CN204963067U - Indoor temperature control system of hydrophily - Google Patents
Indoor temperature control system of hydrophily Download PDFInfo
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- CN204963067U CN204963067U CN201520738393.6U CN201520738393U CN204963067U CN 204963067 U CN204963067 U CN 204963067U CN 201520738393 U CN201520738393 U CN 201520738393U CN 204963067 U CN204963067 U CN 204963067U
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Abstract
The utility model belongs to the technical field of internet technology and specifically relates to an indoor temperature control system of hydrophily is related to, including refrigerator, water heater and heat exchange vent sash, the input of water heater the input of refrigerator respectively with the output of heat exchange vent sash is linked together, the output of water heater the output of refrigerator respectively with the input of heat exchange vent sash is linked together. The utility model discloses in being connected to same temperature control system with refrigerator and water heater, reach refrigeration and heating purpose through using same heat transfer medium, realized between the multi -storey building unit with the different buildings of same architectural complex between the parallelly connected or installation of establishing ties to can be between the different units with the different buildings of same architectural complex between implement the difference service and manage with measuring service, effectually practiced thrift the energy and resource, reduced environmental pollution, use cost is lower.
Description
Technical field
The utility model relates to field of energy-saving technology, especially relates to a kind of hydrophily Indoor Temperature Ore-controlling Role.
Background technology
Along with the development of society, the material and cultural life of people obtains significant raising, and no matter air-conditioning, as a kind of housed device of condition of improving the people's livelihood, is obtained in city or rural area and applies widely.The develop rapidly of recent year market economy, the internal structure of enterprise, industry is in continuous change, and Market competition, by the impact of relation between market supply and demand, Chinese development of air conditioning industry is rapid, and Novel intelligent air-conditioning dominates the market, and its capacity is huge.
At present, the environment parameter control equipment of middle-size and small-size interior architecture has a lot, and as central air conditioning etc., but their common trait is electric power is main energy sources, has refrigeration cost low, heats cost high, do not replace the scarce limits such as economic heating equipment at cold district.Simultaneously, the heat transmission medium of existing central air conditioning is different medium, a unit only has a terminating machine, and the reverse discharge dispersion of the bad factor, not easily manage concentratedly, can not particularly carry out in parallel between tier building at multiple building unit or be installed in series, uniform machinery also can not implement difference service and metering service management between different units, causes comparatively large resource waste.
Utility model content
The purpose of this utility model is to provide hydrophily Indoor Temperature Ore-controlling Role, and to solve, the heat transmission medium of the temperature control device existed in prior art is different medium, can not be in parallel or to be installed in series and same temperature control device can not implement the technical problem of difference service and metering service management between different units between tier building unit.
A kind of hydrophily Indoor Temperature Ore-controlling Role that the utility model provides, comprises refrigerator, water heater and heat exchange air hole; The input of described water heater, the input of described refrigerator are connected with the output of described heat exchange air hole respectively; The output of described water heater, the output of described refrigerator are connected with the input of described heat exchange air hole respectively.
Further, high/low temperature hydrophily converter is also comprised; Described high/low temperature hydrophily converter comprises total input, total output, the first sub-output, the second sub-output, the first sub-input and the second sub-input; Described first sub-output, described second sub-output are connected with described total input respectively; Described first sub-input, described second sub-input are connected with described total output respectively;
The input of described water heater, the input of described refrigerator are connected respectively by the output of high/low temperature hydrophily converter with described heat exchange air hole, wherein: the input of described water heater is connected with described first sub-output, the input of described refrigerator is connected with described second sub-output, and described total input is connected with the output of described heat exchange air hole;
The output of described water heater, the output of described refrigerator are connected respectively by the input of high/low temperature hydrophily converter with described heat exchange air hole, wherein: the output of described water heater is connected with described first sub-input, the output of described refrigerator is connected with described second sub-input, and described total output is connected with the input of described heat exchange air hole.
Further, also circulating pump is comprised; Described circulating pump is connected between described high/low temperature hydrophily converter and described heat exchange air hole, wherein: the input of described circulating pump is connected with the output of described heat exchange air hole, and described circulation delivery side of pump is connected with described total input.
Further, also comprise hydrophily instruction and supplement funnel, described hydrophily instruction supplements funnel and is connected between described high/low temperature hydrophily converter and described circulating pump, wherein: the input that described hydrophily instruction supplements funnel is connected with described circulation delivery side of pump, the output that described hydrophily instruction supplements funnel is connected with described total input.
Further, also comprise hydrophily output filter, described hydrophily output filter is connected between described high/low temperature hydrophily converter and described heat exchange air hole, wherein: the output of described hydrophily output filter is connected with the input of described heat exchange air hole, the input of described hydrophily output filter is connected with described total output.
Further, also comprise hydrophily input filter, described hydrophily input filter is connected to described high/low temperature hydrophily converter and described hydrophily indicates between supplementary funnel, wherein: the output of described hydrophily input filter is connected with described total input, input and the described hydrophily of described hydrophily input filter indicate the output supplementing funnel to be connected.
Further, described hydrophily output filter comprises filter chamber and filter, and described filter is arranged in described filter chamber; Described filter comprises mesh screen rack and filters mesh screen, and described filtration mesh screen is arranged on described mesh screen rack; The relation of the maximum gauge of described filter chamber and the port inner diameter of described hydrophily output filter is 1:2 ~ 30, and the order number of described filtration mesh screen is 30 ~ 100 orders.
Further, described hydrophily input filter comprises filter chamber and filter, and described filter is arranged in described filter chamber; Described filter comprises mesh screen rack and filters mesh screen, and described filtration mesh screen is arranged on described mesh screen rack; The relation of the maximum gauge of described filter chamber and the port inner diameter of described hydrophily input filter is 1:2 ~ 30, and the order number of described filtration mesh screen is 30 ~ 100 orders.
Further, the temperature of the heat transmission medium in this temperature control system is-31 DEG C ~ 110 DEG C.
Further, described first sub-output, the second sub-output, the first sub-input and the second sub-input are provided with change-over switch.
Compared with prior art, the beneficial effects of the utility model are:
A kind of hydrophily Indoor Temperature Ore-controlling Role that the utility model provides, comprises refrigerator, water heater and heat exchange air hole; The input of water heater, the input of refrigerator are connected with the output of heat exchange air hole respectively; The output of water heater, the output of refrigerator are connected with the input of heat exchange air hole respectively.Refrigerator and water heater are connected in same temperature control system by the utility model, refrigeration and heating object is reached by using same heat transmission medium, achieve between tier building unit and same building group difference building between parallel connection or be installed in series, and difference service and metering service management can be implemented between different units and between the difference building of same building group, effectively save the energy and resource, decreased environmental pollution, use cost is lower.
Accompanying drawing explanation
In order to be illustrated more clearly in the utility model detailed description of the invention or technical scheme of the prior art, be briefly described to the accompanying drawing used required in detailed description of the invention or description of the prior art below, apparently, accompanying drawing in the following describes is embodiments more of the present utility model, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to these accompanying drawings.
The structural representation of the hydrophily Indoor Temperature Ore-controlling Role that Fig. 1 provides for the utility model embodiment one;
The structural representation of the hydrophily Indoor Temperature Ore-controlling Role that Fig. 2 provides for the utility model embodiment two.
Reference numeral:
101-refrigerator; 102-water heater; 103-heat exchange air hole; 104-high/low temperature hydrophily converter; The total input of 105-; The total output of 106-; The sub-output of 107-first; The sub-output of 108-second; The sub-input of 109-first; The sub-input of 110-second; 111-circulating pump; The instruction of 112-hydrophily supplements funnel; 113-hydrophily output filter; 114-hydrophily input filter; 115-change-over switch.
Detailed description of the invention
Be clearly and completely described the technical solution of the utility model below in conjunction with accompanying drawing, obviously, described embodiment is the utility model part embodiment, instead of whole embodiments.Based on the embodiment in the utility model, those of ordinary skill in the art are not making the every other embodiment obtained under creative work prerequisite, all belong to the scope of the 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 only the utility model and simplified characterization for convenience of description; instead of instruction or imply the device of indication or element must have specific orientation, with specific azimuth configuration and operation, therefore can not be interpreted as restriction of the present utility model.In addition, term " first ", " second ", " the 3rd " only for describing object, and can not be interpreted as instruction or hint relative importance.
In description of the present utility model, it should be noted that, unless otherwise clearly defined and limited, term " installation ", " being connected ", " connection " should be interpreted broadly, and such as, can be fixedly connected with, also can be removably connect, or connect integratedly; Can be mechanical connection, also can be electrical connection; Can be directly be connected, also indirectly can be connected by intermediary, can be the connection of two element internals.For the ordinary skill in the art, concrete condition the concrete meaning of above-mentioned term in the utility model can be understood.
Embodiment one
The utility model embodiment one provides a kind of hydrophily Indoor Temperature Ore-controlling Role, comprises refrigerator 101, water heater 102 and heat exchange air hole 103; The input of water heater 102, the input of refrigerator 101 are connected with the output of heat exchange air hole 103 respectively; The output of water heater 102, the output of refrigerator 101 are connected with the input of heat exchange air hole 103 respectively.Refrigerator 101 and water heater 102 are connected in same temperature control system by the utility model, refrigeration and heating object is reached by using same heat transmission medium, achieve between tier building unit and same building group difference building between parallel connection or be installed in series, and difference service and metering service management can be implemented between different units and between the difference building of same building group, effectively save the energy and resource, decreased environmental pollution, use cost is lower.
In the present embodiment one, hydrophily Indoor Temperature Ore-controlling Role also comprises high/low temperature hydrophily converter 104; High/low temperature hydrophily converter 104 comprises total input 105, total output the 106, first sub-output 107, second sub-output 108, first sub-input 109 and the second sub-input 110; The sub-output 108 of first sub-output 107, second is connected with total input 105 respectively; The sub-input 110 of first sub-input 109, second is connected with total output 106 respectively; The input of water heater 102, the input of refrigerator 101 are connected with the output of heat exchange air hole 103 respectively by high/low temperature hydrophily converter 104, wherein: the input of water heater 102 is connected with the first sub-output 107, the input of refrigerator 101 is connected with the second sub-output 108, and total input 105 is connected with the output of heat exchange air hole 103; The output of water heater 102, the output of refrigerator 101 are connected with the input of heat exchange air hole 103 respectively by high/low temperature hydrophily converter 104, wherein: the output of water heater 102 is connected with the first sub-input 109, the output of refrigerator 101 is connected with the second sub-input 110, and total output 106 is connected with the input of heat exchange air hole 103.
In the present embodiment one, hydrophily Indoor Temperature Ore-controlling Role also comprises circulating pump 111; Circulating pump 111 is connected between high/low temperature hydrophily converter 104 and heat exchange air hole 103, and wherein: the input of circulating pump 111 is connected with the output of heat exchange air hole 103, the output of circulating pump 111 is connected with total input 105.
In the present embodiment one, hydrophily Indoor Temperature Ore-controlling Role also comprises hydrophily instruction and supplements funnel 112, hydrophily instruction supplements funnel 112 and is connected between high/low temperature hydrophily converter 104 and circulating pump 111, wherein: the input that hydrophily instruction supplements funnel 112 is connected with the output of circulating pump 111, the output that hydrophily instruction supplements funnel 112 is connected with total input 105.Hydrophily instruction supplements between the hydrophily storeroom of funnel 112 and the output of circulating pump 111 can form a linker, utilizes the principle of linker greatly can reduce driving energy consumption in circulation road needed for heat transmission medium like this.
In the present embodiment one, hydrophily Indoor Temperature Ore-controlling Role also comprises hydrophily output filter 113, hydrophily output filter 113 is connected between high/low temperature hydrophily converter 104 and heat exchange air hole 103, wherein: the output of hydrophily output filter 113 is connected with the input of heat exchange air hole 103, the input of hydrophily output filter 113 is connected with total output 106.Heat exchange air hole 103 comprises many heat exchange capillaries in parallel.Can prevent the foreign matter in heat transmission medium from entering heat exchange air hole 103 by hydrophily output filter 113, the heat exchange capillary in blocking heat exchange air hole 103.
In the present embodiment one, hydrophily output filter 113 comprises filter chamber and filter, and filter is arranged in filter chamber; Filter comprises mesh screen rack and filters mesh screen, filters mesh screen and is arranged on mesh screen rack; The relation of the maximum gauge of filter chamber and the port inner diameter of hydrophily output filter 113 is 1:2 ~ 30, and the order number filtering mesh screen is 30 ~ 100 orders.
In the present embodiment one, the heat transmission medium in this temperature control system is the compound aqueous solution of Organic Alcohol and organic nitrogen; The temperature of heat transmission medium is-31 DEG C ~ 110 DEG C.
In the present embodiment one, the first sub-output 107, second sub-input 109 of sub-output 108, first and the second sub-input 110 are provided with change-over switch 115.
The operation principle of the hydrophily Indoor Temperature Ore-controlling Role that the present embodiment one provides is:
1, when needs supply the heat transmission medium of more than 20 DEG C to when carrying out indoor intensification to heat exchange air hole 103, systematic evaluation opens pattern to low, that is, change-over switch 115 on second sub-output 108 and the change-over switch 115 on the second sub-input 110 are closed, change-over switch 115 on first sub-output 107 and the change-over switch 115 of the first sub-input 109 are opened, the heat transmission medium circulated is warming up to 15 DEG C ~ 33 DEG C by water heater 102, then the heat transmission medium of 20 DEG C ~ 110 DEG C is supplied through high/low temperature hydrophily converter 104 and hydrophily output filter 113 to heat exchange air hole 103, heat exchange air hole 103 is just in Central Heating Providing pattern,
2, when needs supply the heat transmission medium of less than 20 DEG C to when carrying out room temperature lowering to heat exchange air hole 103, systematic evaluation is paramount opens pattern, that is, change-over switch 115 on first sub-output 107 and the change-over switch 115 of the first sub-input 109 are closed, change-over switch 115 on second sub-output 108 and the change-over switch 115 on the second sub-input 110 are opened, the heat transmission medium circulated is cooled to 15 DEG C ~ 33 DEG C by refrigerator 101, then the heat transmission medium of-30 DEG C ~ 20 DEG C is supplied through high/low temperature hydrophily converter 104 and hydrophily output filter 113 to heat exchange air hole 103, heat exchange air hole 103 is just in cold air supplying mode.
Embodiment two
The utility model embodiment two provides a kind of hydrophily Indoor Temperature Ore-controlling Role, comprises refrigerator 101, water heater 102 and heat exchange air hole 103; The input of water heater 102, the input of refrigerator 101 are connected with the output of heat exchange air hole 103 respectively; The output of water heater 102, the output of refrigerator 101 are connected with the input of heat exchange air hole 103 respectively.Refrigerator 101 and water heater 102 are connected in same temperature control system by the utility model, refrigeration and heating object is reached by using same heat transmission medium, achieve between tier building unit and same building group difference building between parallel connection or be installed in series, and difference service and metering service management can be implemented between different units and between the difference building of same building group, effectively save the energy and resource, decreased environmental pollution, use cost is lower.
In the present embodiment two, hydrophily Indoor Temperature Ore-controlling Role also comprises high/low temperature hydrophily converter 104; High/low temperature hydrophily converter 104 comprises total input 105, total output the 106, first sub-output 107, second sub-output 108, first sub-input 109 and the second sub-input 110; The sub-output 108 of first sub-output 107, second is connected with total input 105 respectively; The sub-input 110 of first sub-input 109, second is connected with total output 106 respectively; The input of water heater 102, the input of refrigerator 101 are connected with the output of heat exchange air hole 103 respectively by high/low temperature hydrophily converter 104, wherein: the input of water heater 102 is connected with the first sub-output 107, the input of refrigerator 101 is connected with the second sub-output 108, and total input 105 is connected with the output of heat exchange air hole 103; The output of water heater 102, the output of refrigerator 101 are connected with the input of heat exchange air hole 103 respectively by high/low temperature hydrophily converter 104, wherein: the output of water heater 102 is connected with the first sub-input 109, the output of refrigerator 101 is connected with the second sub-input 110, and total output 106 is connected with the input of heat exchange air hole 103.
In the present embodiment two, hydrophily Indoor Temperature Ore-controlling Role also comprises circulating pump 111; Circulating pump 111 is connected between high/low temperature hydrophily converter 104 and heat exchange air hole 103, and wherein: the input of circulating pump 111 is connected with the output of heat exchange air hole 103, the output of circulating pump 111 is connected with total input 105.
In the present embodiment two, hydrophily Indoor Temperature Ore-controlling Role also comprises hydrophily instruction and supplements funnel 112, hydrophily instruction supplements funnel 112 and is connected between high/low temperature hydrophily converter 104 and circulating pump 111, wherein: the input that hydrophily instruction supplements funnel 112 is connected with the output of circulating pump 111, the output that hydrophily instruction supplements funnel 112 is connected with total input 105.Hydrophily instruction supplements between the hydrophily storeroom of funnel 112 and the output of circulating pump 111 can form a linker, utilizes the principle of linker greatly can reduce driving energy consumption in circulation road needed for heat transmission medium like this.
In the present embodiment two, hydrophily Indoor Temperature Ore-controlling Role also comprises hydrophily output filter 113, hydrophily output filter 113 is connected between high/low temperature hydrophily converter 104 and heat exchange air hole 103, wherein: the output of hydrophily output filter 113 is connected with the input of heat exchange air hole 103, the input of hydrophily output filter 113 is connected with total output 106.Heat exchange air hole 103 comprises many heat exchange capillaries in parallel.Can prevent the foreign matter in heat transmission medium from entering heat exchange air hole 103 by hydrophily output filter 113, the heat exchange capillary in blocking heat exchange air hole 103.
In the present embodiment two, hydrophily Indoor Temperature Ore-controlling Role also comprises hydrophily input filter 114, hydrophily input filter 114 is connected to high/low temperature hydrophily converter 104 and hydrophily indicates between supplementary funnel 112, wherein: the output of hydrophily input filter 114 is connected with total input 105, input and the hydrophily of hydrophily input filter 114 indicate the output supplementing funnel 112 to be connected.Can prevent the foreign matter in heat transmission medium from entering refrigerator 101 and water heater 102 by hydrophily input filter 114, accumulate at refrigerator 101 and water heater 102, infringement refrigerator 101 and water heater 102, reduce the service life of refrigerator 101 and water heater 102.
In the present embodiment two, hydrophily output filter 113 comprises filter chamber and filter, and filter is arranged in filter chamber; Filter comprises mesh screen rack and filters mesh screen, filters mesh screen and is arranged on mesh screen rack; The relation of the maximum gauge of filter chamber and the port inner diameter of hydrophily output filter 113 is 1:2 ~ 30, and the order number filtering mesh screen is 30 ~ 100 orders.
In the present embodiment two, hydrophily input filter 114 comprises filter chamber and filter, and filter is arranged in filter chamber; Filter comprises mesh screen rack and filters mesh screen, filters mesh screen and is arranged on mesh screen rack; The relation of the maximum gauge of filter chamber and the port inner diameter of hydrophily input filter 114 is 1:2 ~ 30, and the order number filtering mesh screen is 30 ~ 100 orders.
In the present embodiment two, the heat transmission medium in this temperature control system is the compound aqueous solution of Organic Alcohol and organic nitrogen; The temperature of heat transmission medium is-31 DEG C ~ 110 DEG C.
In the present embodiment two, the first sub-output 107, second sub-input 109 of sub-output 108, first and the second sub-input 110 are provided with change-over switch 115.
The operation principle of the hydrophily Indoor Temperature Ore-controlling Role that the present embodiment two provides is:
1, when needs supply the heat transmission medium of more than 20 DEG C to when carrying out indoor intensification to heat exchange air hole 103, systematic evaluation opens pattern to low, that is, change-over switch 115 on second sub-output 108 and the change-over switch 115 on the second sub-input 110 are closed, change-over switch 115 on first sub-output 107 and the change-over switch 115 of the first sub-input 109 are opened, the heat transmission medium circulated is warming up to 15 DEG C ~ 33 DEG C by water heater 102, then the heat transmission medium of 20 DEG C ~ 110 DEG C is supplied through high/low temperature hydrophily converter 104 and hydrophily output filter 113 to heat exchange air hole 103, heat exchange air hole 103 is just in Central Heating Providing pattern,
2, when needs supply the heat transmission medium of less than 20 DEG C to when carrying out room temperature lowering to heat exchange air hole 103, systematic evaluation is paramount opens pattern, that is, change-over switch 115 on first sub-output 107 and the change-over switch 115 of the first sub-input 109 are closed, change-over switch 115 on second sub-output 108 and the change-over switch 115 on the second sub-input 110 are opened, the heat transmission medium circulated is cooled to 15 DEG C ~ 33 DEG C by refrigerator 101, then the heat transmission medium of-30 DEG C ~ 20 DEG C is supplied through high/low temperature hydrophily converter 104 and hydrophily output filter 113 to heat exchange air hole 103, heat exchange air hole 103 is just in cold air supplying mode.
Last it is noted that above each embodiment is only in order to illustrate the technical solution of the utility model, be not intended to limit; Although be described in detail the utility model with reference to foregoing embodiments, those of ordinary skill in the art is to be understood that: it still can be modified to the technical scheme described in foregoing embodiments, or carries out equivalent replacement to wherein some or all of technical characteristic; And these amendments or replacement, do not make the essence of appropriate technical solution depart from the scope of each embodiment technical scheme of the utility model.
Claims (10)
1. a hydrophily Indoor Temperature Ore-controlling Role, is characterized in that, comprises refrigerator, water heater and heat exchange air hole; The input of described water heater, the input of described refrigerator are connected with the output of described heat exchange air hole respectively; The output of described water heater, the output of described refrigerator are connected with the input of described heat exchange air hole respectively.
2. hydrophily Indoor Temperature Ore-controlling Role according to claim 1, is characterized in that, also comprises high/low temperature hydrophily converter; Described high/low temperature hydrophily converter comprises total input, total output, the first sub-output, the second sub-output, the first sub-input and the second sub-input; Described first sub-output, described second sub-output are connected with described total input respectively; Described first sub-input, described second sub-input are connected with described total output respectively;
The input of described water heater, the input of described refrigerator are connected respectively by the output of high/low temperature hydrophily converter with described heat exchange air hole, wherein: the input of described water heater is connected with described first sub-output, the input of described refrigerator is connected with described second sub-output, and described total input is connected with the output of described heat exchange air hole;
The output of described water heater, the output of described refrigerator are connected respectively by the input of high/low temperature hydrophily converter with described heat exchange air hole, wherein: the output of described water heater is connected with described first sub-input, the output of described refrigerator is connected with described second sub-input, and described total output is connected with the input of described heat exchange air hole.
3. hydrophily Indoor Temperature Ore-controlling Role according to claim 2, is characterized in that, also comprise circulating pump; Described circulating pump is connected between described high/low temperature hydrophily converter and described heat exchange air hole, wherein: the input of described circulating pump is connected with the output of described heat exchange air hole, and described circulation delivery side of pump is connected with described total input.
4. hydrophily Indoor Temperature Ore-controlling Role according to claim 3, it is characterized in that, also comprise hydrophily instruction and supplement funnel, described hydrophily instruction supplements funnel and is connected between described high/low temperature hydrophily converter and described circulating pump, wherein: the input that described hydrophily instruction supplements funnel is connected with described circulation delivery side of pump, the output that described hydrophily instruction supplements funnel is connected with described total input.
5. the hydrophily Indoor Temperature Ore-controlling Role according to any one of claim 2-4, it is characterized in that, also comprise hydrophily output filter, described hydrophily output filter is connected between described high/low temperature hydrophily converter and described heat exchange air hole, wherein: the output of described hydrophily output filter is connected with the input of described heat exchange air hole, the input of described hydrophily output filter is connected with described total output.
6. hydrophily Indoor Temperature Ore-controlling Role according to claim 4, it is characterized in that, also comprise hydrophily input filter, described hydrophily input filter is connected to described high/low temperature hydrophily converter and described hydrophily indicates between supplementary funnel, wherein: the output of described hydrophily input filter is connected with described total input, input and the described hydrophily of described hydrophily input filter indicate the output supplementing funnel to be connected.
7. hydrophily Indoor Temperature Ore-controlling Role according to claim 5, is characterized in that, described hydrophily output filter comprises filter chamber and filter, and described filter is arranged in described filter chamber; Described filter comprises mesh screen rack and filters mesh screen, and described filtration mesh screen is arranged on described mesh screen rack; The relation of the maximum gauge of described filter chamber and the port inner diameter of described hydrophily output filter is 1:2 ~ 30, and the order number of described filtration mesh screen is 30 ~ 100 orders.
8. hydrophily Indoor Temperature Ore-controlling Role according to claim 6, is characterized in that, described hydrophily input filter comprises filter chamber and filter, and described filter is arranged in described filter chamber; Described filter comprises mesh screen rack and filters mesh screen, and described filtration mesh screen is arranged on described mesh screen rack; The relation of the maximum gauge of described filter chamber and the port inner diameter of described hydrophily input filter is 1:2 ~ 30, and the order number of described filtration mesh screen is 30 ~ 100 orders.
9. the hydrophily Indoor Temperature Ore-controlling Role according to any one of claim 1-4, is characterized in that, the temperature of the heat transmission medium in this temperature control system is-31 DEG C ~ 110 DEG C.
10. the hydrophily Indoor Temperature Ore-controlling Role according to any one of claim 2-4, is characterized in that, described first sub-output, the second sub-output, the first sub-input and the second sub-input are provided with change-over switch.
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CN105135574A (en) * | 2015-05-08 | 2015-12-09 | 鲜升文 | Indoor water medium temperature control system |
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