KR101227581B1 - Continuous idle electric generating device - Google Patents

Abstract

PURPOSE: A continuous idle electric generating device is provided to easily control the linear reciprocating motion of a magnet. CONSTITUTION: An outer case(110) has an internal space with a certain size. A bobbin(120) comprises at least one coil arrangement groove(124) in the outer surface of the body. A magnet part(130) is arranged in the central hole formed in the center of body of the bobbin. A guide support part(140) comprises a guide tube inserted into a guide cavity formed in the center of the body of the magnet part. A ball member(150) selectively opens and are closes a first fluid passage and a second fluid passage.

Description

Continuous Idle Electric Generating Device

The present invention relates to a power generation apparatus, and more particularly, to a multi-continuous no-load power generation apparatus capable of generating electricity stably without generating noise by repeated reciprocating linear movements of up and down or left and right while having a simple overall structure.

In general, electricity is produced using nuclear power, hydropower, tidal power, wind power, etc., but is struggling with environmental problems caused by natural destruction, problems that need to be established at specific places, and enormous investment costs are established.

In order to generate electricity, power plants have to be constructed. Depending on the source of energy, the process of the facility and the enormous cost are put in place, and the problem of environmental pollution occurs simultaneously.

In particular, in the case of thermal power generation that generates electricity by burning fossil fuels and generates electricity, various sulfur pollutants are generated when the fossil fuel is burned, causing ozone layer destruction, and the fossil fuel reserves are finite. There is an urgent need for renewable energy sources and devices that can replace fuel.

In addition, most of small portable self-powered / charged products have several gears of different diameters inside to generate induction current, and rotate the gears installed in turn by applying manual or physical force from the outside. The magnet is rotated to produce electricity.

Therefore, in order to provide a constant force, these devices have a complex structure in which a person exerts a constant force by using a force, etc., and also mounts a gear inside to convert this force into rotational force. Power is also limited, so there was a problem in generating electricity continuously.

Republic of Korea Patent Publication No. 10-2002-0026488 (2002.4.10) is equipped with an induction coil for generating an induction current inside the outer case, the inside of the induction coil is made of a magnet made of a magnet for converting the vibration transmitted from the outside into linear reciprocating motion It is magnetized to the same pole as and fixed to the upper and lower parts of the case through the inside of the vibrator so that the stator and vibrator attached to the upper and lower parts of the case to prevent the collision with the vibrator and to provide a repulsive force to the vibrator to perform a constant linear reciprocating motion Disclosed is a self-powered apparatus using vibrations constituted by shafts.

However, the stator must have a magnet of the same polarity so as to have a repulsive force to prevent contact with the reciprocating vibrator, when the magnetic force is lost, the noise generated by the collision between the vibrator and the stator, as well as loss of power generation function There was a problem.

The present invention is to solve the problems as described above, the object is a multi-continuous no-load power generation apparatus that can generate electricity stably without noise by the reciprocating linear movement of the vertical and vertical or left and right while having a simple overall structure To provide.

As a specific means for achieving the above object, the present invention, the both ends by the first and second cover, the outer case having a sealed inner space of a certain size; A bobbin fixed to the inside of the outer case and having at least one coil arrangement groove on the outer surface of the body, the at least one coil being wound a plurality of times; A magnet part disposed reciprocally in a central hole formed in the center of the bobbin so that an induced current is generated in the coil; A guide tube inserted into and disposed in a guide hole formed in the center of the body of the magnet unit, the guide including an extension tube extending radially from both ends of the guide tube and supported to maintain a distance from the first and second covers; It is disposed between the support branch and the inner length of the guide tube, and controls the linear reciprocation of the magnet portion by selectively opening and closing the first fluid passage and the second fluid passage formed on the inner surface of the guide tube during the linear reciprocating operation of the magnet portion Provided is a continuous continuous no-load power generation apparatus including a ball member.

Preferably, the boundary region between the guide tube and the expansion tube is curved to reduce the frictional resistance of the fluid flowing into the guide tube and the fluid discharged from the guide tube.

More preferably, the guide hole of the magnet portion is both ends of the curved surface of the inner diameter increases toward the outside to reduce the frictional resistance between the outer surface of the guide tube and to prevent the pinching phenomenon in the boundary region between the guide tube and the expansion tube It is provided in an inner peripheral surface.

Preferably, the interval between the first fluid passage and the second fluid passage is such that the ball member is in contact with the first and second fluid passages before both ends of the magnet portion contact the boundary region between the guide tube and the expansion tube. It is preferable to provide in the length which cuts off.

Preferably, the first and second covers are provided with first and second auxiliary magnets magnetized with magnets so that magnetic poles facing the same magnetic poles formed at the end of the magnet part face each other on the inner surface corresponding to the magnet part.

Preferably, the magnet unit has at least one iron plate interposed between the first and second magnets magnetized with the N and S poles having different polarities in a reciprocating operation direction, and end portions of the first and second magnets facing the same magnetic poles; It includes a fixed case for fixing the first and second magnets and iron plate.

The present invention as described above has the following effects.

(1) The first fluid of the guide tube during linear reciprocating operation of the magnet part by providing a ball member between the bobbin of the outer case and the guide tube of the guide support, and having a ball member between the first and second fluid passages of the guide tube. By selectively opening and closing the passage or the second fluid passage to form a sealed area on the upper or lower portion of the magnet portion, the linear reciprocating motion of the magnet portion generating the induced current by interaction with the coil provided in the bobbin can be controlled. It can generate electricity stably without noise caused by contact with other members by repeated reciprocating linear movement of up and down or left and right while having the whole structure.

(2) Applied to automobiles and ships that induce linear reciprocation, it can generate electricity without impact from other members during the reciprocation of linear reciprocation. In particular, when applied to waves, which are natural energy sources, vertical movement due to wave force Infinite energy can be obtained by the effect that can be applied to various industries.

1 is a longitudinal sectional view showing a multi-continuous no-load power generation apparatus according to a preferred embodiment of the present invention.
2 is a state diagram in which the magnet portion is lowered in the multi-continuous no-load power generation device according to an embodiment of the present invention.
3 is a state diagram in which the magnet portion is raised in the multi-continuous no-load power generation apparatus according to the preferred embodiment of the present invention.
4 is a configuration diagram of a magnet part employed in a multi-continuous no-load power generation device according to a preferred embodiment of the present invention.

The objects, features and advantages of the present invention described above will become more apparent from the following detailed description. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As illustrated in FIGS. 1 to 3, the multi-continuous no-load power generation device 100 according to the preferred embodiment of the present invention induces a current by an interaction between a coil and a magnet without generating noise by continuous left and right reciprocating operation. It includes an outer case 110, the bobbin 120, the magnet 130, the guide support 140 and the ball member 150 to generate a.

The outer case 110 may be formed of a substantially hollow cylindrical member having an inner space of a predetermined size, the open top is assembled and sealed with the first cover 111, the open bottom is the second cover 112 and Assembled and sealed.

The first cover 111 and the second cover 112 are screwed by forming male screw portions 111a and 111b screwed with female screw portions 113 formed on inner peripheral surfaces of both ends of the outer case 110, respectively. Can be assembled in a manner.

Here, the assembly method between the first and second covers 111 and 112 and the outer case 110 is illustrated and described as being provided by a screw fastening method, but is not limited thereto, and may be variously made by a press-fit method or an adhesive method. have.

The bobbin 120 is a fixed structure that is installed so that the outer surface is in close contact with the inner surface of the outer case 110 is fixed in the middle of the length of the outer case.

At least one coil arrangement groove 124 is provided on the outer surface of the body of the bobbin 120 so that the coil 122 may be wound and disposed a plurality of times, thereby forming the coil 122 as a coil arrangement groove ( The bobbin 120 wound on 124 is inserted into the inner surface of the outer case 110 and fixedly installed in the middle of the length.

In addition, a central hole 126 is formed through the center of the body of the bobbin 120 so that the magnet portion 130 is reciprocally disposed.

Here, the number of windings of the coil wound around the coil arrangement groove 124 may vary in accordance with the design for generating an induction current of the power generator.

The magnet part 130 is a permanent magnet member reciprocally disposed in the central hole 126 formed in the center of the body of the bobbin 120 so that an induced current is generated in the coil 122.

In the center of the body of the magnet portion 130, the guide tube 141 of the guide support 140 is formed through the guide hole 135 is inserted.

The magnet part 130 is formed between the first and second magnets 131 and 132 magnetized with the N and S poles having different polarities in the reciprocating operation direction, and the ends of the first and second magnets 131 and 132 having the same magnetic poles. It includes at least one iron plate 133 is interposed and a fixing case 134 for fixing the first and second magnets (131,132) and the iron plate 133.

Accordingly, the first magnet 131 and the second magnet 132 are joined up and down in the drawing via the iron plate 133 so that the same magnets face each other, and the first and second magnets 131 and 132 and Iron plate 133 is a fixed case consisting of a connecting table 134c for connecting between the first fixing plate 134a in close contact with the first magnet 131 and the second fixing plate 134b in close contact with the second magnet 132. 134 is assembled into a substantially cylindrical shape.

The guide support 140 includes a guide tube 141 and expansion tubes 142 and 143, the guide tube 141 is inserted into the guide hole 135 formed through the center of the body of the magnet portion 130 The guide member is guided during the reciprocating operation of the magnet unit 130.

The extension pipes 142 and 143 extend radially from both ends of the guide pipe 141 and support the support member 145 to maintain a gap for forming a passage in which fluid flows freely between the first and second covers 111 and 112. Is supported via mediation.

Here, the guide tube 141 is preferably provided to be substantially the same or relatively long than the length of the bobbin 120, the extension pipes (142, 143) end is adjacent to the inner surface of the outer case 110 It is desirable to expand.

In addition, the boundary area between the guide tube 141 and the expansion pipes 142 and 143 may be curved to reduce the frictional resistance of the fluid flowing into the guide tube and the fluid discharged from the guide tube. Do.

In addition, the guide hole 135 of the magnet portion 130 is pinched in the boundary region between the guide tube 141 and the expansion tube (142,143) while reducing the frictional resistance of the guide tube on the inner peripheral surface of both ends; It is preferable to have a curved surface 135a whose inner diameter becomes larger toward the outside so as to prevent imaging.

The ball member 150 is disposed to reciprocate by the flow of fluid flowing through the inner length of the guide tube 141, the reciprocating operation of the magnet portion 130 of the guide tube 141 By selectively opening and closing the first fluid passage 151 or the second fluid passage 152 formed on the inner surface to control the reciprocating operation of the magnet unit 130.

The ball member 150 is separated from the first and second fluid passages 151 and 152 because the ball member 150 is formed to have a larger outer diameter than the inner diameter of the first and second fluid passages 151 and 152. It does not deviate and can always be placed between them.

In addition, the distance between the first fluid passage 151 and the second fluid passage 152 may be longer or shorter in proportion to the reciprocating movement distance of the magnet portion 130, but both ends of the magnet portion 130 It is preferable to design the length of the ball member 150 to contact the first and second fluid passages 151 and 152 to block the passage before contacting the boundary area between the guide tube 141 and the expansion tubes 142 and 143. .

That is, when the magnet part 130 moves to the second cover 112 side (when descending downward in the drawing) and the first fluid passage 151 by the fluid flow flowing into the lower portion of the guide tube 141 When the ball member 150 disposed between the second fluid passages 152 is raised to block the first fluid passage 151 or the magnet part 130 moves to the first cover 111 side (upward in the drawing). When the rise of the ball member 150 disposed between the first fluid passage 151 and the second fluid passage 152 by the fluid flow flowing into the upper portion of the guide tube 141 is lowered to the second By blocking the fluid passage 152, collision between the magnet part 130 and the first and second covers 111 and 112 is generated while generating an induced current in the coil by the reciprocating operation of the magnet part by the fluid compression force in the hermetic system. This can be prevented.

Holding the outer case 110 by hand to generate electricity using the power generation device 100 having the above-described configuration, the outer case 110 is fixed to the site that is shaken up and down or vertical vibration occurs, the outer case 110 The outer circumferential surface of the magnet unit 130 reciprocally disposed in the bobbin 120 of () is in contact with or spaced apart from the central hole 126 of the bobbin 120, the guide hole 135 of the magnet unit 130 Is linearly reciprocating along the guide tube 141 because it is assembled so as to reciprocate in the guide tube (141).

At this time, the induced current is generated by the interaction between the magnetic force lines generated in the reciprocating magnet portion 130 and the coil 122 disposed in the coil arrangement groove 124 of the bobbin 120, the generated induced current is It is supplied to an electric device such as a lamp connected to the end of the coil to operate it or to be charged by charging the charger.

When the magnet part 130 descends to the second cover 112 in the drawing, the magnet part 130 is filled between the bobbin 120, the guide tube 141, and the expansion tube 143 by the magnet part 130 that is lowered. As the fluid is pushed downward, the fluid flows into the lower portion of the guide tube 141 through a passage between the expansion tube 143 and the second cover 112.

Accordingly, the ball member 150 disposed between the first fluid passage 151 and the second fluid passage 152 has an upper portion from the lower portion to the upper portion due to the fluid pressure rapidly flowing from the lower portion of the guide tube 141. As it is raised to the first fluid passage 151 in contact with the blocking it to form a sealed area in the lower space of the magnet portion 130.

As a result, the fluid in the sealed region is compressed by the lowering force of the lowering magnet part 130, and when the fluid compression force becomes greater than the lowering force of the lowering magnet part 130, the lowering of the magnetic part 130 is performed. It stops and stops before contacting the boundary area between the guide tube 141 and the lower side expansion tube 143.

On the contrary, when the magnet part 130 rises in the drawing toward the first cover 111, the magnet part 130 is filled between the bobbin 120, the guide tube 141, and the expansion tube 142 by the raised magnet part 130. As the fluid is pushed upward, the fluid flows into the upper portion of the guide tube 141 through a passage between the expansion tube 142 and the first cover 111.

Accordingly, the ball member 150 disposed between the first fluid passage 151 and the second fluid passage 152 is lowered from the top to the bottom by the fluid pressure rapidly flowing from the upper portion of the guide tube 141. As it is lowered to contact the second fluid passage 152 to block it to form a sealed area in the upper space of the magnet portion 130.

For this reason, the fluid in the sealed region is compressed by the lifting force of the magnet portion 130 that is raised, and when the fluid compression force is greater than the lifting force of the magnet portion 130 that is raised, the rise of the magnet portion 130 is increased. It stops and stops before contacting the boundary region between the guide tube 141 and the upper side expansion tube 142.

The first and second subsidiary magnets 118 and 119 are magnetized so that the magnetic poles are magnetized to face the same magnetic poles formed at the end of the magnetic part on the inner surface corresponding to the magnet part 130. Each of the magnet unit 130 and the upper extension tube 142 by the repulsive force caused by the same stimulus at the mutual close proximity between the magnet portion 130 and the first and second cover, respectively) The linear reciprocating operation of the magnet unit 130 may be controlled so as not to be in contact with the boundary region.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. It will be apparent to those of ordinary skill in the art.

110: outer case 111,112: first and second cover
120: bobbin 122: coil
124: coil arrangement groove 126: central hole
130: magnet 131,132: first and second magnet
133: iron plate 134: fixed case
140: guide support 141: guide tube
142,143: expansion pipe 145: support member
150: ball member 151,152: first and second fluid passage

Claims (6)

An outer case having both ends blocked by the first and second covers and having a sealed inner space of a predetermined size;
A bobbin fixed to the inside of the outer case and having at least one coil arrangement groove on the outer surface of the body, the at least one coil being wound a plurality of times;
A magnet part disposed reciprocally in a central hole formed in the center of the bobbin so that an induced current is generated in the coil;
A guide tube inserted into and disposed in a guide hole formed in the center of the body of the magnet unit, the guide including an extension tube extending radially from both ends of the guide tube and supported to maintain a distance from the first and second covers; Support branch and
A ball member disposed between the inner lengths of the guide tubes and selectively opening and closing the first fluid passage and the second fluid passage formed on the inner surface of the guide tube during the linear reciprocating operation of the magnet part to control the linear reciprocation of the magnet part; Continuous continuous no-load generator comprising a. The method of claim 1,
The boundary region between the guide tube and the expansion tube is curved in order to reduce the frictional resistance of the flow of the fluid flowing into the guide tube and the fluid discharged from the guide tube is characterized in that the continuous continuous load generator. The method of claim 2,
The guide hole of the magnet part may have a curved surface on both ends of the inner circumferential surface of which the inner diameter increases toward the outside to reduce the frictional resistance with the outer surface of the guide tube and to prevent the pinching phenomenon in the boundary area between the guide tube and the expansion tube. Multi-continuous no-load power generator. The method of claim 1,
The distance between the first fluid passage and the second fluid passage is a length at which the ball member contacts the first and second fluid passages to block a passage before both ends of the magnet portion contact the boundary region between the guide tube and the expansion tube. Continuous continuous no-load power generation apparatus characterized in that provided with. The method of claim 1,
The first and second covers may include multiple first and second auxiliary magnets each having a magnetic pole magnetized so as to face a magnetic pole identical to a magnetic pole formed at an end portion of the magnet portion on an inner surface corresponding to the magnetic portion. No-load generator. The method of claim 1,
The magnet part includes at least one iron plate interposed between the first and second magnets magnetized with the N and S poles having different polarities in a reciprocating operation direction, and end portions of the first and second magnets facing the same magnetic poles. Multi-continuous no-load power generation apparatus comprising a fixed case for fixing the two magnets and the iron plate.

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