阅读说明：本技术 一种自发电余热回收新能源动力装置 (Self-generating waste heat recovery new energy power device ) 是由 任海军 于 2019-09-25 设计创作，主要内容包括：本发明公开了一种自发电余热回收新能源动力装置,包括底座、半导体发电装置、汽轮装置、集热装置、冷凝装置、减震装置,本发明通过本发明可以将燃料内能转化为机械能,再转化为电能,并储存起来,防止发动机过热损坏的同时,有利于快速将水加热,提高加热效率,通过蒸汽带动转轮转动,带动发电机I工作,有效利用了发动机在工作过程中燃烧燃料产生的热,节约能源的同时,有利于环保,能有效利用发动机产生的热量,发电效率高,热量利用率高,可以多次利用余热发电,防止部分余热散失,减弱浪费情况,可以将尾气进行进一步利用,提升水蒸气的气压和温度,从而收集更多的热能,产生更高的动能。(The invention discloses a self-generating waste heat recovery new energy power device, which comprises a base, a semiconductor power generation device, a steam turbine device, a heat collection device, a condensation device and a damping device, wherein the internal energy of fuel can be converted into mechanical energy, then converted into electric energy and stored, the internal energy of the fuel is prevented from being overheated and damaged, meanwhile, water is favorably and rapidly heated, the heating efficiency is improved, a rotating wheel is driven by steam to rotate, a generator I is driven to work, the heat generated by the combustion of the fuel in the working process of the engine is effectively utilized, the energy is saved, the environment is favorably protected, the heat generated by the engine can be effectively utilized, the power generation efficiency is high, the heat utilization rate is high, the waste heat can be utilized for multiple times for power generation, partial waste heat is prevented from being dissipated, the waste condition is weakened, tail gas can be further utilized, thereby collecting more heat energy and generating higher kinetic energy.)

1. The utility model provides a from electricity generation waste heat recovery new forms of energy power device, includes main base (1), tail gas waste heat recovery device (2), steam waste heat recovery device (3), middle waste heat recovery device (4), pneumatic means (5), pressure device (7), heat sink (10), damping device (27), its characterized in that: the top rear side of main base (1) is equipped with mount table (17), battery I (20), battery II (21) and battery III (22) are installed respectively to the inside of mount table (17), singlechip (36) are still installed to the inside of mount table (17), display screen (18) and control switch group (19) are installed respectively to the left side of mount table (17), the top of mount table (17) is fixed with water tank (16), the top of water tank (16) is equipped with water inlet (14), outside water source is connected in water inlet (14), still install temperature sensor I (15) on water tank (16), the top of main base (1) is equipped with damping device (27), install generator I (9), generator II (12) on damping device (27) respectively and heat sink (10), the front side delivery outlet of water tank (16) with heat sink (10) are connected, the top of the main base (1) is provided with the temperature-increasing pressurizing device (7) and the pneumatic device (5), the temperature-increasing pressurizing device (7) is arranged at the front side of the temperature-reducing device (10), the pneumatic device (5) is arranged at the front side of the temperature-increasing pressurizing device (7), the temperature-reducing device (10) is connected with the temperature-increasing pressurizing device (7), the temperature-increasing pressurizing device (7) is connected with the middle input port of the pneumatic device (5) through a steam inlet pipe (35), an inlet electric valve (29) is arranged at the joint of the water tank (16) and the temperature-reducing device (10), an outlet electric valve (6) is arranged on the steam inlet pipe (35), the right side of the temperature-reducing device (10) is provided with a driving belt wheel II (25), the left side input shaft of the generator II (12) is connected with a driven belt wheel II (13), the driving belt wheel II (25) is connected with the driven belt wheel II (13) through a driving belt II (26), the right-hand member of pneumatic means (5) is equipped with driving pulley I (23), the right side input shaft of generator I (9) is connected from driving pulley I (24), driving pulley I (23) with from driving pulley I (24) are connected through drive belt I (8), the top left side of main base (1) is equipped with respectively tail gas waste heat recovery device (2) with steam waste heat recovery device (3), the delivery outlet at the left and right ends of pneumatic means (5) passes through collecting pipe (34) and connects, be equipped with two on collecting pipe (34) middle waste heat recovery device (4), the middle delivery outlet of collecting pipe (34) passes through steam discharge pipe (33) and connects the one end of steam waste heat recovery device (3), the other end of steam waste heat recovery device (3) passes through back flow (30) and connects the top of water tank (16) input port, the heating and pressurizing device (7) is connected with one end of the tail gas waste heat recovery device (2) through a tail gas discharge pipe (31), the other end of the tail gas waste heat recovery device (2) is connected with an external tail gas recovery device, a control switch group (19) is respectively connected with the single chip microcomputer (36), the storage battery I (20), the storage battery II (21) and the storage battery III (22) in an electric connection mode, the single chip microcomputer (36) is connected with the display screen (18), the outlet electric valve (6), the temperature sensor I (15) and the inlet electric valve (29) in an electric connection mode, the generator I (9) is connected with the storage battery I (20) in an electric connection mode, and the generator II (12) is connected with the storage battery II (21) in an electric connection mode.

2. The self-generating electricity waste heat recovery new energy power device according to claim 1, characterized in that: the damping device (27) comprises a buffer seat (2701), a damping telescopic rod I (2702), a damping spring I (2703), an inner cavity (2704), a damping telescopic rod II (2705), a damping spring II (2706) and an elastic base (2707), the buffer seat (2701) is installed at the bottoms of the generator I (9) and the generator II (12), four corners of the bottom of the buffer seat (2701) are connected with the top of the main base (1) through the four damping telescopic rods I (2702) respectively, the damping spring I (2703) is sleeved on the side face of the damping telescopic rod I (2702), the lower end of the cooling device (10) is connected with the top of the main base (1) through the elastic base (2707), the inner cavity (2704) is arranged inside the elastic base (2707), and the bottom of the inner side of the inner cavity (2704) is connected with the lower end of the damping telescopic rod II (2705), the upper end of shock attenuation telescopic link II (2705) is connected heat sink (10), the outside of shock attenuation telescopic link II (2705) is cup jointed damping spring II (2706).

3. The self-generating electricity waste heat recovery new energy power device according to claim 1, characterized in that: the temperature-increasing and pressure-increasing device (7) comprises a tail gas chamber (701), a steam chamber (702), a steam inlet (703), a temperature sensor II (704), an air pressure sensor (705), a steam outlet (706), a tail gas outlet (707) and a tail gas inlet (708), wherein the tail gas chamber (701) is positioned at the top of the main base (1), the steam chamber (702) is arranged in the tail gas chamber (701), the temperature sensor II (704) and the air pressure sensor (705) are respectively arranged at the top of the tail gas chamber (701), the measuring ends of the temperature sensor II (704) and the air pressure sensor (705) are both positioned in the steam chamber (702), the tail gas inlet (708) is arranged at the left side of the tail gas chamber (701), the tail gas outlet (707) is arranged at the front side of the tail gas chamber (701), the front side of steam chamber (702) is equipped with steam outlet (706), the front end of steam outlet (706) passes the front side of tail gas chamber (701), the rear side of steam chamber (702) is equipped with steam inlet (703), the rear end of steam inlet (703) passes the rear side of tail gas chamber (701), tail gas import (708) are connected through tail gas admission pipe (32) heat sink (10), tail gas export (707) are connected tail gas discharge pipe (31), steam outlet (706) are connected steam admission pipe (35), steam inlet (703) are connected heat sink (10), singlechip (36) with temperature sensor II (704) and baroceptor (705) electric connection.

4. The self-generating electricity waste heat recovery new energy power device according to claim 3, characterized in that: the cooling device (10) comprises a heat absorption pipe (1001), a protective shell (1002), a heat exhaust hole (1003), a heat exhaust ridge (1004) and an engine (1005), the damping device (27) is arranged at the lower end of the protective shell (1002), the engine (1005) is arranged in the protective shell (1002), the left end of the engine (1005) is connected with one end of an oil inlet pipe (11), the other end of the oil inlet pipe (11) is provided with a sealing cover (28), a waste gas exhaust hole of the engine (1005) is connected with the tail gas inlet pipe (32), a right output shaft of the engine (1005) is connected with the driving pulley II (25), the heat exhaust ridge (1004) which is spirally distributed is arranged on the outer side of the engine (1005), the heat exhaust hole (1003) which is uniformly distributed is arranged on the heat exhaust ridge (1004), and the heat absorption pipe (1001) which is spirally distributed is also arranged on the outer side of the engine (1005), one end of the heat absorption pipe (1001) is connected with the front side output port of the water tank (16), the other end of the heat absorption pipe (1001) is connected with the steam inlet (703), and the engine (1005) is electrically connected with the control switch group (19).

5. The self-generating electricity waste heat recovery new energy power device according to claim 1, characterized in that: the pneumatic device (5) comprises a heat insulation shell (501), a guide vane group (502), runner vanes (503), runners (504) and a main shaft (505), wherein the left side of the inside of the heat insulation shell (501) is rotatably connected with the left end of the main shaft (505), the right end of the main shaft (505) penetrates through the right side of the heat insulation shell (501) to be connected with the driving pulley I (23), the left end and the right end of the inside of the heat insulation shell (501) are respectively provided with four guide vane groups (502), the left end and the right end of the side surface of the main shaft (505) are respectively provided with five runners (504), the five runners (504) and the four guide vane groups (502) are distributed in a staggered manner, the side surface of the runner (504) is provided with twelve runner vanes (503) distributed at equal angles, and the middle input port of the heat insulation shell (501) is connected with the steam inlet pipe, the left end and the right end of the heat insulation shell (501) are connected with the left end and the right end of the collecting pipe (34).

6. The self-generating electricity waste heat recovery new energy power device according to claim 1, characterized in that: the tail gas waste heat recovery device (2) comprises a semiconductor power generation sheet I (201), a heat dissipation sleeve I (202), a heat dissipation pipe I (203) and a heat dissipation hole I (204), the heat dissipation sleeve I (202) is positioned at the top of the main base (1), the surface of the heat dissipation sleeve I (202) is provided with the heat dissipation holes I (204) which are uniformly distributed, the heat radiation pipe I (203) which is spirally distributed is arranged in the heat radiation sleeve I (202), one end of the radiating pipe I (203) is connected with the tail gas discharge pipe (31), the other end of the radiating pipe I (203) is connected with an external tail gas collecting device, eight semiconductor power generation pieces I (201) are arranged inside the radiating sleeve I (202), the eight semiconductor power generation pieces I (201) are distributed equidistantly along the front-back direction, the semiconductor power generation piece I (201) is electrically connected with the storage battery III (22).

7. The self-generating electricity waste heat recovery new energy power device according to claim 1, characterized in that: the steam waste heat recovery device (3) comprises a semiconductor power generation sheet II (301), a heat dissipation sleeve II (302), a heat dissipation pipe II (303) and a heat dissipation hole II (304), the heat dissipation sleeve II (302) is positioned at the top of the main base (1), the surface of the heat dissipation sleeve II (302) is provided with the heat dissipation holes II (304) which are uniformly distributed, the heat radiating pipe II (303) is spirally distributed in the heat radiating sleeve II (302), one end of the radiating pipe II (303) is connected with the return pipe (30), the other end of the radiating pipe II (303) is connected with the steam discharge pipe (33), eight semiconductor power generation pieces II (301) are arranged in the heat dissipation sleeve II (302), the eight semiconductor power generation pieces II (301) are distributed at equal intervals in the front-back direction, the semiconductor power generation sheet II (301) is electrically connected with the storage battery III (22).

8. The self-generating electricity waste heat recovery new energy power device according to claim 1, characterized in that: middle waste heat recovery device (4) are including heat dissipation cover III (401), louvre III (402), semiconductor power generation piece III (403), heat dissipation cover III (401) cup joints on collecting pipe (34), the inside of heat dissipation cover III (401) is equipped with four semiconductor power generation piece III (403), four semiconductor power generation piece III (403) are followed the axial equidistance of collecting pipe (34) distributes, the surface of heat dissipation cover III (401) is equipped with evenly distributed louvre III (402), semiconductor power generation piece III (403) with battery III (22) electric connection.

Technical Field

The invention relates to the technical field of waste heat recovery equipment, in particular to a self-generating waste heat recovery new energy power device.

Background

The power device is a device which converts energy in other forms into mechanical energy and can be used for driving a power generation device to generate electricity, the power generation device is mechanical equipment which converts energy in other forms into electric energy and can be driven by a water turbine, a steam turbine, a diesel engine or other power machines to convert energy generated by combustion of water flow, air flow, fuel or fission of atomic nucleus into mechanical energy to be transmitted to a generator and then converted into electric energy by the generator to provide driving power for a vehicle, most of the existing power devices directly drive the vehicle to run through an engine, wherein the engine mostly uses gasoline, diesel oil and the like as fuel, a large amount of harmful gas can be generated in the process of providing power, the power generation device is not beneficial to environmental protection, if the engine is used for driving the generator to generate electricity and then provides electricity for the vehicle to run, the cruising ability of the vehicle can be influenced because the engine can generate a large amount of heat when, the existing power device cannot utilize the heat generated by the engine, has low power generation efficiency and low heat utilization rate, cannot utilize the waste heat for power generation for multiple times, causes partial waste heat to be dissipated, is serious in waste, and cannot ensure the cruising ability of the vehicle when providing power for the vehicle.

Disclosure of Invention

In view of the problems in the prior art, the invention discloses a self-generating electricity waste heat recovery new energy power device, which adopts the technical scheme that the device comprises a main base, a tail gas waste heat recovery device, a steam waste heat recovery device, an intermediate waste heat recovery device, a pneumatic device, a heating and pressurizing device, a cooling device and a damping device, and is characterized in that: the rear side of the top of the main base is provided with an installation platform, the inside of the installation platform is respectively provided with a storage battery I, a storage battery II and a storage battery III, the inside of the installation platform is also provided with a single chip microcomputer, the left side of the installation platform is respectively provided with a display screen and a control switch group, the top of the installation platform is fixed with a water tank, the top of the water tank is provided with a water inlet, the water inlet is connected with an external water source, the water tank is also provided with a temperature sensor I, the top of the main base is provided with the damping device, the damping device is respectively provided with a generator I, a generator II and the cooling device, the front side output port of the water tank is connected with the cooling device, the top of the main base is provided with the temperature and pressure increasing device and the pneumatic device, the temperature and pressure increasing device is positioned at the front side of the cooling device, the pneumatic, the cooling device is connected with the heating and pressurizing device, the heating and pressurizing device is connected with a middle input port of the pneumatic device through a steam inlet pipe, an inlet electric valve is installed at the joint of the water tank and the cooling device, an outlet electric valve is installed on the steam inlet pipe, a driving pulley II is installed on the right side of the cooling device, a left input shaft of the generator II is connected with a driven pulley II, the driving pulley II is connected with the driven pulley II through a driving belt II, a driving pulley I is arranged at the right end of the pneumatic device, a right input shaft of the generator I is connected with a driven pulley I, the driving pulley I is connected with the driven pulley I through a driving belt I, the tail gas waste heat recovery device and the steam waste heat recovery device are respectively arranged on the left side of the top of the main base, output ports at the left end and the right end of the pneumatic device are connected, the collecting pipe is provided with two intermediate waste heat recovery devices, an intermediate output port of the collecting pipe is connected with one end of the steam waste heat recovery device through a steam discharge pipe, the other end of the steam waste heat recovery device is connected with the top input port of the water tank through a return pipe, the temperature and pressure increasing device is connected with one end of the tail gas waste heat recovery device through a tail gas discharge pipe, the other end of the tail gas waste heat recovery device is connected with an external tail gas recovery device, the control switch group is respectively electrically connected with the single chip microcomputer, the storage battery I, the storage battery II and the storage battery III, the singlechip is electrically connected with the display screen, the outlet electric valve, the temperature sensor I and the inlet electric valve, the generator I is electrically connected with the storage battery I, and the generator II is electrically connected with the storage battery II.

As a preferred technical scheme of the invention, the damping device comprises a buffer seat, a damping telescopic rod I, a damping spring I, an inner cavity, a damping telescopic rod II, a damping spring II and an elastic base, the buffer seats are respectively arranged at the bottoms of the generator I and the generator II, four corners of the bottom of each buffer seat are respectively connected with the top of the main base through four damping telescopic rods I, the side surface of the damping telescopic rod I is sleeved with the damping spring I, the lower end of the cooling device is connected with the top of the main base through the elastic base, the elastic base is internally provided with four inner cavities, the bottom of the inner side of each inner cavity is connected with the lower end of the damping telescopic rod II, the upper end of the damping telescopic rod II is connected with the cooling device, and the damping spring II is sleeved on the outer side of the damping telescopic rod II.

As a preferable technical scheme of the invention, the temperature and pressure increasing device comprises a tail gas cavity, a steam inlet, a temperature sensor II, an air pressure sensor, a steam outlet, a tail gas outlet and a tail gas inlet, wherein the tail gas cavity is positioned at the top of the main base, the steam cavity is arranged inside the tail gas cavity, the temperature sensor II and the air pressure sensor are respectively arranged at the top of the tail gas cavity, the measuring ends of the temperature sensor II and the air pressure sensor are both positioned inside the steam cavity, the tail gas inlet is arranged at the left side of the tail gas cavity, the tail gas outlet is arranged at the front side of the tail gas cavity, the steam outlet is arranged at the front side of the steam cavity, the front end of the steam outlet penetrates through the front side of the tail gas cavity, the steam inlet is arranged at the rear side of the steam cavity, the rear end of steam inlet passes the rear side of tail gas cavity, the tail gas import passes through the tail gas admission pipe and connects the heat sink, the tail gas exit linkage the tail gas discharge pipe, the steam exit linkage the steam admission pipe, the steam inlet is connected the heat sink, the singlechip with temperature sensor II with baroceptor electric connection.

As a preferable technical proposal of the invention, the cooling device comprises a heat absorption pipe, a protective shell, a heat exhaust hole, a heat exhaust ridge and an engine, the lower end of the protective shell is provided with the damping device, the engine is arranged in the protective shell, the left end of the engine is connected with one end of an oil inlet pipe, the other end of the oil inlet pipe is provided with a sealing cover, the exhaust gas exhausting port of the engine is connected with the tail gas inlet pipe, the right output shaft of the engine is connected with the driving belt wheel II, the outer side of the engine is provided with the heat discharging ridges which are spirally distributed, the heat discharging ridges are provided with the heat discharging holes which are uniformly distributed, the outer side of the engine is also provided with the heat absorption pipe which is spirally distributed, one end of the heat absorption pipe is connected with the front side output port of the water tank, the other end of the heat absorption pipe is connected with the steam inlet, and the engine is electrically connected with the control switch group.

As a preferred technical scheme of the invention, the pneumatic device comprises a heat insulation shell, a guide vane group, runner vanes, runners and a main shaft, wherein the left side inside the heat insulation shell is rotatably connected with the left end of the main shaft, the right end of the main shaft penetrates through the right side of the heat insulation shell to be connected with the driving pulley I, the left and right ends inside the heat insulation shell are respectively provided with four guide vane groups, the left and right ends of the side surface of the main shaft are respectively provided with five runners, the five runners and the four guide vane groups are distributed in a staggered manner, the side surface of each runner is provided with twelve runner vanes which are distributed at equal angles, a middle input port of the heat insulation shell is connected with the steam inlet pipe, and the left and right ends of the heat insulation shell are connected with the left and right ends of the collecting pipe.

As a preferred technical scheme of the present invention, the tail gas waste heat recovery device includes a semiconductor power generation sheet I, a heat dissipation sleeve I, a heat dissipation pipe I and heat dissipation holes I, the heat dissipation sleeve I is located at the top of the main base, the heat dissipation holes I are uniformly distributed on the surface of the heat dissipation sleeve I, the heat dissipation pipe I is spirally distributed inside the heat dissipation sleeve I, one end of the heat dissipation pipe I is connected to the tail gas discharge pipe, the other end of the heat dissipation pipe I is connected to an external tail gas collection device, eight semiconductor power generation sheets I are arranged inside the heat dissipation sleeve I, the eight semiconductor power generation sheets I are equidistantly distributed along the front-back direction, and the semiconductor power generation sheets I are electrically connected to the storage battery III.

As a preferred technical scheme, the steam waste heat recovery device comprises a semiconductor power generation sheet II, a heat dissipation sleeve II, a heat dissipation pipe II and heat dissipation holes II, wherein the heat dissipation sleeve II is located at the top of the main base, the heat dissipation holes II are uniformly distributed on the surface of the heat dissipation sleeve II, the heat dissipation pipe II is spirally distributed in the heat dissipation sleeve II, one end of the heat dissipation pipe II is connected with the backflow pipe, the other end of the heat dissipation pipe II is connected with the steam discharge pipe, eight semiconductor power generation sheets II are arranged in the heat dissipation sleeve II, the eight semiconductor power generation sheets II are equidistantly distributed in the front-back direction, and the semiconductor power generation sheets II are electrically connected with the storage battery III.

As a preferred technical scheme of the present invention, the intermediate waste heat recovery device includes a heat dissipation sleeve III, heat dissipation holes III, and semiconductor power generation fins III, the heat dissipation sleeve III is sleeved on the bus pipe, four semiconductor power generation fins III are disposed inside the heat dissipation sleeve III, the four semiconductor power generation fins III are equidistantly distributed along an axial direction of the bus pipe, the heat dissipation holes III are uniformly distributed on a surface of the heat dissipation sleeve III, and the semiconductor power generation fins III are electrically connected to the storage battery III.

The invention has the beneficial effects that: the invention drives the generator II to work through the engine, can carry out first-stage power generation, converts internal energy of fuel into mechanical energy and then into electric energy, stores the mechanical energy, accelerates heat dissipation through the heat dissipation ridges and the heat dissipation holes, prevents the engine from being damaged by overheating, is favorable for quickly heating water and improving the heating efficiency, drives the rotating wheel to rotate through steam, can ensure that the steam cannot flow back through the guide vane group, avoids airflow disorder, is favorable for driving the rotating wheel to rotate and driving the generator I to work, carries out second-stage power generation, effectively utilizes heat generated by burning fuel in the working process of the engine, improves the overall mechanical efficiency, reduces heat loss, prevents heat dissipation, saves energy, is favorable for environmental protection, can effectively utilize the heat generated by the engine, has high power generation efficiency, and can carry out first-stage power generation through the semiconductor power generation sheet I and the semiconductor power generation sheet II, Semiconductor power generation piece III's one side and higher temperature contact, the opposite side keeps relatively lower temperature, thereby make semiconductor work, carry out the third level electricity generation, heat utilization is high, can utilize waste heat electricity generation many times, prevent that partial waste heat from scattering and disappearing, weaken the extravagant condition, simultaneously through shock attenuation telescopic link II, shock attenuation telescopic link I and damping spring II protection device can not be impaired, keep stable work, simultaneously can further utilize tail gas, pass through tail gas heating water vapour at the pressure device that heats, thereby promote vapour's atmospheric pressure and temperature, thereby collect more heat energy, increase atmospheric pressure simultaneously can make the runner rotate faster, produce higher kinetic energy.

Drawings

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

FIG. 2 is a schematic side view of the present invention;

FIG. 3 is a cut-away view of an interior elevation structure of the present invention;

FIG. 4 is an enlarged schematic view of the structure at the position A of the present invention;

FIG. 5 is an enlarged view of the structure of the present invention at B;

FIG. 6 is a sectional view of the internal top view of the present invention;

FIG. 7 is an enlarged view of the structure of the present invention at C;

FIG. 8 is an enlarged view of the structure of the present invention at D;

FIG. 9 is a rear view of the present invention;

FIG. 10 is an enlarged view of the structure of the present invention at E;

FIG. 11 is a cut-away view of the shock absorbing device of the present invention;

FIG. 12 is a rear sectional view of the interior of the temperature and pressure increasing device of the present invention;

fig. 13 is a front view schematically illustrating the temperature and pressure increasing device of the present invention.

In the figure: 1-main base, 2-tail gas waste heat recovery device, 201-semiconductor power generation sheet I, 202-heat dissipation sleeve I, 203-heat dissipation pipe I, 204-heat dissipation hole I, 3-steam waste heat recovery device, 301-semiconductor power generation sheet II, 302-heat dissipation sleeve II, 303-heat dissipation pipe II, 304-heat dissipation hole II, 4-middle waste heat recovery device, 401-heat dissipation sleeve III, 402-heat dissipation hole III, 403-semiconductor power generation sheet III, 5-pneumatic device, 501-heat insulation shell, 502-guide vane group, 503-runner vane, 504-runner, 505-main shaft, 6-outlet electric valve, 7-temperature and pressure increasing device, 701-tail gas chamber, 702-steam chamber, 703-steam inlet, 704-temperature sensor II, 705-pressure sensor, 706-steam outlet, 707-tail gas outlet, 708-tail gas inlet, 8-driving belt I, 9-generator I, 10-cooling device, 1001-heat absorption pipe, 1002-protective shell, 1003-heat discharge hole, 1004-heat discharge ridge, 1005-engine, 11-oil inlet pipe, 12-generator II, 13-driven pulley II, 14-water inlet, 15-temperature sensor I, 16-water tank, 17-mounting table, 18-display screen, 19-control switch group, 20-storage battery I, 21-storage battery II, 22-storage battery III, 23-driving pulley I, 24-driven pulley I, 25-driving pulley II, 26-driving belt II, 27-damping device, vibration-damping device, 2701-buffer seat, 2702-shock absorption telescopic rods I, 2703-shock absorption springs I, 2704-inner cavity, 2705-shock absorption telescopic rods II, 2706-shock absorption springs II, 2707-elastic base, 28-sealing cover, 29-inlet electric valve, 30-return pipe, 31-tail gas discharge pipe, 32-tail gas inlet pipe, 33-steam discharge pipe, 34-collecting pipe, 35-steam inlet pipe and 36-single chip microcomputer.

Detailed Description