CN214660398U - High-efficient device that utilizes of power plant's heat energy power device - Google Patents

Abstract

The utility model discloses a high-efficiency utilization device of a power plant heat energy power device, which comprises a pressurizing bin, a power generation assembly, a guide pipe, a circulation bin and a power generation bin, wherein the guide pipe is arranged at the top of the pressurizing bin, the top end of the guide pipe is connected with the circulation bin, the power generation bin is arranged at the left side of the circulation bin, the power generation assembly specifically comprises a booster pump, a turbine, a transmission shaft, a driving gear, a driven gear, a storage battery and a power generator, the guide pipe is arranged at the top of the pressurizing bin, the turbine and the driving gear are connected by the transmission shaft, the turbine is driven to rotate by utilizing the pressurized gas to impact the turbine so as to drive the driven gear which is engaged and connected by the driving gear to rotate, the power generator is driven to rotate for power generation, spring connecting clamping strips are used for fixedly installing the power generator at two sides of the power generator, and a damping spring is arranged at the bottom of a bottom plate to provide buffer protection for the power generator, and a semiconductor refrigerating sheet is arranged at the top in the power generation bin to cool the power generation bin.

Description

High-efficient device that utilizes of power plant's heat energy power device

Technical Field

The utility model relates to a thermal power recovery plant technical field, in particular to high-efficient device that utilizes of power plant's heat energy power device.

Background

The heat pipe is a heat transfer element invented by American national laboratory in 1963, which fully utilizes the heat conduction principle and the rapid heat transfer property of a refrigeration medium, and realizes heat transfer by means of phase change of a working medium in the heat pipe, the heat conduction capability of the heat pipe exceeds the heat conduction capability of any known metal, compared with metals such as silver, copper, aluminum and the like, the heat pipe of unit weight can transfer heat of several orders of magnitude more, the heat transfer capability is higher by thousands of times and even tens of thousands of times, and the heat pipe is called heat superconducting, because the heat pipe has the characteristics of extremely high heat transfer efficiency, extremely low internal thermal resistance, equivalent heat conduction coefficient, flexible and changeable structural form, size of a body, changeable heat flux density of input and output and the like, the heat pipe is widely applied to industries such as space navigation, military industry, coal mine, electric power, electronics, machinery, chemical industry and the like, at present, although a power device for transferring and converting heat energy by utilizing the characteristics of the heat pipe, however, these devices have low efficiency, high energy loss and limited functions.

The high-efficient device that utilizes of a power plant's heat energy power device on the market has following drawback: common heat energy power device high efficiency utilizes the device and directly discharges steam through the pipeline of installing the generator usually, steam is when not reaching certain flow and pressure, can't strike the turbine and drive the generator and rotate the electricity generation, lead to a large amount of steam resources to cause the waste, use cost has been increased, and directly with generator fixed mounting inside equipment, the generator during operation need rotate for a long time and can produce vibrations and give off a large amount of heats, the long-time vibrations of generator lead to inner structure to drop easily and influence the use of generator, and be not convenient for carry out the heat dissipation to the generator and handle, use for a long time because of the generator and lead to generator inside overheated and catch fire and cause dangers such as conflagration easily.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main aim at provides a high-efficient device that utilizes of power plant's heat energy power device can effectively solve the problem in the background art.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a high-efficiency utilization device of a power plant heat energy power device, which comprises a pressurizing bin, a power generation assembly, a flow guide pipe, a circulation bin and a power generation bin, a flow guide pipe is arranged at the top of the pressurizing bin, the top end of the flow guide pipe is connected with a circulation bin, a power generation bin is arranged at the left side of the circulation bin, the power generation assembly specifically comprises a booster pump, a turbine, a transmission shaft, a driving gear, a driven gear, a storage battery and a generator, a booster pump is arranged on the left side in the pressurizing bin, a turbine is arranged in the flow guide pipe, the turbine is arranged at the top end of the transmission shaft, the bottom end of the transmission shaft is inserted at the bottom in the circulation bin and is provided with a driving gear, the driving gear is engaged with a driven gear, the bottom end of the driven gear is connected with the power input end at the top of the generator, a storage battery is arranged above the generator, and the electric energy input end of the storage battery is connected with the electric energy output end of the generator.

Furthermore, the protection assembly specifically comprises semiconductor refrigeration sheets, side plates, clamping strips, a rotating shaft, springs, a bottom plate and damping springs, the generator is installed on the surface of the bottom plate, the side plates are arranged on two sides of the surface of the bottom plate, the springs are arranged at two ends of the inner side of each side plate and connected with the top ends of the clamping strips, the bottom ends of the clamping strips are connected with the inner sides of the side plates through the rotating shaft, the bottom of the bottom plate is installed at the bottom in the power generation bin through the damping springs, the semiconductor refrigeration sheets are installed at the top in the power generation bin, the generator is fixedly installed on two sides by using the spring to connect the clamping strips, the damping springs are arranged at the bottom of the bottom plate to provide buffer protection for the generator, the semiconductor refrigeration sheets are arranged at the top in the power generation bin to cool the power generation bin, and the heat dissipation of the generator is facilitated, the use is safer.

Further, the air inlet has been seted up on pressurization storehouse left side, booster pump gas input end is connected to the air inlet, and the gas input end of booster pump is connected to the air inlet that pressurization storehouse left side set up, uses gas directly to generate electricity in discharging the pressurization storehouse through the booster pump pressurization back, and it is more convenient to use.

Furthermore, the top of the circulation bin is provided with a gas outlet, and the gas outlet formed in the top of the circulation bin is convenient for discharging gas used for power generation for subsequent use.

Compared with the prior art, the utility model discloses following beneficial effect has: set up the honeycomb duct and install the turbine at pressurization storehouse top, use transmission shaft connection turbine and driving gear, thereby utilize the gas after the pressurization to strike the turbine and drive the turbine and rotate the driven gear who drives the meshing through the driving gear and connect and rotate, thereby it rotates and generates electricity the use to drive the generator, use the steam utilization and generate electricity the use, use cost is reduced, save the electric energy, install the generator on the bottom plate surface, and use the spring coupling holding strip to carry out fixed mounting to the generator in both sides, provide buffer protection's effect to the generator through set up damping spring bottom the bottom plate, and the top sets up the semiconductor refrigeration piece and cools down the processing in to the electricity generation storehouse in electricity generation storehouse, the heat dissipation that will be convenient for to the generator is used, it is safer to use.

Drawings

Fig. 1 is the utility model discloses a high-efficient utilization device holistic spatial structure schematic diagram of power plant's heat energy power device.

Fig. 2 is the utility model relates to a planar structure schematic diagram of the high-efficient device honeycomb duct that utilizes of power plant's heat energy power device.

Fig. 3 is the utility model discloses a plane structure schematic diagram of the high-efficient device holding strip that utilizes of power plant's heat energy power device.

In the figure: 1. an air inlet; 2. a pressurizing bin; 3. a power generation cabin; 4. a protection component; 401. a semiconductor refrigeration sheet; 402. a side plate; 403. clamping strips; 404. a rotating shaft; 405. a spring; 406. a base plate; 407. a damping spring; 5. an air outlet; 6. circulating the bin; 7. a flow guide pipe; 8. a power generation assembly; 801. a booster pump; 802. a turbine; 803. a drive shaft; 804. a driving gear; 805. a driven gear; 806. a storage battery; 807. an electric generator.

Detailed Description

In order to make the technical means, creation features, achievement purposes and functions of the present invention easy to understand, the present invention is further described below with reference to the following embodiments.

As shown in fig. 1-3, a device for efficiently utilizing a thermal power plant comprises a pressurizing bin 2, a power generation assembly 8, a flow guide pipe 7, a circulation bin 6 and a power generation bin 3, wherein the top of the pressurizing bin 2 is provided with the flow guide pipe 7, the top end of the flow guide pipe 7 is connected with the circulation bin 6, the left side of the circulation bin 6 is provided with the power generation bin 3, the power generation assembly 8 specifically comprises a booster pump 801, a turbine 802, a transmission shaft 803, a driving gear 804, a driven gear 805, a storage battery 806 and a power generator 807, the left side in the pressurizing bin 2 is provided with the booster pump 801, the flow guide pipe 7 is internally provided with the turbine 802, the turbine 802 is arranged at the top end of the transmission shaft 803, the bottom end of the transmission shaft 803 is inserted at the bottom in the circulation bin 6 and is provided with the driving gear 804, the driving gear 804 is engaged with the driven gear 805, the bottom end of the driven gear 805 is connected with a power input end at the top of the power generator 807, the storage battery 806 is arranged above the power generator 807, the power input end of the storage battery 806 is connected with the power output end of the generator 807.

Wherein, the protection component 4 is specifically composed of a semiconductor refrigeration sheet 401, a side plate 402, a clamping strip 403, a rotating shaft 404, a spring 405, a bottom plate 406 and a damping and shock absorbing spring 407, the generator 807 is installed on the surface of the bottom plate 406, the side plates 402 are arranged on two sides of the surface of the bottom plate 406, two ends of the inner side of the side plate 402 are provided with the spring 405 and are connected with the top end of the clamping strip 403, the bottom end of the clamping strip 403 is connected with the inner side of the side plate 402 through the rotating shaft 404, the bottom of the bottom plate 406 is installed at the bottom in the power generation cabin 3 through the damping and shock absorbing spring 407, the semiconductor refrigeration sheet 401 is installed at the top in the power generation cabin 3, the generator 807 is installed on the surface of the bottom plate 406, the spring 405 is connected with the clamping strip 403 on two sides to fixedly install the generator 807, the damping and shock absorbing spring 407 is arranged at the bottom of the bottom plate 406 to provide the buffer protection effect for the generator 807, and the semiconductor refrigeration sheet 401 is arranged at the top in the power generation cabin 3 to cool the interior of the power generation cabin 3, the generator 807 can be used for dissipating heat conveniently, and the use is safer.

Wherein, pressurizing 2 left sides in storehouse and having seted up air inlet 1, air inlet 1 connects booster pump 801 gas input end, and the air inlet 1 that pressurizing 2 left sides in storehouse set up connects booster pump 801's gas input end, and it uses to generate electricity in 2 directly passing through the booster pump 801 pressurization back row of gas, and it is more convenient to use.

Wherein, the gas outlet 5 has been seted up at 6 tops in circulation storehouse, and the gas outlet 5 that the 6 tops in circulation storehouse were seted up is convenient for follow-up use of gas outgoing after the electricity generation was used.

It should be noted that, the utility model relates to a high-efficient utilization device of power plant's heat energy power device, in operation, connect air inlet 1 with the hot gas pipeline, gas pressurizes and discharges to pressurizing the storehouse 2 in flowing to booster pump 801 back from air inlet 1, high-pressure hot gas circulates and strikes turbine 802 from honeycomb duct 7 upwards, thereby drive turbine 802 rotate and drive driving gear 804 through transmission shaft 803 and rotate and drive meshing connection's driven gear 805, driven gear 805 rotates and drive generator 807 inside rotor rotation and generate electricity and use, and store the electric energy to storage battery 806 and use, generator 807 can produce the vibration in the use, install generator 807 on bottom plate 406 surface and use spring 405 to connect the holding strip in the curb plate 402 inboard at both sides, carry out fixed mounting to generator 807 through holding strip 403, and set up damping spring 407 in bottom plate 406 and provide absorbing effect to bottom plate 406, in order to reach and provide the cushioning guard action to generator 807, prevent that generator 807 from leading to the use that the internals drops and influence generator 807 because of long-time vibrations when long-time during operation, and install semiconductor refrigeration piece 401 in the cooperation of the top of battery 806, start to carry out refrigeration heat dissipation treatment in electricity generation storehouse 3 through semiconductor refrigeration piece 401 circular telegram, in order to give off the heat that generator 807 produced in the use, guarantee the inside temperature in electricity generation storehouse 3, thereby prevent danger such as conflagration from appearing because of the inside overheat in electricity generation storehouse 3, it is safer to use.

The basic principles and the main features of the invention and the advantages of the invention have been shown and described above. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (4)

1. The utility model provides a device is utilized to power plant's heat energy power device high efficiency, includes pressurization storehouse (2), its characterized in that still includes electricity generation subassembly (8), honeycomb duct (7), circulation storehouse (6) and electricity generation storehouse (3), honeycomb duct (7) are installed at pressurization storehouse (2) top, circulation storehouse (6) are connected on honeycomb duct (7) top, electricity generation storehouse (3) are installed in circulation storehouse (6) left side, electricity generation subassembly (8) specifically by booster pump (801), turbine (802), transmission shaft (803), driving gear (804), driven gear (805), battery (806) and generator (807) constitute, booster pump (801) are installed to the left side in pressurization storehouse (2), be provided with turbine (802) in honeycomb duct (7), turbine (802) are installed on transmission shaft (803) top, grafting in circulation storehouse (6) bottom and installing driving gear (804) in transmission shaft (803), the driving gear (804) is meshed with a driven gear (805), the bottom end of the driven gear (805) is connected with the top power input end of a generator (807), a storage battery (806) is arranged above the generator (807), and the electric energy input end of the storage battery (806) is connected with the electric energy output end of the generator (807).

2. A plant thermal power plant efficient use device according to claim 1, characterized by: still include protection component (4), protection component (4) specifically comprise semiconductor refrigeration piece (401), curb plate (402), holding strip (403), pivot (404), spring (405), bottom plate (406) and damping spring (407), install on bottom plate (406) surface generator (807), bottom plate (406) surface both sides are provided with curb plate (402), curb plate (402) inboard both ends are provided with spring (405) and connect holding strip (403) top, curb plate (402) inboard is connected through pivot (404) in holding strip (403) bottom, bottom plate (406) bottom is installed in electricity generation storehouse (3) bottom through damping spring (407), semiconductor refrigeration piece (401) are installed at the top in electricity generation storehouse (3).

3. A plant thermal power plant efficient use device according to claim 1, characterized by: an air inlet (1) is formed in the left side of the pressurizing bin (2), and the air inlet (1) is connected with an air input end of a pressurizing pump (801).

4. A plant thermal power plant efficient use device according to claim 1, characterized by: the top of the circulation bin (6) is provided with an air outlet (5).

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