CN212294621U - Energy pile - Google Patents
Energy pile Download PDFInfo
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- CN212294621U CN212294621U CN202022177231.3U CN202022177231U CN212294621U CN 212294621 U CN212294621 U CN 212294621U CN 202022177231 U CN202022177231 U CN 202022177231U CN 212294621 U CN212294621 U CN 212294621U
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- heat exchange
- hob
- reinforcement cage
- phase change
- exchange tube
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/10—Geothermal energy
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Abstract
The utility model discloses an energy stake relates to ground source heat pump technical field. The method comprises the following steps: steel reinforcement cage, heat exchange tube and phase change concrete, steel reinforcement cage is hollow structure, including the bracing piece with be helical structure's hob, the quantity of bracing piece is a plurality of, each bracing piece all extends along the axial of hob, and be connected with the hob, a plurality of bracing pieces are arranged along the circumference of hob, the heat exchange tube is equipped with inlet and liquid outlet, the heat exchange tube sets up in the hob, and be connected with hob and/or bracing piece, the heat exchange tube, steel reinforcement cage all wraps up in phase change concrete, and the clearance between heat exchange tube and the steel reinforcement cage also fills there is phase change concrete. The energy pile is simple in structure and low in cost, is suitable for large-scale batch production and processing, and the spiral rod is connected with the supporting rod as an integral structure, so that the overall rigidity of the steel reinforcement cage is better, the phase change concrete can effectively delay the temperature rise and the temperature reduction inside the phase change concrete, the highest insulation temperature rise is reduced, and the temperature stress of the concrete structure in the energy pile is reduced.
Description
Technical Field
The utility model relates to a ground source heat pump technical field especially relates to an energy stake and application method thereof.
Background
In the field of construction, an energy pile is a structure which combines a vertical buried pipe ground source heat pump with a pile foundation, so that the energy pile can bear the load of an upper structure and can exchange heat with the surrounding soil body. The essential difference between the energy pile and the traditional earth heat collecting system or the underground heat exchange drilling system is that the energy pile has structural function as a heat exchanger connected with the earth and does not need to be separately built. The energy pile in the prior art has a complex structure and high manufacturing cost, and a soil body heat accumulation effect caused by an internal heat pump system exists in the heat exchange process of the energy pile, so that the energy pile generates a temperature difference effect, and the pile body is cracked. Therefore, it is an urgent technical problem to provide an energy pile with simple structure, low cost and reduced heat accumulation effect.
SUMMERY OF THE UTILITY MODEL
For solving the technical problem, the utility model provides an energy pile with simple structure and low cost to solve the problem that the energy pile structure among the prior art is complicated, and the cost is higher.
In order to achieve the above object, the utility model provides a following scheme:
the utility model provides an energy pile, include: steel reinforcement cage, heat exchange tube and phase change concrete, the steel reinforcement cage is hollow structure, including bracing piece and the hob that is helical structure, the quantity of bracing piece is a plurality of, each the bracing piece is all followed the axial extension of hob, and with the hob is connected, and is a plurality of the bracing piece is followed the circumference of hob is arranged, the heat exchange tube is equipped with inlet and liquid outlet, the heat exchange tube set up in the hob, and with the hob and/or the bracing piece is connected, the heat exchange tube the steel reinforcement cage all wrap up in the phase change concrete, just the heat exchange tube with clearance between the steel reinforcement cage also fills there is the phase change concrete.
Further, each of the support rods is of a solid structure, or each of the support rods is of a hollow structure.
Further, the screw rod is of a solid structure, or the screw rod is of a hollow structure.
Further, the hollow structure is filled with a phase change material.
Further, the heat exchange tube comprises a first spiral tube and a second spiral tube, the first spiral tube and the second spiral tube are arranged in a double-spiral structure, first ends of the first spiral tube and the second spiral tube are communicated with each other, and second ends of the first spiral tube and the second spiral tube are respectively used as the liquid inlet and the liquid outlet.
Further, the heat exchange tube comprises an annular tube and a plurality of U-shaped tubes with openings at two ends, the bottoms of the U-shaped tubes are mutually crossed and communicated, one opening of one U-shaped tube in the U-shaped tubes is used as the liquid inlet, the other opening and all the openings of the other U-shaped tubes are communicated with the annular tube, and the liquid outlet is formed in the annular tube.
Furthermore, a zinc coating or a ceramic coating is arranged on the surface of the steel reinforcement cage.
The utility model discloses for prior art gain following technological effect:
the utility model discloses an energy stake, include: steel reinforcement cage, heat exchange tube and phase change concrete, steel reinforcement cage is hollow structure, including the bracing piece with be helical structure's hob, the quantity of bracing piece is a plurality of, each bracing piece all extends along the axial of hob, and be connected with the hob, a plurality of bracing pieces are arranged along the circumference of hob, the heat exchange tube is equipped with inlet and liquid outlet, the heat exchange tube sets up in the hob, and be connected with hob and/or bracing piece, the heat exchange tube, steel reinforcement cage all wraps up in phase change concrete, and also pack in the clearance between heat exchange tube and the steel reinforcement cage has phase change concrete. According to the configuration, the utility model provides an energy stake simple structure, low cost is suitable for extensive batch production processing, and the hob is connected with the bracing piece as a body structure for steel reinforcement cage bulk rigidity is better, makes energy stake structure firm more stable. Through setting up the phase transition concrete can delay the inside intensification of phase transition concrete and cooling effectively, reduce the highest temperature rise that insulates, concrete structure temperature stress in the reduction energy stake improves the work efficiency of energy stake.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.
Fig. 1 is a schematic structural view of an energy column in an embodiment of the present invention;
FIG. 2 is a schematic view of a fitting structure of a heat exchange tube and a reinforcement cage according to an embodiment of the present invention;
fig. 3 is a schematic structural diagram of a heat exchange tube in an embodiment of the present invention.
Description of reference numerals: 1. a support bar; 2. a screw rod; 3. a first spiral pipe; 4. a second spiral pipe; 5. an annular tube; 6. a U-shaped pipe; 7. a liquid inlet; 8. a liquid outlet; 9. a heat exchange pipe; 10. and (6) binding the belt.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
In order to make the above objects, features and advantages of the present invention more comprehensible, the present invention is described in detail with reference to the accompanying drawings and the detailed description.
As shown in fig. 1-3, an embodiment of the present invention provides an energy pile, including: a steel reinforcement cage, a heat exchange tube 9 and phase change concrete. The steel reinforcement cage is hollow structure, and the steel reinforcement cage includes bracing piece 1 and is helical structure's hob 2. The quantity of bracing piece 1 is a plurality of, and each bracing piece 1 all extends along the axial of hob 2, and is connected with hob 2. A plurality of bracing pieces 1 are arranged along the circumference of hob 2, for example, each bracing piece 1 all can be laminated with the inboard of hob 2. Alternatively, the support rod 1 may be bound to the screw rod 2 by an iron wire. The heat exchange tube 9 is provided with a liquid inlet 7 and a liquid outlet 8. The heat exchange tube 9 is arranged in the spiral rod 2 and is connected with the spiral rod 2 and/or the support rod 1. For example, the heat exchange tube 9 may be connected to the reinforcement cage by a tie 10. Alternatively, the heat exchange pipe 9 is a PVC pipe or a metal pipe. Heat exchange tube, steel reinforcement cage all wrap up in phase change concrete, and also pack in the clearance between heat exchange tube and the steel reinforcement cage and have phase change concrete promptly, the steel reinforcement cage intussuseption is filled with phase change concrete, and the steel reinforcement cage outside also wraps up there is phase change concrete. According to the configuration, the utility model provides an energy pile simple structure, low cost is suitable for extensive batch production processing, and hob 2 is connected with bracing piece 1 as a body structure for steel reinforcement cage bulk rigidity is better, makes energy pile structure firm more stable. Through setting up the phase transition concrete can delay the inside intensification of phase transition concrete and cooling effectively, reduce the highest temperature rise that insulates, concrete structure temperature stress in the reduction energy stake improves the work efficiency of energy stake.
It should be noted that the phase-change concrete of the energy pile may be prefabricated or cast in place. The phase change concrete can be the phase change concrete in the prior art, and can also be the phase change concrete provided by the embodiment.
For example, in some embodiments, the phase change concrete comprises cement, fly ash, sand, gravel, water, fly ash ceramsite, phase change material, sodium thiosulfate, montmorillonite, alumina, triethanolamine in water. Optionally, the phase change material is paraffin, pentadecane or hexadecane.
The embodiment of the utility model provides an in the embodiment material ratio and the performance parameter of phase change concrete:
first, the mix proportion design of the phase change concrete
1.1 materials list
Name (R) | Cement | Sand | Crushing stone | Phase-change ceramsite | Fly ash | Mineral powder | Graphite (II) | Additive agent | Water (W) |
Specification of | P.O42.5 | Medium sand | 5-20mm | 8-15mm | Second stage | Polycarboxylic acids |
1.2 base mix ratio
Wherein the water-gel ratio is the ratio of water to the gel material, i.e. water/gel material, and the gel material is mainly composed of cement and admixture.
1.3 proportion of phase-change concrete in test
Serial number | Cement | Sand | Crushing stone | Phase-change ceramsite | Fly ash | Mineral powder | Graphite (II) | Additive agent | Water (W) |
P | 380 | 770 | 1030 | 0 | 40 | 40 | 0 | 4.6 | 180 |
T10 | 380 | 770 | 927 | 103 | 40 | 40 | 0 | 4.6 | 180 |
T20 | 380 | 770 | 824 | 206 | 40 | 40 | 0 | 4.6 | 180 |
T30 | 380 | 770 | 721 | 309 | 40 | 40 | 0 | 4.6 | 180 |
S201 | 380 | 770 | 927 | 103 | 40 | 36 | 4 | 4.6 | 180 |
S202 | 380 | 770 | 824 | 206 | 40 | 28 | 12 | 4.6 | 180 |
S203 | 380 | 770 | 721 | 309 | 40 | 20 | 20 | 4.6 | 180 |
Wherein, the serial number P represents the common concrete, the serial numbers T10-T30 represent the experimental data after replacing partial crushed stones with phase-change ceramsite (the total amount of the crushed stones and the phase-change ceramsite is still the same as the crushed stones of the common concrete), and the serial numbers S201-S203 represent the experimental data after replacing mineral powder with graphite (the total amount of the graphite and the mineral powder is still the same as the mineral powder amount of the common concrete).
Preparation of phase-change ceramsite
2.1 arrangement of composite phase-change Material
Data relating to phase change materials in the prior art
Phase change material | Phase transition temperature deg.C | Latent heat of phase change j/g | Degree of openness | Molecular formula | Molecular weight |
Pentadecane | 9.5 | 207 | 282.65 | C15H32 | 212.41 |
Hexadecane (Hexadecane) | 16.7 | 236.6 | 289.85 | C16H34 | 226.44 |
Capric acid | 31.3 | 136 | 304.45 | C10H20O2 | 172.26 |
Lauric acid | 43.1 | 150.5 | 316.25 | C14H26O2 | 226.35 |
In this embodiment, the composite phase-change material is obtained by using the phase-change material in the above table
2.2 DSC Curve of the composite phase Change Material
Wherein M-5 and N-3 meet the requirements.
2.3 phase-change ceramsite optimum adsorption time and temperature
Experimental data of M groups of adsorption at 40 ℃ in water bath by using vacuum adsorption method
Single group adsorption time min | Rate of change |
0 | 0.00% |
5 | 14.61% |
10 | 17.75% |
20 | 21.18% |
30 | 22.35% |
60 | 24.61% |
90 | 26.18% |
120 | 27.25% |
180 | 27.65% |
From the above table, the maximum adsorption time was determined to be 120 min.
Time/min | Adsorption rate/%) | Time/min | Adsorption rate/%) |
5 | 13.20% | 115 | 27.30% |
10 | 16.10% | 110 | 26.90% |
20 | 20.80% | 100 | 26.80% |
30 | 22.00% | 90 | 27.20% |
Time/min | Adsorption rate/%) | Time/min | Adsorption rate/%) |
5 | 14.60% | 115 | 27.20% |
10 | 17.83% | 110 | 27.78% |
20 | 20.60% | 100 | 27.83% |
30 | 22.69% | 90 | 27.94% |
Time/min | Adsorption rate/%) | Time/min | Adsorption rate/%) |
5 | 14.51% | 115 | 27.87% |
10 | 17.04% | 110 | 27.76% |
20 | 20.59% | 100 | 27.82% |
30 | 22.65% | 90 | 27.09% |
From the tables, the optimum adsorption temperature was determined to be 40 ℃.
2.4 stability test of phase-change ceramsite
Surface crack condition
Change in mass
Number of cycles | Non-packaged phase-change ceramsite | Silica sol encapsulation | Cement paste package |
Rate of change/%) | Rate of change/%) | Rate of change/%) | |
0 | 0.00% | 0.00% | 0.00% |
10 | 0.60% | 0.20% | 0.00% |
20 | 1.35% | 0.40% | 0.60% |
50 | 3.95% | 0.70% | 1.75% |
100 | 16.20% | 1.32% | 3.40% |
Third, thermodynamic test result of phase change concrete
3.1 compressive Strength (150mm cube)
Serial number | 3d mean/MPa | 7d mean/MPa | 28d mean/MPa |
P | 28.2 | 30.9 | 37.5 |
T10 | 25.9 | 29.2 | 35.3 |
T20 | 23.3 | 27.5 | 32.9 |
T30 | 19.2 | 22.5 | 27.2 |
S201 | 22.5 | 26.0 | 31.5 |
S202 | 22.1 | 25.5 | 30.9 |
S203 | 18.9 | 22.9 | 28.1 |
3.2 thermal conductivity (300X 60, unit mm)
3.3 specific heat capacity
3.4 calculation of Heat storage coefficient
3.5 compressive Strength test under phase Change cycle (Unit: MPa)
So set up, pack the phase transition concrete in the clearance between steel reinforcement cage and heat exchange tube 9, heat-retaining and the heat release function through the phase transition concrete, can delay the inside intensification of phase transition concrete and cooling on the one hand, reduce the highest adiabatic temperature rise, phase transition concrete structure temperature stress in the energy stake is reduced, on the other hand can reduce the coefficient of heat conductivity of concrete, reduce the heat transfer effect between the pile body, and then can effectively alleviate the soil body heat accumulation effect that the heat pump system causes in the short time that the energy stake exists, make heat pump system high efficiency operation all the time in the cycle.
In some embodiments, each support rod 1 is a solid structure. Or, each support rod 1 is a hollow structure. Optionally, the cross-section of the support rod 1 has an outer diameter of 50mm and an inner diameter of 12mm, and the ratio of the hollow area to the cross-sectional area of the support rod 1 is 5.76%. While in other embodiments the screw 2 is of solid construction. Alternatively, the screw rod 2 has a hollow structure. Optionally, the cross-section of the screw rod 2 has an outer diameter of 22mm and an inner diameter of 7mm, and the ratio of the hollow area to the cross-section area of the screw rod 2 is 10.9%. Optionally, the hollow structure of the support rod 1 and/or the hollow structure of the screw rod 2 are provided with phase change material therein. So set up, the inside packing of bracing piece 1 and hob 2 has phase change material for steel reinforcement cage can enough play the fixed effect of support, can make phase change material dispose more evenly in the energy stake again, thereby further slow down the inside intensification of concrete and cool down, reduce the highest adiabatic temperature rise, concrete structure's in the reduction energy stake temperature stress, the work efficiency of the energy stake of improvement.
Referring to FIG. 2, in some embodiments, the heat exchange tubes 9 comprise a first spiral tube 3 and a second spiral tube 4. The first spiral pipe 3 and the second spiral pipe 4 are arranged in a double-spiral structure, the first end of the first spiral pipe 3 and the first end of the second spiral pipe 4 are communicated with each other, and the second end of the first spiral pipe 3 and the second end of the second spiral pipe 4 are respectively used as a liquid inlet 7 and a liquid outlet 8. So set up, can guarantee in less space heat exchange tube 9 still can have great area of contact with energy stake inside to further improve heat exchange efficiency. Of course, the heat exchange pipe 9 is not limited to the above form, and may take other forms, for example, as shown in fig. 3, and in other embodiments, the heat exchange pipe 9 includes an annular pipe 5 and a plurality of U-shaped pipes 6 having openings at both ends. 6 bottoms intercrossing of a plurality of U type pipes and intercommunication, an opening of a U type pipe 6 is as inlet 7 in a plurality of U type pipes 6, all openings of another opening and all the other U type pipes 6 all communicate with ring pipe 5, liquid outlet 8 sets up on ring pipe 5, liquid enters into heat exchange tube 9 from inlet 7 like this, the crossing that enters into each U type pipe 6 along this U type pipe 6 one side is shunted, enter into ring pipe 5 along each U type pipe 6 respectively in, 8 outflow from the liquid outlet on the ring pipe 5, so set up, can make heat exchange tube 9 have great heat transfer area equally, can improve heat exchange efficiency.
In some embodiments, in order to prevent the surface of the reinforcement cage from being corroded, a zinc coating or a ceramic coating can be arranged on the surface of the reinforcement cage.
The principle and the implementation mode of the present invention are explained by applying specific examples in the present specification, and the above descriptions of the examples are only used to help understanding the method and the core idea of the present invention; meanwhile, for the general technical personnel in the field, according to the idea of the present invention, there are changes in the concrete implementation and the application scope. In summary, the content of the present specification should not be construed as a limitation of the present invention.
Claims (7)
1. An energy pile, comprising: steel reinforcement cage, heat exchange tube and phase change concrete, the steel reinforcement cage is hollow structure, including bracing piece and the hob that is helical structure, the quantity of bracing piece is a plurality of, each the bracing piece is all followed the axial extension of hob, and with the hob is connected, and is a plurality of the bracing piece is followed the circumference of hob is arranged, the heat exchange tube is equipped with inlet and liquid outlet, the heat exchange tube set up in the hob, and with the hob and/or the bracing piece is connected, the heat exchange tube the steel reinforcement cage all wrap up in the phase change concrete, just the heat exchange tube with clearance between the steel reinforcement cage also fills there is the phase change concrete.
2. The energy stake of claim 1, wherein each of said support rods is of solid construction or each of said support rods is of hollow construction.
3. The energy pile of claim 1, wherein the screw rod is of solid construction or the screw rod is of hollow construction.
4. An energy pile according to claim 2 or 3, characterised in that the hollow structure is filled with a phase change material.
5. The energy pile of claim 1, wherein the heat exchange tube comprises a first spiral tube and a second spiral tube, the first spiral tube and the second spiral tube are arranged in a double-helix structure, first ends of the first spiral tube and the second spiral tube are communicated with each other, and second ends of the first spiral tube and the second spiral tube are respectively used as the liquid inlet and the liquid outlet.
6. The energy pile according to claim 1, wherein the heat exchange tube comprises an annular tube and a plurality of U-shaped tubes with openings at two ends, the bottoms of the U-shaped tubes are mutually crossed and communicated, one opening of one U-shaped tube in the U-shaped tubes is used as the liquid inlet, the other opening and all openings of the other U-shaped tubes are communicated with the annular tube, and the liquid outlet is arranged on the annular tube.
7. The energy pile of claim 1, wherein the surface of the reinforcement cage is provided with a zinc coating or a ceramic coating.
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CN202022177231.3U CN212294621U (en) | 2020-09-29 | 2020-09-29 | Energy pile |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN113357839A (en) * | 2021-06-26 | 2021-09-07 | 中化地质矿山总局山东地质勘查院 | Medium-deep buried pipe heat exchange device and heat supply system |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN113357839A (en) * | 2021-06-26 | 2021-09-07 | 中化地质矿山总局山东地质勘查院 | Medium-deep buried pipe heat exchange device and heat supply system |
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