CN113153638A

CN113153638A - Wind-solar complementary continuous hillside power generation device

Info

Publication number: CN113153638A
Application number: CN202110577421.0A
Authority: CN
Inventors: 巴雅尔图
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-05-26
Filing date: 2021-05-26
Publication date: 2021-07-23

Abstract

The invention discloses a wind-solar complementary continuous hillside power generation device, which comprises a horizontal air duct, a reducing air duct, a bent pipe, a hillside air duct assembly and an induced air duct which are sequentially connected from the foot of a hill to the top of the hill; the invention has the beneficial effects that: the invention utilizes the temperature difference and the pressure difference of a large echelon generated by a mountain and the transverse wind power of the mountain top as power to generate electricity, thereby not only effectively making up the limitation of the common wind power generation, but also solving the defect that the photovoltaic power generation can not generate electricity at night, and leading the electricity generation by utilizing clean energy to be more continuous and stable.

Description

Wind-solar complementary continuous hillside power generation device

The technical field is as follows:

the invention relates to the technical field of power generation by utilizing clean energy, in particular to a wind-solar complementary continuous hillside power generation device.

Background art:

wind power generation technology is mature day by day and is widely applied to areas with good wind resources; however, the following problems are common to wind power generation: 1. when no wind exists, the wind power cannot generate electricity normally; 2. wind power in China is mostly distributed in wind gap zones such as grasslands, plateaus or hills, and the difference of wind power resources is overlarge along with the change of seasons, but the China is a mountainous country, in fact, the wind power resources on the top of a mountain are more stable and continuous, the wind power resources are better, but the establishment of a wind power generation facility on the top of the mountain is not practical, because the diameter of a fan blade is as high as hundreds of meters, the weight is as high as hundreds of tons, and the wind power generation facility cannot be realized under the prior art condition; another very popular power generation technology is photovoltaic power generation, but photovoltaic power generation also has the following disadvantages: the power generation can not be carried out in rainy days or nights, the power generation can not be continued, and the power generation efficiency is lower; therefore, a concept of using air convection generated by the difference between the temperatures of high mountains to realize continuous power generation has been proposed, and the basic principle is mainly based on the "Stack effect" generated by the difference between the atmospheric pressure and the difference between the atmospheric temperatures: the phenomenon that air is quickly diffused or discharged out of a building along a channel under the action of density difference (temperature difference and pressure difference) in the building and the structure with a shared atrium, a vertical ventilation air duct, a staircase and the like which have similar chimney characteristics, namely a smooth circulation space from the bottom to the top is referred to as a chimney effect; or the phenomenon that the air in the house rises or falls along the space with vertical gradient to cause the air to strengthen convection; there are many examples of electricity generation using this principle around the world: for example, the German designer and construction engineering company Schlaich Bergermann and Partner, in conjunction with the Spanish government, established the world's first solar chimney experimental plant with 50kW of generated power in La Mancha desert around Manzanares at 150km in the south Madire of Spanish; the first solar chimney power generation model in China is built in 2002 for 12 months such as Yanjia width of Chinese science and technology university in China, and the ascending air flow in the chimney can push the generator to normally operate to generate power in sunny days; chinese patent application No. CN200910173004.9 discloses a device for generating electricity comprehensively by atmospheric gradient temperature difference and artificial cyclone, which realizes the idea of generating electricity by convection generated by air temperature difference and pressure difference; it still has the following problems: 1. the continuous power generation function is poor, and the condition of low wind speed also occurs at the top of a mountain occasionally, so that the blades are difficult to push for power generation; 2. since the temperature drops by 0.6 degrees per 100 m rise in altitude, that is, the temperature difference of a hill is not about 10 degrees celsius even if the altitude difference exceeds 1500 m, kinetic energy due to air convection generated only by the altitude difference is limited, and the power generation efficiency is to be further improved.

The invention content is as follows:

the invention aims to provide a wind-solar complementary continuous hillside power generation device.

The invention comprises the following contents: a wind-solar complementary continuous hillside power generation device comprises a horizontal air duct, a reducing air duct, a bent pipe, a hillside air duct assembly and an air inducing duct which are connected in sequence from the bottom of a mountain foot to the top of the mountain, wherein the horizontal air duct and the reducing air duct are horizontally arranged on the horizontal ground under the mountain foot, an air exhaust blade is arranged in the horizontal air duct, a wind generating set is arranged at the reducing position of the reducing air duct, a heat storage tank is laid below the hillside air duct assembly, heat storage materials are arranged in the heat storage tank, the bottom of the hillside air duct assembly is attached to the heat storage materials, the hillside is an upward hillside, the slope of the hillside is more than 40 degrees, the vertical height of the hillside is more than 800 meters, the air inducing duct is arranged on the top of the mountain, the air inducing duct comprises an obliquely arranged connecting duct section and a vertically arranged air inducing duct section, the connecting duct section is connected with the hillside air duct assembly, and the air inducing blade is arranged in the air inducing duct section, the outer sleeve of the induced draft tube section is provided with a rotary sleeve, the rotary sleeve is rotatably connected with the induced draft tube section through a bearing, the outer wall of the rotary sleeve is fixedly connected with a connecting rod radially outwards, the other end of the connecting rod is horizontally provided with an induced draft tube, an auxiliary wind generating set is arranged in the induced draft tube, and the auxiliary wind generating set drives the induced draft blades to rotate.

Furthermore, hillside dryer subassembly includes a plurality of dryer of installing in proper order from the hillside bottom to hillside top, all installs the expansion joint between arbitrary adjacent dryer.

Furthermore, a protective cover with a semicircular cross section is covered on the hillside air duct assembly, the protective cover is fixedly connected with the heat storage tank, the heat storage material is located in the protective cover, and the protective cover is made of transparent materials.

Furthermore, the heat storage material is iron ore powder.

Furthermore, a magnet piece is arranged on the outer edge of the back of the air exhaust blade, a plurality of electromagnets matched with the magnet piece are fixedly inserted on the outer wall of the horizontal air duct, and the magnet piece and the electromagnets repel each other to enable the air exhaust blade to obtain rotary thrust.

Furthermore, a photovoltaic power generation device is installed on the horizontal air duct and is electrically connected with the electromagnet.

Furthermore, a ring gear is coaxially installed on the outer wall of the rotating sleeve, the ring gear is meshed with a driving gear, the driving gear is in transmission connection with a motor through a transmission shaft, the motor is electrically connected with an auxiliary wind generating set, an intelligent wind vane device is further installed on the wind collecting cylinder, a wind direction sensor and a controller are arranged in the intelligent wind vane device, the wind direction sensor is electrically connected with the controller, and the controller is electrically connected with the motor.

Furthermore, a winch device and a pulley device are respectively installed at the bottom end and the top end of the hillside.

Furthermore, roller ways are hinged to the two sides of the heat storage tank.

Furthermore, the roller bed wheel assembly further comprises a detachable roller bed wheel assembly matched with the roller bed, the roller bed wheel assembly comprises two semicircular fixing rings, the two fixing rings are buckled on the air duct through bolts, an L-shaped mounting rod is mounted on the fixing rings, a roller bed wheel is mounted on the mounting rod, and when the roller bed is in an upright state, the roller bed wheel can roll on the roller bed to walk.

The invention has the beneficial effects that: 1. the invention utilizes the temperature difference and the pressure difference of a large echelon generated by a mountain and the transverse wind power of the mountain top as power to generate electricity, thereby not only effectively making up the limitation of the common wind power generation, but also solving the defect that the photovoltaic power generation can not generate electricity at night, and utilizing clean energy to generate electricity more continuously and stably; 2. according to the invention, the heat storage tank device is designed at the bottom of the hillside air duct assembly, and the heat storage material is filled in the heat storage tank Europe, the heat storage material absorbs a large amount of heat in the daytime, and the heat storage material releases heat to heat the hillside air duct device when the temperature is reduced at night, so that the temperature difference in the hillside air duct assembly is increased, and the power generation efficiency is improved; 3. according to the invention, the small auxiliary wind generating set is designed in the wind collecting barrel at the top of the mountain, so that the auxiliary wind generating set can generate power even if the wind power at the top of the mountain is small occasionally, and the induced air blades are powered to prevent the induced air blades from stopping due to undersize wind power, thereby ensuring continuous power generation; 4. a magnetic auxiliary blade is designed in the horizontal air duct, and a photovoltaic power generation device is designed to magnetize an electromagnet, so that the power generation efficiency is further improved.

Description of the drawings:

FIG. 1 is a perspective view of the present invention;

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

FIG. 3 is a top view of the present invention;

FIG. 4 is a left side view of the present invention;

FIG. 5 is a perspective view of the internal structure of the present invention;

FIG. 6 is an enlarged view of part A of FIG. 2;

FIG. 7 is an enlarged view of the portion B of FIG. 4;

FIG. 8 is a cross-sectional view taken along D-D of FIG. 2;

FIG. 9 is a perspective view of the heat storage tank of the present invention;

FIG. 10 is a perspective view of a detachable roller wheel assembly of the present invention;

FIG. 11 is a control block diagram of the intelligent wind vane device of the present invention;

in the figure, a horizontal air duct 1, a diameter-reducing air duct 2, an induced draft blade 3, a bent pipe 4, a wind generating set 5, an air duct 6, a heat storage material 7, an air supply blade 8, an induced draft duct 9, an induced draft duct section 10, a rotating sleeve 11, an air collection duct 12, an auxiliary wind generating set 13, an expansion joint 14, a magnet piece 15, an electromagnet 16, a photovoltaic generating device 17, a protective cover 18, a heat storage tank 19, a ring gear 20, a driving gear 21, an intelligent wind vane device 22, an electric motor 23, a wind direction sensor 24, a controller 25, a winch device 26, a pulley device 27, a roller way 28, a fixed ring 29 and a roller way wheel 30.

The specific implementation mode is as follows:

example 1:

as shown in fig. 1, fig. 2, fig. 3, fig. 5, fig. 6 and fig. 8, the wind-solar complementary continuous hillside power generation device comprises a horizontal wind barrel 1, a reducing wind barrel 2, a bent pipe 4, a hillside wind barrel assembly and a wind inducing barrel 9 which are connected in sequence from the foot of a hill to the top of the hill, wherein the horizontal wind barrel 1 and the reducing wind barrel 2 are both horizontally arranged on the horizontal ground under the foot of the hill, a wind supply blade 8 is arranged in the horizontal wind barrel 1, a wind generating set 5 is arranged at the reducing position of the reducing wind barrel 2, the reducing is favorable for increasing the wind speed so as to increase the generated energy, a heat storage tank 19 is laid below the hillside wind barrel assembly, a heat storage material 7 is arranged in the heat storage tank, the bottom of the hillside wind barrel assembly is attached to the heat storage material, the heat storage material absorbs a large amount of heat in daytime, and releases heat to heat the hillside wind barrel to heat storage device when the temperature is reduced at night, thereby increasing the temperature difference in the hillside wind tube assembly and improving the power generation efficiency; the slope is a sunny slope, the slope of the slope is greater than 40 degrees, the vertical height of the slope is greater than 800 meters, the air draft tube 9 is arranged on the top of the mountain, the air draft tube 9 comprises a connecting tube section which is obliquely arranged and an air draft tube section 10 which is vertically arranged, the connecting tube section is connected with the slope air draft tube assembly, the air draft tube section 10 is internally provided with an air draft blade 3, the air draft tube section 10 is externally sleeved with a rotating sleeve 11, the rotating sleeve 11 is rotatably connected with the air draft tube section 10 through a bearing, the outer wall of the rotating sleeve 11 is fixedly connected with a connecting rod which is radially outward, the other end of the connecting rod is horizontally provided with an air collecting tube 12, the air collecting tube 12 is internally provided with an auxiliary wind generating set 13, the auxiliary wind generating set 13 drives the air draft blade 3 to rotate, and the auxiliary wind generating set is small, even if the wind power at the top of a mountain is small occasionally, the auxiliary wind generating set can be used for generating power and storing energy, power is provided for the induced wind blades to prevent the induced wind blades from stopping due to undersize wind power, and therefore continuous power generation is guaranteed; the hillside air duct assembly comprises a plurality of air ducts 6 which are sequentially arranged from the bottom end of a hillside to the top end of the hillside, expansion joints 14 are arranged between any adjacent air ducts 6, and the expansion joints 14 can well adapt to the phenomenon of thermal barrier contraction caused by temperature change; a protective cover 18 with a semicircular cross section is covered on the hillside air duct assembly, the protective cover 18 is fixedly connected with the heat storage groove 19, the heat storage material 7 is positioned in the protective cover 18, and the protective cover 18 is made of a transparent material; the transparent protective cover 18 has a rainproof function, the transparent material does not influence the heat absorption of the heat storage material 7 in the daytime, and the heat storage material 7 is iron ore powder.

Example 2:

as shown in fig. 1, fig. 2, fig. 3, fig. 5, fig. 6 and fig. 8, the wind-solar complementary continuous hillside power generation device comprises a horizontal wind barrel 1, a reducing wind barrel 2, a bent pipe 4, a hillside wind barrel assembly and a wind inducing barrel 9 which are connected in sequence from the foot of a hill to the top of the hill, wherein the horizontal wind barrel 1 and the reducing wind barrel 2 are both horizontally arranged on the horizontal ground under the foot of the hill, a wind supply blade 8 is arranged in the horizontal wind barrel 1, a wind generating set 5 is arranged at the reducing position of the reducing wind barrel 2, the reducing is favorable for increasing the wind speed so as to increase the generated energy, a heat storage tank 19 is laid below the hillside wind barrel assembly, a heat storage material 7 is arranged in the heat storage tank, the bottom of the hillside wind barrel assembly is attached to the heat storage material, the heat storage material absorbs a large amount of heat in daytime, and releases heat to heat the hillside wind barrel to heat storage device when the temperature is reduced at night, thereby increasing the temperature difference in the hillside wind tube assembly and improving the power generation efficiency; the slope is a sunny slope, the slope of the slope is greater than 40 degrees, the vertical height of the slope is greater than 800 meters, the air draft tube 9 is arranged on the top of the mountain, the air draft tube 9 comprises a connecting tube section which is obliquely arranged and an air draft tube section 10 which is vertically arranged, the connecting tube section is connected with the slope air draft tube assembly, the air draft tube section 10 is internally provided with an air draft blade 3, the air draft tube section 10 is externally sleeved with a rotating sleeve 11, the rotating sleeve 11 is rotatably connected with the air draft tube section 10 through a bearing, the outer wall of the rotating sleeve 11 is fixedly connected with a connecting rod which is radially outward, the other end of the connecting rod is horizontally provided with an air collecting tube 12, the air collecting tube 12 is internally provided with an auxiliary wind generating set 13, the auxiliary wind generating set 13 drives the air draft blade 3 to rotate, and the auxiliary wind generating set is small, even if the wind power at the top of a mountain is small occasionally, the auxiliary wind generating set can be used for generating power and storing energy, power is provided for the induced wind blades to prevent the induced wind blades from stopping due to undersize wind power, and therefore continuous power generation is guaranteed; as shown in fig. 4 and 7, a magnet piece 15 is installed on the outer edge of the back surface of the air supply blade 8, a plurality of electromagnets 16 matched with the magnet piece 15 are fixedly inserted and connected to the outer wall of the horizontal air duct 1, and the magnet piece 15 and the electromagnets 16 repel each other to enable the air supply blade 8 to obtain a rotating thrust; a photovoltaic power generation device 17 is arranged on the horizontal air duct 1, and the photovoltaic power generation device 17 is electrically connected with the electromagnet 16; a magnet piece 15 is arranged on the outer edge of the back of the air supply blade 8, a plurality of electromagnets 16 matched with the magnet piece 15 are fixedly inserted on the outer wall of the horizontal air duct 1, and the magnet piece 15 and the electromagnets 16 are mutually repelled to enable the air supply blade 8 to obtain the rotary thrust; a photovoltaic power generation device 17 is arranged on the horizontal air duct 1, and the photovoltaic power generation device 17 is electrically connected with the electromagnet 16; the magnetic-assisted blade design can further improve the power generation efficiency.

Example 3:

as shown in fig. 1, fig. 2, fig. 3, fig. 5, fig. 6 and fig. 8, the wind-solar complementary continuous hillside power generation device comprises a horizontal wind barrel 1, a reducing wind barrel 2, a bent pipe 4, a hillside wind barrel assembly and a wind inducing barrel 9 which are connected in sequence from the foot of a hill to the top of the hill, wherein the horizontal wind barrel 1 and the reducing wind barrel 2 are both horizontally arranged on the horizontal ground under the foot of the hill, a wind supply blade 8 is arranged in the horizontal wind barrel 1, a wind generating set 5 is arranged at the reducing position of the reducing wind barrel 2, the reducing is favorable for increasing the wind speed so as to increase the generated energy, a heat storage tank 19 is laid below the hillside wind barrel assembly, a heat storage material 7 is arranged in the heat storage tank, the bottom of the hillside wind barrel assembly is attached to the heat storage material, the heat storage material absorbs a large amount of heat in daytime, and releases heat to heat the hillside wind barrel to heat storage device when the temperature is reduced at night, thereby increasing the temperature difference in the hillside wind tube assembly and improving the power generation efficiency; the slope is a sunny slope, the slope of the slope is greater than 40 degrees, the vertical height of the slope is greater than 800 meters, the air draft tube 9 is arranged on the top of the mountain, the air draft tube 9 comprises a connecting tube section which is obliquely arranged and an air draft tube section 10 which is vertically arranged, the connecting tube section is connected with the slope air draft tube assembly, the air draft tube section 10 is internally provided with an air draft blade 3, the air draft tube section 10 is externally sleeved with a rotating sleeve 11, the rotating sleeve 11 is rotatably connected with the air draft tube section 10 through a bearing, the outer wall of the rotating sleeve 11 is fixedly connected with a connecting rod which is radially outward, the other end of the connecting rod is horizontally provided with an air collecting tube 12, the air collecting tube 12 is internally provided with an auxiliary wind generating set 13, the auxiliary wind generating set 13 drives the air draft blade 3 to rotate, and the auxiliary wind generating set is small, even if the wind power at the top of a mountain is small occasionally, the auxiliary wind generating set can be used for generating power and storing energy, power is provided for the induced wind blades to prevent the induced wind blades from stopping due to undersize wind power, and therefore continuous power generation is guaranteed; the hillside air duct assembly comprises a plurality of air ducts 6 which are sequentially arranged from the bottom end of a hillside to the top end of the hillside, expansion joints 14 are arranged between any adjacent air ducts 6, and the expansion joints 14 can well adapt to the phenomenon of thermal barrier contraction caused by temperature change; the slope wind tube assembly is covered with a protective cover 18 with a semicircular cross section, the protective cover 18 is fixedly connected with the heat storage groove 19, the heat storage material 7 is located in the protective cover 18, the protective cover 18 is made of transparent materials, the transparent protective cover 18 has a rainproof function, and the transparent materials do not influence the heat storage material 7 to absorb heat in the daytime; the heat storage material 7 is iron ore powder; as shown in fig. 4 and 7, a magnet piece 15 is installed on the outer edge of the back of the air supply blade 8, a plurality of electromagnets 16 matched with the magnet piece 15 are fixedly inserted on the outer wall of the horizontal air duct 1, the magnet piece 15 and the electromagnets 16 repel each other to enable the air supply blade 8 to obtain a rotating thrust, a photovoltaic power generation device 17 is installed on the horizontal air duct 1, the photovoltaic power generation device 17 is electrically connected with the electromagnets 16, and the power generation efficiency can be further improved by the design of magnetically assisted blades; as shown in fig. 6 and 11, a ring gear 20 is coaxially installed on the outer wall of the rotating sleeve 11, the ring gear 20 is engaged with a driving gear 21, the driving gear 21 is in transmission connection with a motor 23 through a transmission shaft, the motor is electrically connected with the auxiliary wind turbine generator set 13, an intelligent wind vane device 22 is further installed on the wind collecting barrel 12, a wind direction sensor 24 and a controller 25 are arranged in the intelligent wind vane device 22, the wind direction sensor 24 is electrically connected with the controller 25, the controller 25 is electrically connected with the motor 23, the intelligent wind vane device 22 can intelligently control the rotating sleeve 11 to rotate to adapt to the wind direction, the wind direction sensor 24 senses the wind direction signal and converts the wind direction signal into an electric signal to be transmitted to the controller 25 during operation, the controller 25 controls the motor 23 to rotate to adjust the windward direction of the wind collecting barrel 12, and the auxiliary wind turbine generator set 13 is the wind direction sensor 24, The controller 25 and the motor 23 provide power; as shown in fig. 9 and 10, a winch device 26 and a pulley device 27 are respectively installed at the bottom end and the top end of the hillside; roller ways 28 are hinged to the two sides of the heat storage tank 19; it still include with the detachable roller way wheel subassembly of roller way 28 assorted, the roller way wheel subassembly includes two semicircular fixed ring 29, two fixed ring 29 passes through the bolt lock and is in on the dryer 6 gu install the installation pole of L shape on the fixed ring 29 install roller way wheel 30 on the installation pole, work as when roller way 28 is in the state of standing vertically, roller way wheel 30 can roll the walking on roller way 28.

The present invention is not limited to the above preferred embodiments, and any modifications, equivalent substitutions, improvements, etc. within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A wind-solar complementary continuous hillside power generation device is characterized in that: the power generation device comprises a horizontal air duct (1), a reducing air duct (2), a bent pipe (4), a hillside air duct assembly and an air inducing duct (9) which are connected in sequence from the bottom of a hill to the top of the hill, wherein the horizontal air duct (1) and the reducing air duct (2) are horizontally arranged on the horizontal ground under the hill, an air supply blade (8) is arranged in the horizontal air duct (1), a wind generating set (5) is arranged at the reducing position of the reducing air duct (2), a heat storage tank (19) is laid below the hillside air duct assembly, a heat storage material (7) is arranged in the heat storage tank, the bottom of the hillside air duct assembly is attached to the heat storage material, the hillside is a sunny hillside, the slope of the hillside is more than 40 degrees, the vertical height of the hillside is more than 800 meters, the air inducing duct (9) is arranged on the top of the hill, the air inducing duct (9) comprises a connecting duct section which is arranged in an inclined manner and an air inducing duct section (10) which is arranged vertically, the connecting cylinder section with the hillside dryer subassembly is connected, install induced air blade (3) in induced air section of thick bamboo section (10) overcoat is equipped with swivel sleeve (11), swivel sleeve (11) through the bearing with induced air section of thick bamboo section (10) swivelling joint the radial outside fixedly connected with connecting rod of the outer wall of swivel sleeve (11) the other end horizontally of connecting rod installs air collection section of thick bamboo (12) install supplementary wind generating set (13) in air collection section of thick bamboo (12), supplementary wind generating set (13) drive induced air blade (3) are rotatory.

2. The wind-solar hybrid continuous hillside power generation device according to claim 1, wherein: the hillside air duct assembly comprises a plurality of air ducts (6) which are sequentially arranged from the bottom end of the hillside to the top end of the hillside, and expansion joints (14) are arranged between every two adjacent air ducts (6).

3. The wind-solar hybrid continuous hillside power generation device according to claim 1, wherein: the hillside dryer subassembly is gone up to cover and is had cross section semicircular safety cover (18), safety cover (18) with heat storage tank (19) fixed connection, heat-retaining material (7) are located in safety cover (18), safety cover (18) are made by transparent material.

4. The wind-solar complementary continuous hillside power generation device according to any one of claims 1 to 3, wherein: the heat storage material (7) is iron ore powder.

5. The wind-solar hybrid continuous hillside power generation device according to claim 1, wherein: the back outer edge of the air supply blade (8) is provided with a magnet piece (15), the outer wall of the horizontal air duct (1) is fixedly inserted with a plurality of electromagnets (16) matched with the magnet piece (15), and the magnet piece (15) and the electromagnets (16) are mutually repelled to enable the air supply blade (8) to obtain rotary thrust.

6. The wind-solar hybrid continuous hillside power generation device according to claim 5, wherein: the horizontal air duct (1) is provided with a photovoltaic power generation device (17), and the photovoltaic power generation device (17) is electrically connected with the electromagnet (16).

7. The wind-solar hybrid continuous hillside power generation device according to claim 1, wherein: ring gear (20) are coaxially installed on the outer wall of rotary sleeve (11), ring gear (20) and drive gear (21) meshing, drive gear (21) are connected with motor (23) transmission through the transmission shaft, the motor with supplementary wind generating set (13) electricity is connected, still installs intelligent wind vane device (22) on wind-collecting barrel (12), intelligence wind vane device (22) embeds there are wind direction sensor (24) and controller (25), wind direction sensor (24) are connected with controller (25) electricity, controller (25) with motor (23) electricity is connected.

8. The wind-solar hybrid continuous hillside power generation device according to any one of claims 1 to 7, wherein: and a winch device (26) and a pulley device (27) are respectively arranged at the bottom end and the top end of the hillside.

9. The wind-solar hybrid continuous hillside power generation device of claim 8, wherein: roller ways (28) are hinged to the two sides of the heat storage tank (19).

10. The wind-solar hybrid continuous hillside power generation device of claim 9, wherein: it still include with roll table (28) assorted detachable roll table wheel subassembly, the roll table wheel subassembly includes two semicircular fixed ring (29), two fixed ring (29) are in through the bolt lock on dryer (6) install the installation pole of L shape on fixed ring (29) install roll table wheel (30) on the installation pole, work as when roll table (28) are in the upright state, roll table wheel (30) can roll the walking on roll table (28).