JP3123573U - Multi-pole power generator - Google Patents

Abstract

A multi-pole power generator is provided.
The present invention relates to a kind of multi-pole power generation device, and is connected to a rectifying power storage device to provide appropriate power to an electronic product. In this power generation apparatus, a hollow carrier in which an induction coil is mainly wound on an outer peripheral surface, and one or more sliding magnets are provided on the outer peripheral surfaces of both ends of the hollow carrier. N pole and S pole are provided in accordance with the same pole magnet of the sliding magnet provided at the end. One feature is that a weight member is provided on the sliding magnet, and the induction coil is completely cut to improve electromagnetic induction efficiency. Another feature is that a combination of different contours on the inner wall of the hollow carrier and the outer peripheral surface of the sliding magnet provides a better sliding space and can reduce air compression resistance in the sliding process of the sliding magnet. .
[Selection] Figure 4

Description

  The present invention relates to a kind of power generation apparatus, and more particularly to a multi-pole power generation apparatus that generates electricity due to the same repulsive characteristics of a kind of oscillating magnet.

  As information technology has advanced, electronic consumer products have become increasingly popular. In particular, batteries that provide electricity are required to have green products with environmental protection measures in addition to their service life. For this reason, all products such as nickel-metal hydride batteries, lithium ion batteries, solar batteries, etc. that can be used to recharge batteries, improve their storage capacity, or can be used repeatedly, take environmental protection measures into consideration.

  The power generator according to the present invention relates to a kind of oscillating multi-pole power generator. By mainly using the repulsive characteristics of the magnet, by providing fixed magnets at both ends of the path with the induction coil, by providing sliding magnets inside the path, and by changing the magnetic field inside the induction coil by reciprocating motion, Generates electromotive force and provides electricity. This type of design is disclosed in US Pat.

  However, since the magnet assembly of the known multi-pole power generator is incorporated in a sealed bushing, the sliding of the magnet assembly inside the bushing not only hinders the sliding energy of the magnet assembly due to the air compression resistance force. Affects the generation of induced electromotive force. Furthermore, since the induction coil forms an opposite magnetic field in the sliding direction of the sliding magnet according to the electromagnetic induction law, the greater the induced electromotive force generated, the greater the influence on the opposite magnetic field. Therefore, the sliding energy of the sliding magnet set is hindered, which affects the oscillating power generation failure and the magnetic field line cut. Therefore, in Patent Document 2, Patent Document 3, and Patent Document 4, solving means are disclosed respectively. In addition to increasing the weight of the entire magnet by staking multiple magnets together, magnetic fluid is used as a lubricant to reduce the frictional force between the magnet and the motion path, thereby improving the sliding energy of the magnet assembly. is doing.

  The sliding energy of the magnet set is improved by the splicing connection of a plurality of magnets and the increase of liquid. However, it can be costly and the production process can be more complicated.

US Pat. No. 6,768,230 US Pat. No. 6,798,090 US Pat. No. 6,220,719 US Pat. No. 6,812,583

  The present invention provides a multi-pole power generation device that generates a better power effect while realizing a kind of structural simplicity, production process simplification, and cost reduction, and by maintaining an appropriate weight, in the sliding process of the magnet In addition to reducing the effects of sliding energy loss and magnetic field line cutting induction, the main feature is that the air compression resistance due to the sliding process of the magnet is reduced, and the oscillating power generation can be performed smoothly, producing a better power effect. Objective.

  In order to achieve the above object, the multi-pole power generator according to the present invention mainly has both ends and an opening provided in a hollow carrier, and an induction coil is wound around the outer peripheral surface thereof. One or more sliding magnets are provided inside the hollow carrier. Fixed magnets are provided on the outer peripheral surfaces of both ends of the hollow carrier, and the N pole and the S pole are provided in accordance with the same pole magnets of the sliding magnets provided at the ends. A weight member is provided on the sliding magnet. A lid is provided in the opening. With the above structure, the sliding magnet and the weight member smoothly reciprocate with good sliding energy inside the hollow carrier, and the induction coil is completely cut to improve electromagnetic induction efficiency.

  Another feature of the multi-pole power generator according to the present invention is that the inner wall of the hollow carrier and the outer peripheral surface of the sliding magnet provide a better sliding space by combining different contours, and in the sliding process of the magnet Air compression resistance can be reduced.

The invention of claim 1 is connected to a rectifying power storage device and provides appropriate power to an electronic product, including a hollow carrier, a fixed magnet, a weight member, and a lid,
In addition to providing both ends and one or more openings, the hollow carrier is provided with an induction coil on the outer peripheral surface, and further accommodates one or more sliding magnets inside the hollow carrier, and a fixed magnet is provided in the hollow carrier. Provided on the outer peripheral surfaces of both ends of the body, the N pole and the S pole are provided in accordance with the same pole magnet of the sliding magnet provided at the end,
A weight member is provided on the sliding magnet, and a lid is provided on the opening.
With this structure, the sliding magnet and the weight member can obtain good sliding energy and perform a smooth reciprocating motion in the hollow carrier, thereby completely cutting the induction coil and improving the electromagnetic induction efficiency. It is a kind of multi-pole power generator.
The invention of claim 2 is the multi-pole power generator according to claim 1, wherein the weight member and the sliding magnet have the same shape.
The invention of claim 3 is the multi-pole power generator according to claim 2, wherein the weight member is made of a material such as carbon steel or brass.
The invention of claim 4 is the multi-pole power generator according to claim 1, wherein the fixed magnet is provided with an annular magnet, two arc magnets, or a plurality of small magnets.
The invention of claim 5 is the multi-pole power generator according to claim 4, wherein a through-hole is provided in the center of the sliding magnet in order to reduce air compression resistance.
The invention of claim 6 is the multi-pole power generator according to claim 5, wherein the outer peripheral surface of the sliding magnet is further provided with a plurality of cuts.
The invention according to claim 7 is the multi-pole power generator according to claim 5, wherein the inner wall of the sliding magnet is further provided with a plurality of cuts.
In the invention of claim 8, the inner wall of the hollow carrier and the outer peripheral surface of the sliding magnet are provided with a polygonal shape in the inner wall cross section of the hollow carrier, whereas the cross section of the outer surface of the sliding magnet is circular. Or providing a better sliding space by combining different contours, such as providing a polygon on the cross section of the outer peripheral surface of the sliding magnet. 3. The multi-pole power generator according to claim 2, wherein the air compression resistance force during the sliding process of the magnet can be reduced.
The invention of claim 9 is the multi-pole power generator according to claim 8, wherein a through-hole is provided in the center of the sliding magnet in order to reduce air compression resistance.
The invention of claim 10 is provided with a plurality of the sliding magnets, which are also arranged with the magnetic poles facing each other and skewered, or arranged with different magnetic poles facing each other, and skewered or connected. The multi-pole power generator according to claim 1, wherein different magnetic poles are mixed and skewered and connected.
The invention of claim 11 is the multi-pole power generator according to claim 10, wherein the plurality of sliding magnets are connected to each other by a connecting rod, and a partition member is provided between the sliding magnets. .
The invention of claim 12 is characterized in that the connecting rod is a screw rod and the partition member is a member having a partition function such as a nut or a partition object such as a helical insertion member or a washer. It is a magnetic pole power generator.
The invention of claim 13 is connected to a rectifying power storage device to provide appropriate power to an electronic product.
The hollow carrier is provided with one or more sliding magnet sets in which both ends and one or more openings are provided in the hollow carrier, and an induction coil is wound around the outer peripheral surface of the hollow carrier.
A fixed magnet is provided on each of the outer peripheral surfaces of both ends of the hollow carrier, and the N pole and the S pole are provided in accordance with the same pole magnet of the sliding magnet provided at the end.
A lid, provided in the opening,
The inner wall of the hollow carrier and the outer peripheral surface of the sliding magnet are provided with a combination of different contours to provide a better sliding space and to reduce air compression resistance in the sliding process of the sliding magnet. It is a multi-pole power generator.
The invention of claim 14 is provided with a plurality of the sliding magnets, which are also arranged with the magnetic poles facing each other and skewered or connected with different magnetic poles facing each other, and skewered or connected. 14. The multi-pole power generator according to claim 13, wherein different magnetic poles are mixed and skewered and connected.
The invention of claim 15 is the multi-pole power generator according to claim 14, characterized in that in order to reduce the air compression resistance, the central portion of all the sliding magnets is further provided with a through hole.
The invention according to claim 16 is characterized in that the cross section of the hollow conveying body wall is provided with a circular shape, whereas the outer peripheral surface of the sliding magnet is provided with a polygonal shape. It is a power generator.
The invention according to claim 17 is characterized in that the cross section of the hollow conveying body wall is provided with a polygonal shape, whereas the cross section of the outer peripheral surface of the sliding magnet is provided with a circular shape. It is a power generator.
The invention of claim 18 is the multi-pole power generator according to claim 13, wherein the fixed magnet is provided with an annular magnet, two arc magnets, or a plurality of small magnets.
The invention of claim 19 is the multi-pole power generator according to claim 14, wherein the sliding magnet is connected by a plurality of connecting rods, and a partition member is provided between the sliding magnets.
The invention of claim 20 is characterized in that the connecting rod is a screw rod and the partition member is a member having a partition function, such as a nut or a partition object such as a helical insertion member or a washer. It is a magnetic pole power generator.
The invention of claim 21 is connected to a rectifying power storage device to provide appropriate power to an electronic product.
In addition to providing a hollow carrier, both ends and one or more openings, an induction coil is provided on the outer peripheral surface.
One or more sliding magnets are provided inside the hollow carrier, fixed magnets are provided on the outer peripheral surfaces of both ends of the hollow carrier, and the N pole and the S pole are the same poles of the sliding magnets provided at the ends. A kind of multi-pole power generator is provided in which a lid is provided in the opening.

  The multi-pole power generator according to the present invention is mainly provided with both ends and an opening in a hollow carrier, and an induction coil is wound around the outer peripheral surface thereof. One or more sliding magnets are provided inside the hollow carrier. Fixed magnets are provided on the outer peripheral surfaces of both ends of the hollow carrier, and the N pole and the S pole are provided in accordance with the same pole magnets of the sliding magnets provided at the ends. A weight member is provided on the sliding magnet. A lid is provided in the opening. With the above structure, the sliding magnet and the weight member smoothly reciprocate with good sliding energy inside the hollow carrier, and the induction coil is completely cut to improve electromagnetic induction efficiency.

  As shown in FIG. 1, the multi-pole power generator 1 according to the present invention is connected to a socket 80 and an outlet 81 provided in the rectifying power storage device 7 to be conducted. After proper rocking operation, a certain amount of power is provided to the electronic product. The multi-pole power generator 1 is mainly composed of a hollow carrier 2, fixed magnets 30 and 31, a sliding magnet 4, and a weight member 5. Among them, the hollow carrier 2 is provided with both end portions 20 and 21, and furthermore, an opening portion is provided, a lid body 25 is provided, and an induction coil 90 is provided on the outer peripheral surface 401. The fixed magnets 30 and 31 are hollow as shown in FIGS. 2 and 3 (the fixed magnets 30 and 31 may be provided with two arc-shaped magnets or a plurality of small magnets on the outer peripheral surface 401). It is provided on the outer peripheral surface 401 of each end 20 and 21 of the carrier. Among them, the magnetic pole of the fixed magnet 30 is provided with the south pole facing inward, and the magnet of the fixed magnet 31 is provided with the north pole facing inward. Six sliding magnets 40 are provided in the sliding magnet set 4. In order to skew the sliding magnet assembly 4, a through hole 400 is provided in each sliding magnet 40 to reduce the air compression resistance. The sliding magnet 40 is integrally connected by a connecting rod 60 and a partition member 61. Of these, the connecting rod 60 may be a threaded rod. The partition member 61 is formed by sandwiching a partition object such as a nut or a spiral insertion member or a washer between the sliding magnets 40 and connecting them in an integrated manner, and then incorporating them into the hollow carrier 2. In this embodiment, the four magnetic poles of the sliding magnet set are arranged with the opposite magnetic poles facing each other. The weight member 5 includes a suitable member such as carbon steel or brass on both the left and right sides of the sliding magnet assembly 4 to give an appropriate weight to the sliding magnet assembly 4, thereby reducing the loss of sliding energy. And reduce the influence of magnetic field line cutting induction.

  Furthermore, reference is made to FIGS. The inner wall 22 of the hollow carrier 2 and the outer peripheral surface 401 of the sliding magnet 40 according to the present invention provide a better sliding space by combining different contours, and the air compression resistance force in the sliding process of the sliding magnet assembly 4 Reduce. As shown in FIG. 4, the cross section of the inner wall 22 of the hollow carrier 2 is circular, and the cross section of the outer peripheral surface 401 of the sliding magnet 40 is polygonal. As shown in FIG. 5, the inner wall 22 of the hollow carrier 2 has a circular cross section, and the outer peripheral surface 401 of the sliding magnet 40 has a circular cross section, and a plurality of cuts 402 are provided. As shown in FIG. 6, the cross section of the inner wall 22 of the hollow carrier 2 is circular, and the cross section of the outer peripheral surface 401 of the sliding magnet 40 is circular. As shown in FIG. 7, the cross section of the inner wall 22 of the hollow carrier 2 is circular, and a plurality of cuts 221 are provided, whereas the outer peripheral surface 401 of the sliding magnet 40 is circular. As described above, the inner space 22 of the hollow carrier 2 and the outer peripheral surface 401 of the sliding magnet 40 have different contour combinations, so that the remaining space can reduce the air compression resistance force in the sliding process of the sliding magnet assembly 4.

  In particular, the arrangement method of the four magnetic poles of the sliding magnet assembly can be connected in an integrated manner in the same polarity arrangement, or the same polarity and the opposite magnetic pole in a mixed arrangement in addition to the arrangement of the opposite magnetic poles. This structure reciprocates inside a hollow carrier that also has a coil, changes the magnetic field of the coil, generates an induced electromotive force, and realizes the effect of providing power. Further, in order to reduce the frictional force due to the sliding of the sliding magnet assembly 4, friction is generated between the sliding magnet assembly 4 and the inner wall of the hollow carrier 2, or against the sliding magnet assembly 4 or the inner wall of the hollow carrier 2. A member for reducing the force may be provided. Further, according to the application object, as shown in FIG. 8, the sliding magnet 4 'according to the present invention is provided in a flat elliptical shape, and a through hole 400' is provided in the center thereof. With this structure, even if the inner wall of the hollow carrier 2 is provided in an elliptical shape, the effect of reducing the air compression resistance can be realized.

  FIG. 9 shows a second embodiment of the multi-pole power generator 1 'according to the present invention. In this embodiment, the fixed magnets 30 ′ and 31 ′ are provided on the outer peripheral surface of the hollow carrier 2 ′ in the same manner as in the first embodiment, and annular magnets are provided. Only one sliding magnet 4 'is provided. Instead, by increasing the thickness of the weight member 5 ', the appropriate weight of the sliding magnet 4' is maintained, good sliding energy is provided, the reciprocating motion is smoothly performed, and the induction coil 9 'is completely Similarly, the electromagnetic induction efficiency can be improved. In this embodiment, instead of the high-cost sliding magnet 4, weight members such as low-cost carbon steel and brass are provided to simplify the assembly process and further improve its practicality.

  As described above, the multi-pole power generation device according to the present invention meets the purpose of creation, and the present invention can be applied to vibration source objects such as vibration of a material recovery vehicle, vibration due to operation of an air conditioner, natural vibration of the human body, It can be stored after being replaced with electricity. As an alternative power source, it can be applied to information products such as notebook computers, digital cameras and PDAs, as well as communication products such as mobile phones and flashlights.

1 is a cross-sectional view of a first embodiment of a multi-pole power generator according to the present invention and a schematic diagram of a rectifying power storage device. It is Example 2 of the fixed magnet by this invention. It is Example 3 of the fixed magnet by this invention. It is Example 1 of the sliding magnet of the multi-pole power generator by this invention. It is Example 2 of the sliding magnet of the multi-pole power generator by this invention. It is Example 1 of the hollow conveyance body of the multi-pole power generator by this invention. It is Example 2 of the hollow conveyance body of the multi-pole power generator by this invention. 1 is a flat elliptical embodiment of a sliding magnet according to the present invention. It is sectional drawing of Example 2 of the multi-pole power generator by this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Multi magnetic pole power generator 2 Hollow carrier 20, 21 Both ends of hollow carrier 22 Hollow carrier inner wall 25 Cover body 221, 402 Incision 30, 31 Fixed magnet 4, 4 'Sliding magnet set 40 Sliding magnet 400 Through-hole 401 Outer peripheral surface 5 Weight member 60 Connecting rod 61 Partition member 7 Rectifying power storage device 80 Socket 81 Outlet 90 Coil

Claims (21)

Connected to the rectifying power storage device, providing appropriate power to the electronic product, including a hollow carrier, a fixed magnet, a weight member and a lid,
In addition to providing both ends and one or more openings, the hollow carrier has an induction coil on the outer peripheral surface, and further accommodates one or more sliding magnets inside the hollow carrier, and a fixed magnet is provided in the hollow carrier. Provided on the outer peripheral surfaces of both ends of the body, the N pole and the S pole are provided in accordance with the same pole magnet of the sliding magnet provided at the end,
A weight member is provided on the sliding magnet, and a lid is provided on the opening.
With this structure, the sliding magnet and the weight member can obtain good sliding energy and perform a smooth reciprocating motion in the hollow carrier, thereby completely cutting the induction coil and improving the electromagnetic induction efficiency. A kind of multi-pole power generator.   The multi-pole power generator according to claim 1, wherein the weight member and the sliding magnet have the same shape.   The multi-pole power generator according to claim 2, wherein the weight member is made of a material such as carbon steel or brass.   The multi-pole power generator according to claim 1, wherein the fixed magnet is provided with an annular magnet, two arc magnets, or a plurality of small magnets.   The multi-pole power generator according to claim 4, wherein a through-hole is provided in a central portion of the sliding magnet in order to reduce air compression resistance.   6. The multi-pole power generator according to claim 5, wherein the outer peripheral surface of the sliding magnet is further provided with a plurality of cuts.   6. The multi-pole power generator according to claim 5, wherein the inner wall of the sliding magnet is further provided with a plurality of cuts.   The inner wall of the hollow carrier and the outer peripheral surface of the sliding magnet are provided with a polygonal shape on the inner wall cross section of the hollow carrier, whereas the cross section of the outer peripheral surface of the sliding magnet is provided with a circle or the hollow carrier. Provide a better sliding space by combining different contours, such as providing a circular shape in the cross section of the inner wall of the body wall, and providing a polygonal shape in the cross section of the outer peripheral surface of the sliding magnet. The multi-pole power generator according to claim 2, wherein the air compression resistance can be reduced.   The multi-pole power generator according to claim 8, wherein a through-hole is provided in a central portion of the sliding magnet in order to reduce air compression resistance.   A plurality of the sliding magnets are provided, and the magnetic poles are arranged to face each other and skewered or connected, or different magnetic poles are arranged to face each other and skewed and connected, or magnetic poles different from the magnetic poles are mixed, The multi-pole power generator according to claim 1, wherein the multi-pole power generator is skewered and connected.   The multi-pole power generator according to claim 10, wherein the plurality of sliding magnets are connected to each other by a connecting rod, and a partition member is provided between the sliding magnets.   12. The multi-pole power generation device according to claim 11, wherein the connecting rod is a screw rod, the partition member is a nut, or a partition object such as a partition member such as a spiral insertion member or a washer. Connect to a rectifying power storage device to provide appropriate power to electronic products,
The hollow carrier is provided with one or more sliding magnet sets in which both ends and one or more openings are provided in the hollow carrier, and an induction coil is wound around the outer peripheral surface of the hollow carrier.
A fixed magnet is provided on each of the outer peripheral surfaces of both ends of the hollow carrier, and the N pole and the S pole are provided in accordance with the same pole magnet of the sliding magnet provided at the end.
A lid, provided in the opening,
The inner wall of the hollow carrier and the outer peripheral surface of the sliding magnet are provided with a combination of different contours to provide a better sliding space and to reduce air compression resistance in the sliding process of the sliding magnet. Multi-pole power generator.   A plurality of the sliding magnets are provided, and the magnetic poles are arranged to face each other and skewered or connected, or different magnetic poles are arranged to face each other and skewed and connected, or magnetic poles different from the magnetic poles are mixed, The multi-pole power generator according to claim 13, wherein the multi-pole power generator is skewered and connected.   15. The multi-pole power generator according to claim 14, wherein a central portion of all the sliding magnets is further provided with a through hole in order to reduce air compression resistance.   The multi-pole power generating device according to claim 15, wherein the hollow conveying body wall has a circular cross section, whereas the outer peripheral surface of the sliding magnet has a polygonal cross section.   The multi-pole power generating device according to claim 15, wherein the cross section of the inner wall of the hollow conveying body is provided with a polygonal shape, whereas the outer peripheral surface of the sliding magnet is provided with a circular shape.   The multi-pole power generator according to claim 13, wherein the fixed magnet is provided with an annular magnet, two arc magnets, or a plurality of small magnets.   15. The multi-pole power generator according to claim 14, wherein the sliding magnet is connected by a plurality of connecting rods, and a partition member is provided between the sliding magnets.   The multi-pole power generator according to claim 19, wherein the connecting rod is a screw rod, the partition member is a nut, or a partition object such as a spiral insertion member or a washer. Connect to a rectifying power storage device to provide appropriate power to electronic products,
In addition to providing a hollow carrier, both ends and one or more openings, an induction coil is provided on the outer peripheral surface.
One or more sliding magnets are provided inside the hollow carrier, fixed magnets are provided on the outer peripheral surfaces of both ends of the hollow carrier, and the N pole and the S pole are the same poles of the sliding magnets provided at the ends. A kind of multi-pole power generation device in which a lid is provided at the opening.

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