TW202122677A - This equipment is barrel type wine power generator set equip with wine flow guide vane. use multi-machine series connect together into a tunnel of air duct. it connects between the ground and high altitude. the air pressure and temperature are difference between the ground and the high altitude and high altitude form a continuous cyclone wind flow. this continuous cyclone wind flow through this tunnel under inlet filter and control equipment and outlet equip induct deliver fan can turn ran each wine power generator to product electricity. - Google Patents

Abstract

This equipment is barrel type wine power generator set equip with wine flow Guide Vane. Use multi-machine series connect together into a tunnel of air duct. It connects between the ground and high altitude. The air pressure and temperature are difference between the ground and the high altitude form a continuous cyclone wind flow. This continuous cyclone wind flow through this tunnel. Under inlet filter and control equipment. The filter can filter dust and impurities from cyclone wind. The inlet control equipment can control the amount of cyclone wind to adjust total outlet Power electricity. At exhaust duct equips with Induct Deliver Fan to increate outlet amount of cyclone wind. The sunshade cover prevents rainwater entering the air duct.

Description

Single-machine single-tube diversion wind turbines and multiple machines are connected to the ground and high in a series of artificial tornado ducts. A continuous tornado wind is formed by the air pressure and temperature difference between the ground and the high altitude. The inlet is equipped with filtering and control equipment and the outlet is equipped with guides. Fan, a device used to control and drive the generators in the air duct to generate electricity.

The invention belongs to technologies and automatic control systems related to atmospheric science, fluid machinery, tunneling civil engineering, construction engineering, environmental protection engineering, power generation and transformation engineering, welding technology, anti-rust engineering, tunnel excavation and construction engineering, wind power generation, etc. Combine.

Previously used wind turbines only rely on the atmospheric flow of the same gas layer to drive a single impeller wind turbine to generate electricity, and a single unit is independent of each other, and cannot be effectively and continuously generated for a long time under the influence of seasonal wind.

Single-unit single-cylinder wind-driven generators are connected in series to form an artificial tornado air duct (138). The terrain connects the ground to the high-altitude air in the mountains. The air pressure and temperature difference between the two points naturally form an artificial tornado air duct, and the air duct is endless. The rising wind of the tornado can drive each diversion wind turbine (16) in the air duct to run and generate electricity. A filter (4) and control equipment (2, 9, 11) are installed at the inlet to filter the inflow air duct. It can control the air volume of the air duct to control the total output of the series-connected diversion wind turbine of the whole machine, which can be operated in accordance with the needs of the system. The installation of an induced draft fan (32) at the outlet end can increase the suction at high altitude, increase the tornado volume and increase the output. The special structure of the horn-shaped exhaust port (139) and the sunshade (154) forms a flat nozzle air outlet (140). ) To follow the air flow.

Man-made tornado air duct construction method:

1. Tunnel excavation type: According to the selected ground point and the relative altitude high mountain point, the tunnel excavation type is used to construct a connecting air duct directly from the ground to a single or multi-level mountain fixed point, and a monotube type is installed in the air duct Diversion wind turbines are connected in series to form an artificial tornado diversion wind turbine group assembly, which is called "tunnel excavation type multi-machine single-tube wind turbines in series to form an artificial tornado wind turbine group assembly."

Use low, medium, and high single mountain (25), or multiple low, medium, and high-altitude mountains (26) with relatively solid topographic features to excavate from the ground level through low, medium, and high-altitude mountain topography (26, 138), deep excavation to reach the predetermined altitude above the vertical ground relative to the point, while digging and strengthening works. At the same time, another group of engineering teams excavated vertically downwards from a selected point at a predetermined altitude, carried out reinforcement works (26, 138) while digging, and met at opposite points on the vertical ground. In addition to the size of the excavated air duct that can be installed with artificial tornado air ducts, maintenance and operation space must be reserved in the duct. After the horizontal and vertical air ducts are connected, the horizontal air ducts are installed from the inside to the outside (the vertical ducts are from bottom to top) with reinforced giant steel pipes, and they are erected with steel bars and high-pressure concrete mortar to ensure the horizontal ducts and vertical ducts. The straight air duct will not deform or collapse. After the installation of the giant steel pipes in the air duct is completed, the entire line will be reinforced with high-pressure concrete mortar. After the erection of the giant steel pipes in the vertical duct is completed, the horizontal tunnels are all strong round steel pipes, so the horizontal tunnel is excavated. The crown block and the unit support frame of the internal structure (31) of the tornado duct are all welded by structural steel and the position of the unit support frame (170) is set. First, the position of the crown block support frame (176) is welded and completed. The complete set of overhead crane (31) is installed to facilitate the hoisting operation of the unit, and then the horizontally erected single-unit single-tube diversion wind turbine support frame (199) is welded and completed. Starting from the air intake main shut-off valve (11), a single-tube diversion wind turbine assembly is connected to the connection with the vertical tunnel. The bottom of the horizontal tunnel is constructed with a steel frame for the horizontal air duct. And a conveyor belt system (198), supported into a steel pavement to facilitate the entry and exit of the crew and personnel. A variety of pipelines are laid under the road surface for cable ducts, control system cable ducts, tap water source ducts, compression and instrument control air ducts , Fresh air supplementary pipe trenches, sanitary sewer pipe trenches and fire-fighting system laying pipe trenches, etc.

The vertically excavated tunnels are all strong round steel pipes, so the freight elevator and the unit support frame (141) are welded by structural steel. Set the position of the unit support frame, and first weld the position of the freight elevator support frame. The complete set of freight elevator is installed to facilitate the hoisting operation of the unit, and then the support frame (138) of the vertical erection unit is welded to complete. Starting from the intersection of the horizontal and vertical tunnels, install the unit from top to bottom, use the freight elevator to lift the unit to the position to be installed, use the lifting equipment to move the unit to the set position to lock it, and at the same time, the steel The cable collar (135) is sleeved on the horn (134), and is connected with the counterweight (137) across the pulley (136) to reduce the force of the unit's axial sagging. The bottom of the vertical tunnel is erected with a steel structure for laying a variety of pipes, which can be used for cable ducts, control system cable ducts, tap water source ducts, compressed air ducts, fresh air supplement ducts, sanitary sewer ducts and fire-fighting system laying ducts Wait.

The intake end is equipped with an intake chamber (1), an intake muffler chamber (36), and an intake first blocking valve (2), intake filter group (4), intake air capture machine (6), intake second blocking valve (9), intake main shut-off valve (11), horn-type exhaust port (139) ) Install a supercharged induced draft fan (32) and a flat-disc nozzle air outlet (140) to form a full set of artificial tornado wind diversion generator group assembly (23), with a filter and control equipment at the inlet, The outlet is equipped with an induced draft fan to increase the flow of the air duct, which can be used to generate large electricity!

2. Ground laying operations: use low, medium and high-altitude mountainous terrain with relatively hard soil, erect support frames along the terrain, and use the series connection of single-tube diversion wind turbine assemblies to erect from the ground to high-altitude In the mountains, a giant man-made tornado diversion wind turbine group (23) is formed. The site of the tornado air duct needs to be sorted out. A large platform should be excavated from the top. If the soil and rock need to be improved, if necessary, the soil and rock should be transported down the mountain by gravity, and the graded sand should be moved up the mountain at the same time. After the large platform is dug, it is spread with graded stone. If necessary, an adhesive is added to prevent the platform from becoming soft and collapse in the rain. After fixing it, the platform can be excavated. The bottom of each machine support frame must be sufficient. At the same time, the steel bar cage is made on this platform. After the hole is dug, the steel cage can be inserted into the hole to be grouted to make the fixed chip. After the fixed chip is completed, the top steel bar will be broken and bent to a level. Then the steel bars are welded to make the framework of the platform. After the slab is set up around it, the slab mold is set up and then grouted with high compressive concrete slurry to form the platform. The fixed foundation of the support frame is reserved on the platform. The top steel bar of the fixed plinth of the foundation is opened up and straightened and welded to continue the steel structure of the steel bar and erect the supporting column. The fixed slab mold can be poured with high compressive cement and soil slurry to form a supporting column (199).

After pouring the support frame up to a certain design height, tie the steel bars and the surrounding structural steel frame according to the terrain and the designed inclination. A steel beam needs to be installed underneath to support the weight of the steel frame. To support each stand-alone single-cylinder diversion wind turbine, a hanging support frame (133) and pulleys (136) must be made on both sides of the body support base (199) to control each stand-alone single-cylinder The force of the axially downward sliding of the guided wind turbine (20) is balanced by the hanging weight (137).

In this way, the platform is made layer by layer until it reaches the foot of the mountain. The foot of the mountain also needs to be made in this way. The surface soil needs to be removed in the above way, and then backfilled with gradation. If necessary, add an adhesive to prevent the platform from encountering. When it rains, it becomes soft and collapses. After fixing it, you can start to excavate the fixed hole of the platform. The base (200) of the bottom of the intake valve installed at the inlet end of the air duct must have sufficient fixed holes, and the air inlet muffler chamber ( 36). The air intake filter (4) and various gas trap equipment (6) are all set on the same platform. For air-circular houses (1), the bottom locking bolts (58, 59) need to be supported by the anchor), and the steel cage can be inserted into the anchor hole to be grouted to make the anchor. After the anchor is completed, the top of the anchor is reinforced Disperse and bend it into a horizontal shape, then connect steel bars and weld it to make the framework of this platform. After the slab is set up around it, grouting with high compressive concrete slurry is used to make it into a platform. The fixed foundation of the support frame is reserved on the platform. Base, open the top steel bar of the fixed plinth of this base, straighten up the steel structure of the continuous steel bar and erect the supporting column, the fixed plate form can be poured with high compressive cement and soil slurry to form a supporting column, let in Airway silencing chamber (36), intake filter (4), various gas trap equipment (6) and imported round house (1) can be installed in this support column and locking bolts (58, 59) to support Seat (57).

There are often clouds and fog on the top of the mountain. These clouds can accumulate enough energy after a period of sunlight. This is the largest solar cell group in nature. If this solar energy can be received and utilized, it will be of great use. In order to achieve this, the umbrella roof of the exhaust outlet is divided into ten equal parts to install a supporting fixing frame (161). This fixing frame needs to be isolated by insulating barriers to prevent lightning surges from directly impacting the entire unit. Each fixing frame A round copper ball (155) is installed on the top, and a copper arc tube (157) is connected between each copper ball to form a round tube, so that the spheres are connected together, and a wire is installed on the arc tube (159, 160) with insulating skin, connected to the large resistor group (162), large capacitor group (211), and then connected Go to the compressed battery pack (212), use two conductive balloons (122), fill with helium gas to make the balloon lift into the air, and then use the three equiangular installations on the balloon to drive the fan (130) with AI remote control function. ), push the direction of the conductive balloon, push the balloon into the cloud layer, the solar photovoltaic connecting the cloud layer is connected with the copper ball arc tube through the wire (123), and the guided solar photovoltaic power passes through the large resistance group and the large capacitor group The grounding switch (168) is then grounded to release the cloud charge. When the solar photovoltaic power of the cloud is reduced to an acceptable level, the entrance cut-off switch (213) is turned on, and then the grounding switch (168) is opened to make the cloud photoelectricity The resistor group (162) and the large capacitor group (211) are connected to the "solar photovoltaic collection system" of the compressed battery group (212). Before this system is powered on, the inlet cut-off switch (213) must be turned on, and then the grounding switch (168) must be turned on, so that the high-voltage solar photovoltaic system will be grounded first, and then the inlet of the battery group must be cut off after discharging to an acceptable potential. After the cut-off switch (213) is cut in, turn on the grounding switch (168), so that the solar light accumulated in the cloud can be cut off by the copper ball (155) through the large resistor group (162) and the large capacitor group (211) through the entrance. 213) is transmitted into the large compressed battery group (212), and the inlet end of the compressed battery group (212) is connected to a diode, so that lightning can only enter and exit, and prevent the inlet end of the battery pack from being connected to the grounding system during operation. Cause damage. This cloud of solar energy exposed to sunlight can be received and stored from small to large by the installation of the battery pack. After the battery pack is fully charged, another battery pack continues to receive it, and the fully charged battery pack The electric energy can be converted into three-phase alternating current by the DC/AC converter and used in the power system.

51‧‧‧Imported round house roof

52‧‧‧Dome roof pillars

53‧‧‧Inlet air connection outlet

54‧‧‧Roof support frame

55‧‧‧Air Inlet

56‧‧‧Air Inlet Filter

57‧‧‧Inlet chamber round house base

58‧‧‧Inlet chamber dome pillar base

59‧‧‧Inlet chamber dome pillar base fixing bolt

60‧‧‧Inlet pipe and base fixing bolt

61‧‧‧Air duct partition

62‧‧‧Main air duct

63‧‧‧Locking flange

64‧‧‧Block valve gate valve spindle drive motor

65‧‧‧Drive bevel gear of blocking valve, gate valve spindle drive motor

66‧‧‧Block valve gate valve spindle drive bevel gear

67‧‧‧Block valve gate valve spindle

68‧‧‧Block valve gate valve this valve body

69‧‧‧The main air duct blocking valve gate valve is used as a rubber gasket to tighten the valve body

70‧‧‧Compression rubber gasket installed on the edge of the main shut-off valve gate valve body

71‧‧‧Drive motor base

72‧‧‧Inner and outer cylinder support column

73‧‧‧Drive motor

74‧‧‧Coupling

75‧‧‧Bearing

76‧‧‧Ratchet

77‧‧‧Rotating drum

78‧‧‧Drive chain

79‧‧‧Oil tank

80‧‧‧Filter

81‧‧‧Capture shell

82‧‧‧Various gas capture cartridges

83‧‧‧Various gas capture tubes

84‧‧‧Air Inlet

85‧‧‧Air duct partition

86‧‧‧Main air duct

87‧‧‧Locking flange

88‧‧‧Intake main shut-off valve gate valve spindle drive motor

89‧‧‧Bevel gear for main shaft drive motor of intake main shut-off valve gate valve

90‧‧‧Inlet main shut-off valve gate valve spindle drive bevel gear

91‧‧‧Intake main shut-off valve gate valve spindle

92‧‧‧Intake main shut-off valve gate valve This valve body

93‧‧‧Main air duct intake main shut-off valve gate valve as a rubber gasket for tightening the gate valve body

94‧‧‧Pressure rubber gasket installed on the edge of the valve body of the intake main shut-off valve

95‧‧‧Air Inlet

96‧‧‧Inlet connection flange

97‧‧‧First blocking valve

98‧‧‧Isolation board

99‧‧‧Air intake filter set

100‧‧‧Air separator inlet connection flange

101‧‧‧Air Separator

102‧‧‧Air separator outlet connecting cylinder

103‧‧‧Oil tank

104‧‧‧Air separator base

105‧‧‧Connecting cylinder and blocking valve chamber air leakage sealing ring

106‧‧‧Guide Wing

107‧‧‧Support frame

108‧‧‧Inlet air guide wing inner tube

109‧‧‧Inlet guide wing center column

110‧‧‧Outer cylinder of air intake guide wing

111‧‧‧Connecting the air inlet connecting flange

112‧‧‧Shell

113‧‧‧Support frame

114‧‧‧Drive impeller

115‧‧‧Impeller Coupling

116‧‧‧Generator Coupling

117‧‧‧Generator Set

118‧‧‧Wire and control wire outlet box

119‧‧‧Flange connecting with the inlet shut-off valve of the first diversion wind turbine

120‧‧‧Connecting flange with air separator outlet

121‧‧‧Wind Road

122‧‧‧Conductive balloon

123‧‧‧Wire of conductive balloon

124‧‧‧Locking flange

125‧‧‧Wind Road

126‧‧‧Strengthening column

127‧‧‧Locking flange

128‧‧‧Wind Road

129‧‧‧Strengthening Column

130‧‧‧Conductive balloon A1 remote drive fan

133‧‧‧Support hanging ear

134‧‧‧Horn

135‧‧‧Steel cable collar

136‧‧‧Pulley

137‧‧‧Axial sliding gravity counterweight for the whole machine

138‧‧‧Man-made tornado air duct

139‧‧‧Flared exhaust port

140‧‧‧Flat nozzle air outlet

141‧‧‧ Freight elevator bracket

142‧‧‧Connecting cylinder shell

143‧‧‧Flange

144‧‧‧Generator rotor winding

145‧‧‧Generator stator winding

146‧‧‧Generator main circuit breaker

147‧‧‧Generator primary transformer

148‧‧‧Synchronizer

149‧‧‧Bus link main circuit breaker

150‧‧‧Bus

151‧‧‧Permanent Magnet

152‧‧‧Exhaust connection flange

153‧‧‧Support frame

154‧‧‧Sunshade

155‧‧‧Thunder and lightning collect copper balls

156‧‧‧Flange

157‧‧‧Copper ball connecting pipe

158‧‧‧Lightning Collecting Copper Ball Pillar

159‧‧‧Wire Connector

160‧‧‧Wire

161‧‧‧Get the child

162‧‧‧Resistor

163‧‧‧Compressed battery pack

164‧‧‧Load

165‧‧‧Ground wire

166‧‧‧Connecting terminal

167‧‧‧2 polar body

168‧‧‧Connect to the front grounding switch of the battery pack

169‧‧‧Horizontal tornado channel single-tube guide wind turbine

170‧‧‧Diversion wind turbine support frame

171‧‧‧Diversion wind turbine supporting base

172‧‧‧Reinforced concrete base inside horizontal tornado duct

173‧‧‧Horizontal tornado monotube series diversion wind turbine cable trench

174‧‧‧Internal drainage ditch of horizontal tornado

175‧‧‧Crown crane vertical support frame

176‧‧‧Crane Longitudinal Walking Support Drive Group

177‧‧‧Crane Crane Crossarm

178‧‧‧Crane Crane Horizontal Moving Drive Unit

179‧‧‧Crane Crane Hook

180‧‧‧Hanging heavy objects

181‧‧‧Top shelf

182‧‧‧Shell

183‧‧‧Impeller

184‧‧‧Coupling

185‧‧‧Drive motor

186‧‧‧Support frame

187‧‧‧Main power line and control line contact box

188‧‧‧Connecting flange

189‧‧‧Wind Road

190‧‧‧Silence plate frame

191‧‧‧Inlet air flow channel

192‧‧‧Outdoor air intake frame

193‧‧‧Pedestal

194‧‧‧Inlet chamber fixed angle steel

195‧‧‧Upper support frame of air intake silencer block

196‧‧‧The lower support frame of the air intake silencer block

197‧‧‧Muffler panel with dense muffler holes

198‧‧‧Horizontal duct steel frame and conveyor belt

199‧‧‧Single-machine single-tube guide wind turbine support frame

200‧‧‧Intake valve base

201‧‧‧Air duct partition

202‧‧‧Main air duct

203‧‧‧Locking flange

204‧‧‧Intake main shut-off valve gate valve spindle drive motor

205‧‧‧Drive bevel gear for main shaft drive motor of intake main shut-off valve gate valve

206‧‧‧Air intake main shut-off valve gate valve spindle drive bevel gear

207‧‧‧Intake main shut-off valve gate valve spindle

208‧‧‧Intake main shut-off valve gate valve This valve body

209‧‧‧Main air duct intake main shut-off valve gate valve as a rubber gasket for tightening the gate valve body

210‧‧‧The compression rubber pad installed on the edge of the valve body of the intake main shut-off valve

211‧‧‧Large capacitor bank

212‧‧‧Compressed battery pack

213‧‧‧Battery pack inlet cut-off switch

Figure 1 Inlet chamber

Figure 2 First block valve for intake air

Figure 3 Three-dimensional view of the first shut-off valve of the intake air

Figure 4 Air intake filter

Figure 5 Three-dimensional view of air intake filter

Figure 6 Various gas traps

Figure 7 Three-dimensional view of various gas traps

Figure 8 The installation diagram of the first shut-off valve, filter screen and various gas traps

Figure 9 Intake second shutoff valve

Figure 10 Three-dimensional view of the second shutoff valve for intake air

Figure 11 Main intake shut-off valve

Figure 12 Three-dimensional view of intake main shut-off valve

Figure 13 Single-tube intake guide wing

Figure 14 Three-dimensional view of single-cylinder intake guide wing

Figure 15 Single-tube diversion wind turbine

Figure 16 Three-dimensional view of a single-tube diversion wind turbine

Figure 17: Air separator outlet connecting cylinder

Figure 18 Three-dimensional view of the connecting cylinder of the air separator outlet

Figure 19: Schematic diagram of single-unit and single-tube diversion wind turbine assembly

Figure 20: A three-dimensional view of the main components of a single-unit single-tube diversion wind turbine

Figure 21: Schematic diagram of the horizontal series connection of two monotube diversion wind turbines

Figure 22: Schematic diagram of vertical series connection of two monotube diversion wind turbines

Figure 23: Schematic diagram of the multi-unit single-cylinder diversion wind turbine string into a man-made tornado diversion wind turbine group assembly

Figure 24 A single mountain excavated into a tornado tunnel with multiple single-tube diversion wind turbines inside. intention

Figure 25 A schematic diagram of a single high, medium, and low mountain excavation into a tornado tunnel with multiple single-tube diversion wind turbines inside

Figure 26 A schematic diagram of multiple high, medium, and low mountainous areas excavated in series to form a tornado tunnel, with multiple single-tube diversion wind turbines installed inside

Figure 27 Front and side view of connecting cylinders at various angles between units

Figure 28 Winding and wiring diagram of diversion wind turbine

Figure 29 Exhaust port

Figure 30 Lightning Collection System

Figure 31 Schematic diagram of the internal structure of a horizontal mountain excavation tornado tunnel

Figure 32 Schematic diagram of induced draft fan

Figure 33 Three-dimensional view of induced draft fan

Figure 34: Connecting cylinder between main components

Figure 35 Three-dimensional view of the connecting cylinder between the main components

Figure 36 Schematic diagram of the intake silencing chamber

Figure 37 Three-dimensional view of the intake silencing chamber

Figure 38 Intake duct silencer

Figure 39 Three-dimensional view of the intake duct muffler plate

Figure 40 Schematic diagram of the connecting cylinder of the guide wing and the guide wind turbine

Figure 41 Three-dimensional view of the connecting cylinder of the guide wing and the guide wind turbine

Figure 42 Schematic diagram of the outlet coupling cylinder of the diversion wind turbine

Figure 43 Three-dimensional view of the outlet coupling cylinder of the diversion wind turbine

How to turn the theory into reality, let this invention proceed from the selection of the first machine, environmental assessment, engineering planning and design, civil engineering field construction, physical production and field testing, site assembly and various functional tests, and the completion of the entire machine Trial operation: from single machine start, acceleration, constant speed, parallel connection, load increase, full load, load reduction, disconnection, deceleration and full shutdown, start and stop of the whole unit, parallel disconnection, load reduction and full load test, overspeed trip test , The testing of various protection relays of generators and transformers, the implementation of formal commercial operation, operation and maintenance after formal commercial transfer, maintenance isolation and maintenance planning of accidents, and matters needing attention during overhaul. These issues are described as follows:

(1) Site selection: entrust an engineering company with high mountain operation experience to help field surveys and collect and judge the selected site from various data sources (the site must have a harder geology, non-fault, moderate slope, and less impact on the environment).

(2) Environmental impact assessment: The collected data will be sorted and compiled and sent to the environmental impact assessment committee for feasibility assessment, and the construction can only be carried out after passing the environmental assessment.

(3) Engineering planning and design: appoint an experienced engineering consulting company to plan and design the engineering construction sequence and design details according to the original design, according to civil engineering, electrical and mechanical engineering, equipment, operation, maintenance, storage, environmental protection, etc. Construction planning and design.

(4) On-site civil engineering construction: detailed descriptions of 0008, 0009, and 0010.

(5) Physical production and on-site testing: civil engineering is planned and physical production is carried out at the same time. This production is specified by the engineering consulting company for the dimensions and materials of the combined components of the single-unit single-tube diversion wind turbine, and is handed over to a special professional production professional The company’s production, such as the cylindrical steel pipe structure committee, is made by a company that specializes in making such components. The main shut-off valve group and the main shut-off valve group are produced by a special company, and the main generators and impellers are divided into turbine blade groups, Couplings, generators, exciters, and housings will be sent to the assembly company to assemble the assembly after they have been manufactured, and the static balance, vibration test, dynamic operation balance, vibration test, insulation test and related tests will be tested on site. The induced draft fan will then be produced by a specialized production company.

After the aforementioned components are produced and tested, they will be sent to the assembly workshop. After the components are assembled, rust removal, painting and various anti-rust and waterproof facilities will be implemented. After all the components are assembled, various functional tests will be carried out on site, such as It is necessary to make a similar wind tunnel to understand the function of the whole machine. After each function is fully determined, it will be transported to the construction site for installation. The transportation process needs to be checked by the transportation unit and cooperated with the preventive facilities of preservation and insurance. After being delivered to the construction site, it will cooperate with the on-site installation work (single-cylinder multi-machine stringing into artificial tornado The design configuration method of the guide wind turbine group assembly is installed). After the civil engineering is completed, the erection of the pillars and beams is completed, the stand-alone "single-tube diversion wind turbine" is positioned, locked and the counterweight is hung at the predetermined position, and then it is coordinated with the erection of other mechanical parts. The installation of the "Tandem Tornado Diversion Wind Turbine" is completed. The configuration of the various components at the intake end and the installation of various components at the exhaust end are confirmed, and then the various electrical wiring and control lines are installed. Once completed, you can perform various mechanical action tests, such as the opening and closing test of the intake main blocking valve group, the main shut-off valve group, the insulation test of each wiring, the generator insulation test and the various protection relay tests, and you can start Trial operation.

Single machine and the whole machine for trial operation:

Multi-machine single-cylinder guide wind turbines are cascaded into man-made tornado wind turbines. When the wind turbine group assembly is in a static state, the first main blocking valve, the second main blocking valve and the main shut-off of the intake air are at a standstill. The valve remains closed. To start this multi-unit single-cylinder diversion wind turbine string into a man-made tornado diversion wind turbine group assembly, first open the first main blocking valve, and then open the second main blocking valve to start the air filter Net and air capture machine, turn on the main switch of each generator, and then turn on the main shutdown The balance valve of the valve reduces the pressure difference between the front and rear ends of the valve. The shut-off valve is opened by an inch movement. Once opened, a large amount of airflow instantly rushes to the top of the mountain, and all the wind turbines of the whole machine start to increase speed at the same time. Use the synchronizer of each machine to put the generators into the system one by one to generate electricity, and continue to use inch movements to open the main shut-off valve. The output of each generator gradually increases until the main shut-off valve is fully opened. At this point, the whole machine is started. It can be operated in base load, medium load and peak mode as the system needs, and can generate power continuously for 24 hours. This is an inexhaustible and inexhaustible green energy, independent of the climate. Since each generator has a guide wing at the front end, the airflow is stable and there will be no vibration caused by the diversion.

If you want to stop, you still use the inch-action method to gradually close the main shut-off valve until the output of each generator is less than zero, and the reverse power protection electro-interpreter will automatically trip the main circuit breaker of the generator, and each generator has been deactivated. After the connection is completed, the main shut-off valve is closed by inching, and then the second main shut-off valve is closed, and finally the first main shut-off valve is closed. The whole machine is in shutdown state until operation.

Speeding trip test:

Each multi-machine single-tube diversion wind turbine is stringed into a man-made tornado diversion wind turbine group assembly. Before commercial operation, an overspeed trip test is required. First, all generators are connected in parallel to maintain a low load. After running, press the emergency stop button to test whether the closing speed of the main shut-off valve is sufficient to lower the speed of each generator, and adjust it if necessary.

Electro-interpretation tests for various protections of generators and transformers:

Each machine can be tested when the generator is connected in parallel with a low load, and all the protections of the transformer can be tested before the unit is started or after the unit is disconnected. After the aforementioned start, speed increase, constant speed, parallel connection, load removal, full load, load reduction, disconnection, deceleration, and stop trial runs are completed, commercial operation can be declared after one month of continuous operation.

Maintenance after commercial operation:

Because the single-cylinder diversion wind power generator set designed by the present invention adopts the whole machine parts to combine into a single single-cylinder single-machine diversion wind power generator assembly, when the single machine fails, the whole machine can be removed and replaced with another one The standby unit can continue to operate after being locked. The malfunctioning unit is hoisted to the repair factory, after dismantling and repairing and replacing with available accessories, the whole unit can be restored to the standby state, and it can be replaced for continued use when needed.

Accident inspection, isolation and maintenance plan:

Matters needing attention during overhaul: When the unit has been in operation for one year, overhaul operations must be carried out. The necessary parts must be updated during overhaul, such as the bearings of the main shut-off valve drive motor and the carbon brushes inside the motor. If the motor armature is severely worn, The entire motor needs to be replaced. The valve body derusting paint or various gaskets, rubber gaskets and oil seals need to be replaced. The parts of the various valve groups should be updated if necessary. Whether the reinforcement plate of the air inlet chamber and the muffler chamber If there is rust, replace them with new ones if necessary, but the purchased parts must be strictly checked to avoid frequent failures that affect the operation of the unit.

The overhaul of the main part of the monotube diversion wind turbine focuses on two major parts:

(1) Turbine blade part: check whether the blade body is worn, missing, or rusted, whether the root cone is smooth, whether the main shaft and coupling are corroded, whether the main shaft body is corroded or rusted, etc., if necessary Renew all.

(2) Generator body: If the cone of the casing is found to be corroded and rusted, it needs to be treated, and if necessary, replace it with a new one. The generator bearing is absolutely updated, the armature carbon brush is absolutely updated, the generator stator coil insulation test is replaced if necessary, the rotor coil needs to be tested, if necessary, the exciter carbon brush is absolutely replaced, the control card is as follows It is necessary to renew.

Schematic diagram of the group assembly of multi-unit single-tube diversion wind turbines in series into man-made tornado diversion wind turbines

1‧‧‧Inlet Chamber

36‧‧‧Inlet silencing chamber

2‧‧‧First block valve for intake air

4‧‧‧Imported filter set

6‧‧‧Air capture machine

9‧‧‧Second block valve for intake air

11‧‧‧Intake main shut-off valve

19‧‧‧Single-unit single-cylinder diversion wind turbine combination schematic diagram

29‧‧‧Exhaust port

32‧‧‧Induced draft fan diagram

139‧‧‧Speaker export

140‧‧‧Flat nozzle air outlet

Claims (4)

The single-tube wind power is concentrated, and the inlet end is equipped with air inlet guide wings for downstream flow. The combination of the connecting tube and the single-tube wind turbine becomes a "single-tube guide wind turbine assembly" which can be used to generate electricity. This is the invention patent. The air intake of the ground is equipped with an air intake chamber with a filter screen, a filter group, an air catcher, two main intake air blocking valves and main intake air shut-off valves and other auxiliary equipment, which can control and manage the air volume of the air intake. The rear end is connected with a single-tube vortex wind turbine, and multiple machines are connected in series to form an artificial tornado air duct. An induced draft fan is installed at the outlet to induce the air volume, which is connected to the high-altitude mountain air outlet to form a whole set of tornado air flow controllable and manageable air volume The function "single-tube diversion wind turbines with multiple machines connected in series to form an artificial tornado diversion wind turbine group assembly" is a patent of the invention. According to the fixed point of the selected ground and the fixed point of the high altitude relative to the altitude, the tunnel excavation type is adopted to construct a connecting air duct directly from the ground to the fixed point of a single or multi-layer mountain, and a single-tube diversion wind turbine and multiple machines are installed in the air duct. The group assembly of man-made tornado vortex wind generators formed in series, called "Tunnel excavation type multi-machine single-tube wind generators strung into man-made tornado wind generator group assembly" is a patent of the invention. Three equiangularly installed driving fans with AI remote control function are used to drive the conductive balloon to push the balloon into the cloud, and the solar photoelectricity of the cloud is connected to the wire, large resistance group, and large capacitor on the copper ball arc tube. After the group, before starting the photoelectric collection system, first put in the grounding switch and release the cloud layer charge first. When the solar photoelectricity of the cloud layer is reduced to an acceptable level, put in the entrance cut-off switch and cut the grounding switch to make the cloud layer photoelectricity pass through a large resistance. The "Solar Photoelectric Collecting System" in which the large capacitor group is connected to the compressed battery group for storage is a patent of the invention.

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