WO2016095067A1

WO2016095067A1 - Biological physical strength power generating apparatus

Info

Publication number: WO2016095067A1
Application number: PCT/CN2014/001124
Authority: WO
Inventors: 徐振斌
Original assignee: 徐振斌
Priority date: 2014-12-15
Filing date: 2014-12-15
Publication date: 2016-06-23

Abstract

A biological physical strength power generating apparatus. In the apparatus, a certain number and scale of individual organisms are respectively arranged on a group of devices capable of releasing physical strength. The group of devices are provided with a dynamometer, and are connected to a group of small drive gears by means of wheels and axles moved by means of pedaling and swinging. The group of small drive gears are respectively engaged with a big hub under the control of clutches. Or, a group of devices that can release physical strength and that are provided with a dynamometer are fixed to the big hub by means of push-pull devices. The big hub is installed on a perpendicularly and fixedly installed rotating shaft and the height of the big hub can be adjusted, change gear sets are respectively installed on the upper position and the lower position of the big hub on the rotating shaft, and the change gear set, a driving wheel, a booster, a speed increasing box and a big rotor power generator are sequentially connected, so as to achieve automatic, informational and intelligent management of matching devices.

Description

Biological power generation device

Technical field

The invention relates to marginal interdisciplinary technologies such as redevelopment and utilization of traditional physical labor methods, new power generation equipment manufacturing, and large-scale production and application of new renewable clean energy.

Background technique

Solar photovoltaic power generation, wind power, coal power, hydropower, nuclear power, natural gas power generation, biomass power generation, and biogas power generation have been utilized by humans, and power generation technology has been developed. However, bio-power generation and its use in production and life are almost blank, which makes a lot of idle available organisms waste. Moreover, bio-power generation is an ideal renewable energy source, and bio-power generation technology should be highly valued.

The invention is a device for large-scale power generation and practical application for converting biological power into electric power. It is hoped that it will be fully developed and utilized in the fields of production and life, and it will form an obvious substitute for non-renewable and non-clean energy.

For humans, the present invention inherits the traditional way of human physical labor. Can create new jobs to expand employment, and find a new way to solve the employment problem of some special people (such as disabled people who can engage in manual labor, long-term unemployed people who are eager to find employment, and non-compulsory education students who are willing to work and study in family economic difficulties) . It can replace other forms of physical fitness activities, and combine physical fitness activities with the creation of economic, social and ecological values, giving new meaning to physical fitness activities. It is also possible to develop new competitions that combine labor competition and physical fitness, and organize useful labor-type sports competitions.

For animals, the present invention inherits the traditional methods of physical labor, and preserves the servant genes that have been domesticated by humans for millions of years. From a strategic point of view, it can also serve to preserve large-scale livestock. When it encounters an unpredictable extraordinary period, it plays an irreplaceable special role. For example, when there is a sudden shortage of agricultural machinery energy and the road is suddenly damaged, it can be used as a large-scale Agricultural farming and transportation plans to maintain safety in agricultural production and transportation.

Summary of the invention

1. A main axle (axle-1) is vertically mounted between the upper, middle and lower layers of the three-story building, and the main axle (axle-1) is fixed to the upper, middle and lower decks by rolling bearings or On the stand.

2. In the middle layer of the building, with the main axle (axle-1) as the axis, install a hub (hub-1) of sufficient diameter, horizontally mounted, and movable up and down.

3. Around the hub (hub-1), there is a large number of large-scale scales that can release bio-physical strength in the traditional way of pedaling, shaking, pushing and pulling, and can perform dynamometer work on the work of each individual organism. Device (device group-1).

4. The device group-1 is respectively connected with a set of small driving gears through the pedals which are stepped and rocked, and the small driving gears are respectively vertically meshed with the teeth on the edge of the large hub (hub-1) through the control of the clutches; Alternatively, the device set-1 is fixed to the edge of the large hub (hub-1) by a push-pull device, respectively.

5. In the upper and lower floors of the building, with the main axle (axle-1) as the axis, fix a belt (or chain, tooth) wheel with a larger diameter (greater than the hub-1) (wheel 1-up, Wheel 1 - down).

6. Two larger diameter (greater than hub-1) belt (or chain, tooth) wheels (wheel 1 - up, wheel 1 - down) through the drive belt (or chain, gear teeth) respectively installed with the upper and lower diameter The smaller drive wheels (wheel 2 - up, wheel 2 - down) constitute the transmission relationship.

7. Two smaller diameter drive wheels (wheel 2 - upper, wheel 2 - bottom) are connected to the upper and lower mounted crankshafts (crank 1 - up, crank 1 - down).

8. Two crankshafts (Crank 1 - Upper, Crank 1 - Bottom) are connected to the upper and lower installed booster groups (Poster Group - Upper, Booster Group - Bottom).

9. The output of the two booster groups (the booster group - the upper, the booster group - the lower) are respectively connected to the upper and lower layers of the crankshaft (crank 2 - up, crank 2 - down).

10. The output ends of another set of crankshafts (crankshaft 2 - upper, crankshaft 2 - down) are respectively connected to the upper and lower installed speed increasing boxes (increasing speed box - upper, speed increasing box - lower).

11. The output terminals of the speed increasing box (increasing speed box - upper, speed increasing box - lower) are fixedly installed with the upper and lower mounted large rotor generators (large rotor generator - upper, large rotor generator - lower).

detailed description

1. A main axle (axle-1) is vertically mounted between the upper, middle and lower layers of the three-story building, and the main axle (axle-1) is fixed to the upper, middle and lower decks by rolling bearings or On the bracket, the main axle (axle-1) is free to rotate.

2. In the middle layer of the building, with the main axle (axle-1) as the axis, install a hub (hub-1) of sufficient diameter, horizontally mounted, and movable up and down. The rotation of the hub (hub-1) drives the rotation of the main axle (axle-1).

3. Around the hub (hub-1), a large number of large-scale configuration of biological groups on devices capable of releasing physical strength and separately measuring dynamometer work can be performed in a traditional manner such as squatting, shaking, pushing and pulling, The hub (hub-1) is driven to rotate by a small drive gear with a clutch function (far smaller than the hub-1) or a push-pull drive.

4. The device capable of releasing physical strength and separately measuring the force of the force is suitable for the biological individual to perform work by pedaling, shaking, pushing and pulling, and measuring the work of the biological individual in the working state.

5. The installation of the hub (hub-1) can move the device up and down, in order to meet the needs of a variety of different heights of biological work and increase the proportion of effective work.

6. The diameter of the hub (hub-1) is large enough to be able to mesh with more small drive gears or to be able to install more push-pull drives, providing a common working place for more biological individuals, and Enough to achieve high power generation. In addition, when the push-pull drive is used, the diameter of the hub (hub-1) is large enough to eliminate as much as possible the stun caused by the circular motion to the biological individual.

7. When the small drive gear with the clutch function (far smaller than the hub-1) is in the working state, it will automatically mesh with the gear on the edge of the hub (hub-1); when it is not in operation, it will Automatically separated from the gear on the edge of the hub (hub-1).

8. In the upper and lower floors of the building, with the main axle (axle-1) as the axis, fix a belt (or chain, tooth) wheel with a larger diameter (greater than the hub-1) (wheel 1-up, Wheel 1 - down) rotates as the hub (hub-1) rotates.

9. Rotating on two belt (or chain, tooth) wheels (wheel 1 - up, wheel 1 - down) with larger diameter (greater than hub - 1) During the process, the transmission belt (or chain, gear teeth) drives the upper and lower diameter mounting wheels (wheel 2 - up, wheel 2 - bottom) to rotate rapidly.

10. Two smaller diameter drive wheels (wheel 2 - up, wheel 2 - down) drive the upper and lower mounted crankshafts (crank 1 - up, crank 1 - down) respectively.

11. Two crankshafts (Crank 1 - Upper, Crank 1 - Down) respectively drive the upper and lower installed force booster groups (enhanced force group - upper, booster group - lower).

12. The output of the two booster groups (the booster group - the upper, the booster group - the lower) respectively drive the other set of crankshafts (crank 2 - up, crank 2 - down) installed in the upper and lower layers. The role of the booster is to amplify the biological force to meet the needs of the normal rotation of the large rotor generator.

13. Another set of crankshafts (crankshaft 2 - upper, crankshaft 2 - down) is further installed on the upper and lower layers by the speed increasing boxes (increasing speed box - upper, speed increasing box - lower) respectively installed in the upper and lower layers. Large-rotor generators (large-rotor generators - upper and large rotor generators - under) high-power generation. The role of the speed increase box is to increase the operating speed of the generator rotor.

Claims

The invention discloses a biological power generating device, which is characterized in that biological force movement is converted into mechanical energy by pedaling, shaking, pushing and pulling device, etc., and then through the axle, the driving gear, the gear teeth, the hub, the rolling bearing, the belt (or the chain) , tooth) wheel, transmission wheel, crankshaft, booster group, speed-increasing box, large-rotor generator, etc., which further transmit mechanical power, increase power, speed up and generate electricity, and pass the device of moving up and down, clutch, and dynamometer Such as the height of the appropriate biological individual, the control of the working clutch state and the physical exertion of each organism.
According to claim 1, the invention is also characterized in that a main axle (axle-1) needs to be vertically mounted between the upper, middle and lower layers of the three-story building, and the main axle (axle-1) is fixed by the rolling bearing respectively. The main axle (axle-1) can be freely rotated on the upper, middle and lower decks or brackets, wherein the number of layers of the building can also be changed, which can be one or more layers, the axle (axle-1) In addition to the vertical installation, it can be installed at other angles or positions by adding transmission parts. In order to enhance the bearing capacity of the rolling bearing, the number of rolling bearings can be increased by installing on the bracket as needed.
According to claim 1, the invention is also characterized in that, in the intermediate layer of the building, a hub having a diameter large enough, horizontally mounted, and movable up and down (the hub-1) is mounted with the main axle (axle-1) as the axis. ), the rotation of the hub (hub-1) drives the rotation of the main axle (axle-1), wherein the intermediate layer of the building can also be any other layer, and the mounting hub (hub-1) can be moved up and down for more suitable The need for different heights of individual work and the need to increase the proportion of effective work, the diameter of the hub (hub-1) is large enough to be able to mesh with more small drive gears or to be able to install more push-pull drives, A large number of biological individuals provide a common workplace and are sufficient for high-power generation. In addition, when the push-pull drive is used, the diameter of the hub (hub-1) is large enough to eliminate the circular motion as much as possible for the biological individual. dizziness.
According to claim 1, the invention is further characterized in that: around the hub (hub-1), a large number of scales can be used to release the biological force in a conventional manner such as pedaling, shaking, pushing and pulling, and can respectively be used for each A device for measuring dynamometer work (device group-1) is operated by a biological individual. The device group-1 is connected to a group of small driving gears by a pedaling and rocking axle, respectively, and the small driving gears are controlled by a clutch and a large The teeth on the edge of the hub (hub-1) are vertically meshed, or the device set-1 is fixed to the edge of the large hub (hub-1) by means of a push-pull device, respectively, wherein a small drive gear with a clutch function is installed ( It is far smaller than the hub-1). It automatically meshes with the gear on the edge of the hub (hub-1) when it is in working condition, and automatically separates from the gear on the edge of the hub (hub-1) when it is not in operation. .
According to claim 1, the invention is also characterized in that, in the upper and lower layers of the building, a belt having a larger diameter (greater than the hub-1) (or a chain) is fixedly mounted with the main axle (axle-1) as the axis. , the tooth) wheel (wheel 1 - up, wheel 1 - down) rotates with the rotation of the hub (hub-1), wherein the upper and lower layers of the building can also be changed to other layers, or one of the layers can be reduced. Belts (or chains, teeth) with larger diameters (greater than hub-1) (wheel 1 - top, wheel 1 - bottom) can also be increased in number or reduced in number.
According to claim 1, the invention is also characterized in that, during the rotation of two belts (or chains, teeth) wheels (wheel 1 - up, wheel 1 - down) having a larger diameter (greater than the hub-1), The drive belt (or chain, gear teeth) respectively drives the upper and lower mounted smaller diameter drive wheels (wheel 2 - up, wheel 2 - down) to rotate rapidly, wherein according to the power requirement 5, when the diameter is larger (greater than the hub - 1) When the number of belt (or chain, tooth) wheels (wheel 1 - top, wheel 1 - bottom) increases or decreases, The number of moving belts (or chains, teeth) and smaller diameter transmission wheels (wheel 2, upper 2, lower 2) are correspondingly increased or decreased.
According to claim 1, the invention is also characterized in that two smaller diameter transmission wheels (wheel 2 - upper, wheel 2 - bottom) respectively drive the upper and lower mounted crankshafts (crank 1 - up, crank 1 - down) Rotating, two crankshafts (crank 1 - up, crank 1 - down) respectively drive the upper and lower installed force booster groups (enhanced force group - upper, booster group - lower), two booster groups (the booster group - upper, booster group - lower) output end drives a set of crankshafts (crank 2 - up, crank 2 - down) installed in the upper and lower layers respectively, wherein the force booster is for Amplifying the biological force to meet the needs of the normal rotation power generation of the large rotor generator, and according to the power requirement 6, when the number of the smaller diameter transmission wheels (wheel 2 - up, wheel 2 - down) increases or decreases, the crankshaft ( The number of crankshaft 1 - up, crankshaft 1 - down), booster group (enhanced force group - upper, booster group - lower) and crankshaft (crank 2 - up, crank 2 - down) are also increased accordingly In addition, the crankshaft (crank 1 - up, crank 1 - down), booster set (enhanced force group - upper, booster set - lower) and crankshaft (crank 2 - upper, crankshaft 2) can be canceled according to the situation. Bottom) component, when When the crankshaft (crank 1 - up, crank 1 - down), booster set (pot force group - upper, booster group - lower) and crankshaft (crank 2 - up, crank 2 - down) components are eliminated The components are connected in order.
According to claim 1, the invention is further characterized in that another set of crankshafts (crankshaft 2 - upper, crankshaft 2 - down) are respectively installed in the upper and lower speed increasing boxes (increasing speed box - upper, speed increasing box - lower) Further driving the large-rotor generators (large-rotor generator-upper, large-rotor generator-down) installed in the upper and lower layers respectively, wherein the speed increasing box functions to increase the operating speed of the generator rotor, and according to the power Requirement 7, when the number of crankshafts (crankshaft 2 - up, crankshaft 2 - down) increases or decreases, the speed increase box (increasing speed box - upper, speed increasing box - lower) and the large rotor generator (large rotor generator - The number of upper and large rotor generators - down) is also increased or decreased accordingly. In addition, the speed increase box (speed increase box - upper, speed increase box - down) can be cancelled according to the situation, when the speed increase box (speed increase box - When the upper speed increase box is down, the remaining components are connected in sequence.
According to claim 1 to claim 8, the present invention is also characterized in that a plurality of sets of biophysical power generation devices and biological power generation devices of the present invention are integrated into a larger combined (or composite) biological power generation device. .