CN219197558U

CN219197558U - Auxiliary gravity circulation power generation device

Info

Publication number: CN219197558U
Application number: CN202223062602.9U
Authority: CN
Inventors: 鸦明春
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-11-18
Filing date: 2022-11-18
Publication date: 2023-06-16
Anticipated expiration: 2032-11-18

Abstract

The utility model discloses an auxiliary gravity circulation power generation device in the technical field of power generation devices, which comprises a base, wherein a bracket is arranged on the base, the top of the bracket is fixedly connected with the center of a rotating wheel, a power generating unit is arranged at the center of the rotating wheel, ball frames are arranged on the peripheral surface of the rotating wheel at equal intervals, a transmission mechanism is further arranged on the base, the transmission mechanism comprises a ball inlet groove arranged at the upper part of an air cylinder upright post and a ball outlet groove arranged at the lower part of the air cylinder upright post, and the ball outlet end part of the ball inlet groove and the ball inlet end part of the ball outlet groove are respectively connected to the ball frames of the rotating wheel. The gravity ball is fed into the ball frame from the ball feeding groove above through the transmission mechanism, and is conveyed back into the transmission mechanism by the ball discharging groove below the rotating wheel along with the rotation of the rotating wheel, the gravity ball is conveyed into the ball feeding groove again by the action of the cylinder, so that the rotating wheel continuously rotates continuously due to the circulation, and the mechanical energy of the rotation of the rotating wheel is converted into electric energy by the generator set under the rotation of the rotating wheel, so that the electric energy can be supplied to families and factories.

Description

Auxiliary gravity circulation power generation device

Technical Field

The utility model relates to the technical field of power generation devices, in particular to an auxiliary gravity circulation power generation device.

Background

The currently used power generation device mainly comprises hydroelectric power generation, thermal power generation, nuclear power generation, wind power generation and the like, and the power generation modes have different defects, so that the hydroelectric power generation needs to be constructed into a large-scale water storage facility, depends on sufficient water source flow and is limited by factors such as geographic positions, climate conditions and the like; the thermal power generation needs to consume petrochemical fuel, so that the environmental pollution is serious and the power generation cost is high; the construction cost of nuclear power generation is high, and the requirement on the safety level is high; wind power generation is affected by geographical locations and ambient weather, which limits the application of wind power generation devices.

The gravity (heavy energy) is used as the leading edge technical breakthrough of mechanical power (kinetic energy) for converting fossil energy power generation of coal, petroleum, natural gas and the like into gravity power generation, so that the dependence of countries around the world on fossil energy such as coal, petroleum, natural gas and the like can be broken, the bottleneck of energy depletion affecting world harmonious development is relieved, and the realization of energy conversion in the early days is facilitated.

A slope type sand, water and soil gravity circulation generator is disclosed in a national patent database, and the publication number is as follows: CN114876750a, publication date: 2022.08.09 the device comprises a slope type steel plate welding bracket, a roller type water turbine unit, a sand-yielding water-soil tank, an Archimedes screw pump, a gear box and a generator; the device supplies sand, water and soil energy storage (gravitational potential energy) through a manual or power screw pump, does not destroy ecology, can effectively reduce the limitations of huge cost and no energy consumption and no recycling of the current power generation construction cost, breaks through the bottleneck of gradually exhausting fossil energy in various countries in the world, breaks through the dependence on fossil energy such as coal, petroleum, natural gas and the like, breaks away from the energy sanctions of geopolitical conflicts, accelerates the iterative upgrading of renewable energy and new energy technologies to realize energy conversion, and makes the gravitational energy benefit mankind early, and can contribute to realizing carbon-peak carbon neutralization by using the slope type sand, water and soil gravity cycle generator, thereby achieving the technological innovation of the power assisted energy and the national construction. The device has the following defects: the device structure is complicated, need the manual work, power screw pump supplies sand, water supply, multiple modes such as supply soil get into first drum-type hydraulic turbine and form sand, water, soil gravity (well can) rotatory whereabouts (kinetic energy), the second drum-type hydraulic turbine is as the circulation motive power of slope sand soil water gravity circulation generator, the device is big to the demand of sand, water, soil, to receiving geographical position restriction great, form the mixture of sand, water, soil in the device inside and carry out the circulation and carry, its inside causes the embolism easily and leads to equipment damage, then leads to the electricity generation to break, the maintenance cost of equipment is also high.

Disclosure of Invention

The utility model aims to overcome the defects in the prior art and provide an auxiliary gravity circulation power generation device which is not influenced by climatic conditions and limited by geographical positions and continuously and stably drives a power generation unit to generate power.

The purpose of the utility model is realized in the following way: the utility model provides an auxiliary type gravity circulation power generation facility, includes the base, be equipped with the support on the base, support top and runner center fixed connection still install generating set at the center of runner, runner peripheral surface equidistant is equipped with the ball frame that is used for placing gravity ball still be equipped with drive mechanism on the base of runner one side, drive mechanism is including setting up the ball groove of advancing on cylinder stand upper portion and setting up at cylinder stand lower part ball groove, the inside cavity of cylinder stand, the fixed setting in bottom is on the base, the ball tip of advancing of ball groove and the ball tip of advancing of ball groove are connected respectively on the ball frame of runner.

Further, the transmission mechanism further comprises a first-stage transmission connecting rod, a second-stage transmission connecting rod, a third-stage transmission connecting rod and a fourth-stage transmission connecting rod which are arranged between the ball outlet groove and the ball inlet groove, the first-stage transmission connecting rod comprises a first telescopic cylinder, a cylinder ejector rod of the first telescopic cylinder penetrates through the ball outlet end of the ball outlet groove and is connected with one end of the first transmission groove, a cylinder ejector rod of the second telescopic cylinder penetrates through the other end of the first transmission groove and is connected with one end of the second transmission groove, and a cylinder ejector rod of the third telescopic cylinder penetrates through the other end of the second transmission groove and is connected to the second-stage transmission connecting rod.

Further, the secondary transmission connecting rod comprises a third transmission groove connected with a cylinder ejector rod of a telescopic cylinder III, the cylinder ejector rod of the telescopic cylinder IV passes through the other end of the third transmission groove to be connected with one end of a fourth transmission groove, and the cylinder ejector rod of the telescopic cylinder V passes through the other end of the fourth transmission groove to be connected to the tertiary transmission connecting rod.

Further, the three-stage transmission connecting rod comprises a fifth transmission groove connected with the cylinder ejector rod of the telescopic cylinder five, the cylinder ejector rod of the telescopic cylinder six passes through the other end of the fifth transmission groove to be connected with one end of the sixth transmission groove, the cylinder ejector rod of the telescopic cylinder seven passes through the other end of the sixth transmission groove to be connected with one end of the seventh transmission groove, and the cylinder ejector rod of the telescopic cylinder eight passes through the other end of the seventh transmission groove to be connected to the four-stage transmission connecting rod.

Further, the four-stage transmission connecting rod comprises an eighth transmission groove connected with a cylinder ejector rod of the telescopic cylinder eight, the cylinder ejector rod of the telescopic cylinder nine passes through the other end of the eighth transmission groove to be connected with one end of the ninth transmission groove, the cylinder ejector rod of the telescopic cylinder ten passes through the other end of the ninth transmission groove to be connected with one end of the tenth transmission groove, and the cylinder ejector rod of the telescopic cylinder eleven passes through the other end of the tenth transmission groove to be connected with a ball inlet end part of the ball inlet groove.

Further, the first telescopic cylinder is communicated with the air storage tank through a pipeline, and the air storage tank is inflated through the rebound air bag.

Further, a soft baffle is arranged on the periphery of the rotating wheel.

Further, at least one group of rotating wheels, brackets and transmission mechanisms are arranged, and the rotating wheels, the brackets and the transmission mechanisms are arranged in one-to-one correspondence.

Further, the gravity ball is an iron ball or a steel ball.

When the utility model works, the gravity ball is fed into the ball frame at the periphery of the rotating wheel by the transmission mechanism from the ball feeding groove at the upper part, and the ball discharging groove at the lower part of the rotating wheel is used for conveying the gravity ball in the ball frame at the periphery of the rotating wheel back into the transmission mechanism along with the rotation of the rotating wheel, and the gravity ball is conveyed into the ball feeding groove at the upper part of the rotating wheel again through the action of the air cylinder, so that the rotating wheel continuously rotates under the action of the gravity ball, and the generator set can convert the mechanical energy of the rotation of the rotating wheel into electric energy under the continuous rotation of the rotating wheel and can be used for families and factories. Compared with the prior art, the utility model has the beneficial effects that: firstly, the auxiliary gravity circulation power generation device is not affected by climate and limited by geographic position, can be installed in combination with an actual building site, can be built indoors to generate power quickly, can also be built into a power generation unit, is built in places with dense personnel and large flow of people, and is used in factories and residential areas with large power demand; secondly, the auxiliary gravity circulation power generation device can also be built into a small power generation model, is arranged and installed in a science and technology museum or an exhibition museum, and plays roles in science popularization and education by performing exhibition and demonstration on groups such as visited students, and converting heavy energy into mechanical energy and then into energy conversion process of electric energy.

Drawings

Fig. 1 is a schematic structural diagram of the present utility model.

Fig. 2 is a schematic structural diagram of the second embodiment of the present utility model.

In the upper drawing, a base 1, a support 2, a rotating wheel 3, a ball inlet groove 4, a ball outlet groove 5, a ball frame 6, a soft baffle 7, an 8-generator set, a 9-cylinder column, a 10-expansion cylinder I, a 11-expansion cylinder II, a 12-expansion cylinder III, a 13-expansion cylinder IV, a 14-expansion cylinder V, a 15-expansion cylinder VI, a 16-expansion cylinder seven, a 17-expansion cylinder eight, a 18-expansion cylinder nine, a 19-expansion cylinder ten, a 20-expansion cylinder eleven, a 21-first transmission groove, a 22-second transmission groove, a 23-third transmission groove, a 24-fourth transmission groove, a 25-fifth transmission groove, a 26-sixth transmission groove, a 27-seventh transmission groove, a 28-eighth transmission groove, a 29-ninth transmission groove, a 30-tenth transmission groove and a 31-gas storage tank.

Detailed Description

Example 1:

the auxiliary gravity circulation power generation device comprises a base 1, wherein a support 2 is arranged on the base 1, the top of the support 2 is fixedly connected with the center of a rotating wheel 3, a generator set 8 is further arranged at the center of the rotating wheel 3, ball frames 6 for placing gravity balls are arranged on the outer peripheral surface of the rotating wheel 3 at equal intervals, a transmission mechanism is further arranged on the base 1 on one side of the rotating wheel 3, the transmission mechanism comprises a ball inlet groove 4 arranged on the upper portion of an air cylinder upright post 9 and a ball outlet groove 5 arranged on the lower portion of the air cylinder upright post 9, the air cylinder upright post 9 is hollow, the bottom of the air cylinder upright post 9 is fixedly arranged on the base 1, and the ball outlet end of the ball inlet groove 4 and the ball inlet end of the ball outlet groove 5 are respectively connected to the ball frames 6 of the rotating wheel 3.

The transmission mechanism further comprises a first-stage transmission connecting rod, a second-stage transmission connecting rod, a third-stage transmission connecting rod and a fourth-stage transmission connecting rod which are arranged between the ball outlet groove 5 and the ball inlet groove 4, wherein the first-stage transmission connecting rod comprises a first telescopic cylinder 10, a cylinder ejector rod of the first telescopic cylinder 10 penetrates through the ball outlet end of the ball outlet groove 5 and is connected with one end of the first transmission groove 21, a cylinder ejector rod of a second telescopic cylinder 11 penetrates through the other end of the first transmission groove 21 and is connected with one end of the second transmission groove 22, and a cylinder ejector rod of a third telescopic cylinder 12 penetrates through the other end of the second transmission groove 22 and is connected to the second-stage transmission connecting rod.

The secondary transmission connecting rod comprises a third transmission groove 23 connected with the cylinder ejector rod of the telescopic cylinder III 12, the cylinder ejector rod of the telescopic cylinder IV 13 passes through the other end of the third transmission groove 23 to be connected with one end of a fourth transmission groove 24, and the cylinder ejector rod of the telescopic cylinder V14 passes through the other end of the fourth transmission groove 24 to be connected with the tertiary transmission connecting rod.

The three-stage transmission connecting rod comprises a fifth transmission groove 25 connected with the cylinder ejector rod of the telescopic cylinder five 14, the cylinder ejector rod of the telescopic cylinder six 15 passes through the other end of the fifth transmission groove 25 to be connected with one end of a sixth transmission groove 26, the cylinder ejector rod of the telescopic cylinder seven 16 passes through the other end of the sixth transmission groove 26 to be connected with one end of a seventh transmission groove 27, and the cylinder ejector rod of the telescopic cylinder eight 17 passes through the other end of the seventh transmission groove 27 to be connected to the four-stage transmission connecting rod.

The four-stage transmission connecting rod comprises an eighth transmission groove 28 connected with a cylinder ejector rod of a telescopic cylinder eight 17, the cylinder ejector rod of a telescopic cylinder nine 18 passes through the other end of the eighth transmission groove 28 to be connected with one end of a ninth transmission groove 29, the cylinder ejector rod of a telescopic cylinder ten 19 passes through the other end of the ninth transmission groove 29 to be connected with one end of a tenth transmission groove 30, and the cylinder ejector rod of a telescopic cylinder eleven 20 passes through the other end of the tenth transmission groove 30 to be connected with the goal end of the goal groove 4.

The first telescopic cylinder 10 is communicated with the air storage tank 31 through a pipeline, and the air storage tank 31 is inflated through a rebound air bag.

The periphery of the rotating wheel 3 is provided with a soft baffle 7, under the rotation of the rotating wheel 3, the gravity ball slowly rolls under the dead weight in the ball frame 6, and the soft baffle 7 is outwards opened after being extruded by the gravity ball, so that the gravity ball falls into the ball outlet groove 5.

The rotating wheel 3, the bracket 2 and the transmission mechanism are at least provided with one group, and the rotating wheel 3, the bracket 2 and the transmission mechanism are arranged in one-to-one correspondence.

The gravity ball is an iron ball or a steel ball.

The auxiliary gravity circulation power generation device of the embodiment 1 is arranged at a place with high flow rate of people, a base 1 and a support 2 are arranged, a runner 3 is arranged at the top of the support 2, a generator set 8 is arranged at the center of the runner 3, a cylinder upright 9 is arranged at one side of the runner 3, the upper part of the cylinder upright 9 is connected with a ball inlet groove 4, the ball outlet end of the ball inlet groove 4 is connected with a ball frame 6 on the runner 3, the lower part of the cylinder upright 9 is connected with a ball outlet groove 5, the ball inlet end of the ball outlet groove 5 is connected with the ball frame 6 on the runner 3, the first telescopic cylinder 10 acts, a cylinder ejector rod of the first telescopic cylinder 10 pushes an iron ball or a steel ball upwards into a first transmission groove 21, the iron ball rolls from the upper end to the lower end of the first transmission groove 21, then a cylinder ejector rod of the second telescopic cylinder 11 pushes the iron ball upwards into a second transmission groove 22, the iron ball rolls from the upper end to the lower end of the second transmission groove 22, then the cylinder ejector rod of the third telescopic cylinder 12 pushes the iron ball upwards into a third transmission groove 23, the iron ball is continuously pushed by the action of the cylinder ejector rod of the third transmission groove 23, the iron ball ejector rod of the third cylinder ejector rod pushes the iron ball upwards into the lower end of the second transmission groove 3, and the iron ball ejector rod 3 continuously rotates down to the iron ball 3 continuously along the lower end of the second transmission groove 3, and the iron ball ejector rod 3 can continuously enters the iron ball frame 3, and the iron ball ejector rod 3 continuously rotates continuously, and the iron ball carrier 3 can continuously enters the iron frame 3 from the ball frame 3, and can continuously enter the iron frame 3, and the electric machine frame 3 continuously rotates and can continuously and continuously enters the ball frame 3.

In order to ensure that a stable and continuous power source is obtained for the cylinder upright post 9, a first telescopic cylinder 10 is communicated with a first air storage tank 31 through a pipeline, the first air storage tank 31 is inflated through a rebound air bag, the circulating power generation device is arranged at places with more people flow, such as squares, subway stations, stations and the like, a ground mat for normal walking is arranged on the ground, the rebound air bag is arranged below the ground mat, when a pedestrian walks on the ground mat, downward pressure is applied to the ground mat, the rebound air bag is inflated into the first air storage tank, and the first air storage tank is connected into the first telescopic cylinder through a pipeline, so that an iron ball is pushed to continuously upwards until reaching a ball feeding groove; the air storage tank can be inflated through electric drive, a generator set in the center of the rotating wheel is connected with the transmission mechanism, and electric energy generated by rotation of the rotating wheel is supplied to the transmission mechanism to drive the iron balls, so that the self-circulation of the power generation device is realized.

When the utility model works, the gravity ball is fed into the ball frame at the periphery of the rotating wheel by the transmission mechanism from the ball feeding groove at the upper part, and the ball discharging groove at the lower part of the rotating wheel is used for conveying the gravity ball in the ball frame at the periphery of the rotating wheel back into the transmission mechanism along with the rotation of the rotating wheel, and the gravity ball is conveyed into the ball feeding groove at the upper part of the rotating wheel again through the action of the air cylinder, so that the rotating wheel continuously rotates under the action of the gravity ball, and the generator set can convert the mechanical energy of the rotation of the rotating wheel into electric energy under the continuous rotation of the rotating wheel and can be used for families and factories.

Example 2:

the specific structure of the embodiment is the same as that of embodiment 1, the auxiliary gravity circulation power generation device of embodiment 2 is installed in a science and technology center and an exhibition center, a small power generation model is built, visual and vivid demonstration is carried out for the visited students and other groups, and the energy conversion process that heavy energy is converted into mechanical energy and then into electric energy is demonstrated, so that the device has popular science and education effects.

The utility model is not limited to the above embodiments, and based on the technical solution disclosed in the utility model, a person skilled in the art may make some substitutions and modifications to some technical features thereof without creative effort according to the technical content disclosed, and all the substitutions and modifications are within the protection scope of the utility model.

Claims

1. An auxiliary gravity circulation power generation device is characterized in that: including the base, be equipped with the support on the base, support top and runner center fixed connection still install generating set at the center of runner, runner peripheral surface equidistant is equipped with the ball frame that is used for placing gravity ball still be equipped with drive mechanism on the base of runner one side, drive mechanism is including setting up the ball groove of advancing on cylinder stand upper portion and setting up at cylinder stand lower part ball groove, the inside cavity of cylinder stand, the fixed setting in bottom is on the base, the ball tip of advancing of ball groove and the ball tip of advancing of ball groove are connected respectively on the ball frame of runner.

2. An auxiliary gravity cycle power plant as claimed in claim 1 wherein: the transmission mechanism further comprises a first-stage transmission connecting rod, a second-stage transmission connecting rod, a third-stage transmission connecting rod and a fourth-stage transmission connecting rod which are arranged between the ball outlet groove and the ball inlet groove, the first-stage transmission connecting rod comprises a first telescopic cylinder, a cylinder ejector rod of the first telescopic cylinder penetrates through the ball outlet end of the ball outlet groove and is connected with one end of the first transmission groove, a cylinder ejector rod of the second telescopic cylinder penetrates through the other end of the first transmission groove and is connected with one end of the second transmission groove, and a cylinder ejector rod of the third telescopic cylinder penetrates through the other end of the second transmission groove and is connected to the second-stage transmission connecting rod.

3. An auxiliary gravity cycle power plant as claimed in claim 2 wherein: the second-stage transmission connecting rod comprises a third transmission groove connected with a cylinder ejector rod of a telescopic cylinder III, the cylinder ejector rod of a telescopic cylinder IV passes through the other end of the third transmission groove to be connected with one end of a fourth transmission groove, and the cylinder ejector rod of a telescopic cylinder V passes through the other end of the fourth transmission groove to be connected to the third-stage transmission connecting rod.

4. An auxiliary gravity cycle power plant according to claim 3, wherein: the three-stage transmission connecting rod comprises a fifth transmission groove connected with a cylinder ejector rod of a telescopic cylinder five, the cylinder ejector rod of the telescopic cylinder six passes through the other end of the fifth transmission groove to be connected with one end of the sixth transmission groove, the cylinder ejector rod of the telescopic cylinder seven passes through the other end of the sixth transmission groove to be connected with one end of the seventh transmission groove, and the cylinder ejector rod of the telescopic cylinder eight passes through the other end of the seventh transmission groove to be connected to the four-stage transmission connecting rod.

5. An auxiliary gravity cycle power plant as claimed in claim 4 wherein: the four-stage transmission connecting rod comprises an eighth transmission groove connected with a cylinder ejector rod of a telescopic cylinder eight, the cylinder ejector rod of the telescopic cylinder nine passes through the other end of the eighth transmission groove to be connected with one end of the ninth transmission groove, the cylinder ejector rod of the telescopic cylinder ten passes through the other end of the ninth transmission groove to be connected with one end of the tenth transmission groove, and the cylinder ejector rod of the telescopic cylinder eleven passes through the other end of the tenth transmission groove to be connected with the ball inlet end of the ball inlet groove.

6. An auxiliary gravity cycle power plant as claimed in claim 2 wherein: the first telescopic cylinder is communicated with the air storage tank through a pipeline, and the air storage tank is inflated through a rebound air bag.

7. An auxiliary gravity cycle power plant as claimed in claim 1 wherein: the periphery of the rotating wheel is provided with a soft baffle.

8. An auxiliary gravity cycle power plant as claimed in claim 1 wherein: the rotating wheel, the support and the transmission mechanism are at least provided with one group, and the rotating wheel, the support and the transmission mechanism are arranged in one-to-one correspondence.

9. An auxiliary gravity cycle power plant as claimed in claim 1 wherein: the gravity ball is an iron ball or a steel ball.