CN204963033U - Domestic cooling / warm radiant type central air conditioning and new trend system - Google Patents

Abstract

The utility model provides a domestic cooling / warm radiant type central air conditioning and new trend system. Relate to central air conditioning and new trend system. There is the extravagant energy in order to solve above -mentioned current compound domestic air conditioning system to the problem that this system's device volume is huge, the cost is high, the practicality is poor. Install indoor supply -air outlet and indoor return air inlet in every room, every indoor supply -air outlet is linked together with the supply -air outlet of new trend dehumidification all -in -one, every indoor return air inlet is linked together with the return air inlet of new trend dehumidification all -in -one, the new trend entry and outdoor being linked together of new trend dehumidification all -in -one, and humidity transducer is installed to the return air inlet of new trend dehumidification all -in -one, every capillary network unit is by three -way valve no. 2, the capillary network heat exchanger, dew point sensor, the 2nd temperature sensor and temperature controller constitute, dew point sensor and the 2nd temperature sensor all install in corresponding room and are connected with the temperature controller respectively, thermostat controller connects three -way valve no. 2.

Description

A kind of family expenses cooling/warm radiant type central air-conditioning and VMC

Technical field

The utility model relates to central air-conditioning and VMC, particularly relates to a kind of family expenses cooling/warm radiant type central air-conditioning and VMC.

Background technology

Along with the development of society, the economic level of people improves day by day, causes people to pursue more and more higher to the quality of life.Traditional household air-conditioning system can not meet the high request of people to domestic environment gradually; Therefore, just there is the compound domestic air-conditioning system of the radiation cooling/heating installation of high degree of comfort and aeration device and dehumidification equipment phase compound in recent years, namely adopt the air-conditioning system that air-conditioning box combines with radiation tail end.

But because air-conditioning box is coordinated operation, when needs run one of them device, when such as supplying separately new wind or carry out dehumidification treatments to room air separately, two devices all need to open, and such energy resource consumption is large, is unfavorable for energy-conservation.

Further, the air-conditioning box volume in this compound domestic air-conditioning system is comparatively large, and cost is high and need special equipment machine room, is unfavorable for applying.

Utility model content

An object of the present utility model to provide a kind of family expenses cooling/warm radiant type central air-conditioning and VMC, waste energy, and this system bulk is huge, cost is high, the problem of poor practicability to solve above-mentioned existing air-conditioning box existence.

Especially, the utility model provides a kind of family expenses cooling/warm radiant type central air-conditioning and VMC, described system comprises: source pump, fresh air dehumidification all-in-one, plate type heat exchanger, water collecting and diversifying device, triple valve one and multiple capillary network unit, each capillary network cellular installation is in a room

Indoor air outlet and indoor return air mouth are installed in each room, each indoor air outlet is connected with the air outlet of fresh air dehumidification all-in-one, each indoor return air mouth is connected with the return air inlet of fresh air dehumidification all-in-one, the new wind entrance of fresh air dehumidification all-in-one is connected with outdoor, and the return air inlet of fresh air dehumidification all-in-one is provided with humidity sensor

Each capillary network unit is made up of triple valve two, capillary network heat exchanger, dew point transducer, the second temperature sensor and temperature controller, dew point transducer and the second temperature sensor are all installed in corresponding room and are also connected with temperature controller respectively, temperature controller control connection triple valve two

The water side of source pump is communicated with the backwater end of source pump through plate type heat exchanger, and point water end (W.E.) of water collecting and diversifying device is connected with the end that catchments of water collecting and diversifying device through plate type heat exchanger, to make source pump, by plate type heat exchanger, heat is sent to water collecting and diversifying device,

Triple valve one connection is arranged between the water side of source pump and plate type heat exchanger, and the 3rd end of triple valve one is communicated with the backwater end of source pump,

The water inlet end of each capillary network heat exchanger is communicated with a point water end (W.E.) for water collecting and diversifying device, and the catchmenting to hold of the water side of each capillary network heat exchanger and water collecting and diversifying device is communicated with,

Be communicated with between described point of water end (W.E.) and the water inlet end of each capillary network heat exchanger and be provided with a triple valve two, 3rd end of described triple valve two is connected with the described end that catchments, the end that catchments of water collecting and diversifying device is provided with the first temperature sensor, the first temperature sensor control connection triple valve one with the connectivity part of plate type heat exchanger.

Further, described source pump is air-cooled heat pump assembly or earth source heat pump assembly.

Further, triple valve one and triple valve two are electric T-shaped valve.

Further, the end that catchments described in is provided with water pump with being communicated with between plate type heat exchanger.

Further, capillary network heat exchanger is installed on ceiling or the ground in corresponding room.

Further, described water pump is circulating pump.

Further, the air outlet of fresh air dehumidification all-in-one is provided with blast main road, each indoor air outlet is connected with described blast main road, and the return air inlet of fresh air dehumidification all-in-one is provided with return air main pipeline, and each indoor return air mouth is connected with described return air main pipeline.

The beneficial effects of the utility model are at least as follows:

Capillary network heat exchanger has the feature of environmental protection and energy saving, and relatively existing fan coil system is more comfortable, is more applicable for family and uses.

Fresh air dehumidification all-in-one has the advantages that noise is little, volume is little, and its thickness is only 28cm, can installation of ceiling in indoor, do not need special equipment machine room to place, be more applicable for family, practicality is stronger.

Fresh air dehumidification all-in-one can carry out work independent of air-conditioning system, and can control separately, is particularly suited for non-air-conditioning and uses season, can isolated operation to meet the demand of people to room humidity and new wind.Thus hinge structure reduces power consumption.

Each branch road of water collecting and diversifying device connects separately the capillary network heat exchanger in a room, to facilitate control.

Described system of the present utility model reaches the object reduced costs.Although source pump of the prior art has the low huge advantage of cost, prior art can not solve source pump and dock with capillary network heat exchanger and use this problem.Present inventor, by using plate type heat exchanger, solves this technical problem.That is, source pump is first connected with plate type heat exchanger, and then plate type heat exchanger is connected with capillary network heat exchanger again.Thus reduce the manufacturing cost of system described in the utility model.And plate type heat exchanger has little, that heat exchange efficiency the is high advantage that takes up room.

Further, described source pump is air-cooled heat pump assembly or earth source heat pump assembly, and air-cooled heat pump assembly or earth source heat pump assembly are convenient to buy, install and maintenance.

Further, triple valve one and triple valve two are electric T-shaped valve, and it is fast that electric T-shaped valve has corresponding speed, the advantage be active in one's movements.

Further, capillary network heat exchanger is installed on corresponding room ceiling or ground, so arranges, and makes capillary network heat exchanger to play maximal efficiency.

According to hereafter by reference to the accompanying drawings to the detailed description of the utility model specific embodiment, those skilled in the art will understand above-mentioned and other objects, advantage and feature of the present utility model more.

Accompanying drawing explanation

Hereinafter describe specific embodiments more of the present utility model with reference to the accompanying drawings by way of example, and not by way of limitation in detail.Reference numeral identical in accompanying drawing denotes same or similar parts or part.It should be appreciated by those skilled in the art that these accompanying drawings may not be drawn in proportion.In accompanying drawing:

Fig. 1 is the schematic block diagram of system described in the utility model;

Fig. 2 is the schematic block diagram of the capillary network unit of system described in the utility model;

In Fig. 1, hollow black surround arrow represent aeration flow to, black arrow represents the current direction of system described in the utility model.

In Fig. 1 and Fig. 2, source pump 01, fresh air dehumidification all-in-one 02, plate type heat exchanger 03, triple valve 2 41, capillary network heat exchanger 42, dew point transducer 43, the second temperature sensor 44, point water end (W.E.) 71, catchment end 72, water pump 08, triple valve 1, the first temperature sensor 10.

Detailed description of the invention

Detailed description of the invention one: composition graphs 1 and Fig. 2 are described, described system of the present utility model is general to be comprised, source pump 01, fresh air dehumidification all-in-one 02, plate type heat exchanger 03, water collecting and diversifying device, triple valve 1 and multiple capillary network unit, each capillary network cellular installation is in a room

Indoor air outlet 05 and indoor return air mouth 06 are installed in each room, each indoor air outlet 05 is connected with the air outlet of fresh air dehumidification all-in-one 02, each indoor return air mouth 06 is connected with the return air inlet of fresh air dehumidification all-in-one 02, the new wind entrance of fresh air dehumidification all-in-one 02 is connected with outdoor, and the return air inlet of fresh air dehumidification all-in-one 02 is provided with humidity sensor

Each capillary network unit is made up of triple valve 2 41, capillary network heat exchanger 42, dew point transducer 43, second temperature sensor 44 and temperature controller, dew point transducer 43 and the second temperature sensor 44 are all installed in corresponding room and are also connected with temperature controller respectively, temperature controller control connection triple valve 2 41

The water side of source pump 01 is communicated with the backwater end of source pump 01 through plate type heat exchanger 03, point water end (W.E.) 71 of water collecting and diversifying device is connected with the end 72 that catchments of water collecting and diversifying device through plate type heat exchanger 03, by plate type heat exchanger 03, heat is sent to water collecting and diversifying device to make source pump 01

Triple valve 1 connection is arranged between the water side of source pump 01 and plate type heat exchanger 03, and the 3rd end of triple valve 1 is communicated with the backwater end of source pump 01,

The water inlet end of each capillary network heat exchanger 42 is communicated with a point water end (W.E.) 71 for water collecting and diversifying device, and the water side of each capillary network heat exchanger 42 is communicated with the end 72 that catchments of water collecting and diversifying device,

Be communicated with between described point of water end (W.E.) 71 and the water inlet end of each capillary network heat exchanger 42 and be provided with a triple valve 2 41, the 3rd end of described triple valve 2 41 is connected with the described end 72 that catchments,

The end 72 that catchments of water collecting and diversifying device is provided with the first temperature sensor 10, first temperature sensor 10 control connection triple valve 1 with the connectivity part of plate type heat exchanger 03.

Detailed description of the invention two: composition graphs 1 and Fig. 2 are described, the described source pump 01 of present embodiment is air-cooled heat pump assembly or earth source heat pump assembly.

Described source pump is air-cooled heat pump assembly or earth source heat pump assembly, and air-cooled heat pump assembly or earth source heat pump assembly are convenient to buy, install and maintenance.

In present embodiment, undocumented technical characteristic is identical with detailed description of the invention one.

Detailed description of the invention three: composition graphs 1 and Fig. 2 are described, triple valve 1 and the triple valve 2 41 of present embodiment are electric T-shaped valve.

Triple valve one and triple valve two are electric T-shaped valve, and electric T-shaped valve has fast response time, the advantage be active in one's movements.

In present embodiment, undocumented technical characteristic is identical with detailed description of the invention one or two.

Detailed description of the invention four: composition graphs 1 and Fig. 2 are described, catchmenting described in present embodiment to be communicated with between end 72 with plate type heat exchanger 03 is provided with water pump 08.

Described water pump 08 is the Water circulation hydrodynamics device of system described in the utility model.

Undocumented technical characteristic and detailed description of the invention one in present embodiment, two or three identical.

Detailed description of the invention five: composition graphs 1 and Fig. 2 are described, the capillary network heat exchanger 42 of present embodiment is installed on corresponding room ceiling or ground.

Capillary network heat exchanger is installed on corresponding room ceiling or ground, so arranges, and makes capillary network heat exchanger to play maximal efficiency.

In present embodiment, undocumented technical characteristic is identical with detailed description of the invention four.

Detailed description of the invention six: composition graphs 1 and Fig. 2 are described, the described water pump 08 of present embodiment is circulating pump, is specially secondary cycle pump.

Undocumented technical characteristic and detailed description of the invention one in present embodiment, two, three, four or five identical.

Detailed description of the invention seven: composition graphs 1 and Fig. 2 are described, the air outlet of the fresh air dehumidification all-in-one 02 of present embodiment is provided with blast main road, each indoor air outlet 05 is connected with described blast main road, the return air inlet of fresh air dehumidification all-in-one 02 is provided with return air main pipeline, and each indoor return air mouth 06 is connected with described return air main pipeline.

The operation principle of system described in the utility model is:

Illustrate see accompanying drawing 1,

In summer, from the cryogenic freezing water (supply water temperature 7 DEG C of heat pump 01, return water temperature 12 DEG C) become high temperature chilled water (supply water temperature 16 DEG C, return water temperature 19 DEG C) to be then delivered to capillary network heat exchanger 42 by the effect of water pump 08 through plate type heat exchanger 03 heat exchange; In like manner, in the winter time, the high-temperature-hot-water (supply water temperature 45 DEG C, return water temperature 40 DEG C) from heat pump 01 becomes low-temperature water heating (supply water temperature 30 DEG C through plate type heat exchanger 03 heat exchange, return water temperature 33 DEG C), be then delivered to capillary network heat exchanger 42 by the effect of water pump 08.

Temperature setting is carried out to the first temperature sensor 10, when indoor temperature exceed this arrange time, the first temperature sensor 10 controls triple valve 1 action, by chilled water bypass to the backwater end of heat pump 01.

Illustrate see accompanying drawing 2, after plate type heat exchanger 03 heat exchange, described point of water end (W.E.) 71 by delivery to the capillary network heat exchanger 42 in each room.When the dew point transducer 43 in each room detects indoor air humidity close to dew point saturated humidity, send signal to temperature controller, temperature controller controls triple valve 2 41 action, by chilled water bypass to described in catchment end 72, prevent room from condensing; Or carry out temperature setting to the second temperature sensor 44, when the second temperature sensor 44 detects that room exceedes design temperature, send a signal to temperature controller, temperature controller controls triple valve 2 41 action, by chilled water bypass to described in catchment end 72.

So far, those skilled in the art will recognize that, although multiple exemplary embodiment of the present utility model is illustrate and described herein detailed, but, when not departing from the utility model spirit and scope, still can directly determine or derive other modification many or amendment of meeting the utility model principle according to content disclosed in the utility model.Therefore, scope of the present utility model should be understood and regard as and cover all these other modification or amendments.

Claims (7)

1. family expenses cooling/warm radiant type central air-conditioning and a VMC, it is characterized in that, described system comprises:

Source pump (01), fresh air dehumidification all-in-one (02), plate type heat exchanger (03), water collecting and diversifying device, triple valve one (09) and multiple capillary network unit, each capillary network cellular installation is in a room

Indoor air outlet (05) and indoor return air mouth (06) are installed in each room, each indoor air outlet (05) is connected with the air outlet of fresh air dehumidification all-in-one (02), each indoor return air mouth (06) is connected with the return air inlet of fresh air dehumidification all-in-one (02), the new wind entrance of fresh air dehumidification all-in-one (02) is connected with outdoor, and the return air inlet of fresh air dehumidification all-in-one (02) is provided with humidity sensor

Each capillary network unit is made up of triple valve two (41), capillary network heat exchanger (42), dew point transducer (43), the second temperature sensor (44) and temperature controller, dew point transducer (43) and the second temperature sensor (44) are all installed in corresponding room and are also connected with temperature controller respectively, temperature controller control connection triple valve two (41)

The water side of source pump (01) is communicated with the backwater end of source pump (01) through plate type heat exchanger (03), a point water end (W.E.) (71) for water collecting and diversifying device holds (72) to be connected through plate type heat exchanger (03) with catchmenting of water collecting and diversifying device, by plate type heat exchanger (03), heat is sent to water collecting and diversifying device to make source pump (01)

Triple valve one (09) connection is arranged between the water side of source pump (01) and plate type heat exchanger (03), and the 3rd end of triple valve one (09) is communicated with the backwater end of source pump (01),

The water inlet end of each capillary network heat exchanger (42) is communicated with a point water end (W.E.) (71) for water collecting and diversifying device, and the water side of each capillary network heat exchanger (42) holds (72) to be communicated with catchmenting of water collecting and diversifying device,

Be communicated with between described point of water end (W.E.) (71) and the water inlet end of each capillary network heat exchanger (42) and be provided with a triple valve two (41), 3rd end of described triple valve two (41) holds (72) to be connected with described catchmenting

The end (72) that catchments of water collecting and diversifying device is provided with the first temperature sensor (10), the first temperature sensor (10) control connection triple valve one (09).

2. system according to claim 1, is characterized in that, described source pump (01) is air-cooled heat pump assembly or earth source heat pump assembly.

3. system according to claim 2, is characterized in that, triple valve one (09) and triple valve two (41) are electric T-shaped valve.

4. system according to claim 3, is characterized in that, described in connectivity part between end (72) and plate type heat exchanger (03) of catchmenting be provided with water pump (08).

5. system according to claim 4, is characterized in that, capillary network heat exchanger (42) is installed on ceiling or the ground in corresponding room.

6. system according to claim 5, is characterized in that, described water pump (08) is circulating pump.

7. system according to claim 6, it is characterized in that, the air outlet of fresh air dehumidification all-in-one (02) is provided with blast main road, each indoor air outlet (05) is connected with described blast main road, the return air inlet of fresh air dehumidification all-in-one (02) is provided with return air main pipeline, and each indoor return air mouth (06) is connected with described return air main pipeline.