JP6099538B2 - Vibration power generator using magnetostrictive element - Google Patents

Description

  The present invention relates to a vibration power generation apparatus that generates electric power by converting vibration energy into electric energy, and more particularly to a magnetostrictive vibration power generation apparatus that uses an inverse magnetostriction effect due to deformation of a magnetostrictive element.

  Conventionally, as a power generator that converts vibration energy into electric energy, a power generator that uses the inverse magnetostrictive action of a magnetostrictive element has been proposed. For example, the one described in Japanese Patent No. 4905820 (Patent Document 1) is a structure in which a coil is wound around a magnetostrictive rod as a magnetostrictive element.

  And in the electric power generating apparatus using such a magnetostrictive element, the magnetostrictive rod is repeatedly compressed and deformed by being attached to the vibrating body and by the vibration exerted from the vibrating body. By applying a magnetic field change caused by the inverse magnetostrictive action to the coil as the compression deformation of the magnetostrictive rod is repeated, an electromotive force due to the electromagnetic induction action is taken out from the coil.

  By the way, in the power generation device using such a magnetostrictive element, improvement of conversion efficiency from vibration energy to electric energy is considered as one of the problems.

  However, in a power generation device using a magnetostrictive element, an effective technique for improving the conversion efficiency from vibration energy to electric energy has not yet been realized.

  In Patent Document 1, for example, by using a plurality of magnetostrictive elements, the bending load of the member is used as the vibration load in the compression direction with respect to the magnetostrictive element, thereby utilizing the bending resonance of the member. A technique for improving the efficiency of changing vibration energy into electric energy has also been proposed. However, the power generation efficiency of each magnetostrictive element is still difficult to obtain, and there is a problem that it is difficult to put it to practical use because many magnetostrictive elements that are difficult to manufacture and obtain and cause high costs are required. .

Japanese Patent No. 4905820

  The present invention has been made in the background of the above-mentioned circumstances, and the problem to be solved is vibration using a magnetostrictive element having a novel structure capable of improving the conversion efficiency of vibration energy into electric energy. It is to provide a power generation device.

  A first aspect of the present invention is a vibration power generation device that is attached to a vibration member and converts vibration energy into electric energy using the inverse magnetostriction effect of the magnetostrictive material, and is made of a magnetostrictive material and wound with a first coil. A bias magnetic field exerted from the magnet and the yoke member is applied in parallel to the first power generation element and the second power generation element made of a magnetic material that is not a magnetostrictive material and wound with the second coil. A change in magnetic flux due to the bias magnetic field induced in the first power generation element by vibration exerted from the vibration member is extracted as electric energy by the first coil; A change in magnetic flux of the second power generating element caused by a change in magnetic flux accompanying compression and tensile deformation is extracted as electric energy by the second coil. The vibration generating apparatus of the magnetostrictive element utilized was characterized.

  In the vibration power generation device of this aspect, paying attention to the change in magnetoresistance caused by the first power generation element that is a magnetostrictive element, the second power generation element that exerts a bias magnetic field in parallel with the first power generation element, It was constructed without using a magnetostrictive material. In such a parallel magnetic circuit, the magnetoresistance of the first power generating element and the magnetic permeability thereof are changed based on the inverse magnetostrictive action of the magnetostrictive element, and therefore, the magnetic circuit is composed of a simple magnetic material instead of the magnetostrictive element. The magnetic flux is also changed in the second power generation element. Therefore, the main dynamic change of the magnetic flux in the first power generation element that is deformed by vibration is taken out as electric energy by the first coil, and the second power is passively induced in accordance with the change in the magnetic flux of the first power generation element. The change in magnetic flux in the second power generation element can be taken out as electrical energy by the second coil. As a result, it is possible to improve the conversion efficiency from vibration energy to electric energy in the vibration power generation device using the magnetostrictive element by using the second power generation element composed of a simple magnetic material without using a special material called a magnetostrictive material. It can be done.

  In the vibration power generation device of the present invention, the first power generation element in which the main dynamic magnetic flux is generated needs to be stressed by the vibration external force, but with the change in the magnetic resistance of the first power generation element. The second power generating element in which the passive magnetic flux change is generated does not need to be stressed by the vibration external force. Therefore, the second power generating element can have a structure in which a vibration external force is not applied, in addition to a structure in which a vibration external force is exerted.

  A second aspect of the present invention is the vibration power generation apparatus according to the first aspect, wherein the first power generation element and the second power generation element are affected by vibration exerted from the vibration member. The power generating element and the second power generating element are arranged so that compression deformation to one side and tensile deformation to the other side are alternately and repeatedly generated.

  In the vibration power generation device of this aspect, it is also possible to use the second power generation element as a strength member with respect to the first power generation element, thereby using, for example, the strength of the second power generation element, By setting the moment center of the external force exerted in the bending direction with respect to the first power generating element to the outside of the first power generating element, a stress in the compression / tensile direction is generated on the first power generating element to generate power. Can be improved.

  A third aspect of the present invention is the vibration power generation apparatus according to the second aspect, wherein the first power generation element and the second power generation element are arranged in parallel with each other and in the length direction. A vibration deforming member having a composite structure is configured by fixing both end portions to each other, and when the vibration by the vibrating member is exerted on the vibration deforming member in a bending direction, the first power generating element One of the second power generation elements is caused to undergo compressive deformation and the other is caused to undergo tensile deformation.

  In the vibration power generation apparatus according to this aspect, the first power generation element and the second power generation element are configured as a vibration deformation member having a composite structure constituting a beam in which the mechanical structure is arranged in parallel. Therefore, by setting the neutral axis when an external force is exerted on the vibration deforming member in the bending direction, for example, at an intermediate portion between the first power generating element and the second power generating element, It becomes possible to generate compression deformation and tensile deformation alternately and more efficiently for one power generation element.

  A fourth aspect of the present invention is the vibration power generation apparatus according to any one of the first to third aspects, wherein the magnetism on at least one side of the first power generation element and the second power generation element. A magnetic resistance adjusting mechanism is provided on the road.

  In the vibration power generation apparatus of this aspect, by adopting the magnetoresistive adjustment mechanism, the magnetic resistance in the magnetic path on the first power generation element side and the magnetic path on the second power generation element side that form parallel magnetic paths is reduced. It becomes possible to adjust relatively. Then, by adjusting the magnetic resistance in the magnetic path on the first power generation element side and the magnetic path on the second power generation element side relatively, the amount of change in the magnetic flux induced in the second power generation element and the second It becomes possible to increase the electric energy obtained by the coils of the above-mentioned coils more efficiently.

  A fifth aspect of the present invention is the vibration power generation apparatus according to the fourth aspect, wherein the first and second power generation element sides are arranged in parallel as the magnetoresistive adjustment mechanism. A magnetic gap provided on at least one of the magnetic paths and at least one of the magnetic paths parallel to each other on the first power generation element side and the second power generation element side. At least one of a nonmagnetic material and a relative shape difference between the first power generation element and the second power generation element is employed.

  In the vibration power generator of this aspect, the magnetoresistive adjustment mechanism can be realized with a simple member or structure.

A sixth aspect of the present invention is the vibration power generation apparatus according to any one of the first to fifth aspects, wherein the first power generation element side and the second power generation element side are parallel to each other. In the magnetic path, the magnetic path on the second power generating element side is expressed by the following equation with respect to the minimum value R1 _min and the maximum value R1 _max of the magnetic resistance R1 in the magnetic path on the first power generating element side. A resistor R2 is provided.
R1 _min * 1.2 ≦ R2 ≦ R1 _max * 0.8

  In the vibration power generation apparatus according to this aspect, the magnetic resistances in the magnetic paths on the first power generation element side and the second power generation element side are adjusted so as to satisfy the above expression, thereby causing the first power generation element side. As a result of the change in the magnetic flux based on the inverse magnetostriction effect, it is possible to secure a larger amount of change in the magnetic flux induced on the second power generation element side. As a result, electrical energy can be obtained more efficiently by the first and second coils.

A seventh aspect of the present invention is the vibration power generation apparatus according to any one of the first to sixth aspects, wherein the second power generation element has a saturation magnetization Ms1 of the first power generation element. The saturation magnetization Ms2 satisfies the following formula.
Ms1 * 0.4 ≦ Ms2

  In the vibration power generation device of this aspect, the change in magnetic flux based on the inverse magnetostriction effect induced on the first power generation element side without making the cross-sectional areas of the first power generation element and the second power generation element greatly different from each other. Accordingly, it becomes possible to secure a larger amount of change in magnetic flux induced on the second power generation element side. In this aspect, it is preferable that the conditional expression described in the sixth aspect is also satisfied.

An eighth aspect of the present invention is the vibration power generation apparatus according to any one of the first to seventh aspects, wherein the bias magnetic flux Φ in the bias magnetic field is a magnetic field in the magnetic path on the first power generation element side. The following formula is satisfied with respect to the minimum value R1 _min and the maximum value R1 _{max of the} resistor R1.
Φ '* 0.4 ≦ Φ ≦ Φ' * 1.5
Φ ′ = ((√ (R1 _max * R1 _min ) + R1 _min ) / √ (R1 _max * R1 _min ))
* Ms1
In the above formula, Ms1 is the saturation magnetization of the first power generating element.

  In the vibration power generation device of this aspect, it is possible to efficiently obtain the amount of change in magnetic flux due to the inverse magnetostrictive action of the first power generation element without unnecessarily increasing the bias magnetic field. Further, in this aspect, it is preferable to set the saturation magnetization of the second power generation element to a value equal to or greater than the saturation magnetization of the first power generation element. Therefore, it is not necessary to significantly increase the power generation element, and a large amount of change in magnetic flux can be efficiently ensured.

  In the vibration power generation device using the magnetostrictive element having the structure according to the present invention, the magnetic path for the first power generation element made of the magnetostrictive material is configured in parallel by the second power generation element made of the non-magnetostrictive material, and the first power generation In addition to the magnetic flux change that is primarily induced with respect to the element, the vibration energy that is passively induced with respect to the second power generation element is also used to reduce the vibration energy exerted on the first power generation element. The first coil and the second coil can be efficiently converted into electric energy, and the power generation efficiency can be improved.

It is a figure which shows the vibration electric power generating apparatus as 1st embodiment of this invention, Comprising: II sectional drawing in FIG. II-II sectional drawing in FIG. Explanatory drawing for demonstrating the magnetic circuit of the vibration electric power generating apparatus shown by FIG. Explanatory drawing for demonstrating the action | operation at the time of the vibration input in the vibration electric power generating apparatus shown by FIG. The graph for demonstrating the operating characteristic at the time of the vibration input in the vibration electric power generating apparatus shown by FIG. It is a figure which shows the vibration electric power generating apparatus as 2nd embodiment of this invention, Comprising: VI-VI sectional drawing in FIG. VII-VII sectional drawing in FIG. Explanatory drawing for demonstrating the magnetic circuit of the vibration electric power generating apparatus shown by FIG. Explanatory drawing which shows three types of another structural example which can be employ | adopted as a 2nd electric power generation element in the vibration electric power generating apparatus shown by FIG. The front view which shows roughly the vibration electric power generating apparatus as 3rd embodiment of this invention. The schematic of the right side surface in the vibration electric power generating apparatus shown by FIG. The front view which shows roughly the vibration electric power generating apparatus as 4th embodiment of this invention. The longitudinal cross-sectional view which shows roughly the vibration electric power generating apparatus as 5th embodiment of this invention. The schematic of the plane in the vibration electric power generating apparatus shown by FIG. The front view which shows schematically the vibration electric power generating apparatus as 6th embodiment of this invention. The schematic of the right side surface in the vibration electric power generating apparatus shown by FIG.

  Embodiments of the present invention will be described below with reference to the drawings.

  First, FIG. 1 and FIG. 2 show a front view and a plan view of a vibration power generation apparatus 10 using a magnetostrictive element as a first embodiment of the present invention. The vibration power generation apparatus 10 is used by being mounted on a vibration member such as a vehicle body of an automobile. The vibration energy exerted as the excitation force from the vibration member can be converted into electric energy to extract the electromotive force.

  More specifically, the vibration power generation apparatus 10 includes an attachment-side member 12 that is fixedly attached to the vibration member 11, and a mass-side member 14 that is spaced apart from the attachment-side member 12 is provided. Yes. The attachment side member 12 and the mass side member 14 are connected by the first power generation element 16 and the second power generation element 18.

  Each of the first power generation element 16 and the second power generation element 18 has a longitudinal shape such as a plate shape or a rod shape. The first power generation element 16 and the second power generation element 18 are arranged in parallel at a predetermined distance from each other, and the end portions in the length direction are respectively attached to the attachment side member 12 and the mass side member 14. By being fixed to, the attachment side member 12 and the mass side member 14 are arranged straddling.

  In addition, the fixing structure with respect to the attachment side member 12 and the mass side member 14 of each end in the first and second power generation elements 16 and 18 is not limited, and in addition to press-fitting and welding, adhesion, caulking, bolts, rivets, etc. Various known fixing structures can be employed as appropriate.

  Thus, the attachment-side member 12 and the mass-side member 14 arranged on both sides in the length direction are connected by the first and second power generation elements 16 and 18 to have a longitudinal shape as a whole. The vibration power generator 10 is configured as a single beam-like member. The vibration power generation apparatus 10 has a cantilever structure vibration power generation projecting outward from the vibration member 11 by attaching the attachment side member 12 to the vibration member 11 directly or appropriately via a bracket or the like. This constitutes a device.

  Here, the 1st electric power generation element 16 is comprised with the material which is a magnetostriction element. In other words, the first power generation element 16 has a permeability that changes due to a stress change accompanying deformation, and vibration, which is mechanical energy, is converted into magnetic energy by the inverse magnetostriction effect of the first power generation element 16. It will be. The magnetostrictive material constituting the first power generation element 16 is not particularly limited, but an iron-based magnetostrictive material having excellent strength is desirable. For example, an iron-gallium alloy, an iron-cobalt alloy, iron- A nickel-based alloy, a terdium-dysprosium-iron-based alloy, or the like can be suitably employed.

  A first coil 20 is wound around the first power generation element 16 in an extrapolated state, and magnetic flux as magnetic energy accompanying vibration deformation caused by the inverse magnetostriction effect in the first power generation element 16. The change is converted into electromotive force as electric energy by the first coil 20. Then, both ends of the winding of the first coil 20 are electrically connected to a power storage device such as a capacitor (not shown) via a rectifying device or the like as necessary. The electrical energy that is generated is extracted outside.

  On the other hand, the second power generation element 18 does not need to actively induce a magnetic flux change with vibration deformation and is made of a material made of a magnetic material that is not a magnetostrictive element. The magnetic material constituting the second power generation element 18 may employ various known ferromagnetic materials that can constitute a magnetic path such as iron and iron-based alloys, hermalloy-based alloys, ferrite compounds, and amorphous, Although not particularly limited, a soft magnetic material is desirable in order to efficiently achieve the desired passive power generation. Among them, it is desirable to select and use as an index the high permeability such as the initial permeability and the maximum permeability, the high residual magnetic flux density and the saturation magnetic flux density, and the low coercive force. Specifically, ferromagnetic materials having ferromagnetism such as elements such as Fe, Co, Ni, Gb, Tb, Dy and their alloys / intermetallic compounds, FeSi, NiFe, CoFe, SmCo, NdFeB, CoCr, CoPt, etc. In addition, ferromagnetic materials having ferrimagnetism, such as various ferrite materials such as Fe, Ni, Co oxide, etc., and intermetallic compounds of heavy rare earth metals such as Fe, Co, such as TbFe, can be suitably used.

  A yoke member 22 is assembled to the second power generation element 18 that is not a magnetostrictive element, and a magnetic circuit parallel to the first power generation element 16 is formed, and a bias magnetic field is applied to the magnetic circuit. A permanent magnet 24 is provided as a magnet means for exerting the above. Specifically, the yoke member 22 is arranged to extend sideways of the first and second power generation elements 16 and 18 in parallel. The yoke member 22 has a longitudinal shape extending between the attachment side member 12 and the mass side member 14 and is laterally separated from the first and second power generation elements 16 and 18. Are arranged. Then, one end in the length direction of the yoke member 22 is magnetically connected to the end on the attachment side member 12 side in the first and second power generation elements 16 and 18 via the permanent magnet 24. ing. The other end in the longitudinal direction of the yoke member 22 is magnetically connected to the end on the mass side member 14 side of the first and second power generating elements 16 and 18 via the connection yoke 26. ing.

  Thus, as shown in model form in FIG. 3, the first and second power generating elements 16, 18, the yoke member 22, the connecting yoke 26 and the permanent magnet 24 constitute a closed magnetic circuit-like magnetic circuit. A bias magnetic flux is exerted on the magnetic circuit based on the magnetic force generated by the permanent magnet 24, and the first power generating element 16 and the second power generating element 18 form a parallel magnetic path on the magnetic circuit. doing.

  Therefore, in such a magnetic circuit, as shown in a model form in FIG. 4, vibration is applied from the vibration member 11 to the vibration power generation device 10, and the first power generation element 16 is deformed, so that the magnetism is generated by the inverse magnetostriction effect. When the resistance changes, the magnetic resistance of the second power generation element 18 that forms a parallel circuit with the first power generation element 16 changes relatively. As a result, with the main dynamic flux change of the first power generation element 16 made of a magnetostrictive element, the second power generation element 18 that is not a magnetostrictive element is also passively caused to change the magnetic flux. Become. Incidentally, in the vibration power generation apparatus 10 having the structure according to the present embodiment, an operation for simulating a change mode of the magnetic flux that is induced dynamically and passively in the first power generation element 16 and the second power generation element 18 at the time of vibration input. The results are shown in FIG.

  In the present embodiment, the second coil 28 is wound around the second power generation element 18 in an extrapolated state. That is, although the second power generation element 18 is not a magnetostrictive element, when vibration is applied to the vibration power generation apparatus 10, the magnetic flux changes as described above. A change in magnetic flux as generated magnetic energy is converted into electromotive force as electric energy by the second coil 28. The electrical energy obtained through the second coil 28 is extracted to the outside in the same manner as the first coil 20.

  In FIGS. 1 and 2, the first power generation element 16 and the second power generation element 18 are shown in substantially the same shape, but they may be different, and the cross-sectional shapes such as a circular cross section and a rectangular cross section may be different. It can be arbitrarily adopted. The first and second power generating elements 16 and 18 do not need to have a constant cross-sectional shape over the entire length, and may be curved in the length direction. Furthermore, in FIGS. 1 and 2, the first power generation element 16 and the second power generation element 18 are arranged in a substantially extending state, but they may not be arranged in parallel to each other.

  However, the vibration power generation apparatus 10 of the present embodiment is attached to the vibration member 11 with a cantilever structure, and the vibration in the vibration member 11 acts as an excitation force in the bending direction. Therefore, an excitation force in the bending direction is exerted in a plane substantially parallel to the paper surface of FIG. 1 which is a parallel surface of the first and second power generating elements 16 and 18, and the first and second power generation elements 16 and 18. It is desirable to arrange the first power generation element 16 and the second power generation element 18 substantially in parallel with each other in a state in which the power generation elements 16 and 18 extend in a direction substantially orthogonal to the vibration direction of the vibration member 11.

  As a result, the linear reciprocating excitation force in the vibration member 11 can be exerted with high efficiency as the excitation force in the bending direction of the vibration power generation apparatus 10 and based on the vibration deformation in the bending direction of the vibration power generation apparatus 10. It becomes possible to cause the compressive stress and the tensile stress to be alternately and efficiently caused to the first power generation element 16 and the second power generation element 18. As a result, the main dynamic flux change amount in the first power generation element 16 is more efficiently generated, and the magnetic flux change in the first and second power generation elements 16 and 18, and the first and second coils 20 and 28. It is possible to increase the acquired electrical energy. In particular, in the present embodiment, both ends of the first and second power generation elements 16 and 18 are fixed by the attachment side member 12 and the mass side member 14, thereby constituting a composite structure vibration deformation member. As a result, vibration is exerted on the vibration deforming member, so that one of the first power generating element 16 and the second power generating element 18 causes compressive deformation, while the other generates tensile deformation. As described above, the vibration is applied to the first and second power generation elements 16 and 18 as one body, whereby compression and tensile deformation can be more easily caused.

  The yoke member 22 can also be used as a strength member that generates stress in the compression and tension directions on the first power generation element 16 at the time of vibration input, for example, using its rigidity. Further, the first and second power generating elements 16 and 18 are arranged on the sides of the first power generating element 16 and may cause deformation resistance to the first power generating element 16 to reduce the generated stress and thus the conversion efficiency from vibration energy to electrical energy. is there. Therefore, in this embodiment, it is desirable to employ a material having a low bending rigidity or a structure having a small section modulus as the yoke member 22. Further, as will be described later, one end side of the yoke member 22 may be disposed with a gap or the like with respect to the first and second power generation elements 16 and 18 so as to be relatively displaceable.

  In the vibration power generation apparatus 10 of the present embodiment having the above-described structure, the first power generation element 16 made of a magnetostrictive element and the second power generation element 18 are arranged so as to form a parallel magnetic circuit. At the time of input, a passive magnetic flux change is also generated in the second power generating element 18 together with a main dynamic magnetic flux change generated in the first power generating element 16. Therefore, when the second power generation element 18 made of a simple magnetic material is skillfully used without requiring a large amount of rare magnetostrictive material, and only the first power generation element 16 and the first coil 20 are used. In comparison, vibration energy can be converted into electric energy more efficiently and a large electromotive force can be obtained.

The first power generation element 16 and the second power generation element 18 constitute a parallel circuit that guides magnetic fluxes complementarily on the magnetic circuit. Therefore, in order to efficiently secure the respective magnetic fluxes and magnetic flux variations in the first power generation element 16 and the second power generation element 18, the magnetic resistance in the magnetic path on the first power generation element 16 side in the parallel magnetic path. It is desirable that the minimum value R1 _min and the maximum value R1 _max of R1 and the magnetic resistance R2 in the magnetic path on the second power generating element 18 side satisfy the following relationship. However, in the present embodiment, since the first power generating element 16 and the second power generating element 18 each independently form a parallel magnetic path, the magnetic resistance of the first power generating element 16 itself is R1, The magnetic resistance of the power generating element 18 itself can be set as R2.
R1 _min * 1.2 ≦ R2 ≦ R1 _max * 0.8

Further, the magnetic flux Φ2 _min of the second power generation element 18 when the magnetic resistance of the first power generation element 16 is minimized, and the second power generation when the magnetic resistance of the first power generation element 16 is maximum. The magnetic flux Φ2 _{max of the} element 18 is expressed by the following formula, respectively. Note that Φ is a bias magnetic flux.
Φ2 _min = R1 _min / (R1 _min + R2) * Φ
Φ2 _max = R1 _max / (R1 _max + R2) * Φ

Therefore, the following equation can be obtained as a conditional expression for the maximum amount of change in the magnetic flux of the second power generation element 18 expressed as the difference between the two magnetic fluxes Φ2 _min and Φ2 _max .
R2 = √ (R1 _max * R1 _min )
Therefore, the value of the magnetic resistance R2 in the second power generation element 18 is set within a predetermined range, for example, a range of 0.8 to 1.2 times, with the value of √ (R1 _max * R1 _min ) as an index. Is preferred.

Further, in order to sufficiently secure the passive magnetoresistance change induced in the second power generation element 18 due to the main dynamic magnetoresistance change of the first power generation element 16, the second power generation element 18 is sufficient. Magnetic flux change should be allowed. Therefore, it is desirable that the saturation magnetization Ms2 of the second power generation element 18 satisfies the following expression with respect to the saturation magnetization Ms1 of the first power generation element 16.
Ms1 * 0.4 ≦ Ms2

When the cross-sectional area of the second power generating element 18 can be set differently with respect to the first power generating element 16, the cross-sectional area A1 of the first power generating element 16 and the second power generating element 18 are set. In consideration of the cross sectional area A2, the above equation can be rewritten as follows.
Bm1 * A1 * 0.4 ≦ Bm2 * A2
In the above equation, Bm1 is the saturation magnetic flux density of the first power generation element 16, and Bm2 is the saturation magnetic flux density of the second power generation element 18.

Furthermore, if the bias magnetic flux Φ is too small, the power generation efficiency is lowered. On the other hand, if the bias magnetic flux Φ is too large, the amount of change in the magnetic flux on the second power generation element 18 side and thus the power generation efficiency may be lowered. Therefore, the bias magnetic flux Φ in the bias magnetic field is desirably set so as to satisfy the following expression with respect to the minimum value R1 _min and the maximum value R1 _max of the magnetic resistance R1 in the magnetic path on the first power generating element 16 side. .
Φ '* 0.4 ≦ Φ ≦ Φ' * 1.5
Φ ′ = ((√ (R1 _max * R1 _min ) + R1 _min ) / √ (R1 _max * R1 _min ))
* Ms1
However, in the above formula, Ms1 is the saturation magnetization of the first power generating element.
Further, the saturation magnetization on the second power generation element 18 side is ensured more than the saturation magnetization on the first power generation element 16 side so that a passive magnetic flux change amount on the second power generation element 18 side is allowed. When the same cross-sectional area is assumed, it is desirable that the saturation magnetic flux density of the second power generation element 18 is set to be equal to or higher than the saturation magnetic flux density of the first power generation element 16.

  Next, FIGS. 6 to 7 show a vibration power generator 30 using a magnetostrictive element as a second embodiment of the present invention, and FIG. 8 shows a magnetic circuit configuration of the vibration power generator 30. It is shown as a model.

  The vibration power generation apparatus 30 of this embodiment illustrates another aspect of the magnetic path on the second power generation element 18 side provided in parallel with the magnetic path on the first power generation element 16 side in the first embodiment. It is. Therefore, members and parts having the same structure as that of the first embodiment are denoted by the same reference numerals as those of the first embodiment in the drawings, and detailed description thereof is omitted.

  That is, in the present embodiment, the magnetic path on the second power generation element 18 side provided in parallel with the magnetic path on the first power generation element 16 side is non-magnetic in series with the second power generation element 18. A resistance member 32 having the above is disposed. Specifically, as shown in FIG. 8, as the first power generation element 16, a magnetostrictive element made of an iron-gallium alloy is adopted, and the relative permeability is set to 100, while the second By adopting a soft magnetic material made of ferritic stainless steel as the power generation element 18, when the relative permeability is 500, a nonmagnetic material having a relative permeability of 1 can be interposed as the resistance member 32.

  By interposing the resistance member 32, the magnetic resistance of the magnetic path on the second power generation element 18 side can be increased while adopting the second power generation element 18 having a large relative permeability. . As a result, it is possible to relatively adjust the magnetic resistance on the first power generation element 16 side and the magnetic resistance on the second power generation element 18 side, which constitute magnetic paths parallel to each other, by the resistance member 32. . In addition, as the resistance member 32, it is also possible to employ a nonmagnetic or diamagnetic metal other than a synthetic resin.

  As a result, it becomes easy to set so as to satisfy the above-described conditional expressions exemplified as suitable tuning ranges in the first embodiment, and it becomes possible to obtain higher power generation efficiency. In addition, by providing the resistance member 32, the degree of freedom in design of the material and shape of the second power generation element 18 can be secured greatly, and for example, it is easy to facilitate manufacturing, reduce manufacturing cost, and the like. Become.

  The specific mode for adjusting the magnetic resistance on the second power generation element 18 side is not limited to the second embodiment. Specifically, for example, as shown in FIGS. 9A to 9C, the structure for adjusting the magnetic resistance on the second power generation element 18 side in the second embodiment is the second embodiment. In the embodiment, it is possible to adopt instead of or in addition to the resistance member 32 provided on the second power generation element 18 side.

  That is, as shown in FIG. 9A, by configuring the second power generating element 18 with a soft magnetic material or the like whose effective cross-sectional area is set sufficiently small, the magnetoresistance is reduced with a small cross-sectional area. Large adjustment is also possible. The strength and rigidity of the second power generation element 18 having a small cross-sectional area can be ensured by the reinforcing member 34 made of a nonmagnetic material provided to be overlapped.

  Further, in FIG. 9B, each of the second power generation elements 18 is composed of soft magnetic materials 18a and 18b divided into a plurality (two in the drawing) in the length direction of the magnetic path. A mode in which the magnetic resistance is largely adjusted by the magnetic gap set in the divided portion is illustrated. In the present embodiment, the strength and rigidity of the second power generation element 18 are ensured by connecting and fixing the divided portions of the soft magnetic materials 18a and 18b to each other with a connecting member 36 made of a nonmagnetic material.

  Furthermore, in FIG. 9C, the second power generating element 18 itself is provided with a hollow slit or a thin wall portion, thereby ensuring the strength and rigidity as a whole and reducing the effective sectional area. A mode in which the magnetic resistance can be largely adjusted is illustrated. In addition, the specific shape and size of the slit and the thin portion provided in the second power generation element 18 are not limited at all.

  Furthermore, in the first and second embodiments, the second power generation element 18 is also subjected to an external force due to vibration input, and mechanically juxtaposed with the first power generation element 16. As a structure, it acts as a strength member that generates stress in the compression / tensile direction on the first power generating element 16 when vibration is input in the bending direction. However, the second power generation element 18 does not need to have a structure in which deformation or stress is generated because the second power generation element 18 does not generate a magnetic flux change mainly based on deformation or stress. Several embodiments of the structure in which vibration input is not positively applied to the second power generation element 18 will be described below as embodiments.

  A vibration power generation apparatus 40 using a magnetostrictive element as a third embodiment of the present invention shown in FIGS. 10 to 11 is such that a vibration member 41 reciprocates in the left-right direction in the figure, and has a cantilever structure. The vibration power generation device 40 provided so as to protrude upward in the drawing includes a first power generation element 16 and a strength member provided so as to extend in parallel across the attachment side member 12 and the mass side member 14. 42 is provided. When the mass side member 14 swings and moves in the left-right direction in the figure, which is the vibration direction, the first power generating element 16 and the strength member 42 are deformed in cooperation, and the overall section coefficient is large. Thus, deformation and stress in the compression / tensile direction are generated in the first power generation element 16.

  On the other hand, the first power generation element 16 is provided with a second power generation element 18 so as to form a parallel magnetic path. One end of the second power generation element 18 is fixed to one end of the yoke member 46 in parallel with the first power generation element 16 via a permanent magnet 44. The other end of the second power generation element 18 is magnetically connected to the other end of the yoke member 46 in parallel with the first power generation element 16. As the magnetic connection structure, in the present embodiment, a structure is used that is opposed to each other with a gap therebetween, and a vibration external force is directly applied to the second power generation element 18 and the yoke member 46. Not to be.

  Further, in the vibration power generation device 50 using a magnetostrictive element as the fourth embodiment of the present invention shown in FIG. 12, the vibration member 41 reciprocates in the left-right direction in the figure as in the third embodiment. And the two 1st electric power generation elements 16 and 16 are provided so that it may extend across in parallel between the attachment side member 12 and the mass side member 14. As shown in FIG. The two first power generation elements 16 and 16 function as a reinforcing member, so that deformation and stress in the compression / tensile direction are generated in the first power generation element 16 when vibration is input. ing.

  On the other hand, each first power generation element 16 is provided with a second power generation element 18 so as to form a parallel magnetic path, as in the third embodiment. Further, the first power generation element 16 and the second power generation element 18 that form a pair have a structure similar to that of the vibration power generation apparatus 40 shown in FIG. It is configured. That is, also in the present embodiment, the vibration external force is not directly applied to the second power generation element 18 and the yoke member 46.

  Furthermore, in the vibration power generation apparatus 60 as the fifth embodiment of the present invention shown in FIGS. 13 to 14, the function of the strength member 42 in the third embodiment is exhibited using the vibration member. It has become. That is, the long first power generation elements 16 are arranged at a predetermined distance in a state of extending along the surface of the flat plate-like vibration member 61. The vibration member 61 is configured to generate vibration accompanied by bending deformation such that the surface is curved. Both ends in the length direction of the first power generating element 16 are superimposed on the surface of the vibration member 61 via spacers 62 having a predetermined thickness, and the vibration members 61 are mutually connected by fixing bolts 63a and 63b. It is fixed at a remote site.

  As a result, the bending vibration in the vibration member 61 is amplified using the thickness of the spacer 62, causing the first power generation element 16 to undergo compression / tensile deformation in the length direction. Therefore, in this embodiment, without providing the strength member 42 in the third embodiment, the vibration of the vibration member 61 is exerted on the first power generation element 16, thereby applying a compression / tensile stress to the first power generation element 16. It can be produced effectively.

  In the present embodiment, the second power generation element 18 is arranged in parallel with the first power generation element 16 so as to extend in the length direction along the first power generation element 16. . One end portion of the second power generation element 18 is overlapped with one end portion of the first power generation element 16 and is fixed to the vibration member 61 by a fixing bolt 63a. Further, the other end of the second power generation element 18 is opposed to the other end of the second power generation element 16 so as to be relatively displaceable while being magnetically connected with a gap therebetween. Yes.

  Furthermore, the first and second power generation elements 16 and 18 are provided with a yoke member 64 that extends in a laterally spaced manner. One end portion of the yoke member 64 is magnetically connected to one end portion of the first and second power generating elements 16 and 18 with the permanent magnet 66 interposed therebetween, and the yoke member 64. Is connected to the other ends of the first and second power generating elements 16 and 18 magnetically. Thereby, a magnetic path having a closed magnetic circuit structure is formed as a whole, and the first power generation element 16 and the second power generation element 18 form a parallel magnetic path on the magnetic path. The first power generating element 16 is directly connected to the yoke member 64 at both axial ends, but the second power generating element 18 is directly connected to the yoke member 64 only at one axial end side. The other end in the axial direction is connected to the yoke member 64 via a magnetoresistive adjustment mechanism having a predetermined gap.

  In the vibration power generation device 60 having such a structure, even if a strength member is not specially provided, the first power generation element 16 is subjected to compression / tensile deformation due to bending vibration in the vibration member, and the inverse magnetostriction is caused. The power generation action by the action is effectively exhibited. Further, a vibration external force is not directly applied to the second power generation element 18 and the yoke member 64 so that a stress change in the first power generation element 16 is more efficiently induced.

  15 and 16 show a vibration power generator 70 as a sixth embodiment of the present invention. In the vibration power generation apparatus 70 of the present embodiment, the first power generation element 16 has a rod shape extending in the vertical direction in the figure, and the second power generation element 18 has a rod shape, so that the first power generation element The elements 16 are arranged side by side at a predetermined distance. In the present embodiment, a pair of second power generation elements 18 and 18 are disposed on both sides of the first power generation element 16.

  The lower end of the first power generation element 16 is fixed to a support member 72 fixedly mounted on the base member 71, while the upper end of the first power generation element 16 is fixed to the vibration member 73. Is attached. Such a vibration member 73 is oscillated and displaced with respect to the base member 71 in a direction approaching and separating from each other in the vertical direction in the figure. The vibration of the vibration member 73 is directly applied to the first power generating element 16 in the axial compression / tensile direction.

  On the other hand, the lower end of the second power generating element 18 is fixed to the support member 72, while the upper end is a free end separated from the vibration member 73 so that no vibration external force is exerted. In particular, in the present embodiment, the upper end of the second power generation element 18 has a structure separated from the first power generation element 16.

  Further, a yoke member 74 extending in the vertical direction is disposed on the side of the first and second power generating elements 16 and 18. The yoke member 74 has a lower end fixed to the support member 72 and an upper end that is a free end separated from the vibration member 73, and the upper ends of the second power generation elements 18, 18 via the connection member 76. Are fixedly connected to each other. Thus, by providing the yoke member 74 formed of a ferromagnetic material and constituting the magnetic path, a magnetic path having a closed magnetic path structure is configured as a whole, and the first power generation element 16 is formed on the magnetic path. And the 2nd electric power generation elements 18 and 18 comprise the mutually parallel magnetic path.

  In addition, on the magnetic path of the closed magnetic circuit structure, a permanent magnet 78 is disposed, for example, at a middle portion in the longitudinal direction of the yoke member 74 as shown in the figure, and a bias magnetic flux is exerted on the magnetic path. It is like that. The second power generation element 18 is directly connected to the yoke member 74 at both axial ends, but the first power generation element 16 is directly connected to the yoke member 74 only at the lower end in the axial direction. The upper end in the axial direction is connected to the yoke member 74 via a magnetoresistive adjustment mechanism having a predetermined gap.

  In the vibration power generation apparatus 70 of the present embodiment, the external force that approaches and separates the vibration member from the base member is exerted as the vibration external force in the compression / tensile direction on the first power generation element 16. Therefore, a special structure such as a strength member for generating a compression / tensile stress during bending vibration as in the first embodiment is unnecessary, and the structure can be simplified.

  The second power generation element may be single or three or more. However, if a plurality of second power generation elements are provided as in the present embodiment, the cross-sectional area of each second power generation element can be reduced. It is preferable that no external force be exerted on the yoke member and the second power generation element. The yoke member and the second power generation element do not generate the magnetic flux change dynamically even if a vibration external force is applied, and the vibration energy is converted into the electric energy by applying the vibration external force only to the first power generation element. This is because the conversion efficiency can be further improved.

  As mentioned above, although embodiment of this invention was explained in full detail, this invention is not limitedly interpreted by the specific description in the above-mentioned embodiment.

  For example, in the second embodiment or the like, a magnetoresistive adjustment mechanism is employed for the magnetic path on the second power generation element 18 side, while in the sixth embodiment, the first power generation element 16 side is employed. The magnetic resistance adjusting mechanism having a gap with respect to the magnetic path of the first power generation element 16 and the second power generation element 18 side, which form a magnetic path parallel to each other, is employed. It is also possible to increase the degree of freedom of adjustment by employing one magnetoresistive adjustment mechanism.

10, 30, 40, 50, 60, 70: vibration power generation apparatus (using magnetostrictive element), 11, 41, 61, 73: vibration member, 16: first power generation element, 18: second power generation element, 20 : First coil, 22, 46, 64, 74: yoke member, 24, 44, 66, 78: permanent magnet, 26: connection yoke, 28: second coil

Claims (8)

In a vibration power generator that is attached to a vibration member and converts vibration energy into electric energy using the inverse magnetostriction effect of the magnetostrictive material,
A magnet and a yoke member are applied to a first power generating element made of a magnetostrictive material and wound with a first coil, and a second power generating element made of a magnetic material that is not a magnetostrictive material and wound with a second coil. The bias magnetic field to be applied is applied in parallel,
A change in magnetic flux due to the bias magnetic field induced in the first power generation element due to vibration exerted from the vibration member is extracted as electric energy by the first coil, and compression of the first power generation element is performed. A magnetostrictive element-based vibration power generation apparatus characterized in that a change in magnetic flux of the second power generation element exerted by a change in magnetic flux accompanying tensile deformation is taken out as electric energy by the second coil.   The first power generation element and the second power generation element are subjected to compression deformation to one side and tension to the other side with respect to the first power generation element and the second power generation element by vibration exerted from the vibration member. The vibration power generation apparatus using a magnetostrictive element according to claim 1, wherein the vibration power generation apparatus is arranged so that deformation is alternately and repeatedly generated. The first power generation element and the second power generation element are arranged in parallel with each other, and both end portions in the length direction are fixed to each other to constitute a composite structure vibration deformation member,
When vibration caused by the vibration member is exerted on the vibration deformation member in a bending direction, one of the first power generation element and the second power generation element causes compression deformation and the other undergoes tensile deformation. The vibration power generator using a magnetostrictive element according to claim 2, which is generated.   The magnetostrictive element-based vibration according to any one of claims 1 to 3, wherein a magnetoresistive adjustment mechanism is provided on a magnetic path on at least one side of the first power generation element and the second power generation element. Power generation device. As the magnetoresistive adjustment mechanism,
A magnetic gap provided on at least one of the magnetic paths parallel to each other on the first power generation element side and the second power generation element side;
A nonmagnetic material disposed on at least one of the magnetic paths parallel to each other on the first power generation element side and the second power generation element side;
5. The vibration power generation apparatus using a magnetostrictive element according to claim 4, wherein at least one of a relative shape difference between the first power generation element and the second power generation element is employed. In the magnetic paths parallel to each other on the first power generation element side and the second power generation element side,
With respect to the minimum value R1 _min and the maximum value R1 _max of the magnetic resistance R1 in the magnetic path on the first power generation element side, the magnetic path on the second power generation element side has a magnetic resistance R2 represented by the following equation. The vibration power generator using the magnetostrictive element according to any one of claims 1 to 5.
R1 _min * 1.2 ≦ R2 ≦ R1 _max * 0.8 The vibration power generation using the magnetostrictive element according to any one of claims 1 to 6, wherein the saturation magnetization Ms2 of the second power generation element satisfies the following expression with respect to the saturation magnetization Ms1 of the first power generation element. apparatus.
Ms1 * 0.4 ≦ Ms2 The bias magnetic flux Φ in the bias magnetic field is
The magnetostrictive element utilization according to any one of claims 1 to 7, wherein the following equation is satisfied with respect to the minimum value R1 _min and the maximum value R1 _max of the magnetic resistance R1 in the magnetic path on the first power generation element side. Vibration power generator.
Φ '* 0.4 ≦ Φ ≦ Φ' * 1.5
Φ ′ = ((√ (R1 _max * R1 _min ) + R1 _min ) / √ (R1 _max * R1 _min ))
* Ms1
In the above equation, Ms1 is the saturation magnetization of the first power generating element.