CN113236477B

CN113236477B - Non-contact wave power generation device

Info

Publication number: CN113236477B
Application number: CN202110537069.8A
Authority: CN
Inventors: 王贤成; 鲍灵杰; 陈俊华; 姜楚华; 郑祥辉; 张文杰
Original assignee: College of Science and Technology of Ningbo University
Current assignee: College of Science and Technology of Ningbo University
Priority date: 2021-05-18
Filing date: 2021-05-18
Publication date: 2022-06-03
Anticipated expiration: 2041-05-18
Also published as: CN113236477A

Abstract

The invention discloses a wave energy power generation device, in particular to a non-contact wave energy power generation device which comprises a mandrel, a multi-step shaft, a first pendulum body, a second pendulum body, a first support, a first transmission belt mechanism, a second transmission belt mechanism, a third transmission belt mechanism, a first reversing mechanism, a second reversing mechanism, a third reversing mechanism, a first differential mechanism, a second differential mechanism, a first transmission gear mechanism, a second transmission gear mechanism, a generator, a box body and a second support. The invention solves the technical problem of improving the power generation efficiency of the non-contact wave power generation device. Meanwhile, the invention has the advantages of simple structure, good stability, low use failure rate and the like.

Description

Non-contact wave power generation device

Technical Field

The invention relates to a wave energy power generation device, in particular to a non-contact wave energy power generation device.

Background

Wave energy is a specific form of ocean energy and is one of the most important energy sources in ocean energy, and the development and utilization of the wave energy are very important for relieving the energy crisis and reducing the environmental pollution.

The traditional wave energy power generation device is characterized in that a floater is arranged in water, mechanical motion is generated under the action of waves through the floater, and then mechanical energy is converted into electric energy.

In view of the above situation, chinese invention patent document No. CN201410041601.7 provides a pendulum power generation device using hull oscillation; chinese patent application No. CN202011021944.9 provides an on-board impact type wave generator driven by swinging. Both adopt non-contact wave energy power generation principle, and in the whole process that the wave strikes the hull, through catching the mechanical energy that pendulum (pendulum clock) swayed and produced, the rethread energy conversion device (generator) generates electricity.

However, the conventional non-contact wave power generation device has relatively low power generation efficiency due to structural design problems.

Disclosure of Invention

The invention aims to solve the defects of the prior art and provide a non-contact wave power generation device with relatively high power generation efficiency.

In order to achieve the above object, the present invention provides a non-contact wave power generation device, including:

the system comprises a mandrel, a multi-step shaft, a first pendulum body, a second pendulum body, a first support, a first transmission belt mechanism, a second transmission belt mechanism, a third transmission belt mechanism, a first reversing mechanism, a second reversing mechanism, a third reversing mechanism, a first differential mechanism, a second differential mechanism, a first transmission gear mechanism, a second transmission gear mechanism, a generator, a box body and a second support;

the multi-step shaft is provided with a central through hole along the axis direction, the multi-step shaft comprises a first section, two second sections positioned at two sides of the first section, a third section positioned at the outer side of each second section and a fourth section positioned at the outer side of each third section, and the diameters of the first section to the fourth section are decreased progressively; the first section is provided with a radial opening, a pair of bevel gear pairs is arranged in the radial opening, an articulated shaft penetrates through the driving bevel gear, two shaft ends radially penetrate through the first section and then extend out of the first section, and the articulated shaft is linked with the driving bevel gear; one end part of the mandrel penetrates through the central through hole of the multi-step shaft, extends into the radial opening hole and is linked with the driven bevel gear;

the first pendulum body comprises a pendulum ball, a pendulum rod and a U-shaped hinge; two ends of the U-shaped articulated element are positioned at two radial sides of the first section, correspond to two ends of the articulated shaft one by one and are fixed with each other, one end of the swing rod is fixed on the U-shaped articulated element, and the other end of the swing rod is fixed with the swing ball;

the second pendulum body is of a U-shaped structure, and two end parts of the second pendulum body are respectively fixed on the third section of the multi-step shaft;

two second sections of the multi-step shaft are respectively provided with a first bearing, the inner ring of each first bearing is fixed with the multi-step shaft, and the outer ring of each first bearing is fixed with the first bearing seat on the first support;

the box body is fixed on the second support, and a first reversing mechanism, a second reversing mechanism, a third reversing mechanism, a first differential mechanism, a second differential mechanism, a first transmission gear mechanism, a second transmission gear mechanism and a generator are all arranged in the box body, wherein the first reversing mechanism and the second reversing mechanism are respectively positioned at two sides of the first differential mechanism, the third reversing mechanism is positioned at one side of the second differential mechanism, the first gear transmission mechanism is positioned between the first differential mechanism and the second differential mechanism, and the second gear transmission mechanism is positioned between the second differential mechanism and the generator;

the first reversing mechanism, the second reversing mechanism and the third reversing mechanism respectively comprise a driving gear, two driven gears, a reversing gear, a sliding block and a third support; a guide chute is formed on the third support, a sliding block is positioned in the guide chute and reciprocates along the guide chute, a reversing gear is hinged to the sliding block, a driving gear and two driven gears are respectively hinged to the third support, the driving gear and the two driven gears are respectively positioned on two sides of the guide chute, and the driving gear is always meshed with any one driven gear through the reversing gear;

the first transmission gear mechanism comprises a first transmission gear assembly and a fourth belt transmission mechanism; the first transmission gear shaft of the first transmission gear assembly is hinged to the box body;

the second transmission gear mechanism comprises a second transmission gear assembly and a coupler; wherein, a second transmission gear shaft of the second transmission gear assembly is articulated to the box body;

two input shafts of the first differential and the second differential are respectively provided with a second bearing, the inner ring of each second bearing is fixed with the corresponding input shaft, and the outer ring of each second bearing is fixed with a second bearing seat on the box body;

two input shafts of the first differential mechanism rotate in the same direction, one input shaft is connected with a driven gear of the first reversing mechanism, and are linked with each other, the other input shaft is connected with a driven gear of the second reversing mechanism and is linked with the driven gear, the planet carrier of the first differential is meshed with the first transmission gear of the first transmission gear assembly, the first transmission gear shaft of the first transmission gear assembly is linked with one input shaft of the second differential through the fourth belt transmission mechanism, the other input shaft of the second differential is meshed with one driven gear of the third reversing mechanism, two input shafts of the second differential mechanism rotate in the same direction, a planet wheel carrier of the second differential mechanism is meshed with a second transmission gear of the second transmission gear assembly, and a second transmission gear shaft of the second transmission gear assembly is linked with a motor shaft of the generator through a coupler;

the multi-step shaft is linked with a driving gear of the first reversing mechanism through a first transmission belt mechanism and linked with a driving gear of the second reversing mechanism through a second transmission belt mechanism; the mandrel is linked with a driving gear of a third reversing mechanism through a third transmission belt mechanism.

The differential mechanism adopted in the invention, namely the reverse use of the automobile differential mechanism, takes two output shafts of the automobile differential mechanism as two input shafts, takes a planet wheel carrier originally taken as an input end as an output end, and is combined with three reversing mechanisms, so that the torques with different rotating speeds and different rotating directions generated when a pair of pendulums work simultaneously are integrated into the torques with the same rotating speed and the same rotating direction for collection, and the generator is driven to work efficiently through the transmission relationship of a plurality of rows.

Compared with the prior art, the non-contact wave power generation device has the following advantages: 1. firstly, the swing tracks of a pair of pendulum bodies in the structure of the non-contact wave power generation device are mutually vertical, so that when the non-contact wave power generation device is combined on a ship body to be actually used, the corresponding pendulum bodies can be effectively driven to do reciprocating swinging back motion no matter wave impact in the ship body navigation direction or wave impact in the direction vertical to the ship body navigation direction, and finally, a generator is driven to work efficiently through a plurality of rows of transmission relations;

2. secondly, the invention provides a non-contact wave power generation device, because the first pendulum body in the structure can not only swing back and forth around the multi-step shaft, but also swing back and forth along the axial direction of the multi-step shaft, when the non-contact wave power generation device is combined on a ship body to be actually used, the first pendulum body can be effectively driven to do reciprocating swinging back and forth action no matter wave impact in the ship body navigation direction or wave impact perpendicular to the ship body navigation direction, so as to drive a generator to work efficiently;

3. finally, the non-contact wave power generation device provided by the invention is simple in structure, good in stability and low in use failure rate, and can effectively provide normal electricity for the ship body after being combined with the ship body for use.

Drawings

Fig. 1 is a schematic structural diagram of a non-contact wave power generation device;

FIG. 2 is a schematic view of a multi-step shaft;

FIG. 3 is an exploded view of a reversing mechanism;

fig. 4 is a partial structure schematic diagram I of a non-contact wave energy power generation device;

FIG. 5 is an enlarged partial schematic view at A of FIG. 4;

fig. 6 is a schematic diagram of a part of a non-contact wave energy power generation device.

In the figure: the multi-step shaft type generator comprises a mandrel 1, a multi-step shaft 2, a first swing body 3, a second swing body 4, a first support 5, a first transmission belt mechanism 6, a second transmission belt mechanism 7, a third transmission belt mechanism 8, a first reversing mechanism 9, a second reversing mechanism 10, a third reversing mechanism 11, a first differential mechanism 12, a second differential mechanism 13, a first transmission gear mechanism 14, a second transmission gear mechanism 15, a generator 16, a box body 17, a second support 18, a central through hole 19, a first section 20, a second section 21, a third section 22, a fourth section 23, a radial opening 24, a hinge shaft 25, a driving umbrella-shaped gear 26, a driven umbrella-shaped gear 27, a swing ball 28, a swing rod 29, a U-shaped hinge part 30, a first bearing 31, a first bearing seat 32, a driving gear 33, a driven gear 34, a reversing gear 35, a slide block 36, a third support 37, a guide chute 38, a fourth transmission belt mechanism 39, a first transmission gear 40, a multi-step shaft 2, a first reversing mechanism 8, a second reversing mechanism 18, a second reversing mechanism 9, a third reversing mechanism 20, a third reversing mechanism, a third differential mechanism, a fourth, The transmission gear comprises a coupler 41, a second transmission gear shaft 42, an input shaft 43, a second bearing 44, a second bearing seat 45, a planet carrier 46, a first transmission gear 47, a second transmission gear 48 and a motor shaft 49.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments that can be derived from the embodiments of the present invention by a person of ordinary skill in the art are intended to fall within the scope of the present invention.

As shown in fig. 1 to 6, as an embodiment of the present invention, there is provided a non-contact wave energy power generation device, including:

a mandrel 1, a multi-step shaft 2, a first pendulum body 3, a second pendulum body 4, a first support 5, a first transmission belt mechanism 6, a second transmission belt mechanism 7, a third transmission belt mechanism 8, a first reversing mechanism 9, a second reversing mechanism 10, a third reversing mechanism 11, a first differential 12, a second differential 13, a first transmission gear mechanism 14, a second transmission gear mechanism 15, a generator 16, a box 17 and a second support 18;

as shown in fig. 2, a central through hole 19 is formed in the multi-step shaft 2 along the axial direction of the multi-step shaft, the multi-step shaft 2 includes a first section 20, two second sections 21 located at two sides of the first section 20, a third section 22 located at the outer side of each second section 21, and a fourth section 23 located at the outer side of each third section 22, and the diameters of the first section 20 to the fourth section 23 decrease progressively; a radial opening 24 is formed in the first section 20, a pair of bevel gear pairs is arranged in the radial opening 24, a hinge shaft 25 penetrates through the driving bevel gear 26, two shaft ends radially penetrate through the first section 20 and then extend out of the first section 20, and the hinge shaft 25 is linked with the driving bevel gear 26; one end part of the mandrel 1 penetrates through a central through hole 19 of the multi-step shaft 2, then extends into the radial opening 24 and is linked with a driven bevel gear 27;

the first pendulum body 3 comprises a pendulum ball 28, a pendulum rod 29 and a U-shaped hinge 30; wherein, two ends of the U-shaped hinge 30 are located at two radial sides of the first segment 20, which correspond to two ends of the hinge shaft 25 one by one and are fixed together, one end of the swing link 29 is fixed to the U-shaped hinge 30, and the other end is fixed to the swing ball 28;

the second pendulum body 4 is of a U-shaped structure, and two end parts of the second pendulum body are respectively fixed on the third section 22 of the multi-step shaft 2;

two second sections 21 of the multi-step shaft 2 are respectively provided with a first bearing 31, the inner ring of each first bearing 31 is fixed with the multi-step shaft 2, and the outer ring is fixed with a first bearing seat 32 on the first bracket 5;

the box body 17 is fixed on the second bracket 18, and a first reversing mechanism 9, a second reversing mechanism 10, a third reversing mechanism 11, a first differential mechanism 12, a second differential mechanism 13, a first transmission gear mechanism 14, a second transmission gear mechanism 15 and a generator 16 are all arranged in the box body 17, wherein the first reversing mechanism 9 and the second reversing mechanism 10 are respectively positioned at two sides of the first differential mechanism 12, the third reversing mechanism 11 is positioned at one side of the second differential mechanism 13, the first gear transmission mechanism is positioned between the first differential mechanism 12 and the second differential mechanism 13, and the second gear transmission mechanism is positioned between the second differential mechanism 13 and the generator 16;

as shown in fig. 3, each of the first reversing mechanism 9, the second reversing mechanism 10 and the third reversing mechanism 11 includes a driving gear 33, two driven gears 34, a reversing gear 35, a slider 36 and a third bracket 37; a guide chute 38 is formed on the third bracket 37, a sliding block 36 is positioned in the guide chute 38 and reciprocates along the guide chute 38, a reversing gear 35 is hinged to the sliding block 36, a driving gear 33 and two driven gears 34 are respectively hinged to the third bracket 37, the driving gear 33 and the two driven gears 34 are respectively positioned at two sides of the guide chute 38, and the driving gear 33 is always meshed with any one driven gear 34 through the reversing gear 35;

the first drive gear mechanism 14 includes a first drive gear assembly and a fourth belt drive mechanism 39; wherein, the first transmission gear shaft 40 of the first transmission gear assembly is hinged to the box body 17;

the second transmission gear mechanism 15 comprises a second transmission gear assembly and a coupling 41; wherein, the second transmission gear shaft 42 of the second transmission gear assembly is hinged to the box 17;

two input shafts 43 of the first differential mechanism 12 and the second differential mechanism 13 are respectively provided with a second bearing 44, the inner ring of each second bearing 44 is fixed with the corresponding input shaft 43, and the outer ring thereof is fixed with a second bearing seat 45 on the box body 17;

the two input shafts 43 of the first differential mechanism 12 rotate in the same direction, one input shaft 43 is connected with and linked with one driven gear 34 of the first reversing mechanism 9, the other input shaft 43 is connected with and linked with one driven gear 34 of the second reversing mechanism 10, the carrier 46 of the first differential mechanism 12 is engaged with the first transmission gear 47 of the first transmission gear assembly, the first transmission gear shaft 40 of the first transmission gear assembly is linked with one input shaft 43 of the second differential mechanism 13 through the fourth belt transmission mechanism 39, the other input shaft 43 of the second differential mechanism 13 is engaged with one driven gear 34 of the third reversing mechanism 11, the two input shafts 43 of the second differential mechanism 13 rotate in the same direction, the carrier 46 of the second differential mechanism 13 is engaged with the second transmission gear 48 of the second transmission gear assembly, and the second transmission gear shaft 42 of the second transmission gear assembly is linked with the motor shaft 49 of the generator 16 through the coupler 41;

the multi-step shaft 2 is linked with a driving gear 33 of the first reversing mechanism 9 through a first driving belt mechanism 6, and is linked with a driving gear 33 of the second reversing mechanism 10 through a second driving belt mechanism 7; the mandrel 1 is linked with a driving gear 33 of the third reversing mechanism 11 through a third belt mechanism 8.

The specific working mode of the non-contact wave power generation device is as follows:

this power generation facility combines to use on the hull, no matter be the ascending wave impact of hull navigation direction or the ascending wave impact of perpendicular to hull navigation direction at the whole navigation in-process of hull, all can drive the pendulum body that corresponds (first pendulum body 3 and second pendulum body 4) and do reciprocal backswing action, and then drive multi-step axle 2 and/or dabber 1 and do rotary motion, and then pass through the drive belt structure again, combine reversing mechanism and differential mechanism finally to drive 16 high-efficient work of generator simultaneously.

The present invention is not limited to the above-mentioned preferred embodiments, and any other products in various forms can be obtained by anyone in the light of the present invention, but any changes in the shape or structure thereof, which have the same or similar technical solutions as those of the present application, should fall within the protection scope of the present invention.

Claims

1. A non-contact wave energy power generation device is characterized by comprising:

the multi-step shaft is provided with a central through hole along the axis direction, the multi-step shaft comprises a first section, two second sections positioned at two sides of the first section, a third section positioned at the outer side of each second section and a fourth section positioned at the outer side of each third section, and the diameters of the first section to the fourth section are decreased progressively; the first section is provided with a radial opening, a pair of bevel gear pairs is arranged in the radial opening, an articulated shaft penetrates through the driving bevel gear, two shaft ends radially penetrate through the first section and then extend out of the first section, and the articulated shaft is linked with the driving bevel gear; one end of the mandrel penetrates through the central through hole of the multi-step shaft and then extends into the radial opening hole and is linked with the driven bevel gear;

the first pendulum body comprises a pendulum ball, a pendulum rod and a U-shaped hinged part; two ends of the U-shaped articulated element are positioned at two radial sides of the first section, correspond to two ends of the articulated shaft one by one and are fixed with each other, one end of the swing rod is fixed on the U-shaped articulated element, and the other end of the swing rod is fixed with the swing ball;

two input shafts of the first differential mechanism rotate in the same direction, one input shaft is connected with a driven gear of the first reversing mechanism, and linked with each other, the other input shaft is connected with a driven gear of the second reversing mechanism and linked with each other, the planet carrier of the first differential is meshed with the first transmission gear of the first transmission gear assembly, the first transmission gear shaft of the first transmission gear assembly is linked with one input shaft of the second differential through the fourth belt transmission mechanism, the other input shaft of the second differential is meshed with one driven gear of the third reversing mechanism, two input shafts of the second differential mechanism rotate in the same direction, a planet carrier of the second differential mechanism is meshed with a second transmission gear of the second transmission gear assembly, and a second transmission gear shaft of the second transmission gear assembly is linked with a motor shaft of the generator through a coupler;

the multi-step shaft is linked with a driving gear of the first reversing mechanism through a first driving belt mechanism and linked with a driving gear of the second reversing mechanism through a second driving belt mechanism; the mandrel is linked with a driving gear of a third reversing mechanism through a third transmission belt mechanism.