阅读说明：本技术 一种振动微能量收集装置 (Little energy collection device of vibration ) 是由 黄峰 吴少杰 于 2019-09-30 设计创作，主要内容包括：本发明公开了一种振动微能量的收集装置。包括盖板、四个运动件、四块挡板、四个L形连接件和底座；挡板等间距布置在盖板和底座内,围成的正方形内装有带磁芯的三个十字形绕线件,每个绕线件四端绕制感应线圈；运动件分别置于相邻挡板间隙中,连接件均位于各自挡板外,将连接件和各自运动件用连接杆连接成一个整体,能在四块挡板上滑动。每个运动件内均有二块永磁体与导磁件组成,各自相邻且磁极相反的两端与运动件形成一个完整的闭合磁路。当受到外界振动时,运动件在上中磁芯与中下磁芯间运动,使中央磁芯内的磁通量发生反转,上下磁芯内的磁通量发生变化,绕制在各端上的感应线圈内产生感应电动势。本发明可收集工作台及人体运动中产生的能量。(The invention discloses a collection device for vibration micro-energy. The device comprises a cover plate, four moving parts, four baffles, four L-shaped connecting parts and a base; the baffles are arranged in the cover plate and the base at equal intervals, three cross-shaped winding pieces with magnetic cores are arranged in a square formed by the baffles, and induction coils are wound at four ends of each winding piece; the moving parts are respectively arranged in the gaps of the adjacent baffles, the connecting parts are respectively positioned outside the baffles, and the connecting parts and the moving parts are connected into a whole by connecting rods and can slide on the four baffles. Each moving part is internally provided with two permanent magnets and magnetic conduction parts, and two ends which are adjacent to each other and have opposite magnetic poles form a complete closed magnetic circuit with the moving part. When the vibration is received by the outside, the moving part moves between the upper middle magnetic core and the middle lower magnetic core, so that the magnetic flux in the central magnetic core is reversed, the magnetic fluxes in the upper magnetic core and the lower magnetic core are changed, and the induced electromotive force is generated in the induction coils wound on the ends. The invention can collect the energy generated in the working table and the human body movement.)

1. A vibration micro-energy collection device is characterized in that: comprises a cover plate (1), four moving parts (2), four baffle plates (3), four L-shaped connecting parts (4) and a base (5); four baffles (3) are arranged in a cover plate (1) and a base (5) at equal intervals in a square shape, a gap is formed between every two adjacent baffles, three cross-shaped winding parts (10) which have the same size, are aligned in parallel and are arranged at equal intervals are arranged in the square shape surrounded by the four baffles (3), a cross-shaped magnetic core is arranged in each winding part and is an upper magnetic core (6), a middle magnetic core (7) and a lower magnetic core (8), and an induction coil (8) is wound outside each four ends of each winding part; the four moving parts (2) are respectively arranged in gaps formed between adjacent baffles, the moving tracks of the four moving parts (2) are limited by the gaps between the adjacent baffles, the four L-shaped connecting parts (4) are respectively positioned outside the baffles (3), and in order to ensure that the four moving parts (2) can move synchronously, the four L-shaped connecting parts (4) and the moving parts are respectively connected into a whole by connecting rods and can slide up and down on the four baffles (3);

the lower end face of the cover plate (1) above the four moving parts (2) is provided with a rubber magnetic strip (11), and the upper end face of the base (5) below the four moving parts (2) is provided with the rubber magnetic strip (11); the upper and lower end faces of the four moving parts (2) are also provided with rubber magnetic stripes (11), and the rubber magnetic stripes (11) on the upper and lower end faces of the four moving parts (2) correspond to the rubber magnetic stripes (11) on the lower end face of the cover plate (1) and the rubber magnetic stripes (11) on the upper end face of the base (5).

2. A vibratory micro energy harvesting device as set forth in claim 1 wherein: each moving part is fixed by an upper permanent magnet (12), a lower permanent magnet (12) and a magnetic conduction part (13) on the outer side through a moving part plastic frame (14) to form a horseshoe-shaped magnet respectively.

3. A vibratory micro energy harvesting device as set forth in claim 1 wherein: when the moving parts are arranged on the upper magnetic core (6) and the middle magnetic core (7) or the middle magnetic core (7) and the lower magnetic core (8), two ends which are adjacent to each other and have opposite magnetic poles and each moving part form a complete closed magnetic circuit, and the moving parts are driven to move upwards or downwards along the baffle plates (3) by external vibration.

4. A vibratory micro energy harvesting device as set forth in claim 1 wherein: the cross-shaped magnetic core has two different magnetic circuits according to different magnetizing directions; when the magnetic poles of the opposite surfaces in the two opposite moving parts are opposite, an internal magnetic circuit of the magnetic core is formed; when the magnetic poles of the opposite surfaces of two opposite moving parts are the same and the magnetic poles of the two adjacent ends are opposite, another magnetic core internal magnetic circuit is formed.

5. A vibratory micro energy harvesting device as set forth in claim 1 wherein: the upper magnetic core (6), the middle magnetic core (7) and the lower magnetic core (8) are made of ferrite or industrial pure iron, and the induction coil (9) is a copper wire.

6. A vibratory micro energy harvesting device as set forth in claim 2 wherein: the permanent magnets (12) in the four moving parts (2) are made of neodymium iron boron, and the magnetic conduction parts (13) are made of industrial pure iron or ferrite.

7. A vibratory micro energy harvesting device as set forth in claim 2 wherein: the section of the permanent magnet (12) is rectangular.

Technical Field

The invention relates to an energy collecting device, in particular to a vibration micro-energy collecting device.

Background

As sensor networks are developed and applied in various complex environments, conventional chemical material batteries have limited stored energy; short service life and frequent replacement; the long service time may cause the leakage of chemical raw materials, and a new power supply mode which can continuously generate power, has a longer service life and is less influenced by environmental factors compared with the traditional battery needs to be found, and the energy collection technology is paid attention to because of meeting the characteristics.

Disclosure of Invention

The invention aims to provide a vibration micro-energy collecting device which can convert external vibration into electric energy to supply power for a subsequent low-power-consumption circuit.

For the purpose of the invention, the technical scheme adopted by the invention is as follows:

the invention comprises a cover plate, four moving parts, four baffles, four L-shaped connecting parts and a base; the four baffles are arranged in the cover plate and the base in an equidistant square mode, gaps are formed between every two adjacent baffles, three cross-shaped winding parts which are the same in size, aligned in parallel and arranged at equal intervals are arranged in the square defined by the four baffles, a cross-shaped magnetic core is arranged in each winding part and is an upper magnetic core, a middle magnetic core and a lower magnetic core, and induction coils are wound outside the four ends of each winding part; the four moving pieces are respectively arranged in gaps formed between adjacent baffles, the moving tracks of the four moving pieces are limited by the gaps of the adjacent baffles, the four L-shaped connecting pieces are positioned outside the baffles respectively, and in order to ensure that the four moving pieces can move synchronously, the four L-shaped connecting pieces and the moving pieces are respectively connected into a whole by connecting rods and can slide up and down on the four baffles;

the lower end face of the cover plate above the four moving parts is provided with a rubber magnetic strip, and the upper end face of the base below the four moving parts is provided with a rubber magnetic strip; the upper and lower end faces of the four moving parts are also provided with rubber magnetic stripes, and the rubber magnetic stripes of the upper and lower end faces of the four moving parts correspond to the rubber magnetic stripes of the lower end face of the cover plate and the rubber magnetic stripes of the upper end face of the base.

Each moving part is fixed by an upper permanent magnet and a lower permanent magnet which are the same and a magnetic conduction part on the outer side through a moving part plastic frame to respectively form a horseshoe-shaped magnet.

When the moving parts are arranged on the upper magnetic core and the middle magnetic core or the middle magnetic core and the lower magnetic core, the two ends which are adjacent to each other and have opposite magnetic poles and each moving part form a complete closed magnetic circuit, and the moving parts are driven to move upwards or downwards along the baffle plates by external vibration.

The cross-shaped magnetic core has two different magnetic circuits according to different magnetizing directions; when the magnetic poles of the opposite surfaces in the two opposite moving parts are opposite, an internal magnetic circuit of the magnetic core is formed; when the magnetic poles of the opposite surfaces of two opposite moving parts are the same and the magnetic poles of the two adjacent ends are opposite, another magnetic core internal magnetic circuit is formed.

The upper magnetic core, the middle magnetic core and the lower magnetic core are made of ferrite or industrial pure iron, and the induction coil is a copper wire.

The permanent magnets in the four moving parts are made of neodymium iron boron, and the magnetic conduction parts are made of industrial pure iron or ferrite.

The section of the permanent magnet is rectangular.

The invention has the beneficial effects that:

the invention has simpler structure, the device contains less parts, each part can be separately and independently processed, and the assembly is simple; the volume is small, and the micro-energy vibration sensor can be integrated into products such as a wireless switch and the like which need a vibration micro-energy collection device; the rubber magnetic strips are respectively arranged at the collision positions of the moving part and the fixed part, so that the damage caused by collision can be effectively reduced, and the kinetic energy of the moving part can be converted into potential energy; the induction coil array is used, the induction coils are arranged at four ends of three magnetic cores, the magnetic flux in the central magnetic core of the device is completely reversed once, so that large induced electromotive force can be generated, and meanwhile, the magnetic flux in the upper magnetic core and the lower magnetic core also changes in the motion process and can also generate induced electromotive force; meanwhile, the gap between the permanent magnet and the magnetic core is small, the magnetic leakage is small, and large induced electromotive force can be generated.

The invention can collect the vibration energy generated in the working environment such as the workbench and the like, and can also collect the energy generated in the biological environment such as the human motion and the like.

Drawings

FIG. 1 is a three-dimensional schematic of the structure of the present invention.

Fig. 2 is a sectional view taken along line a-a of fig. 1.

Fig. 3 is a schematic diagram of the principle of the present invention.

Fig. 4 is a diagram of a toroidal magnetic circuit with the moving member in the upper center core position, opposite in polarity to the permanent magnets.

Fig. 5 is a view of a toroidal magnetic circuit with the moving member in a middle lower core position, opposite in magnetic polarity to the permanent magnets.

Fig. 6 is a top view of the magnetic circuit in the upper core at the opposite position in the toroidal magnetic circuit with respect to the poles of the permanent magnets.

Fig. 7 is a diagram of a toroidal magnetic circuit with the moving member in the upper center core position, with the same magnetic poles with respect to the permanent magnets.

Fig. 8 is a view of a toroidal magnetic circuit with the same magnetic pole with respect to the permanent magnet and the mover located at the lower center core position.

Fig. 9 is a top view of the magnetic circuit with the same magnetic pole relative to the permanent magnet and relative to the upper core in the toroidal magnetic circuit.

Figure 10 is a three-dimensional schematic of the fastener construction of the present invention.

Fig. 11 is a three-dimensional schematic view of the structure of four moving parts of the present invention connected together by connecting members.

Fig. 12 is a sectional view taken along line B-B of fig. 11.

Fig. 13 is a three-dimensional schematic view of the spool structure.

In the figure: 1. the magnetic-inductive magnetic-field-generating device comprises a cover plate, 2, a moving part, 3, a baffle plate, 4, an L-shaped connecting piece, 5, a base, 6, an upper magnetic core, 7, a middle magnetic core, 8, a lower magnetic core, 9, an inductive coil, 10, a winding part, 11, a rubber magnetic strip, 12, a permanent magnet, 13, a magnetic conducting part, 14, a moving part plastic frame and 15 partition plates.

Detailed Description

The invention is further described below with reference to the accompanying drawings and examples.

As shown in fig. 1, 2, 3, 10, 11, 12 and 13, the invention comprises a cover plate 1, four moving parts 2, four baffle plates 3, four L-shaped connecting parts 4 and a base 5; four baffles 3 (the cross section of each baffle is square or L-shaped) are arranged in a square in equal interval in a cover plate 1 and a base 5, a gap is formed between every two adjacent baffles 3, three cross-shaped winding parts 10 (a partition plate 15 can be added between every two adjacent winding parts 10 for equal interval separation) which are the same in size, aligned in parallel and arranged at equal interval are arranged in the square surrounded by the four baffles 3, a cross-shaped magnetic core is respectively arranged in each winding part 10 and is respectively an upper magnetic core 6, a middle magnetic core 7 and a lower magnetic core 8, and an induction coil 9 is wound outside each four ends of each winding part 10; four moving parts 2 are respectively arranged in the gaps formed between the adjacent baffles 3, the moving tracks of the four moving parts 2 are limited by the gaps of the adjacent baffles 3, the four L-shaped connecting parts 4 are respectively positioned outside the baffles 3, and in order to ensure that the four moving parts 2 can move synchronously, the four L-shaped connecting parts 4 and the moving parts 2 are respectively connected into a whole by connecting rods, so that the four moving parts can slide up and down on the four baffles 3.

The four ends of each wire winding piece 10 are wound with induction coils 9 to form a coil array, when 2 pieces of motion are performed, the magnetic flux in the central magnetic core can be reversed, and the magnetic fluxes in the upper magnetic core and the lower magnetic core can be changed, so that induced electromotive force can be generated in each induction coil 9, and the induced electromotive force generated by each induction coil is rectified together through an external circuit.

As shown in fig. 1, 2 and 10, the device drives the moving member 2 to move up and down by external vibration, and in order to prevent the frame from being damaged by the violent movement of the device, rubber magnetic strips 11 are respectively arranged at the contact parts of four horseshoe-shaped magnet parts of the moving member 2 with the cover plate 1 and the base 5 to buffer the impact force and convert the kinetic energy into potential energy. Namely, the lower end surface of the cover plate 1 above the four moving parts 2 is provided with a rubber magnetic strip 11, and the upper end surface of the base 5 below the four moving parts 2 is provided with a rubber magnetic strip 11; the upper and lower terminal surfaces of the four moving parts 2 are also provided with rubber magnetic strips 11, and the rubber magnetic strips 11 on the upper and lower terminal surfaces of the four moving parts 2 correspond to the rubber magnetic strips 11 on the lower terminal surface of the cover plate 1 and the rubber magnetic strips 11 on the upper terminal surface of the base 5.

As shown in fig. 1, 2 and 11, each moving part 2 is formed by fixing an upper permanent magnet 12, a lower permanent magnet 12 and an outer magnetic conductive part 13 together through a moving part plastic frame 14 to form a horseshoe-shaped magnet respectively.

As shown in fig. 2, when the moving element 2 is disposed on the upper magnetic core 6 and the middle magnetic core 7 or the middle magnetic core 7 and the lower magnetic core 8, the two adjacent ends with opposite magnetic poles and each moving element 2 form a complete closed magnetic circuit, and the moving element 2 is driven to move up or down along the respective baffle 3 by external vibration.

As shown in fig. 4, 5, 6, 7, 8, and 9, the cross-shaped magnetic core has two different magnetic paths according to different magnetizing directions; when the magnetic poles of the opposite surfaces in the two opposite moving parts are opposite, an internal magnetic circuit of the magnetic core is formed; when the magnetic poles of the opposite surfaces of two opposite moving parts are the same and the magnetic poles at two adjacent ends are opposite, another magnetic core internal magnetic circuit is formed; in two different magnetic circuit states, when the moving part is respectively positioned at the upper middle magnetic core or the middle lower magnetic core, the inner closed magnetic circuit is shown in the figure.

The upper magnetic core 6, the middle magnetic core 7 and the lower magnetic core 8 are made of ferrite or industrial pure iron, and the induction coil 9 is a copper wire.

The permanent magnets 12 in the four moving parts 2 are made of neodymium iron boron, and the magnetic conduction parts 13 are made of industrial pure iron or ferrite.

The cross section of the permanent magnet 12 is rectangular.

The working principle of the invention is as follows:

as shown in fig. 4, 5, 6, 7, 8, 9, the magnetic poles of the same group of permanent magnets 12 facing the magnetic core are opposite, i.e. if the permanent magnet 12 in one moving member 2 faces the magnetic core as the N pole, the permanent magnet 12 in the same moving member 2 faces the magnetic core as the S pole, while the magnetic poles of two opposite permanent magnets 12 on the same magnetic core can be the same or opposite, and the magnetic poles of two permanent magnets 12 facing the magnetic core at two adjacent ends of the same magnetic core must be opposite, so that the horseshoe-shaped magnets of two moving members 2 can form a complete annular magnetic circuit with the upper magnetic core 6 and the middle magnetic core 7 or the middle magnetic core 7 and the lower magnetic core 8.

When the sections of the permanent magnet and the magnetic core are aligned, namely, the permanent magnet and the magnetic core are positioned in the positions shown in fig. 4, 5, 7 and 8, the permanent magnet-the magnetic core-the permanent magnet-the magnetic core form a closed magnetic ring, the air gap is small, the magnetic leakage rate is small, and the utilization rate of the magnetic field is improved.

As shown in fig. 1, 2, 4, 5, 7 and 8, when the device is excited by external vibration, the moving member 2 moves between the upper core 6 and the middle core 7 and between the middle core 7 and the lower core 8, so that the magnetic induction lines passing through the middle core 7 are reversed, and the magnetic fluxes in the upper core 6 and the lower core 8 are changed, thereby generating induced electromotive force in each induction coil 9 according to the principle of electromagnetic induction. The induced electromotive forces need to be rectified together through an external circuit, and then energy is collected by a capacitor to be used as a power supply source of some low-power consumption application circuits.