, the heat exchange intersegmental part has hydrophily input geothermol power balance pipe and exports the geothermol power balance pipe with the hydrophily of hydrophily input geothermol power balance pipe intercommunication, and the import of hydrophily input geothermol power balance pipe and the export of hydrophily output geothermol power balance pipe all set up the first end in the heat exchange section, the deferent segment is connected with the first end of heat exchange section, and the deferent segment is the annular, hydrophily input geothermol power balance pipe and hydrophily output geothermol power balance pipe extend to in the deferent segment. Carry out the heat exchange between outer geological stratification of hydrophily ground heat compensator and the water, the water behind the alternating temperature passes through hydrophily heating medium output main pipe's export output, carries out intensification or the cooling that the heat exchange realized the environment with user terminal again, does not have environmental pollution, need not exploit groundwater with the hot spring can utilize geothermal resource, has avoided pumping groundwater to destroy the harm of geology ecology.

Description

Hydrophily ground heat compensator and high/low temperature integral type hydrophily underground heat static organ

Technical field

This utility model relates to energy-conserving and environment-protective technical field, especially relates to a kind of hydrophily ground heat compensator and high/low temperature integral type hydrophily underground heat static organ.

Background technology

Coal, oil, natural gas are referred to as fossil can be former, along with people, the most constantly and exploitation utilizes, fossil energy resource constantly consumes to be on the verge of to buy and exhausts, and the produced waste gas severe contamination air of these fossil energies burning, thus it is possible to the exploitation substituting the new forms of energy of fossil energy has become the task that the whole world is extremely urgent.

Geothermal energy resources are a kind of cleaning, cheap, renewable, the new forms of energy that can directly utilize, develop geothermal energy resources, being conducive to improving existing energy resource structure, advantageously reduce energy resource consumption and cost, beneficially limits ground reduces waste gas, dust and sound pollution etc..But, presently relevant geothermal utilization technology device such as ground source heat water pump etc., it is all based on exploiting groundwater or hot spring, a large amount of groundwater abstractions can make level of ground water decline, surface subsidence, cause underground water pollution, making the mankind may utilize water money and former buy the risk exhausted, power consumption is relatively large simultaneously.

Utility model content

The purpose of this utility model is to provide a kind of hydrophily ground heat compensator and high/low temperature integral type hydrophily underground heat static organ, must extract the technical problem of subsoil water out solving Geotherm utilizing device of the prior art.

This utility model provides a kind of hydrophily ground heat compensator, including: heat exchange segment and deferent segment；

Described heat exchange segment has the first end and the second end being oppositely arranged；Having hydrophily input underground heat balance pipe and the hydrophily output underground heat balance pipe connected with described hydrophily input underground heat balance pipe inside described heat exchange segment, the outlet of import and described hydrophily output underground heat balance pipe that described hydrophily inputs underground heat balance pipe is arranged at the first end of described heat exchange segment；

Described deferent segment is connected with the first end of described heat exchange segment, and described deferent segment is annular；Described hydrophily input underground heat balance pipe and described hydrophily output underground heat balance pipe extend in described deferent segment, and the extension of described hydrophily input underground heat balance pipe is that hydrophily inputs house steward, and described hydrophily output underground heat balance pipe extension is hydrophily delivery trunk；Described hydrophily input underground heat balance pipe and described hydrophily output underground heat balance pipe are one to multiple group, and many group hydrophily input underground heat balance pipes and hydrophily output underground heat balance pipe carry out serial communication by intermediate connection tube or collection silt device.

Further, also include hydrophily input filter and hydrophily output filter, along the flow direction of water, described hydrophily input filter is positioned at the upstream of the import of described hydrophily input house steward, and described hydrophily output filter is positioned at the downstream of the outlet of described hydrophily delivery trunk.

Further, also include that base segment, described base segment are connected with the second end of described heat exchange segment.

Further, described base segment includes collecting silt device, described hydrophily input underground heat balance pipe and described hydrophily output underground heat balance pipe be arranged in parallel, and described hydrophily input underground heat balance pipe and described hydrophily output underground heat balance pipe carry out serial communication by described collection silt device or intermediate connection tube.

Further, also including maintaining passage, described maintenance passage includes maintaining passage base segment and maintenance passage heat exchange segment, and described maintenance passage base segment is arranged in described base segment, and described maintenance passage heat exchange segment is arranged in described heat exchange segment.

Further, described hydrophily output underground heat balance pipe is provided with row's silt mouth, and along the flow direction of water, the described row mouth that becomes silted up is arranged on the downstream of outlet of described hydrophily delivery trunk.

This utility model additionally provides a kind of high/low temperature integral type hydrophily underground heat static organ, including high temperature hydrophily underground heat static organ be connected to the low temperature hydrophily underground heat static organ above described high temperature hydrophily underground heat static organ, described high temperature hydrophily underground heat static organ and described low temperature hydrophily underground heat static organ all for according to hydrophily described in the utility model ground heat compensator.

Further, described high/low temperature integral type hydrophily underground heat static organ also includes high/low temperature hydrophily transducer, described high/low temperature hydrophily transducer includes the first switch, second switch, 3rd switch and the 4th switch, wherein, in the hydrophily output channel of the hydrophily delivery trunk that described 4th switch is arranged on described high temperature hydrophily underground heat static organ, described second switch is arranged in the hydrophily input channel of hydrophily input house steward of described high temperature hydrophily underground heat static organ, in the hydrophily output channel of the hydrophily delivery trunk that described 3rd switch is arranged on described low temperature hydrophily underground heat static organ, in the hydrophily input channel of the hydrophily delivery trunk that described first switch is arranged on described low temperature hydrophily underground heat static organ.

Further, described collection silt device and described row are become silted up mouth, are configured for alternative.

Further, described hydrophily input filter and collection silt device or be and deposit relation.

The hydrophily ground heat compensator that this utility model provides, in hydrophily input underground heat balance pipe, water is injected by the import of hydrophily input house steward, water is at hydrophily input underground heat balance pipe and hydrophily output underground heat balance Bottomhole pressure, heat exchange is carried out by hydrophily ground heat compensator between geological stratification and water outside hydrophily ground heat compensator, water temperature after heat absorption raises, lower the temperature after heat radiation, water after alternating temperature is exported by the outlet of hydrophily delivery trunk, carry out heat exchange again with user terminal and realize intensification or the cooling of environment, the hydrophily ground heat compensator that this utility model provides does not has environmental pollution, and it is not required to exploiting groundwater and hot spring i.e. may utilize geothermal energy resources, effectively prevent groundwater abstraction and destroy the harm of geological ecology.

Accompanying drawing explanation

In order to be illustrated more clearly that this utility model detailed description of the invention or technical scheme of the prior art, the accompanying drawing used required in detailed description of the invention or description of the prior art will be briefly described below, apparently, accompanying drawing in describing below is embodiments more of the present utility model, for those of ordinary skill in the art, on the premise of not paying creative work, it is also possible to obtain other accompanying drawing according to these accompanying drawings.

The overall structure schematic diagram of the hydrophily ground heat compensator that Fig. 1 provides for this utility model embodiment；

The overall structure schematic diagram of the high/low temperature integral type hydrophily underground heat static organ that Fig. 2 provides for this utility model embodiment；

The structural representation of the massif horizontally embedded formula hydrophily ground heat compensator that Fig. 3 provides for this utility model embodiment；

The structural representation of the high/low temperature hydrophily transducer that Fig. 4 provides for this utility model embodiment；

Fig. 5 is the structural representation of this utility model embodiment filter.Reference:

nullIn figure: 101、Base segment，102、Heat exchange segment，103、Deferent segment，104、Hydrophily delivery trunk，105、Hydrophily input house steward，106、Heat-insulating cover，107、Maintenance passage heat exchange segment，108、Intermediate connection tube，109、Later group hydrophily output underground heat balance pipe，110、Collection silt device later group hydrophily output underground heat balance pipe docking port，111、Collection silt device later group hydrophily input underground heat balance pipe docking port，112、First group of hydrophily input underground heat balance pipe docking port of collection silt device，113、First group of hydrophily output underground heat balance pipe docking port of collection silt device，114、Maintenance passage base segment，115、Collection silt device，116、Hoisting tray，117、Lifting pulley，201、High temperature base segment，202、High-temperature hot exchange section，203、First group of high temperature hydrophily output underground heat balance pipe，204、Later group high temperature hydrophily input underground heat balance pipe，205、Connect the collection silt device of first group of low temperature hydrophily underground heat balance pipe，206、Low Temperature Thermal exchange section，207、Later group low temperature hydrophily output underground heat balance pipe，208、First group of low temperature hydrophily input underground heat balance pipe，209、Deferent segment，210、Low temperature hydrophily input house steward，211、Low temperature hydrophily delivery trunk，212、Maintenance passage low-temperature zone，213、High temperature hydrophily input house steward，214、High temperature hydrophily delivery trunk，215、Low temperature hydrophily underground heat balance pipe intermediate connection tube，216、Later group low temperature hydrophily input underground heat balance pipe，217、First group of low temperature hydrophily output underground heat balance pipe，218、Connect the collection silt device of later group low temperature hydrophily underground heat balance pipe，219、High temperature hydrophily underground heat balance pipe intermediate connection tube，220、First group of high temperature hydrophily input underground heat balance pipe，221、Maintenance passage high temperature section，222、Later group high temperature hydrophily output underground heat balance pipe，223、Connect the collection silt device of first group of high temperature hydrophily underground heat balance pipe，224、Connect the collection silt device of later group high temperature hydrophily underground heat balance pipe，225、Hoisting tray，226、Lifting pulley，301、Hydrophily input house steward，302、Hydrophily delivery trunk，303、Maintenance passage，304、Intermediate connection tube，305、Second group of hydrophily output underground heat balance pipe，306、Later group hydrophily output underground heat balance pipe，307、Later group hydrophily input underground heat balance pipe，308、Second group of hydrophily input underground heat balance pipe，309、First group of hydrophily output underground heat balance pipe，310、First group of hydrophily input underground heat balance pipe，311、Sealing plug，312、Row's silt mouth，401、Input，402、Outfan，403、First port，404、3rd port，405、4th port，406、Second port，407、Second switch，408、4th switch，409、3rd switch，410、First switch，501、Sealing plug，502、Row's silt mouth，503、Input，504、Input side abdominal part，505、Filter mesh screen fixed disk，506、Outlet side abdominal part，507、Outfan.

Detailed description of the invention

Below in conjunction with accompanying drawing, the technical solution of the utility model is clearly and completely described, it is clear that described embodiment is a part of embodiment of this utility model rather than whole embodiments.Based on the embodiment in this utility model, the every other embodiment that those of ordinary skill in the art are obtained under not making creative work premise, broadly fall into the scope of this utility model protection.

In description of the present utility model, it should be noted that, orientation or the position relationship of the instruction such as term " " center ", " on ", D score, "left", "right", " vertically ", " level ", " interior ", " outward " they be based on orientation shown in the drawings or position relationship; be for only for ease of description this utility model and simplifying and describe; rather than instruction or imply the device of indication or element must have specific orientation, with specific azimuth configuration and operation, therefore it is not intended that to restriction of the present utility model.Additionally, term " first ", " second ", " the 3rd " are only used for describing purpose, and it is not intended that instruction or hint relative importance.

In description of the present utility model, it should be noted that unless otherwise clearly defined and limited, term " is installed ", " being connected ", " connection " should be interpreted broadly, and connects for example, it may be fixing, it is also possible to be to removably connect, or be integrally connected；Can be to be mechanically connected, it is also possible to be electrical connection；Can be to be joined directly together, it is also possible to be indirectly connected to by intermediary, can be the connection of two element internals.For the ordinary skill in the art, above-mentioned term concrete meaning in this utility model can be understood with concrete condition.

Embodiment one

As it is shown in figure 1, monomer high temperature hydrophily underground heat static organ or the construction program of low temperature hydrophily underground heat static organ

Integrated low-temperature hydrophily ground heat compensator is built in effective geology thermostat layer on 200 meters of below earth's surface

Level, to vertical arbitrarily angled, main produces 15 20 DEG C or the hydrophily of 20 25 DEG C, can be used for heat

Band and subtropical zone ambient temperature constant, or the environment temperature reduction in refrigerant latitudes summer.

Monomer high temperature hydrophily underground heat static organ is built in the most thermally the 5 of 200 1000 meters of below earth's surface

In matter layer, level is to vertical arbitrarily angled, for producing the hydrophily of 20 90 DEG C, can be used for frigid zone or

Subtropical zone winter for warm artificial hot-spring.

In frigid zone or subtropical zone, integrated low-temperature hydrophily ground heat compensator and monomer high temperature hydrophily underground heat

Static organ is combined utilizing by the connection of high/low temperature hydrophily transducer, can realize the environment temperature reduction in summer

Heating with winter.10

Integrated low-temperature hydrophily ground heat compensator and monomer high temperature hydrophily underground heat static organ concrete are described below

Embodiment

As it is shown in figure 1, present embodiments provide a kind of integrated low-temperature or high temperature hydrophily underground heat static organ, this hydrophily ground heat compensator includes: deferent segment 103, heat exchange segment 102 and base segment 101.

Base segment 101, including hoisting tray 116, collection silt device 115, hoisting tray 116 surrounding is provided with lifting pulley 117, is provided with collection silt device 115, the axis of symmetry of collection silt device 115 is provided with maintenance passage base segment 114 on hoisting tray 116 card.

Heat exchange segment 102, including organizing hydrophily input underground heat balance pipe and many group hydrophily output ground thermal balance more

Pipe, on the axis of symmetry of many group hydrophily output underground heat balance pipes and many group hydrophily input underground heat balance pipes, is provided with maintenance passage heat exchange segment 107.

Deferent segment 103, including hydrophily input house steward 105, hydrophily delivery trunk 104 and heat-insulating cover 106.

The outfan of hydrophily input house steward 105 and the input of first group of hydrophily input underground heat balance pipe are connected, first group of hydrophily input underground heat balance pipe docking port 112 of the outfan of first group of hydrophily input underground heat balance pipe and collection silt device is connected, first group of hydrophily output underground heat balance pipe docking port 113 of the input of first group of hydrophily output underground heat balance pipe and collection silt device is connected, the outfan of first group of hydrophily output underground heat balance pipe is connected with second group of hydrophily input underground heat balance pipe input by intermediate connection tube 108, second group of hydrophily input ground thermal balance of second group of hydrophily input underground heat balance pipe outfan and collection silt device

Pipe docking port is connected, second group of hydrophily output underground heat balance pipe docking port of second group of hydrophily output underground heat balance pipe input and collection silt device is connected, one to multiple group of underground heat balance pipe so can be had to be serially connected in roundabout shape, until the outfan of later group hydrophily input underground heat balance pipe is connected with collection silt device later group hydrophily input underground heat balance pipe docking port 111, the input of later group hydrophily output underground heat balance pipe 109 is connected with collection silt device later group hydrophily output underground heat balance pipe docking port 110, the outfan of later group hydrophily output underground heat balance pipe 109 is connected with the input of hydrophily delivery trunk 104.

The heat exchange segment 102 of hydrophily ground heat compensator and base segment 101；Can be built by docking by high temperature resistant, corrosion-resistant, damp proof graded ceramic tender, the gap between tender and geological stratification gap and section and section makes both combine closely by the material encapsulation high temperature resistant, corrosion-resistant, damp proof, leakproof that intensity is C10-C50 and forms an entirety；Also can be shaped by corrosion resistant steel or plastic cement setting bracket, the ion permeability material segmentation integral cast of high temperature resistant, corrosion-resistant, the damp proof leakproof that intensity is C10-C50 build.

Deferent segment 103, can be shaped by corrosion resistant steel or plastic cement setting bracket, the material segmentation integral cast high temperature resistant, corrosion-resistant, damp proof, leakproof that intensity is C10-C5015 build.

The cross-sectional area of one to multiple group of hydrophily input underground heat balance pipe, one to multiple group of hydrophily input underground heat balance pipe, hydrophily input house steward 105, hydrophily delivery trunk 104 and intermediate connection tube 108 is 0.001-0.3m2.Outer a length of 50 150cm of intermediate connection tube 108.

The total height of base segment 101 is 10 750 meters, and the total height of heat exchange segment 102 is 150 75020 meters, and the total height of deferent segment 103 is 20 200 meters.

Monomer high temperature hydrophily underground heat static organ is connected with the outfan 507 of hydrophily input filter with the input of the hydrophily input house steward 105 of integrated low-temperature hydrophily ground heat compensator, and the input 503 of hydrophily input filter is connected with the hydrophily return duct being connected user terminal；Monomer high temperature hydrophily underground heat static organ is connected with the input 503 of hydrophily output filter with the outfan of hydrophily delivery trunk 104 of integrated low-temperature hydrophily ground heat compensator, and the outfan 507 of hydrophily output filter is connected with the hydrophily input pipe being connected user terminal.

nullWhen monomer high temperature hydrophily underground heat static organ and the heat compensator combination of integrated low-temperature hydrophily ground utilize，The outfan of hydrophily delivery trunk 104 of monomer high temperature hydrophily underground heat static organ is connected with the 4th port 405 of high/low temperature hydrophily transducer，The input of the hydrophily input house steward 105 of monomer high temperature hydrophily underground heat static organ is connected with the second port 406 of high/low temperature hydrophily transducer，The outfan of hydrophily delivery trunk 104 of integrated low-temperature hydrophily ground heat compensator is connected with the 3rd port 404 of high/low temperature hydrophily transducer，The input of the hydrophily input house steward 105 of integrated low-temperature hydrophily ground heat compensator is connected with the first port 403 of high/low temperature hydrophily transducer，The outfan 507 of hydrophily input filter is connected with the input 401 of high/low temperature hydrophily transducer，The input 503 of hydrophily input filter is connected with the hydrophily return duct being connected user terminal，The input 503 of hydrophily output filter is connected with the outfan 402 of high-low-temperature 10 matchmaker's transducer，The outfan 507 of hydrophily output filter is connected with the hydrophily input pipe being connected user terminal.

User terminal can be that one or more is connected in series or parallel.The outfan of the hydrophily delivery trunk 104 of monomer high temperature hydrophily underground heat static organ can set up one or more output branch separately, and each output branch can distribute a kind of different purposes, as supply artificial hot-spring and heating can be carried out function distribution by different branches.

The operation principle of monomer high temperature hydrophily underground heat static organ

nullWhen user terminal needs the hydrophily of 20-90 DEG C，Hydrophily is inputted from the input 503 of hydrophily input filter the input side abdominal part 504 of hydrophily input filter，The outlet side abdominal part 506 of hydrophily input filter is entered be likely to result in the foreign body of high temperature hydrophily underground heat static organ heat exchange segment 102 silting via the 30 300 mesh filtration screen filtration reductions being fixed on filtration mesh screen fixed disk 505 after，In the heat exchange segment 102 of exogenous hydrophily injection high temperature hydrophily underground heat static organ, heat exchange is carried out again by the outfan 507 of hydrophily input filter and the hydrophily input house steward 105 of high temperature hydrophily underground heat static organ，In hydrophily, the drift sedimentation of remaining is collected in collection silt device，After hydrophily temperature is increased to 20-90 DEG C，The input side abdominal part 504 of hydrophily output filter is inputted again by the hydrophily delivery trunk 104 of high temperature hydrophily underground heat static organ and the input 503 of hydrophily output filter，The outlet side abdominal part 506 entering hydrophily output filter after being filtered to remove the foreign body being likely to result in user terminal silting is sieved via the 30 300 mesh drainage screens being fixed on filtration mesh screen fixed disk 505，Then supplied the hydrophily of 20-90 DEG C to user terminal by the outfan 507 of hydrophily output filter.

As it is shown in figure 5, when occurring foreign body to heap in the input side abdominal part 504 of hydrophily input filter, the sealing plug 501 on the removable row of being placed in silt mouth 502 carries out row and becomes silted up, and then puts back to sealing plug 501；When having served as filter mesh sieve generation blocking, drainage screen sieve fixed disk 505 can be pulled down, clear up being fixed on the filtration mesh screen filtered on mesh screen fixed disk 505 or replace.

When occurring foreign body to heap in the input side abdominal part 504 of hydrophily output filter, the sealing plug 501 on the removable row of being placed in silt mouth 502 carries out row and becomes silted up, and then puts back to sealing plug 501；When having served as filter mesh sieve generation blocking, drainage screen sieve fixed disk 505 can be pulled down, clear up being fixed on the filtration mesh screen filtered on mesh screen fixed disk 505 or replace.

The operation principle of integrated low-temperature hydrophily ground heat compensator

nullWhen user terminal needs the hydrophily of 15 20 DEG C or 20 25 DEG C，Hydrophily is inputted from the input 503 of hydrophily input filter the input side abdominal part 504 of hydrophily input filter，The outlet side abdominal part 506 of hydrophily input filter is entered be likely to result in the foreign body of low temperature hydrophily underground heat static organ heat exchange segment 102 silting via the 30 300 mesh filtration screen filtration reductions being fixed on filtration mesh screen fixed disk 505 after，In the heat exchange segment 102 of exogenous hydrophily injection low temperature hydrophily underground heat static organ, heat exchange is carried out again by the outfan 507 of hydrophily input filter and the hydrophily input house steward 105 of low temperature hydrophily underground heat static organ，In hydrophily, the drift sedimentation of remaining is collected in collection silt device，After hydrophily temperature is reduced to 15-20 DEG C or is increased to 20-25 DEG C，Gone out the input 503 of filter by the hydrophily delivery trunk 104 of low temperature hydrophily underground heat static organ and hydrophily defeated 20 again and input the input side abdominal part 504 of hydrophily output filter，Sieve via the 30 300 mesh drainage screens being fixed on filtration mesh screen fixed disk 505 and enter hydrophily output filter outlet side abdominal part 506 after being filtered to remove the foreign body being likely to result in user terminal silting，Then 15 20 DEG C or the hydrophily of 20 25 DEG C are supplied by the outfan 507 of hydrophily output filter to user terminal.

When in the input side abdominal part 504 of hydrophily input filter, generation foreign body is heaped, removable 25 sealing plugs 501 on row's silt mouth 502 of laying carry out row's silt, then put back to sealing plug 501；When having served as filter mesh sieve generation blocking, drainage screen sieve fixed disk 505 can be pulled down, clear up being fixed on the filtration mesh screen filtered on mesh screen fixed disk 505 or replace.

When occurring foreign body to heap in the input side abdominal part 504 of hydrophily output filter, the sealing plug 501 on the removable row of being placed in silt mouth 502 carries out row and becomes silted up, and then puts back to sealing plug 501；When having served as filter mesh sieve generation blocking, drainage screen sieve fixed disk 505 can be pulled down, clear up being fixed on the filtration mesh screen filtered on mesh screen fixed disk 505 or replace.

Operation principle when monomer high temperature hydrophily underground heat static organ and the heat compensator combination of integrated low-temperature hydrophily ground utilize

When user terminal needs the hydrophily supplying 15 20 DEG C, it is connected on the high/low temperature hydrophily transducer of monomer high temperature hydrophily underground heat static organ and integrated low-temperature hydrophily ground heat compensator, see Fig. 4, the first switch 410 and the 3rd switch 409 unlatching being positioned on the first port 403 and the 3rd port 404 passage, the second switch 407 being positioned on the second port 406 and the 4th port 405 passage and the 4th switch 408 closedown, high temperature hydrophily underground heat static organ is in resting state, and low temperature hydrophily underground heat static organ is in running order；nullHydrophily is inputted from the input 503 of hydrophily input filter the input side abdominal part 504 of hydrophily input filter，The outlet side abdominal part 506 of hydrophily input filter is entered be likely to result in the foreign body of low temperature hydrophily underground heat static organ heat exchange segment 102 silting via the 30 300 mesh filtration screen filtration reductions being fixed on filtration mesh screen fixed disk 505 after，In the heat exchange segment 102 of exogenous hydrophily injection low temperature hydrophily underground heat static organ, heat exchange is carried out again by the outfan 507 of hydrophily input filter and the hydrophily input house steward 105 of the first port 403 of high/low temperature hydrophily transducer and low temperature hydrophily underground heat static organ，In hydrophily, the drift sedimentation of remaining is collected in collection silt device，After hydrophily temperature is reduced to 20 25 DEG C，Again by low temperature hydrophily underground heat static organ hydrophily delivery trunk 104、3rd port 404 of high/low temperature hydrophily transducer and the input 503 of hydrophily output filter input the input side abdominal part 504 of hydrophily output filter，The outlet side abdominal part 506 entering hydrophily output filter after being filtered to remove the foreign body being likely to result in user terminal silting is sieved via the 30 300 mesh drainage screens being fixed on filtration mesh screen fixed disk 505，Then supplied the hydrophily of 20 25 DEG C to user terminal by the outfan 507 of hydrophily output filter.

When user terminal needs the hydrophily supplying 20 90 DEG C, connect on the high/low temperature hydrophily transducer of monomer high temperature hydrophily underground heat static organ and monomer low hydrophily temperature ground heat compensator, the first switch 410 and the 3rd switch 409 closedown being positioned on the first port 403 and the 3rd port 404 passage, the second switch 407 being positioned on the second port 406 and the 4th port 405 passage and the 4th switch 408 unlatching, high temperature hydrophily underground heat static organ is in running order, and low temperature hydrophily underground heat static organ is in resting state；nullHydrophily is inputted from the input 503 of hydrophily input filter the input side abdominal part 504 of hydrophily input filter，The outlet side abdominal part 506 of hydrophily input filter is entered be likely to result in the foreign body of high temperature hydrophily underground heat static organ heat exchange segment 102 silting via the 30 300 mesh filtration screen filtration reductions being fixed on filtration mesh screen fixed disk 505 after，Again by the outfan 507 of hydrophily input filter、Second port 406 of high/low temperature hydrophily transducer and the hydrophily input house steward 105 of high temperature hydrophily underground heat static organ carry out heat exchange in the heat exchange segment 102 of exogenous hydrophily injection high temperature hydrophily underground heat static organ，In hydrophily, the drift sedimentation of remaining is collected in collection silt device，After hydrophily temperature is increased to 20-90 DEG C，Again by the hydrophily delivery trunk 104 of high temperature hydrophily underground heat static organ、4th port 405 of high/low temperature hydrophily transducer and the input 503 of hydrophily output filter input the input side abdominal part 504 of hydrophily output filter，The outlet side abdominal part 506 entering hydrophily output filter after being filtered to remove the foreign body being likely to result in user terminal silting is sieved via the 30 300 mesh drainage screens being fixed on filtration mesh screen fixed disk 505，Then supplied the hydrophily of 20-90 DEG C to user terminal by hydrophily output filter outfan 507.

When occurring foreign body to heap in the input side abdominal part 504 of hydrophily input filter, the sealing plug 501 on the removable row of being placed in silt mouth 502 carries out row and becomes silted up, and then puts back to sealing plug 501；When having served as filter mesh sieve generation blocking, drainage screen sieve fixed disk 505 can be pulled down, clear up being fixed on the filtration mesh screen filtered on mesh screen fixed disk 505 or replace.

When occurring foreign body to heap in the input side abdominal part 504 of hydrophily output filter, the sealing plug 501 on the removable row of being placed in silt mouth 502 carries out row and becomes silted up, and then puts back to sealing plug 501；When having served as filter mesh sieve generation blocking, drainage screen sieve fixed disk 505 can be pulled down, clear up being fixed on the filtration mesh screen filtered on mesh screen fixed disk 505 or replace.

Embodiment two

The construction program of high/low temperature integral type hydrophily underground heat static organ

High/low temperature integral type hydrophily underground heat static organ is built in level in effective geological stratification on 1000 meters of below earth's surface to vertical arbitrarily angled, produces 15 25 DEG C and the hydrophily of 20 90 DEG C, can be used for the constant of subtropical and tropical zones ambient temperature and artificial hot-spring.

The specific embodiments of high/low temperature integral type hydrophily underground heat static organ is described below

As shown in Figure 2, present embodiments providing a kind of high/low temperature integral type hydrophily underground heat static organ, this hydrophily ground heat compensator includes: deferent segment 209, Low Temperature Thermal exchange section 206, high-temperature hot exchange section 202, high temperature base segment 201, high/low temperature hydrophily transducer, hydrophily input filter and hydrophily output filter.

High temperature base segment 201, it is positioned at effective geotherm geology layer on 250 1000 meters of below earth's surface, including connecting the collection silt device 223 of first group of high temperature hydrophily underground heat balance pipe, connecting collection silt device 224, the support hoisting tray 225 of later group high temperature hydrophily underground heat balance pipe and be distributed in multiple lifting pulleys 226 that support is peripheral.

High-temperature hot exchange section 202, it is positioned at effective geotherm geology layer on 200 1000 meters of below earth's surface, including first group of high temperature hydrophily output underground heat balance pipe 203, later group high temperature hydrophily input underground heat balance pipe 204,219, first group of high temperature hydrophily input underground heat balance pipe 220 of high temperature hydrophily underground heat balance pipe intermediate connection tube, maintenance passage high temperature section 221 and later group high temperature hydrophily output underground heat balance pipe 222.

Low Temperature Thermal exchange section 206, it is positioned at effective geology thermostat layer on 20 200 meters of below earth's surface, including connecting the collection silt device 205 of first group of low temperature hydrophily underground heat balance pipe, 207, first group of low temperature hydrophily input underground heat balance pipe 208 of later group low temperature hydrophily output underground heat balance pipe, low temperature hydrophily underground heat balance pipe intermediate connection tube 215,216, first group of low temperature hydrophily output underground heat balance pipe 217 of later group low temperature hydrophily input underground heat balance pipe and connecting the collection silt device 218 of later group low temperature hydrophily underground heat balance pipe.

Deferent segment 209, is positioned at effective geological stratification on 20 200 meters of below earth's surface, including low temperature hydrophily input house steward 210, low temperature hydrophily delivery trunk 211, maintenance passage low-temperature zone 212, high temperature hydrophily input house steward 213 and high temperature hydrophily delivery trunk 214.

High/low temperature hydrophily transducer includes, input 401, outfan the 402, first port the 403, the 3rd port the 404, the 4th port the 405, second port 406, second switch the 407, the 4th switch the 408, the 3rd switch 409 and the first switch 410.

Hydrophily input filter and hydrophily output filter include, sealing plug 501, row's silt mouth 502, input 503, input side abdominal part 504, filtration mesh screen fixed disk 505, outlet side abdominal part 506 and outfan 507.

nullThe outfan of high temperature hydrophily input house steward 213 and the input of first group of high temperature hydrophily input underground heat balance pipe 2205 are connected，The outfan of first group of high temperature hydrophily input underground heat balance pipe 220 and the input of first group of high temperature hydrophily output underground heat balance pipe 203，Serial communication is carried out by connecting the collection silt device 223 of first group of high temperature hydrophily underground heat balance pipe，The outfan of first group of high temperature hydrophily output underground heat balance pipe 203 carries out serial communication by the input of high temperature hydrophily underground heat balance pipe intermediate connection tube 219 and second group of high temperature hydrophily input underground heat balance pipe，The outfan of later group high temperature hydrophily input underground heat balance pipe 204 and the input of later group high temperature hydrophily output underground heat balance pipe 222，Serial communication is carried out by connecting the collection silt device 224 of later group high temperature hydrophily underground heat balance pipe，One to multiple group of high temperature hydrophily underground heat balance pipe so can be had to be connected in series in into roundabout shape，The outfan of later group high temperature hydrophily output underground heat balance pipe 222 is connected with the input of high temperature hydrophily delivery trunk 214.

The input of high temperature hydrophily input house steward 213 is connected with the second port 406 of high/low temperature hydrophily transducer, the outfan of high temperature hydrophily delivery trunk 214 is connected with the 4th port 405 of high/low temperature hydrophily transducer, the outfan of high temperature hydrophily delivery trunk 214 can connect one to multiple output branchs, each output branch can distribute a kind of different purposes, as supply artificial hot-spring and heating can be carried out function distribution by different branches.

nullThe outfan of low temperature hydrophily input house steward 210 and the input of first group of low temperature hydrophily input underground heat balance pipe 208 are connected，The outfan of first group of low temperature hydrophily input underground heat balance pipe 208 and the input of first group of low temperature hydrophily output underground heat balance pipe 217，Serial communication is carried out by connecting the collection silt device 205 of first group of low temperature hydrophily underground heat balance pipe，The outfan of first group of low temperature hydrophily output underground heat balance pipe 217 carries out serial communication by the input of low temperature hydrophily underground heat balance pipe intermediate connection tube 215 and second group of low temperature hydrophily input underground heat balance pipe，The outfan of later group low temperature hydrophily input underground heat balance pipe 216 and the input of later group low temperature hydrophily output underground heat balance pipe 207，Serial communication is carried out by connecting the collection silt device 218 of later group low temperature hydrophily underground heat balance pipe，One to multiple group of low temperature hydrophily underground heat balance pipe so can be had to be serially connected in roundabout shape，The outfan of later group low temperature hydrophily output underground heat balance pipe 207 is connected with the input of low temperature hydrophily delivery trunk 211.

The maintenance passage high temperature section 221 of high/low temperature integral type hydrophily underground heat static organ is positioned on the axis of symmetry of many group high temperature hydrophily underground heat balance pipes and high temperature collection silt device, on the axis of symmetry of the Low Temperature Thermal exchange section that the maintenance passage low-temperature zone 212 of high/low temperature integral type hydrophily underground heat static organ is positioned at many group low temperature hydrophily underground heat balance pipes, low temperature collection silt device, high temperature hydrophily delivery trunk 214 and high temperature hydrophily input house steward 213, the maintenance passage high temperature section 221 of high/low temperature integral type hydrophily underground heat static organ and maintenance passage low-temperature zone 212 serial communication of high/low temperature integral type hydrophily underground heat static organ.

The input of low temperature hydrophily input house steward 210 is connected with the first port 403 of high/low temperature hydrophily transducer, and the outfan of low temperature hydrophily delivery trunk 211 is connected with the 3rd port 404 of high/low temperature hydrophily transducer.

The outfan 507 of hydrophily input filter is connected with the input 401 of high/low temperature hydrophily transducer, the input 503 of hydrophily input filter is connected with the hydrophily return duct being connected user terminal, the input 503 of hydrophily output filter is connected with the outfan 402 of high/low temperature hydrophily transducer, and the outfan 507 of hydrophily output filter is connected with the hydrophily input pipe being connected user terminal.

The high temperature base segment 201 of high/low temperature integral type hydrophily underground heat static organ, high-temperature hot exchange section 202, Low Temperature Thermal exchange section 206, can be built by docking by high temperature resistant, corrosion-resistant, damp proof graded ceramic tender, the gap between tender and geological stratification gap and section and section makes both combine closely by the material encapsulation high temperature resistant, corrosion-resistant, damp proof, leakproof that intensity is C10-C50 and forms an entirety；Also can be shaped by corrosion resistant steel or plastic cement setting bracket, the ion permeability material segmentation integral cast high temperature resistant, corrosion-resistant, damp proof, leakproof that intensity is C10-C50 build.

Deferent segment 209, can be shaped by corrosion resistant steel or plastic cement setting bracket, the material segmentation integral cast high temperature resistant, corrosion-resistant, damp proof, leakproof that intensity is C10-C50 build.

Between one to multiple group of high temperature and low temperature hydrophily input underground heat balance pipe, one to multiple group of high temperature and low temperature hydrophily input underground heat balance pipe, high/low temperature hydrophily input house steward, high/low temperature hydrophily delivery trunk and group, the cross-sectional area of connecting tube is 0.001-0.3m².Outer a length of 50 150cm of intermediate connection tube.

User terminal can be that one or more carries out series winding connection or is connected in parallel.

The operation principle of high/low temperature integral type hydrophily underground heat static organ

When user terminal needs the hydrophily supplying 15 25 DEG C, the first switch 410 and the 3rd switch 409 unlatching being positioned on the first port 403 and the 3rd port 404 passage, the second switch 407 being positioned on the second port 406 and the 4th port 405 passage and the 4th switch 408 closedown, the high temperature section of high/low temperature integral type hydrophily underground heat static organ or be in resting state, the low-temperature zone of high/low temperature integral type hydrophily underground heat static organ is in running order；nullHydrophily is inputted from the input 503 of hydrophily input filter the input side abdominal part 504 of hydrophily input filter，The outlet side abdominal part 506 of hydrophily input filter is entered be likely to result in the foreign body of high/low temperature integral type hydrophily underground heat static organ Low Temperature Thermal exchange section 206 silting via the 30 300 mesh filtration screen filtration reductions being fixed on filtration mesh screen fixed disk 505 after，Heat exchange is carried out in exogenous hydrophily being injected the Low Temperature Thermal exchange section 206 that high/low temperature integral type hydrophily underground heat balances by the outfan 507 of hydrophily input filter and the low temperature hydrophily input house steward 210 of the first port 403 of high/low temperature hydrophily transducer and high/low temperature integral type hydrophily underground heat static organ again，In hydrophily, the drift sedimentation of remaining is collected in collection silt device，After hydrophily temperature is reduced to 15-25 DEG C，Again through low temperature hydrophily delivery trunk 211、3rd port 404 of high/low temperature hydrophily transducer and the input 503 of hydrophily output filter input the input side abdominal part 504 of hydrophily output filter，The outlet side abdominal part 506 entering hydrophily output filter after being filtered to remove the foreign body being likely to result in user terminal silting is sieved via the 30 300 mesh drainage screens being fixed on filtration mesh screen fixed disk 505，Then supplied the hydrophily of 15 25 DEG C to user terminal by the outfan 507 of hydrophily output filter.

When user terminal needs the hydrophily supplying 20 90 DEG C, the first switch 410 and the 3rd switch 409 closedown being positioned on the first port 403 and the 3rd port 404 passage, the second switch 407 being positioned on the second port 406 and the 4th port 405 passage and the 4th switch 408 unlatching, high/low temperature integral type hydrophily underground heat static organ high temperature section is in running order, and high/low temperature integral type hydrophily underground heat static organ low-temperature zone is in resting state；nullHydrophily is inputted from the input 503 of hydrophily input filter the input side abdominal part 504 of hydrophily input filter，The outlet side abdominal part 506 of hydrophily input filter is entered filter the foreign body of high-temperature hot exchange section 202 silting that screen filtration reduction is likely to result in high/low temperature integral type hydrophily underground heat static organ via 30 300 mesh being fixed on filtration mesh screen fixed disk 505 after，Again by hydrophily input filter outfan 507、Second port 406 of high/low temperature hydrophily transducer and the high temperature hydrophily input house steward 213 of high/low temperature integral type hydrophily underground heat static organ carry out heat exchange in the high-temperature hot exchange section 202 of exogenous hydrophily injection high/low temperature integral type hydrophily underground heat static organ，In hydrophily, the drift sedimentation of remaining is collected in collection silt device，After hydrophily temperature is increased to 20-90 DEG C，Again by the high temperature hydrophily delivery trunk 214 of high/low temperature integral type hydrophily underground heat static organ、4th port 405 of high/low temperature hydrophily transducer and the input 503 of hydrophily output filter input the input side abdominal part 504 of hydrophily output filter，The outlet side abdominal part 506 entering hydrophily output filter after being filtered to remove the foreign body being likely to result in user terminal silting is sieved via the 30 300 mesh drainage screens being fixed on filtration mesh screen fixed disk 505，Then supplied the hydrophily of 20-90 DEG C to user terminal by the outfan 507 of hydrophily output filter.

When occurring foreign body to heap in the input side abdominal part 504 of hydrophily input filter, the sealing plug 501 on the removable row of being placed in silt mouth 502 carries out row and becomes silted up, and then puts back to sealing plug 501；When having served as filter mesh sieve generation blocking, drainage screen sieve fixed disk 505 can be pulled down, clear up being fixed on the filtration mesh screen filtered on mesh screen fixed disk 505 or replace.

When occurring foreign body to heap in the input side abdominal part 504 of hydrophily output filter, the sealing plug 501 on the removable row of being placed in silt mouth 502 carries out row and becomes silted up, and then puts back to sealing plug 501；When having served as filter mesh sieve generation blocking, drainage screen sieve fixed disk 505 can be pulled down, clear up being fixed on the filtration mesh screen filtered on mesh screen fixed disk 505 or replace.

Embodiment three

The present embodiment provides the construction program of a kind of massif horizontally embedded formula ground heat compensator

Massif embedded type hydrophily ground heat compensator, horizontally embedded Yushan Hill body thickness is more than in the massif of 300-1500 rice, there is no the massif built-in orogenetic body horizontally embedded formula constant temperature ground heat compensator of geothermal energy resources, construction program and basic module with removing the monomer high temperature hydrophily underground heat static organ outside base segment or integrated low-temperature hydrophily ground heat compensator；Building high/low temperature one massif horizontally embedded formula ground heat compensator in having the massif of geothermal energy resources, construction program and basic module are with removing the high/low temperature integral type hydrophily underground heat static organ outside base segment.

The construction program of massif horizontally embedded formula hydrophily ground heat compensator is described below

As it is shown on figure 3, massif horizontally embedded formula hydrophily ground heat compensator include heat exchange segment, deferent segment,

Hydrophily output filter or high/low temperature hydrophily transducer.

The heat exchange segment of massif horizontally embedded formula hydrophily ground heat compensator, the geological stratification of 30 1300 meters within the massif of heat compensator heads on being positioned at massif horizontally embedded formula hydrophily, heat exchange segment includes that 304, second group of hydrophily output underground heat balance pipe 305 of intermediate connection tube, later group hydrophily output underground heat balance pipe 306, later group hydrophily input 307, second group of hydrophily of underground heat balance pipe input 308, first group of hydrophily output underground heat balance pipe 309 of underground heat balance pipe and first group of hydrophily input underground heat balance pipe 310.

The deferent segment of massif horizontally embedded formula hydrophily ground heat compensator, the geological stratification of 30 meters within the massif of heat compensator heads on being positioned at massif horizontally embedded formula hydrophily, deferent segment includes hydrophily input house steward 301, hydrophily delivery trunk 302, maintenance passage 303, sealing plug 311 and row's silt mouth 312.

nullThe input of hydrophily input house steward 301 is connected with external hydrophily user terminal return duct，The outfan of hydrophily input house steward 301 and the input of first group of hydrophily input underground heat balance pipe 310 are connected，The outfan of first group of hydrophily input underground heat balance pipe 310 and the input of first group of hydrophily output underground heat balance pipe 309 carry out serial communication by intermediate connection tube 304，The outfan of first group of hydrophily output underground heat balance pipe 309 carries out serial communication by the input of intermediate connection tube 304 and second group of hydrophily input underground heat balance pipe 308，The outfan of second group of hydrophily input underground heat balance pipe 308 carries out serial communication by the input of intermediate connection tube 304 and second group of hydrophily output underground heat balance pipe 305，So many group of underground heat balance pipe is concatenated into roundabout shape，And with later group hydrophily input underground heat balance pipe 307 input carry out serial communication，The outfan of later group hydrophily input underground heat balance pipe 307 is by centre

Connecting tube 304 carries out serial communication with the input of later group hydrophily output underground heat balance pipe 306, the outfan of later group hydrophily output underground heat balance pipe 306 is connected with the input of hydrophily delivery trunk 302, the downstream of the outfan of hydrophily delivery trunk 302 is provided with row's silt mouth 312, removable sealing plug 311 is had on row's silt mouth 312, the outfan of hydrophily delivery trunk 302 is connected with the input 503 of hydrophily output filter, and the outfan 507 of hydrophily output filter utilizes terminal to be connected with external hydrophily.

The heat exchange segment of massif horizontally embedded formula hydrophily ground heat compensator and deferent segment, by corrosion-resistant, damp proof, the steel material of leakproof or shaped by plastic shape-forming support, building with the material segmentation casting corrosion-resistant, damp proof, leakproof that intensity is C10-C30, maintenance passage 303 is positioned on the axis of symmetry of many group hydrophily input underground heat balance pipes and many group hydrophily output underground heat balance pipes.

The cross-sectional area of hydrophily input underground heat balance pipe, hydrophily output underground heat balance pipe, intermediate connection tube 304, hydrophily delivery trunk 302 and hydrophily input house steward 301 is 0.001-0.3m2.

The operation principle of horizontal massif embedded type hydrophily ground heat compensator:

nullWhen user terminal needs the hydrophily realization intensification of 15 20 DEG C or the hydrophily of 20 25 DEG C realizes cooling，From hydrophily, input house steward 301 carries out heat exchange in the heat exchange segment of exogenous hydrophily Injection Level formula massif embedded type hydrophily ground heat compensator，After hydrophily temperature is reduced to 20-25 DEG C or is increased to 15-20 DEG C，The input side abdominal part 504 of hydrophily output filter is inputted again by the horizontal massif embedded type hydrophily ground hydrophily delivery trunk 302 of heat compensator and the input 503 of hydrophily output filter，The outlet side abdominal part 506 entering hydrophily output filter after being filtered to remove the foreign body being likely to result in user terminal silting is sieved via the 30 300 mesh drainage screens being fixed on filtration mesh screen fixed disk 505，Then 15 20 DEG C or the hydrophily of 20 25 DEG C are supplied by the outfan 507 of hydrophily output filter to user terminal.

When occurring foreign body to heap in the defeated mistake of hydrophily goes out the input side abdominal part 504 of filter, the sealing plug 501 on the removable row of being placed in silt mouth 502 carries out row and becomes silted up, and then puts back to sealing plug 501；When having served as filter mesh sieve generation blocking, drainage screen sieve fixed disk 505 can be pulled down, clear up being fixed on the filtration mesh screen filtered on mesh screen fixed disk 505 or replace.

When foreign body is more in the hydrophily of hydrophily delivery trunk 302 output, directly can carry out row and become silted up by the sealing plug 311 on the row of removing silt mouth 312, row's silt complete after again by sealing plug 311 row of being seated to silt mouth 312 and realize sealing.

Last it is noted that various embodiments above is only in order to illustrate the technical solution of the utility model, it is not intended to limit；Although this utility model being described in detail with reference to foregoing embodiments, it will be understood by those within the art that: the technical scheme described in foregoing embodiments still can be modified by it, or the most some or all of technical characteristic is carried out equivalent；And these amendments or replacement, do not make the essence of appropriate technical solution depart from the scope of this utility model each embodiment technical scheme.

Claims (8)

1. a hydrophily ground heat compensator, it is characterised in that including: heat exchange segment and deferent segment；

Described heat exchange segment has the first end and the second end being oppositely arranged；Having hydrophily input underground heat balance pipe and the hydrophily output underground heat balance pipe connected with described hydrophily input underground heat balance pipe inside described heat exchange segment, the outlet of import and described hydrophily output underground heat balance pipe that described hydrophily inputs underground heat balance pipe is arranged at the first end of described heat exchange segment；

Described deferent segment is connected with the first end of described heat exchange segment, and described deferent segment is annular；Described hydrophily input underground heat balance pipe and described hydrophily output underground heat balance pipe extend in described deferent segment；It is that hydrophily inputs house steward that hydrophily input underground heat balance pipe extends to described deferent segment part, and it is hydrophily delivery trunk that hydrophily output underground heat balance pipe extends to described deferent segment part；Described hydrophily input underground heat balance pipe and described hydrophily output underground heat balance pipe are one to multiple group.

Hydrophily the most according to claim 1 ground heat compensator, it is characterized in that, also include hydrophily input filter and hydrophily output filter, flow direction along water, described hydrophily input filter is positioned at the upstream of the import of described hydrophily input house steward, and described hydrophily output filter is positioned at the downstream of the outlet of described hydrophily delivery trunk.

Hydrophily the most according to claim 1 ground heat compensator, it is characterised in that also include that base segment, described base segment are connected with the second end of described heat exchange segment.

Hydrophily the most according to claim 3 ground heat compensator, it is characterized in that, described base segment includes collecting silt device, described hydrophily input underground heat balance pipe and described hydrophily output underground heat balance pipe be arranged in parallel, and described hydrophily input underground heat balance pipe and described hydrophily output underground heat balance pipe are connected by described collection silt device or intermediate connection tube.

Hydrophily the most according to claim 3 ground heat compensator, it is characterized in that, also include maintaining passage, described maintenance passage includes maintaining passage base segment and maintenance passage heat exchange segment, described maintenance passage base segment is arranged in described base segment, and described maintenance passage heat exchange segment is arranged in described heat exchange segment.

Hydrophily the most according to claim 1 ground heat compensator, it is characterised in that described hydrophily delivery trunk is provided with row's silt mouth, along the flow direction of water, the described row mouth that becomes silted up is arranged on the downstream of outlet of described hydrophily delivery trunk.

7. a high/low temperature integral type hydrophily underground heat static organ, it is characterized in that, including high temperature hydrophily underground heat static organ be connected to the low temperature hydrophily underground heat static organ above described high temperature hydrophily underground heat static organ, described high temperature hydrophily underground heat static organ and described low temperature hydrophily underground heat static organ all for according to hydrophily according to any one of claim 1-6 ground heat compensator.

High/low temperature integral type hydrophily underground heat static organ the most according to claim 7, it is characterized in that, also include high/low temperature hydrophily transducer, described high/low temperature hydrophily transducer includes the first switch, second switch, 3rd switch and the 4th switch, wherein, in the hydrophily output channel of the hydrophily delivery trunk that described 4th switch is arranged on described high temperature hydrophily underground heat static organ, described second switch is arranged in the hydrophily input channel of hydrophily input house steward of described high temperature hydrophily underground heat static organ, in the hydrophily output channel of the hydrophily delivery trunk that described 3rd switch is arranged on described low temperature hydrophily underground heat static organ, described first switch is arranged in the hydrophily input channel of hydrophily input house steward of described low temperature hydrophily underground heat static organ.