CN203161465U

CN203161465U - Circulation heat pipe type temperature difference ventilation power generation system for bottom layer of high-rise building

Info

Publication number: CN203161465U
Application number: CN2013201685933U
Authority: CN
Inventors: 许陵; 陈梅芬; 张国金
Original assignee: Minnan Normal University
Current assignee: Minnan Normal University
Priority date: 2013-04-07
Filing date: 2013-04-07
Publication date: 2013-08-28
Anticipated expiration: 2023-04-07

Abstract

The utility model discloses a circulation heat pipe type temperature difference ventilation power generation system for a bottom layer of a high-rise building. The power generation system comprises a solar collector, a pressurized insulation water tank, a relay pressurized insulation water tank and a ventilating pipe from the top down, wherein the solar collector is connected with the pressurized insulation water tank through a heat input circulation heat pipe group; the pressurized insulation water tank is connected with the relay pressurized insulation water tank through a relay circulation heat pipe group; the relay pressurized insulation water tank is connected with an inlet of the ventilating pipe trough a heat output circulation heat pipe group so as to heat air at an inlet of the ventilating pipe of the bottom layer of the high-rise building; and a wind power generation device in circuit connection with the bottom layer of the high-rise building is arranged at an outlet of the ventilating pipe. According to the utility model, artificial wind is generated through the chimney effect caused by temperature difference so as to realize ventilation of the bottom layer; and meanwhile, the wind power generation device at the outlet of the ventilating pipe is driven to power the underground parking at the bottom for lighting, and accorindly, commercial power for realizing ventilation and lighting of the underground parking is avoided, and the purposes of energy conservation and environmental protection are achieved.

Description

Cycling hot tubular type tall building bottom temperature difference ventilating power generation system

Technical field

The utility model belongs to the energy-saving equipment field, is specifically related to a kind of cycling hot tubular type tall building bottom temperature difference ventilating power generation system.

Background technique

At present, the bottom of urban skyscraper is generally as the underground parking, and its ventilation and illumination all adopt the mode of mains-supplied to carry out, and have caused the waste of electric resources, are unfavorable for environmental protection.

The model utility content

The purpose of this utility model is to overcome the prior art defective, and a kind of cycling hot tubular type tall building bottom temperature difference ventilating power generation system is provided.

The technical solution of the utility model is as follows:

Hot tube tall building bottom temperature difference ventilating power generation system, comprise successively from top to bottom: solar thermal collector, the pressure-bearing heat-insulating water tanks, relaying pressure-bearing heat-insulating water tanks and ventilation duct, solar thermal collector links to each other with the pressure-bearing heat-insulating water tanks by heat input circulating heat pipe group, the pressure-bearing heat-insulating water tanks links to each other with relaying pressure-bearing heat-insulating water tanks by relaying circulating heat pipe group, relaying pressure-bearing heat-insulating water tanks links to each other with the entrance of ventilation duct by heat output circulating heat pipe group and is positioned at the air of the ventilation duct ingress of tall building bottom with heating, and the outlet port of ventilation duct is provided with the wind generating unit that links to each other with tall building bottom circuit.

In a preferred embodiment of the present utility model, described heat input circulating heat pipe group comprises elevated temperature heat pipeline section, endless metal radiating segment and the Cryo Heat Tube section that links to each other successively, the elevated temperature heat pipeline section links to each other with Cryo Heat Tube Duan Junyu solar thermal collector, and the endless metal radiating segment is located in the pressure-bearing heat-insulating water tanks.

In a preferred embodiment of the present utility model, described relaying circulating heat pipe group comprises relaying endless metal endotherm section, relaying elevated temperature heat pipeline section, relaying annular heat dissipation metal section and relaying Cryo Heat Tube section, relaying endless metal endotherm section links to each other with relaying Cryo Heat Tube section by relaying elevated temperature heat pipeline section with relaying annular heat dissipation metal section, and relaying endless metal endotherm section is located in the described pressure-bearing heat-insulating water tanks, and relaying annular heat dissipation metal section is located in the relaying pressure-bearing heat-insulating water tanks.

In a preferred embodiment of the present utility model, described relaying pressure-bearing heat-insulating water tanks can be two or more, previous relaying pressure-bearing heat-insulating water tanks links to each other by relaying circulating heat pipe group with a back relaying pressure-bearing heat-insulating water tanks, be that described relaying circulating heat pipe group comprises relaying endless metal endotherm section, relaying elevated temperature heat pipeline section, relaying annular heat dissipation metal section and relaying Cryo Heat Tube section, relaying endless metal endotherm section links to each other with relaying Cryo Heat Tube section by relaying elevated temperature heat pipeline section with relaying annular heat dissipation metal section, and relaying endless metal endotherm section is located in the previous relaying pressure-bearing heat-insulating water tanks, and relaying annular heat dissipation metal section is located in the back relaying pressure-bearing heat-insulating water tanks.

In a preferred embodiment of the present utility model, described heat output circulating heat pipe group comprises heat output endless metal endotherm section, heat output elevated temperature heat pipeline section, heat output endless metal radiating segment and heat output Cryo Heat Tube section, heat output endless metal endotherm section links to each other with heat output Cryo Heat Tube section by heat output elevated temperature heat pipeline section with heat output endless metal radiating segment, and heat output endless metal endotherm section is located in the described relaying pressure-bearing heat-insulating water tanks, and heat output endless metal radiating segment is located at the ingress of described ventilation duct with the air of heating ventilation duct ingress.

In a preferred embodiment of the present utility model, described wind power plant is omnidirectional's gentle breeze-driven generator.

In a preferred embodiment of the present utility model, described solar thermal collector and pressure-bearing heat-insulating water tanks all are arranged on the top layer of tall building.

The beneficial effects of the utility model are:

1, the utility model utilization is arranged at solar thermal collector and the pressure-bearing heat-insulating water tanks absorption solar energy of tall building top layer, pass through relaying pressure-bearing heat-insulating water tanks and circulating heat pipe group again with the ingress of thermal energy conduction to the ventilation duct of bottom, utilize the high stack effect of the temperature difference formation at entrance and exit place to produce the ventilation that " artificial wind " realizes bottom, the power generating equipment that drives the ventilation duct outlet port simultaneously generates electricity to supply the electric consumption on lighting of bottom underground parking, thereby exempted the commercial power supply to ventilation and the illumination in underground parking lot, energy-conserving and environment-protective;

2, the utility model is positioned at the top layer of tall building in the outlet port of ventilation duct, in this outlet port wind power plant is set, when the tall building top layer has wind, can ventilate and utilize wind energy power, also can generate electricity by " the artificial wind " that the temperature difference in the pipeline produces and ventilate when the tall building top layer is calm, improved the generating efficiency of ventilation effect and wind power plant.

Description of drawings

Fig. 1 is structural representation of the present utility model.

Embodiment

Below will be by reference to the accompanying drawings by embodiment, the technical solution of the utility model is further detailed and describes.

As shown in Figure 1, cycling hot tubular type tall building bottom temperature difference ventilating power generation system, comprise successively from top to bottom: solar thermal collector 1, pressure-bearing heat-insulating water tanks 2, relaying pressure-bearing heat-insulating water tanks 3 and ventilation duct 4, solar thermal collector 1 links to each other with pressure-bearing heat-insulating water tanks 2 by heat input circulating heat pipe group 11, pressure-bearing heat-insulating water tanks 2 links to each other with relaying pressure-bearing heat-insulating water tanks 3 by relaying circulating heat pipe group 21, relaying pressure-bearing heat-insulating water tanks 3 links to each other with the entrance of ventilation duct 4 by heat output circulating heat pipe group 31 and is positioned at the air of ventilation duct 4 ingress of tall building bottom with heating, and the outlet port of ventilation duct 4 is provided with the omnidirectional's gentle breeze-driven generator 41 that links to each other with tall building bottom circuit.

Solar thermal collector 1 links to each other with pressure-bearing heat-insulating water tanks 2 by heat input circulating heat pipe group 11, with the thermal energy transfer that solar thermal collector 1 is collected to pressure-bearing heat-insulating water tanks 2.Concrete, described heat input circulating heat pipe group 11 comprises heat input elevated temperature heat pipeline section 111, heat input endless metal radiating segment 112 and the heat input Cryo Heat Tube section 113 that links to each other successively, heat input elevated temperature heat pipeline section 111 all links to each other with solar thermal collector 1 with heat input Cryo Heat Tube section 113, and heat input endless metal radiating segment 112 is located in the pressure-bearing heat-insulating water tanks 2.

Pressure-bearing heat-insulating water tanks 2 links to each other with relaying pressure-bearing heat-insulating water tanks 3 by relaying circulating heat pipe group 21, with the thermal energy transfer in the pressure-bearing heat-insulating water tanks 2 to relaying pressure-bearing heat-insulating water tanks 3.Concrete, described relaying circulating heat pipe group 21 comprises relaying endless metal endotherm section 211, relaying elevated temperature heat pipeline section 212, relaying annular heat dissipation metal section 213 and relaying Cryo Heat Tube section 214, relaying endless metal endotherm section 211 links to each other with relaying Cryo Heat Tube section 214 by relaying elevated temperature heat pipeline section 212 with relaying annular heat dissipation metal section 213, and relaying endless metal endotherm section 211 is located in the described pressure-bearing heat-insulating water tanks 2, and relaying annular heat dissipation metal section 213 is located in the relaying pressure-bearing heat-insulating water tanks 3; Preferably, described relaying pressure-bearing heat-insulating water tanks 3 can be two or more, previous relaying pressure-bearing heat-insulating water tanks 3 links to each other by relaying circulating heat pipe group 21 with a back relaying pressure-bearing heat-insulating water tanks 3, be that described relaying circulating heat pipe group 21 comprises relaying endless metal endotherm section 211, relaying elevated temperature heat pipeline section 212, relaying annular heat dissipation metal section 213 and relaying Cryo Heat Tube section 214, relaying endless metal endotherm section 211 links to each other with relaying Cryo Heat Tube section 214 by relaying elevated temperature heat pipeline section 212 with relaying annular heat dissipation metal section 213, and relaying endless metal endotherm section 211 is located in the previous relaying pressure-bearing heat-insulating water tanks 3, and relaying annular heat dissipation metal section 213 is located in the back relaying pressure-bearing heat-insulating water tanks 3.

Relaying pressure-bearing heat-insulating water tanks 3 links to each other with the entrance of ventilation duct 4 by heat output circulating heat pipe group 31 and is positioned at the air of ventilation duct 4 ingress of tall building bottom with heating, make the air of ventilation duct 4 ingress and the air in outlet port produce the temperature difference, form artificial wind by high stack effect and drive 41 generatings of omnidirectional's gentle breeze-driven generator, with the circuit supply to the tall building bottom.Concrete, described heat output circulating heat pipe group 31 comprises heat output endless metal endotherm section 311, heat output elevated temperature heat pipeline section 312, heat output endless metal radiating segment 313 and heat output Cryo Heat Tube section 314, heat output endless metal endotherm section 311 links to each other with heat output Cryo Heat Tube section 314 by heat output elevated temperature heat pipeline section 312 with heat output endless metal radiating segment 313, and heat output endless metal endotherm section 311 is located in the described relaying pressure-bearing heat-insulating water tanks 3, and heat output endless metal radiating segment 313 is located at the ingress of described ventilation duct 4 with the air of heating ventilation duct 4 ingress.

Solar thermal collector 1 is through shining upon, collect heat energy, be stored to pressure-bearing heat-insulating water tanks 2 through heat input circulating heat pipe group 11, heat energy in the pressure-bearing heat-insulating water tanks 2 is through relaying circulating heat pipe group 21, relaying pressure-bearing heat-insulating water tanks and heat output circulating heat pipe group 31 conduct to ventilation duct 4 ingress, heat the air at this place, to form the temperature difference in the ventilation duct 4, generation can drive " artificial wind " (being high stack effect) of omnidirectional's gentle breeze-driven generator 41 generatings in ventilation duct 4 outlet ports, the electric energy that this omnidirectional's gentle breeze-driven generator 41 sends is in order to the usefulness of the illumination of supplying with the tall building bottom, exempted the commercial power supply to ventilation and the illumination in underground parking lot, energy-conserving and environment-protective; In addition, omnidirectional's gentle breeze-driven generator 41 is arranged on the outlet port of the ventilation duct 4 that is positioned at top layer, when the tall building top layer has wind, can ventilate and utilize wind energy power, also can generate electricity by " the artificial wind " that the temperature difference in the pipeline produces and ventilate when the tall building top layer is calm, improved the generating efficiency of ventilation effect and omnidirectional's gentle breeze-driven generator 41.

The above, it only is preferred embodiment of the present utility model, so can not limit the scope that the utility model is implemented according to this, i.e. the equivalence of doing according to the utility model claim and description changes and modifies, and all should still belong in the scope that the utility model contains.

Claims

1. cycling hot tubular type tall building bottom temperature difference ventilating power generation system, it is characterized in that: comprise successively from top to bottom: solar thermal collector, the pressure-bearing heat-insulating water tanks, relaying pressure-bearing heat-insulating water tanks and ventilation duct, solar thermal collector links to each other with the pressure-bearing heat-insulating water tanks by heat input circulating heat pipe group, the pressure-bearing heat-insulating water tanks links to each other with relaying pressure-bearing heat-insulating water tanks by relaying circulating heat pipe group, relaying pressure-bearing heat-insulating water tanks links to each other with the entrance of ventilation duct by heat output circulating heat pipe group and is positioned at the air of the ventilation duct ingress of tall building bottom with heating, and the outlet port of ventilation duct is provided with the wind generating unit that links to each other with tall building bottom circuit.

2. cycling hot tubular type tall building bottom temperature difference ventilating power generation system as claimed in claim 1, it is characterized in that: described heat input circulating heat pipe group comprises heat input elevated temperature heat pipeline section, heat input endless metal radiating segment and the heat input Cryo Heat Tube section that links to each other successively, heat input elevated temperature heat pipeline section links to each other with heat input Cryo Heat Tube Duan Junyu solar thermal collector, and heat input endless metal radiating segment is located in the pressure-bearing heat-insulating water tanks.

3. cycling hot tubular type tall building bottom temperature difference ventilating power generation system as claimed in claim 1, it is characterized in that: described relaying circulating heat pipe group comprises relaying endless metal endotherm section, relaying elevated temperature heat pipeline section, relaying annular heat dissipation metal section and relaying Cryo Heat Tube section, relaying endless metal endotherm section links to each other with relaying Cryo Heat Tube section by relaying elevated temperature heat pipeline section with relaying annular heat dissipation metal section, and relaying endless metal endotherm section is located in the described pressure-bearing heat-insulating water tanks, and relaying annular heat dissipation metal section is located in the relaying pressure-bearing heat-insulating water tanks.

4. cycling hot tubular type tall building bottom temperature difference ventilating power generation system as claimed in claim 3, it is characterized in that: described relaying pressure-bearing heat-insulating water tanks can be two or more, previous relaying pressure-bearing heat-insulating water tanks links to each other by relaying circulating heat pipe group with a back relaying pressure-bearing heat-insulating water tanks, be that described relaying circulating heat pipe group comprises relaying endless metal endotherm section, relaying elevated temperature heat pipeline section, relaying annular heat dissipation metal section and relaying Cryo Heat Tube section, relaying endless metal endotherm section links to each other with relaying Cryo Heat Tube section by relaying elevated temperature heat pipeline section with relaying annular heat dissipation metal section, and relaying endless metal endotherm section is located in the previous relaying pressure-bearing heat-insulating water tanks, and relaying annular heat dissipation metal section is located in the back relaying pressure-bearing heat-insulating water tanks.

5. cycling hot tubular type tall building bottom temperature difference ventilating power generation system as claimed in claim 1, it is characterized in that: described heat output circulating heat pipe group comprises heat output endless metal endotherm section, heat output elevated temperature heat pipeline section, heat output endless metal radiating segment and heat output Cryo Heat Tube section, heat output endless metal endotherm section links to each other with heat output Cryo Heat Tube section by heat output elevated temperature heat pipeline section with heat output endless metal radiating segment, and heat output endless metal endotherm section is located in the described relaying pressure-bearing heat-insulating water tanks, and heat output endless metal radiating segment is located at the ingress of described ventilation duct with the air of heating ventilation duct ingress.

6. cycling hot tubular type tall building bottom temperature difference ventilating power generation system as claimed in claim 1, it is characterized in that: described wind power plant is omnidirectional's gentle breeze-driven generator.

7. cycling hot tubular type tall building bottom temperature difference ventilating power generation system as claimed in claim 1, it is characterized in that: the outlet of described ventilation duct is arranged on the top layer of tall building.

8. cycling hot tubular type tall building bottom temperature difference ventilating power generation system as claimed in claim 1, it is characterized in that: described solar thermal collector and pressure-bearing heat-insulating water tanks all are arranged on the top layer of tall building.