CN114562757A - Heating equipment utilizing wind power photovoltaic air renewable energy - Google Patents

Abstract

The utility model discloses a heating device utilizing wind power photovoltaic air renewable energy, wherein an air duct is arranged on an installation block, a driving shaft is arranged in the air duct, fan blades are arranged on one end of the driving shaft, the other end of the driving shaft is connected with a differential power storage mechanism, and a photovoltaic panel is connected with the differential power storage mechanism; an evaporation chamber is arranged in the installation block, an electric heating plate is arranged in the evaporation chamber and connected with the differential power storage mechanism, a driving water tank, a spiral conveying rod and a connecting shaft are arranged on the installation block, the driving water tank is connected with a water outlet pipe and a water inlet pipe, and the water outlet pipe is communicated with the evaporation chamber; the outlet of the evaporation chamber is communicated with a heat supply pipe, the spiral conveying rod is positioned in the driving water tank, one end of the connecting shaft is connected with the end part of the spiral conveying rod after being inserted into the driving water tank, the connecting shaft is connected with the driving shaft through a belt, and the equipment can control heat in and out according to the wind power.

Description

Heating equipment utilizing wind power photovoltaic air renewable energy

Technical Field

The utility model belongs to the technical field of wind power heat supply, and particularly relates to heat supply equipment utilizing wind power photovoltaic air renewable energy.

Background

Wind power generation refers to converting kinetic energy of wind into electric energy, and photovoltaic is a short term for a solar photovoltaic power generation system, and is a novel power generation system which directly converts solar radiation energy into electric energy by utilizing the photovoltaic effect of a solar cell semiconductor material and has two modes of independent operation and grid-connected operation.

Through the retrieval, chinese patent is CN 211625444U's utility model patent discloses an utilize heating equipment of wind-powered electricity generation photovoltaic air renewable energy, including the support frame, the water pump has been placed to one side of support frame, photovoltaic water heater has been placed to one side of water pump, the last fixed surface of support frame is connected with the storage water tank, the rear side fixedly connected with aerogenerator of storage water tank, and the last fixed surface of storage water tank is connected with the fixed box, the water inlet fixedly connected with inlet tube of water pump, and the delivery port fixedly connected with outlet pipe of water pump, the water inlet of inlet tube and storage water tank fixed connection, the utility model relates to renewable energy equipment pore-forming technical field. The heating equipment utilizing the wind power photovoltaic air renewable energy can preliminarily heat water through the water storage tank plated with the heat absorption coating, and meanwhile, through the wind driven generator, the water storage tank can be stirred through the gearbox and the stirring shaft, so that the contact part of the water and the inner wall of the water storage tank can be changed;

however, in the working process of the above-mentioned device, only the water storage tank can be stirred, the contact part between water and the inner wall of the water storage tank can be changed, and further the transmission of heat energy is realized, but the above-mentioned device only conducts heat conduction through photovoltaic to heat the heating efficiency too slowly, and at the same time, the heat transfer through water flow is slower than the steam speed, and at the same time, additional devices are needed to conduct and discharge water flow, so that the heat in and out is difficult to control according to the current wind power.

Disclosure of Invention

The utility model aims to overcome the defects of the prior art and provides heating equipment utilizing wind power, photovoltaic and air renewable energy, which can control the heat input and output according to the wind power.

In order to achieve the purpose, the heat supply equipment utilizing the wind power photovoltaic air renewable energy comprises an installation block and a wind power photovoltaic mechanism, wherein the wind power photovoltaic mechanism comprises an air duct, a photovoltaic plate, fan blades, a driving shaft and a differential power storage mechanism;

the wind barrel is arranged on the mounting block, the driving shaft is arranged in the wind barrel, the fan blades are arranged on one end of the driving shaft, the other end of the driving shaft is connected with the differential electricity storage mechanism, and the photovoltaic panel is connected with the differential electricity storage mechanism;

an evaporation chamber is arranged in the installation block, an electric heating plate is arranged in the evaporation chamber and connected with the differential power storage mechanism, a driving water tank, a spiral conveying rod and a connecting shaft are arranged on the installation block, the driving water tank is connected with a water outlet pipe and a water inlet pipe, and the water outlet pipe is communicated with the evaporation chamber;

an outlet of the evaporation chamber is communicated with a heat supply pipe, the spiral conveying rod is positioned in the driving water tank, one end of the connecting shaft is inserted into the driving water tank and then connected with the end part of the spiral conveying rod, and the connecting shaft is connected with the driving shaft through a belt.

The bottom of the mounting block is provided with a base.

The drive shaft is arranged in the air duct through a bearing rod.

The mounting block is provided with a positioning groove, and the driving water tank is mounted in the positioning groove.

The photovoltaic board is installed on the outer wall of installation piece.

The connecting shaft is connected with the driving shaft through a belt.

The differential power storage mechanism is arranged in the air duct.

A driving mechanism is arranged in the water outlet pipe, the driving mechanism comprises a positioning shaft and a driving box, a water inlet and a water outlet are formed in the driving box, the positioning shaft penetrates through the driving box, a plurality of impact blades are arranged on the positioning shaft, and the impact blades are positioned in the driving box;

the water outlet pipe is internally provided with a fixed bearing rod, wherein one end of the fixed bearing rod is fixed on the inner wall of the water outlet pipe, the other end of the fixed bearing rod is sleeved on the driven shaft, the end part of the positioning shaft is connected with one end of the driven shaft through a connecting piece, the other end of the driven shaft is connected with a shearing blade through a connecting rod, and the shearing blade is positioned at the outlet of the water outlet pipe.

The connecting piece includes initiative bevel gear and driven bevel gear, and initiative bevel gear cup joints on the location axle, and driven bevel gear cup joints on the driven shaft, and the initiative bevel gear meshes with driven bevel gear mutually.

The installation cover is installed to the one end of outlet pipe export, and the inside of installation cover is provided with the cutting mechanism who is used for cuting rivers, cutting mechanism includes the locking block, and a plurality of drive grooves have been seted up to the locking block inside, and the drive inslot portion is provided with the movable rod, is provided with the drive plate on the movable rod, is provided with the gasbag of a plurality of symmetric distributions between the inner wall in drive plate and drive groove, and the leaf is cuted to the tip installation of movable rod.

The utility model has the following beneficial effects:

when the heating equipment utilizing the wind power photovoltaic air renewable energy sources is specifically operated, solar radiation is absorbed by the photovoltaic panel and converted into electric energy, meanwhile, the fan blades start to rotate by external wind power, the connecting shaft starts to rotate in the rotating process of the fan blades, the connecting shaft drives the spiral conveying rod to rotate in the rotating process, the spiral conveying rod rotates to suck external water flow through the water inlet pipe, the water flow entering the driving water tank is discharged into the evaporation chamber through the water outlet pipe, then the water flow is heated by the electric heating plate, and the water flow is heated to form steam and then discharged through the heating pipe, so that the input water flow can be changed by the external wind speed, and the heating efficiency is ensured.

Furthermore, rivers flow into inside the drive box through the in-process of outlet pipe entering evaporation chamber, flow into the in-process at rivers and strike the leaf, strike the leaf and receive the impact to make the location axle begin to rotate, the location axle makes the driven shaft begin to rotate at the rotation in-process, and then makes the shearing leaf begin to rotate, cuts the leaf and rotates the realization and to the shearing of discharge rivers, makes rivers form water smoke for the evaporation rate of rivers.

Further, when input water flows through when many, the phenomenon of blocking up can appear in the inside steam of evaporating chamber and is difficult to discharge fast through the heating supply pipe, the heat of steam self can make the gasbag begin to expand, the gasbag inflation makes the drive plate begin to rotate, the drive plate drives the movable rod and begins to rotate, the movable rod makes the shearing leaf begin to rotate, and then make the shearing leaf produce decurrent downforce simultaneously in the shearing process to rivers, the steam of being convenient for discharges through the heating supply pipe, realize the control to producing the downforce size according to the size of wind speed, guarantee thermal transport efficiency.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a perspective view of the present invention;

FIG. 3 is a first internal schematic view of the present invention;

FIG. 4 is a second internal structural view of the present invention;

FIG. 5 is a schematic view of the locking block 18 and shear blade 20 of the present invention;

FIG. 6 is a schematic view of the locking block 18 of the present invention;

FIG. 7 is a schematic structural diagram of the water outlet pipe 17 and the mounting cover 14 according to the present invention;

FIG. 8 is an enlarged view of the structure at A in FIG. 4;

FIG. 9 is an enlarged view of the structure at B in FIG. 6;

fig. 10 is an enlarged view of the structure at C in fig. 7.

Wherein, 1 is an installation block, 2 is a base, 3 is an air duct, 4 is a photovoltaic panel, 5 is a heat supply pipe, 6 is a fan blade, 7 is a driving shaft, 8 is a differential power storage mechanism, 9 is a positioning groove, 10 is a water inlet pipe, 11 is a belt, 12 is an evaporation chamber, 13 is an electric heating plate, 13, 14 is an installation cover, 15 is a driving water tank, 16 is a spiral conveying rod, 17 is a water outlet pipe, 18 is a locking block, 19 is a connecting shaft, 20 is a shearing blade, 21 is a driving groove, 22 is a movable rod, 23 is a driving plate, 24 is an air bag, 25 is a driving box, 26 is a positioning shaft, 27 is an impact blade, 28 is a driven shaft, 29 is a connecting rod, 30 is a fixed bearing rod, 31 is a driving bevel gear, and 32 is a driven bevel gear.

Detailed Description

In order to make the technical solutions of the present invention better understood, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, not all of the embodiments, and are not intended to limit the scope of the present disclosure. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present disclosure. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, shall fall within the protection scope of the present invention.

There is shown in the drawings a schematic block diagram of a disclosed embodiment in accordance with the utility model. The figures are not drawn to scale, wherein certain details are exaggerated and possibly omitted for clarity of presentation. The shapes of various regions, layers and their relative sizes and positional relationships shown in the drawings are merely exemplary, and deviations may occur in practice due to manufacturing tolerances or technical limitations, and a person skilled in the art may additionally design regions/layers having different shapes, sizes, relative positions, according to actual needs.

Referring to fig. 1 to 10, the heat supply device using wind power photovoltaic air renewable energy according to the present invention includes an installation block 1 and a wind power photovoltaic mechanism, the wind power photovoltaic mechanism includes an air duct 3, a photovoltaic panel 4, fan blades 6, a driving shaft 7 and a differential power storage mechanism 8, the air duct 3 is installed on the installation block 1, the driving shaft 7 is installed in the air duct 3 through a bearing rod, the fan blades 6 are installed on one end of the driving shaft 7, the other end of the driving shaft 7 is connected to the differential power storage mechanism 8, and the photovoltaic panel 4 is connected to the differential power storage mechanism 8;

an evaporation chamber 12 is arranged in the installation block 1, an electric heating plate 13 is arranged in the evaporation chamber 12, the electric heating plate 13 is connected with the differential power storage mechanism 8, a positioning groove 9 is arranged on the installation block 1, a flow guide mechanism is arranged in the positioning groove 9, the flow guide mechanism comprises a driving water tank 15, the driving water tank 15 is arranged in the positioning groove 9, the driving water tank 15 is connected with a water outlet pipe 17 and a water inlet pipe 10, wherein the water inlet pipe 10 is communicated with the driving water tank 15, and the water outlet pipe 17 is communicated with the evaporation chamber 12;

differential power storage mechanism 8 is installed in dryer 3, and photovoltaic board 4 is installed on the outer wall of installation piece 1, and the bottom of installation piece 1 is provided with base 2, the export intercommunication of evaporating chamber 12 has heating supply pipe 5, and water conservancy diversion mechanism still includes screw conveying pole 16 and connecting axle 19, and screw conveying pole 16 is located driving water tank 15, and the one end of connecting axle 19 is inserted and is connected with screw conveying pole 16's tip behind driving water tank 15, is connected through belt 11 between the other end of connecting axle 19 and the drive shaft 7.

The specific working process of the utility model is as follows:

the photovoltaic panel 4 absorbs solar radiation and converts the solar radiation into electric energy, meanwhile, the fan blade 6 starts to rotate due to external wind power, the driving shaft 7 starts to rotate due to the rotation of the fan blade 6, the driving shaft 7 drives the differential power storage mechanism 8 to store the electric energy, the differential power storage mechanism 8 enables the electric heating plate 13 to work, and the electric heating plate 13 works to emit heat to heat and evaporate water flow;

meanwhile, the drive shaft 7 makes the connecting shaft 19 begin to rotate through the belt 11, the connecting shaft 19 drives the spiral conveying rod 16 to rotate, the spiral conveying rod 16 rotates to suck the outside water flow through the water inlet pipe 10, make the outside water flow enter into the inside of the drive water tank 15, the rethread outlet pipe 17 discharges to the evaporation chamber 12 in, then rethread electric heating plate 13 heats, water flow forms steam after heating, discharge through the heating pipe 5 at last, thereby can be through the change of the size of outside wind speed to input water flow, guarantee the efficiency of heat supply.

Example one

A driving mechanism is arranged in the water outlet pipe 17, the driving mechanism comprises a positioning shaft 26 and a driving box 25, a water inlet and a water outlet are arranged on the driving box 25, the positioning shaft 26 penetrates through the driving box 25, a plurality of impact blades 27 are arranged on the positioning shaft 26, and the impact blades 27 are positioned in the driving box 25;

a fixed bearing rod 30 is installed in the water outlet pipe 17, wherein one end of the fixed bearing rod 30 is fixed on the inner wall of the water outlet pipe 17, the other end of the fixed bearing rod 30 is sleeved on the driven shaft 28, the end part of the positioning shaft 26 is connected with one end of the driven shaft 28 through a connecting piece, the other end of the driven shaft 28 is connected with a shearing blade 20 through a connecting rod 29, and the shearing blade 20 is positioned at the outlet of the water outlet pipe 17;

the connecting piece comprises a driving bevel gear 31 and a driven bevel gear 32, wherein the driving bevel gear 31 is sleeved on the positioning shaft 26, the driven bevel gear 32 is sleeved on the driven shaft 28, and the driving bevel gear 31 is meshed with the driven bevel gear 32.

At specific during operation, rivers flow into drive box 25 at the in-process that gets into evaporating chamber 12 through outlet pipe 17, rivers are when passing through drive box 25, strike leaf 27, strike the leaf 27 and receive the impact after, make location axle 26 begin to rotate, location axle 26 drives initiative bevel gear 31 at the pivoted in-process and rotates, initiative bevel gear 31 meshes with driven bevel gear 32 mutually, thereby make driven shaft 28 rotate, driven shaft 28 drives connecting rod 29 and rotates, connecting rod 29 makes shearing leaf 20 rotate, shearing leaf 20 realizes the shearing to outlet pipe 17's discharge rivers at the pivoted in-process, make rivers form water smoke, accelerate the evaporation rate of rivers.

Example two

Installation cover 14 is installed to the one end of outlet pipe 17 export, and the inside of installation cover 14 is provided with the cutting mechanism who is used for cuting rivers, cutting mechanism includes locking block 18, and a plurality of drive grooves 21 have been seted up to locking block 18 inside, and drive groove 21 is inside to be provided with movable rod 22, is provided with drive plate 23 on the movable rod 22, is provided with the gasbag 24 of a plurality of symmetric distributions between the inner wall of drive plate 23 and drive groove 21, and shearing leaf 20 is installed to movable rod 22's tip.

When the heat supply device works, when external wind power is increased, so that input water flows through more time, the phenomenon of congestion can occur to steam inside the evaporation chamber 12 at the moment, the steam is difficult to be quickly discharged through the heat supply pipe 5, the steam increases the temperature inside the evaporation chamber 12, the steam can make the air bags 24 begin to expand due to the heat of the steam, the air bags 24 can make the driving plate 23 begin to rotate due to the expansion of the air bags 24, the two air bags 24 are arranged in a central symmetry mode, the driving plate 23 drives the movable rod 22 to begin to rotate, the movable rod 22 makes the shearing blades 20 begin to rotate, the shearing blades 20 form a certain included angle with the horizontal plane, and then the shearing blades 20 can simultaneously generate downward pressure in the process of shearing water flow, the steam can be conveniently discharged through the heat supply pipe 5, the control of the generated downward pressure can be realized according to the wind speed, and the heat conveying efficiency is ensured.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (10)

1. A heating device utilizing wind power photovoltaic air renewable energy is characterized by comprising an installation block (1) and a wind power photovoltaic mechanism, wherein the wind power photovoltaic mechanism comprises an air duct (3), a photovoltaic plate (4), fan blades (6), a driving shaft (7) and a differential power storage mechanism (8);

the wind barrel (3) is arranged on the mounting block (1), the driving shaft (7) is arranged in the wind barrel (3), the fan blades (6) are arranged on one end of the driving shaft (7), the other end of the driving shaft (7) is connected with the differential electricity storage mechanism (8), and the photovoltaic panel (4) is connected with the differential electricity storage mechanism (8);

an evaporation chamber (12) is arranged in the mounting block (1), an electric heating plate (13) is arranged in the evaporation chamber (12), the electric heating plate (13) is connected with the differential power storage mechanism (8), a driving water tank (15), a spiral conveying rod (16) and a connecting shaft (19) are arranged on the mounting block (1), the driving water tank (15) is connected with a water outlet pipe (17) and a water inlet pipe (10), wherein the water outlet pipe (17) is communicated with the evaporation chamber (12);

an outlet of the evaporation chamber (12) is communicated with a heat supply pipe (5), the spiral conveying rod (16) is positioned in the driving water tank (15), one end of the connecting shaft (19) is inserted into the driving water tank (15) and then connected with the end part of the spiral conveying rod (16), and the connecting shaft (19) is connected with the driving shaft (7) through a belt (11).

2. Heating equipment with wind-electricity photovoltaic air renewable energy according to claim 1, characterized in that the bottom of the mounting block (1) is provided with a base (2).

3. Heating equipment with wind-electricity photovoltaic air renewable energy according to claim 1, characterized in that the drive shaft (7) is mounted inside the wind tunnel (3) through a bearing rod.

4. Heating equipment using wind electricity, photovoltaic and air as renewable energy according to claim 1, characterized in that the mounting block (1) is provided with a positioning groove (9), and the driving water tank (15) is mounted in the positioning groove (9).

5. A heating installation with wind-powered photovoltaic air renewable energy sources according to claim 1, characterized in that the photovoltaic panels (4) are mounted on the outer wall of the mounting block (1).

6. A heating installation with wind-powered photovoltaic air renewable energy as claimed in claim 1, characterized in that the connection shaft (19) is connected to the drive shaft (7) by means of a belt (11).

7. A heating plant using wind electricity, photovoltaic and air as renewable energy according to claim 1, characterized in that the differential electricity storage mechanism (8) is installed inside the wind tunnel (3).

8. The heating device utilizing wind power, photovoltaic and air renewable energy according to claim 1, characterized in that a driving mechanism is installed in the water outlet pipe (17), the driving mechanism comprises a positioning shaft (26) and a driving box (25), the driving box (25) is provided with a water inlet and a water outlet, the positioning shaft (26) penetrates through the driving box (25), the positioning shaft (26) is provided with a plurality of impact blades (27), and the impact blades (27) are located in the driving box (25);

install fixed bearing pole (30) in outlet pipe (17), wherein, on the one end of fixed bearing pole (30) was fixed in the inner wall of outlet pipe (17), the other end of fixed bearing pole (30) cup jointed on driven shaft (28), the tip of location axle (26) is connected through the connecting piece with the one end of driven shaft (28), the other end of driven shaft (28) is connected with through connecting rod (29) and cuts leaf (20), cuts the exit that leaf (20) are located outlet pipe (17).

9. The heating equipment using wind power, photovoltaic and air renewable energy according to claim 8, wherein the connecting piece comprises a driving bevel gear (31) and a driven bevel gear (32), the driving bevel gear (31) is sleeved on the positioning shaft (26), the driven bevel gear (32) is sleeved on the driven shaft (28), and the driving bevel gear (31) is meshed with the driven bevel gear (32).

10. The heating equipment utilizing wind power, photovoltaic and air renewable energy according to claim 1, characterized in that an installation cover (14) is installed at one end of an outlet of a water outlet pipe (17), a cutting mechanism for cutting water flow is arranged inside the installation cover (14), the cutting mechanism comprises a locking block (18), a plurality of driving grooves (21) are formed inside the locking block (18), movable rods (22) are arranged inside the driving grooves (21), driving plates (23) are arranged on the movable rods (22), a plurality of symmetrically distributed air bags (24) are arranged between the driving plates (23) and the inner walls of the driving grooves (21), and cutting blades (20) are installed at the end parts of the movable rods (22).

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