CN207438940U - The integration of high efficiency dual intensity supplies collecting system - Google Patents
The integration of high efficiency dual intensity supplies collecting system Download PDFInfo
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- CN207438940U CN207438940U CN201720889025.0U CN201720889025U CN207438940U CN 207438940 U CN207438940 U CN 207438940U CN 201720889025 U CN201720889025 U CN 201720889025U CN 207438940 U CN207438940 U CN 207438940U
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- air
- housing
- high efficiency
- collecting system
- dual intensity
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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
- Y02E10/40—Solar thermal energy, e.g. solar towers
- Y02E10/44—Heat exchange systems
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- Drying Of Solid Materials (AREA)
Abstract
The utility model discloses a kind of integrations of high efficiency dual intensity to supply collecting system, including:Air energy heat pump integrates, freezer and dryer;Air energy heat pump is integrated including multiple heat pump modules, and one end of heat pump module is connected by cold air duct with freezer, and the other end is connected by hot air duct with dryer;Heat pump module includes housing A and housing B, and air intake is both provided on housing A and housing B;Air energy converter structure is provided in the integral structure of housing A and housing B compositions, air in housing A can be converted to cold air and is discharged into cold air duct by air energy converter structure, and air in housing B can be converted to hot-air and and is discharged into hot air duct by air energy converter structure;Air intake has been provided opposite to curved surface heating plate, and the both ends of curved surface heating plate are hinged with wing plate, heating air duct is formed between curved surface heating plate, wing plate and the air intake.High efficiency dual intensity integration has the utilization rate of excellent energy for collecting system.
Description
Technical field
The utility model is related to energy-collecting devices, and in particular, to a kind of high efficiency dual intensity integration supplies collecting system.
Background technology
Energy-collecting device can be divided into heating unit and refrigerating plant, and in the prior art, current energy-collecting device is generally
Although being that either chemical energy runs electric energy or chemical energy disclosure satisfy that general demand by electric energy, exist certain
Advantage and defect, be specially:It consumes energy big and pollutes although requirement of the chemical energy device to equipment is relatively low, during use
Environment;Electrical energy devices have that power is big, free of contamination advantage, but its cost is larger, especially needs to add in heating unit
Electrically heated component and then improve production cost;Meanwhile electrical energy devices also suffer from the influence of weather (such as heating component
On form frost), especially under extremely low temperature, electrical energy devices start more difficult, while energy conversion rate is relatively low.
Utility model content
The purpose of this utility model is to provide a kind of high efficiency dual intensity integration for collecting system, high efficiency dual intensity integration
It can utilize electric energy and solar energy that can provide energy to freezer and dryer simultaneously for collecting system, and then improve the utilization of energy
Rate.
To achieve these goals, the utility model provides the utility model and provides a kind of high efficiency dual intensity integration
For collecting system, including:Air energy heat pump integrates, freezer and dryer;Air energy heat pump is integrated including multiple heat pump modules, heat pump
One end of module is connected by cold air duct with freezer, and the other end is connected by hot air duct with dryer;Heat pump module
Including housing A and housing B, air intake is both provided on housing A and housing B;In the integral structure of housing A and housing B compositions
Air energy converter structure is provided with, the air in housing A can be converted to cold air and is discharged into cold by air energy converter structure
Air in housing B can be converted to hot-air and is discharged into hot air duct by wind pipeline, air energy converter structure;Air intake
Be provided opposite to curved surface heating plate, the both ends of the curved surface heating plate are hinged with wing plate, the curved surface heating plate, wing plate with it is described
Heating air duct is formed between air intake.
Preferably, the external coating of curved surface heating plate and wing plate has collection thermosphere.
Preferably, collection thermosphere is from bottom to top disposed with layer of mineral wool and black chrome coating.
Preferably, air energy converter structure include by pipeline cycle successively the expansion valve of connection, evaporator, condenser and
Compressor;Wherein, expansion valve, evaporator are located in housing A, and condenser and compressor are arranged in housing B.
Preferably, heat pump module further includes thermal insulation board, and housing A is arranged on the one side of thermal insulation board, housing B be arranged at every
On the opposite side of hot plate.
Preferably, multiple exhaust fans are provided on the housing of housing A, the outlet of exhaust fan is connected with cold air duct.
Preferably, the both sides of housing B are both provided with air intake, and are provided with hot-blast outlet between two air intakes,
Hot-blast outlet is connected with hot air duct.
Preferably, the warm thermostat of automatic benefit is additionally provided in housing B.
Preferably, the outside of cold air duct is enclosed with asbestos insulating layer, and the outside of the pipeline of hot air duct is provided with carbon black
Heat-sink shell.
Preferably, it is hinged with arc air intake plate at the top of curved surface heating plate.
In the above-mentioned technical solutions, high efficiency dual intensity integration provided by the utility model passes through curved surface first for collecting system
Heating plate, wing plate heat air, and the air after then heating can enter housing A and housing B by heating air duct, lead to
Cross more hot air can customer service in cold weather air energy converter structure difficulty in starting the defects of, and then air can be converted
Mechanism enables to the air in housing A to be converted to cold air and is discharged into the cold air duct to provide cold air to freezer,
Meanwhile air energy converter structure air in the housing B can be converted to hot-air and be discharged into the hot air duct with to
Dryer provides hot-air.On this basis, i.e., carried respectively to freezer and dryer by the dual energy of electric energy and solar energy
For cold air and hot-air, thus solar energy can make fully to be utilized, so that energy utilization rate is able to significantly
Degree improves.
Other feature and advantage of the utility model will be described in detail in subsequent specific embodiment part.
Description of the drawings
Attached drawing is to be used to provide a further understanding of the present invention, and a part for constitution instruction, and following
Specific embodiment together for explaining the utility model, but do not form the limitation to the utility model.In the accompanying drawings:
Fig. 1 is the structure diagram that high efficiency dual intensity integration provided by the utility model supplies collecting system;
Fig. 2 is the structure diagram of the preferred embodiment of heat pump module in Fig. 1;
Fig. 3 is the structure diagram of the preferred embodiment of Fig. 1 mean camber heating plates.
Reference sign
1st, heat pump module 2, cold air duct
3rd, freezer 4, hot air duct
5th, dryer 6, housing A
7th, housing B 8, expansion valve
9th, evaporator 10, condenser
11st, compressor 12, air intake
14th, hot-blast outlet 15, thermal insulation board
16th, exhaust fan 17, curved surface heating plate
18th, wing plate 19, the warm thermostat of automatic benefit
20th, arc air intake plate
Specific embodiment
Specific embodiment of the present utility model is described in detail below in conjunction with attached drawing.It should be appreciated that herein
Described specific embodiment is only used for describing and explaining the present invention, and is not intended to limit the utility model.
In the utility model in the case where not making explanation on the contrary, the noun of locality included in term such as " inside and outside " is only
Represent orientation of the term under normal service condition or be those skilled in the art understand that be commonly called as, and be not construed as to this
The limitation of term.
The utility model provides a kind of high efficiency dual intensity integration and supplies collecting system, as depicted in figs. 1 and 2, including:Air
Can heat pump integrate, freezer 3 and dryer 5;Air energy heat pump is integrated including multiple heat pump modules 1, and one end of heat pump module 1 passes through
Cold air duct 2 is connected with freezer 3, and the other end is connected by hot air duct 4 with dryer 5;Heat pump module 1 includes housing A6
Air intake 12 is both provided with on housing B7, housing A6 and housing B7;It is set in the integral structure of housing A6 and housing B7 compositions
Air energy converter structure is equipped with, the air in housing A6 can be converted to cold air and is discharged into cold wind by air energy converter structure
Air in housing B7 can be converted to hot-air and is discharged into hot air duct 4 by pipeline 2, air energy converter structure;Air intake
12 have been provided opposite to curved surface heating plate 17, and the both ends of the curved surface heating plate 17 are hinged with wing plate 18 (for different wind speed
Can housing A6 and housing B7 be more rapidly introduced into so that wind energy is enough by the angle of wing plate 18), the curved surface heating
Heating air duct is formed between plate 17, wing plate 18 and the air intake 12.
Above-mentioned high efficiency dual intensity integration first adds air by curved surface heating plate 17, wing plate 18 for collecting system
Heat, the air after then heating can enter housing A6 and housing B7 by heating air duct, being capable of visitor by more hot air
The defects of taking air energy converter structure difficulty in starting in cold weather, and then air energy converter structure is enabled in housing A6
Air be converted to cold air and be discharged into the cold air duct 2 with to freezer 3 provide cold air, meanwhile, air energy converter
Air in the housing B7 can be converted to hot-air and be discharged into the hot air duct 4 to provide hot sky to dryer 5 by structure
Gas.On this basis, i.e., cold air and heat are provided to freezer 3 and dryer 5 respectively by the dual energy of electric energy and solar energy
Thus air can make solar energy fully to be utilized, so that energy utilization rate is greatly improved.
In above-mentioned curved surface heating plate 17, wing plate 18, curved surface heating plate 17, wing plate 18 specific mode of heating can be in width
In the range of select, but in order to further improve curved surface heating plate 17, wing plate 18 for air heating effect, it is preferable that
Curved surface heating plate 17 and the external coating of wing plate 18 have collection thermosphere.Curved surface heating plate 17 can be so enabled to by collection thermosphere
Realize that rapidly heating has higher temperature to the air in heating air duct with wing plate 18, so that high efficiency dual intensity one
Bodyization has superior collection energy efficiency for collecting system.
Wherein, the concrete structure of above-mentioned collection thermosphere can also select in wide scope, but in order to further improve
The heating effect of air, it is preferable that collection thermosphere is from bottom to top disposed with layer of mineral wool and black chrome coating, one side layer of mineral wool energy
The effect of heat preservation is enough played, another aspect black chrome coating has the effect of heat absorption and then can improve the heating effect of air.
In the utility model, the concrete structure of air energy converter structure can select in wide scope, but in order to
Further so that housing A6 is capable of providing the lower cold air of temperature, housing B7 is capable of providing the higher hot-air of temperature, excellent
Selection of land, as shown in Fig. 2, air energy converter structure includes the expansion valve 8, evaporator 9, condenser that cycle connection successively by pipeline
10 and compressor 11;Wherein, expansion valve 8, evaporator 9 are located in housing A6, and condenser 10 and compressor 11 are arranged at housing B7
It is interior.In this way, hot-air enters in housing A6 and housing B7 the startup that can be convenient for evaporator 9, condenser 10 and compressor 11, one
After denier evaporator 9, condenser 10 and compressor 11 start, the refrigerant in pipeline can be converted to gas by evaporator 9 by liquid
State is so that the air themperature of housing A6 reduces, and then refrigerant enters condenser 10 and compressor 11, so that refrigeration
Agent is converted to liquid by gaseous state, can so raise the temperature of the air in housing B7.
In the utility model, housing A6 and the specific installation sites of housing B7 and connection relation can be in wide scopes
Selection, but in order to save device take up space and avoid energy scatter and disappear, it is preferable that heat pump module 1 further includes heat-insulated
Plate 15, housing A6 are arranged on the one side of thermal insulation board 15, and housing B7 is arranged on the opposite side of thermal insulation board 15.It thus can be by shell
Body A6 and housing B7, which is arranged to integral mechanism, can greatly reduce its space occupied, while the presence of thermal insulation board 15 also can
Scattering and disappearing for energy is avoided, and then improves the utilization rate of energy.
In addition, the expulsion efficiency of the cold air in order to further improve housing A6, it is preferable that on the housing of housing A6
Multiple exhaust fans 16 are provided with, the outlet of exhaust fan 16 is connected with cold air duct 2;It thus being capable of pole by exhaust fan 16
Efficient cold air is discharged into cold air duct 2 greatly.
Meanwhile the discharge mode of the hot-air of housing B7 can also select in wide scope, but in order to further
Improve the expulsion efficiency of hot-air, it is preferable that the both sides of housing B7 are both provided with air intake 12, and two air intakes 12 it
Between be provided with hot-blast outlet 14, hot-blast outlet 14 is connected with hot air duct 4.Pass through hot-blast outlet 14 and air intake 12
It sets, the formation efficiency and expulsion efficiency of hot-air can be greatlyd improve.
On the basis of the above, it is contemplated that under rainy weather, the utilization rate of solar energy is relatively low, in order to further ensure
The discharge rate of hot-air in housing B7, it is preferable that the warm thermostat 19 of automatic benefit is additionally provided in housing B7.It so can be by certainly
The dynamic electrical heating for mending warm thermostat 19 with overcome rainy weather solar energy utilization ratio there are it is low the defects of.
In the utility model, in order to further improve the utilization rate of energy, it is preferable that the external bag of cold air duct 2
Asbestos insulating layer is wrapped with, the outside of the pipeline of hot air duct 4 is provided with carbon black heat-sink shell, so air can be overcome to be transmitted across
In journey the defects of energy dissipation.
On the basis of the above, in order to preferably be heated to air, at the same allow air to rapidly into
Enter heating air duct, it is preferable that as shown in figure 3, the top of curved surface heating plate 17 is hinged with arc air intake plate 20, can so pass through
Adjust the angle of arc air intake plate 20 so that air can quickly and then heating air duct, so as to fulfill the quick of air plus
Thermal effect.
The preferred embodiment of the utility model, still, the utility model and unlimited are described in detail above in association with attached drawing
Detail in the above embodiment, can be to the skill of the utility model in the range of the technology design of the utility model
Art scheme carries out a variety of simple variants, these simple variants belong to the scope of protection of the utility model.
It is further to note that the specific technical features described in the above specific embodiments, in not lance
It in the case of shield, can be combined by any suitable means, in order to avoid unnecessary repetition, the utility model is to each
The possible combination of kind no longer separately illustrates.
In addition, it can also be combined between a variety of embodiments of the utility model, as long as it is not disobeyed
The thought of the utility model is carried on the back, should equally be considered as content disclosed in the utility model.
Claims (10)
1. a kind of high efficiency dual intensity integration supplies collecting system, which is characterized in that including:Air energy heat pump integrates, freezer (3) and dry
Dry machine (5);The air energy heat pump is integrated including multiple heat pump modules (1), and one end of the heat pump module (1) passes through cool air hose
Road (2) is connected with the freezer (3), and the other end is connected by hot air duct (4) with the dryer (5);The heat pump
Module (1) includes housing A (6) and housing B (7), and air intake (12) is both provided on the housing A (6) and housing B (7);Institute
It states in the integral structure of housing A (6) and housing B (7) compositions and is provided with air energy converter structure, the air energy converter structure energy
It is enough that air in the housing A (6) is converted into cold air and is discharged into the cold air duct (2), the air energy converter
The interior air of the housing B (7) can be converted to hot-air and is discharged into the hot air duct (4) by structure;The air intake
(12) be provided opposite to curved surface heating plate (17), the both ends of the curved surface heating plate (17) are hinged with wing plate (18), the song
Heating air duct is formed between face heating plate (17), wing plate (18) and the air intake (12).
2. high efficiency dual intensity integration according to claim 1 supplies collecting system, which is characterized in that the curved surface heating plate
(17) there is collection thermosphere with the external coating of wing plate (18).
3. high efficiency dual intensity according to claim 2 integration supplies collecting system, which is characterized in that the collection thermosphere by lower and
On be disposed with layer of mineral wool and black chrome coating.
4. the high efficiency dual intensity integration according to any one in claim 1-3 supplies collecting system, which is characterized in that described
Air energy converter structure includes cycling expansion valve (8), evaporator (9), condenser (10) and the compression of connection successively by pipeline
Machine (11);Wherein, the expansion valve (8), evaporator (9) are located in the housing A (6), the condenser (10) and compressor
(11) it is arranged in the housing B (7).
5. high efficiency dual intensity integration according to claim 4 supplies collecting system, which is characterized in that the heat pump module (1)
Thermal insulation board (15) is further included, the housing A (6) is arranged on the one side of the thermal insulation board (15), and the housing B (7) is arranged at
On the opposite side of the thermal insulation board (15).
6. high efficiency dual intensity integration according to claim 4 supplies collecting system, which is characterized in that the shell of the housing A (6)
Multiple exhaust fans (16) are provided on body, the outlet of the exhaust fan (16) is connected with the cold air duct (2).
7. high efficiency dual intensity integration according to claim 4 supplies collecting system, which is characterized in that the two of the housing B (7)
Side is both provided with the air intake (12), and is provided with hot-blast outlet (14) between two air intakes (12), described
Hot-blast outlet (14) is connected with the hot air duct (4).
8. high efficiency dual intensity integration according to claim 4 supplies collecting system, which is characterized in that in the housing B (7) also
It is provided with the warm thermostat (19) of automatic benefit.
9. high efficiency dual intensity integration according to claim 1 supplies collecting system, which is characterized in that the cold air duct (2)
Outside be enclosed with asbestos insulating layer, the outside of the pipeline of the hot air duct (4) is provided with carbon black heat-sink shell.
10. high efficiency dual intensity integration according to claim 1 supplies collecting system, which is characterized in that the curved surface heating plate
(17) arc air intake plate (20) is hinged at the top of.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN201720889025.0U CN207438940U (en) | 2017-07-21 | 2017-07-21 | The integration of high efficiency dual intensity supplies collecting system |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN201720889025.0U CN207438940U (en) | 2017-07-21 | 2017-07-21 | The integration of high efficiency dual intensity supplies collecting system |
Publications (1)
Publication Number | Publication Date |
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CN207438940U true CN207438940U (en) | 2018-06-01 |
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2017
- 2017-07-21 CN CN201720889025.0U patent/CN207438940U/en active Active
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Legal Events
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GR01 | Patent grant | ||
GR01 | Patent grant | ||
TR01 | Transfer of patent right |
Effective date of registration: 20201230 Address after: 210000 no.1007, jinrunda Zhongchuang space, Nanjing National Agricultural Innovation Park, No.20 Yanshan Avenue, Pukou District, Nanjing City, Jiangsu Province Patentee after: Jiangsu hot air environmental protection technology Co.,Ltd. Address before: 241000 2nd floor, No.11 workshop, small and medium sized enterprise Pioneer Park, South District, Wuhu hi tech Industrial Development Zone, Anhui Province Patentee before: WUHU CHANGQI FURNACE Co.,Ltd. |
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TR01 | Transfer of patent right |