CN220769626U - Breeze power generation and heat storage device - Google Patents

Abstract

The utility model provides a breeze electricity generation heat accumulation device, relates to an electricity heat accumulation device, and the device includes breeze generator, relay control, wind speed sensing control, heat energy storage four parts; the fan blade combination (3-1) of the breeze generator (3) is hinged on the upper bearing (3-3) of the transmission shaft (3-2), and the lower part of the transmission shaft (3-2) is provided with a coupler (3-4), a speed increasing gear train (3-5) and a permanent magnet direct current generator (3-6) according to the sequence; the output end of the permanent magnet direct current generator (3-6) is respectively connected with a normally open contact (2-4) of the relay (2) and a breeze electric heater (4-1) in the oil and water meson thermal energy storage container (4); the utility model improves the kinetic energy through the structural design, fully utilizes the wind energy, expands the effective utilization space of the wind energy, reduces the wind energy generation investment, reduces the wind energy generation cost, and is suitable for breeze power generation and heat storage places with low altitude, low wind speed and wide site selection.

Description

Breeze power generation and heat storage device

Technical Field

The utility model relates to an electric heating energy storage device, in particular to a breeze power generation heat storage device.

Background

The conventional wind power generation has large investment, including equipment, installation, site selection, network access and the like, and has high technical standard. The development of renewable energy sources can make up for the shortage of fossil energy sources in China, and photovoltaic power generation and wind power generation are clean renewable energy sources. The development relationship of energy sources is national and civil, natural resources are fully utilized, high benefits are obtained at low cost, and the energy-saving technology problem is very worth researching.

The breeze power generation can reduce investment, reduce application cost, fully utilize wind energy resources and enlarge the application range of thermal energy storage. Such as heating for production and living, heating for greenhouse for breeding in agricultural production, etc. The existing breeze power generation and heat storage device is relatively complex or high in cost, is difficult to be accepted by common consumers of individuals or entity units,

therefore, it is very necessary to design a device which is relatively small in size and simple in structure and generates heat energy through breeze power generation, and the device solves the problem of small-sized energy conservation of individual heat storage and heating in factories, rural areas and the like.

Disclosure of Invention

The utility model aims to provide a breeze power generation and heat storage device, which realizes instant heat energy storage by instant generation and automatically controls the switching of wind power and a network electric heating energy storage power supply circuit according to the intensity and the wind power. The wind energy generation system has the advantages that the kinetic energy is improved through the structural design, the wind energy is fully utilized, the effective utilization space of the wind energy is expanded, the wind energy generation investment is reduced, the wind energy generation cost is reduced, and the wind energy generation system is suitable for being applied to breeze power generation heat storage places with low altitude, low wind speed and wide site selection.

The utility model aims at realizing the following technical scheme:

the breeze power generation and heat storage device comprises four parts, namely a breeze power generator, relay control, wind speed sensing control and thermal energy storage; the fan blade combination of the breeze generator is hinged on the upper bearing of the transmission shaft, and the lower part of the transmission shaft is provided with a coupler, a speed increasing gear train and a permanent magnet direct current generator according to the sequence; the output end of the permanent magnet direct current generator is respectively connected with a normally open contact of the relay and a breeze electric generator in the oil and water meson thermal energy storage container; the relay control part comprises a relay, a coil, a base contact, a normally closed contact, a normally open contact and a spring; the wind blades of the wind speed sensing control part are symmetrically assembled at the upper part of the rotating shaft; the upper and lower positions of the rotating shaft are provided with ball covers through bearings, and the ball covers seal the sensing control components in the ball covers; the ball cover is internally provided with a fixed hinge point, a centrifugal heavy hammer, a hinge point sliding sleeve passage contact, an open contact, a fixed contact connecting rod, a fixed hinge point and a connecting rod lower hinge point combined sensing component; a vertical support rod supporting ring frame is arranged below the rotating shaft, namely a switching sensing part for supporting breeze power generation wind speed sensing control; the oil and water meson thermal energy storage container is internally provided with a breeze electric heater and a net electric heater which are respectively communicated with the relay controller.

The wind speed sensing controller comprises wind blades, a rotating shaft, a centrifugal heavy hammer, a hinge point sliding sleeve passage contact, an open contact, a fixed contact connecting rod, a fixed hinge point, a connecting rod lower hinge point and a spherical cover.

The breeze power generation and heat storage device comprises a fan blade combination, a blade shaft, a blade plate, a blade transposition limiting seat and a blade shaft seat; the device comprises a transmission shaft, a bearing, a coupler, a speed-increasing gear train and a permanent magnet direct current generator.

The breeze power generation and heat storage device is characterized in that the spherical cover is in a closed state, and a ring frame support is arranged outside the spherical cover.

The breeze power generation heat storage device is characterized in that an injection port and an output port are respectively arranged on the oil and water meson heat energy storage container.

The utility model has the advantages and effects that:

the utility model fully utilizes wind energy, promotes kinetic energy through structural design, expands the effective utilization space of wind energy, thereby reducing wind energy generation investment, reducing wind energy generation cost, being applicable to breeze places with low altitude, low wind speed and wide site selection area.

Drawings

FIG. 1 is a schematic diagram of a breeze power generation and heat storage device of the utility model;

FIG. 2 is a schematic view of the windward state of the combined fan blade of the present utility model;

FIG. 3 is a top view of FIG. 2 in accordance with the present utility model;

FIG. 4 is a schematic view of a generator blade according to the present utility model;

FIG. 5 is a cross-sectional view of a generator blade of the present utility model;

FIG. 6 is a partial cross-sectional view of the generator blade I-I of the present utility model;

FIG. 7 is a partial cross-sectional view of a generator blade II-II according to the present utility model;

FIG. 8 is a partial cross-sectional view of a generator blade III-III according to the present utility model.

The components in the figure: the wind speed sensing device comprises a wind speed sensing controller 1, wind blades 1-1, a rotating shaft 1-2, a centrifugal heavy hammer 1-3, a hinge point sliding sleeve passage contact 1-4, an open contact 1-5, a fixed contact connecting rod 1-6, a fixed hinge point 1-7, a connecting rod lower hinge point 1-8 and a spherical cover 1-9;

the device comprises a relay 2, a coil 2-1, a base contact 2-2, a normally closed contact 2-3, a normally open contact 2-4 and a spring 2-5;

the breeze generator 3 comprises a fan blade combination 3-1, a blade shaft 3-1-1, a blade plate 3-1-2, a blade transposition limiting seat 3-1-3 and a blade shaft seat 3-1-4; the device comprises a transmission shaft 3-2, a bearing 3-3, a coupler 3-4, a speed increasing gear train 3-5 and a permanent magnet direct current generator 3-6;

the device comprises an oil and water meson thermal energy storage container 4, a breeze electric heater 4-1, a net electric heater 4-2, an injection port 4-3 and an output port 4-4.

Description of the embodiments

The present utility model will be described in detail with reference to the embodiments shown in the drawings.

As shown in the figure, the utility model is designed with a fan blade combined structure which has high windward efficiency and small downwind resistance and automatically adjusts the electric heating energy storage of power generation; the wind power is transmitted to the generator by the fan blade through the main shaft, the main shaft bearing, the coupler and the speed increasing gear train, and the current generated by the generator is conducted into the energy storage container by using oil and water as mesons through electromagnetic induction or resistance heating. The utility model can be matched with network electricity supplement to compensate the instability of wind power generation; in operation, the wind speed sensor controller and the relay are used for switching control. The rotation torque and the current generated by breeze power generation are determined by the wind speed, the wind area of the fan blade, the wind efficiency of the fan blade, the distance between the fan blade and the center of the rotating shaft, and the like. The utility model relates to a breeze generator blade combination 3-1, which comprises a blade shaft 3-1-1, a blade plate 3-1-2, a blade transposition limiting seat 3-1-3 and a blade shaft seat 3-1-4; the device comprises a transmission shaft 3-2, a bearing 3-3, a coupler 3-4, a speed increasing gear train 3-5 and a permanent magnet direct current generator 3-6.

The breeze power generation and heat storage device comprises four parts, namely a breeze power generator, relay control, wind speed sensing control and thermal energy storage; the fan blade combination 3-1 of the breeze generator 3 is hinged on the upper bearing 3-3 of the transmission shaft 3-2, and the lower part of the transmission shaft 3-2 is provided with a coupler 3-4, a speed increasing gear train 3-5 and a permanent magnet direct current generator 3-6 in sequence; the output end of the permanent magnet direct current generator 3-6 is respectively connected with a normally open contact 2-4 of the relay 2 and a breeze electric generator 4-1 in the oil and water meson thermal energy storage container 4; the relay control part comprises a relay 2, a coil 2-1, a base contact 2-2, a normally closed contact 2-3, a normally open contact 2-4 and a spring 2-5; the wind blades 1-1 of the wind speed sensing control part are symmetrically assembled at the upper part of the rotating shaft 1-2, and can be provided with upper and lower groups of combinations according to the use condition; the upper and lower positions of the rotating shaft 1-2 are provided with ball covers 1-9 through bearings, and the ball covers 1-9 seal the sensing control components in the ball covers; the spherical cover 1-9 is in a closed state, and a fixed hinge point 1-7, a centrifugal heavy hammer 1-3, a hinge point sliding sleeve passage contact 1-4, an open contact 1-5, a fixed contact connecting rod 1-6, a fixed hinge point 1-7 and a connecting rod lower hinge point 1-8 combined sensing component are arranged in the spherical cover 1-9; a vertical support rod is arranged below the rotating shaft 1-2 to support a ring frame, namely a breeze power generation wind speed sensing control switching sensing part; the oil and water meson thermal energy storage container 4 is internally provided with a breeze electric heater 4-1 and a net electric heater 4-2, and the breeze electric heater 4-1 and the net electric heater 4-2 are respectively communicated with a relay controller; the oil and water meson thermal energy storage container 4 is respectively provided with an injection port 4-3 and an output port 4-4.

When the engine works against the wind, wind blows on the concave surface, and as the limit of the vane position-changing limit seat 3-1-3 is in a vertical working state, the downwind blows on the convex surface, and similarly, the M2 surface of the vane plate 3-1-2 is stressed greatly, and the vane plate 3-1-2 is turned over to be in a horizontal state under the limit of the vane position-changing limit seat 3-1-3, and turns back with minimum resistance to enter the windward working state. The blade plate 3-1-2 rotationally sleeved on the blade shaft 3-1-1 is provided with two parts of M1 and M2 (see figure 4), the blade plate 3-1-2 is fixed on the blade shaft seat 3-1-4, the breeze generator blade combination 3-1 works in a rotating space (see figures 2 and 3), and the positions of the blades are respectively provided with a windward surface and a downwind surface. The blade plate 3-1-2 is curved and one end is warped (see fig. 5, 6, 7 and 8) so as to reduce concave wind leakage when the blade plate 3-1-2 works and improve working efficiency.

The generator and transmission system transmission shaft 3-2 receives the rotating force of the fan blade combination 3-1, and the current generated from the generator coupler 3-4, the speed increasing gear train 3-5 and the permanent magnet direct current generator 3-6 is distributed to the breeze electric heater 4-1 in the oil and water meson thermal energy storage container 4 through the wind speed sensing controller 1 and the relay 2 for energy storage. When wind is weak or no wind, the fan blade combination 3-1 has no torsion to transmit, the permanent magnet direct current generator 3-6 has no current to transmit, and the wind speed sensing controller 1 and the relay 2 automatically switch the network electricity to supply power and store energy. The breeze and power generation energy storage part comprises a wind speed sensing controller 1; the device comprises a fan blade 1-1, a rotating shaft 1-2, a centrifugal heavy hammer 1-3, a hinge point sliding sleeve passage contact 1-4, an open contact 1-5, a fixed contact connecting rod 1-6, a fixed hinge point 1-7 and a connecting rod lower hinge point 1-8; the wind blade 1-1 of the wind speed sensing controller 1 rotates under the blowing of wind force, and at the moment, the rotating shaft 1-2 rotates together with the fixed hinge point 1-7, the middle hinge point centrifugal heavy hammer 1-3 and the hinge point sliding sleeve passage contact 1-4. Under the action of centrifugal force, the middle hinge point centrifugal heavy hammer 1-3 is thrown away from the center of the rotating shaft 1-2, contacts F 'and E' on the hinge point sliding sleeve access contact 1-4 move to the H position along the rotating shaft 1-2 under the linkage of the fixed contact connecting rod 1-6, and the open contact 1-5 is separated from the fixed contact connecting rod 1-6 contact F, E to be open-circuited (see figure 1).

The relay 2 comprises a coil 2-1, a normally closed contact 2-3, a normally open contact 2-4 and a spring 2-5; when the wind speed sensing controller is in an open state, the coil 2-1 is not powered, the normally closed contact 2-3 is disconnected under the action of the spring 2-5, the base contact 2-2 is in contact combination with the normally open contact 2-4 to form a passage, and the breeze power generation circuit and the breeze power generation electric heater 4-1 in the oil-water meson thermal energy storage container 4 are used for heating and storing energy. The oil-water meson thermal energy storage container 4 comprises a breeze electric heater 4-1, a net electric heater 4-2, an injection port 4-3 and an output port 4-4. When the wind power energy storage, breeze power generation and net electric heat energy storage control are carried out, in the windless state, the centrifugal weight 1-3 at the middle hinge point in the wind speed sensing controller 1 has no centrifugal force, the contacts F 'and E' on the hinge point sliding sleeve passage contact 1-4 are contacted with the contact F, E of the coming passage contact 1-5 to be communicated with the relay 2, the coil 2-1 generates magnetic attraction, the normally closed contact 2-3 is communicated with the base contact 2-2, the net power forms a passage, and the heating energy storage can be completed by communicating the electric heater 5-2.

Claims (5)

1. The breeze power generation and heat storage device is characterized by comprising four parts, namely a breeze power generator, a relay controller, a wind speed sensing controller and a heat energy storage controller; the fan blade combination (3-1) of the breeze generator (3) is hinged on the upper bearing (3-3) of the transmission shaft (3-2), and the lower part of the transmission shaft (3-2) is sequentially provided with a coupler (3-4), a speed increasing gear train (3-5) and a permanent magnet direct current generator (3-6); the output end of the permanent magnet direct current generator (3-6) is respectively connected with a normally open contact (2-4) of the relay (2) and a breeze electric heater (4-1) in the oil and water meson thermal energy storage container (4); the relay control part comprises a relay (2), a coil (2-1), a base contact (2-2), a normally closed contact (2-3), a normally open contact (2-4) and a spring (2-5); the wind blades (1-1) of the wind speed sensing control part are symmetrically assembled at the upper part of the rotating shaft (1-2); the upper and lower positions of the rotating shaft (1-2) are provided with ball covers (1-9) through bearings, and the ball covers (1-9) seal the sensing control components in the ball covers; the ball cover (1-9) is internally provided with a fixed hinge point (1-7), a centrifugal weight (1-3), a hinge point sliding sleeve passage contact (1-4), an open contact (1-5), a fixed contact connecting rod (1-6), a fixed hinge point (1-7) and a connecting rod lower hinge point (1-8) combined sensing component; a vertical support rod supporting ring frame is arranged below the rotating shaft (1-2), namely a switching sensing part for supporting breeze power generation wind speed sensing control; the oil and water meson thermal energy storage container (4) is internally provided with a breeze electric heater (4-1) and a net electric heater (4-2), and the breeze electric heater (4-1) and the net electric heater (4-2) are respectively communicated with the relay controller.

2. A breeze power generation and heat storage device according to claim 1, wherein the wind speed sensing control comprises a fan blade (1-1), a rotating shaft (1-2), a centrifugal weight (1-3), a hinge point sliding sleeve passage contact (1-4), an open contact (1-5), a fixed contact connecting rod (1-6), a fixed hinge point (1-7), a connecting rod lower hinge point (1-8) and a spherical cover (1-9).

3. The breeze power generation and heat storage device according to claim 1, wherein the breeze power generator comprises a blade combination (3-1), a blade shaft (3-1-1), a blade plate (3-1-2), a blade transposition limiting seat (3-1-3) and a blade shaft seat (3-1-4); the device comprises a transmission shaft (3-2), a bearing (3-3), a coupler (3-4), a speed increasing gear train (3-5) and a permanent magnet direct current generator (3-6).

4. A breeze power generation heat storage device according to claim 1, characterized in that the spherical cap (1-9) is in a closed state, and is provided with a ring frame support outside.

5. The breeze power generation and heat storage device according to claim 1, wherein the oil and water meson thermal energy storage container (4) is respectively provided with an injection port (4-3) and an output port (4-4).