Energy extracting mechanism having a magnetic spring

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to a magnetic spring having a plurality of permanent magnets and, in particular but not exclusively, to an energy extracting mechanism provided with a magnetic spring having negative damping characteristics by utilizing a repulsive force of a plurality of permanent magnets.

2. Description of Related Art

Various pressure mechanisms are widely used today. A press for performing pressure molding upon insertion of a workpiece between upper and lower bases is a typical example of the pressure mechanisms. The pressure mechanisms generally make use of water or oil pressures, a mechanical structure, or both of them.

An exciter or vibration generator is used to artificially generate vibration to investigate vibration characteristics of a structure. Exciters of an electromotive type and those employing an unbalance mass or a cam are known.

Because the conventional pressure mechanisms or exciters are generally of a complicated structure and are, hence, heavy and costly, light and inexpensive ones have been desired.

SUMMARY OF THE INVENTION

The present invention has been developed to overcome the above-described disadvantages.

It is accordingly an objective of the present invention to provide an energy extracting mechanism provided with a magnetic spring having negative damping characteristics in order to realize inexpensive pressure mechanisms or exciters of a simple construction by effectively utilizing potential energy existing in a magnetic field.

In accomplishing the above and other objectives, the energy extracting mechanism according to the present invention includes first and second permanent magnets spaced from each other with the same magnetic poles opposed to each other, and a magnetic spring formed by the first and second permanent magnets. The magnetic spring provides negative damping characteristics or changes static magnetic energy by changing an opposing area of said first and second permanent magnets so that an output may be extracted from said second permanent magnet by applying an input to said first permanent magnet, making it possible to simplify the construction of the energy extracting mechanism.

Advantageously, the first permanent magnet is rotated, while the second permanent magnet is caused to slide. By so doing, a press, an exciter or the like can be manufactured at a low cost.

The second permanent magnet can be rotated continuously by means of a force acting thereon for returning the second permanent magnet to a position where potential energy thereof is minimum, kinetic energy thereof, and an inertia moment thereof by applying a load to the first permanent magnet to impart potential energy thereto and by oscillating the first permanent magnet at a balanced position with the second permanent magnet. The continuous rotation of the second permanent magnet can derive electromagnetic induction and, hence, is applicable to a dynamo or the like.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other objectives and features of the present invention will become more apparent from the following description of preferred embodiments thereof with reference to the accompanying drawings, throughout which like parts are designated by like reference numerals, and wherein:

FIG. 1

is a schematic diagram of a magnetic spring according to the present invention, particularly depicting balanced positions of two permanent magnets on the input side and on the output side;

FIG. 2

is a graph of the fundamental characteristics of the magnetic spring of

FIG. 1

, particularly showing a relationship between the load applied to one of the two permanent magnets and the deflection thereof from the balanced position;

FIG. 3

is a graph showing a relationship between the load measured and the deflection;

FIG. 4A

is a schematic diagram depicting the way of thinking of input and output in a charge model assuming that magnetic charges are uniformly a distributed on end surfaces of the permanent magnets, and particularly showing attraction;

FIG. 4B

is a diagram similar to

FIG. 4A

, but particularly showing repulsion;

FIG. 4C

is a diagram similar to

FIG. 4A

, but particularly showing repulsion at locations different from those shown in

FIG. 4B

;

FIG. 5

is a schematic diagram depicting mutually spaced permanent magnets with the same magnetic poles opposed to each other and also depicting the case where one of the permanent magnets is moved relative to the other (to change the opposing area thereof);

FIG. 6

is a graph showing the load in X-axis and Z-axis directions relative to the amount of movement in X-axis direction when calculation has been carried out based on

FIG. 5

;

FIG. 7

is a graph showing a relationship between the load and deflection when the distance between the permanent magnets of

FIG. 5

is kept constant, and one of the magnets is moved relative to the other from the completely slipped condition to the completely lapped one, and again to the completely slipped one;

FIG. 8

is a schematic diagram depicting mutually spaced permanent magnets with the same magnetic poles opposed to each other and also depicting the case where one of the magnets is rotated relative to the other (to change the opposing area thereof);

FIG. 9

is a graph showing the maximum load relative to the opposing area when one of the magnets is rotated, as shown in

FIG. 8

;

FIG. 10

is a graph showing a relationship between the load and the distance between the magnets when neodymium-based magnets are employed;

FIG. 11

is a perspective view of a rotary mechanism wherein geometric dimensions are changed by changing the opposing area of the permanent magnets;

FIG. 12

is a schematic view of a mechanical model of the rotary mechanism of

FIG. 11

;

FIG. 13

is a graph showing a relationship between input torque and output work in the rotary mechanism of

FIG. 11

;

FIG. 14

is a graph showing a relationship between input work and output work in the rotary mechanism of

FIG. 11

;

FIG. 15

is a graph showing a relationship between input load and output load in the rotary mechanism of

FIG. 11

;

FIG. 16

is a perspective view of another rotary mechanism;

FIG. 17

is a perspective view of a reciprocating mechanism wherein the geometric dimensions are changed by changing the opposing area of the permanent magnets;

FIG. 18

is an energy extracting mechanism wherein rotational energy is extracted by rotating one of two permanent magnets;

FIG. 19

is a graph showing electromagnetic induction characteristics when a coil is rotated together with one of the two permanent magnets;

FIG. 20

is a perspective view of another energy extracting mechanism;

FIG. 21

is a fragmentary perspective view, partly in section, of a main portion of the energy extracting mechanism of

FIG. 20

;

FIG. 22

is a front view of the energy extracting mechanism of

FIG. 20

when a drive source is mounted therein;

FIG. 23

is a perspective view of one of two magnets mounted in the energy extracting mechanism of

FIG. 20

;

FIG. 24

is a top plan view of the main portion of the energy extracting mechanism of

FIG. 20

, particularly showing a positional relationship between the lower permanent magnet and flywheels secured thereto;

FIG. 25

is a view similar to

FIG. 24

, but showing a positional relationship between the two opposing permanent magnets;

FIG. 26

is a front view of a modification of the energy extracting mechanism of

FIG. 20

;

FIG. 27

is a schematic view of a fundamental model explanatory of the characteristics of the magnetic spring; and

FIG. 28

is a graph showing a spring constant and a coefficient both changing with time in the magnetic spring structure according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

This application is based on applications Nos. 8-259810 and 9-127557 filed Sep. 30, 1996 and May 16, 1997, respectively, in Japan, the content of which is incorporated hereinto by reference.

Referring now to the drawings, preferred embodiments of the present invention are discussed hereinafter.

When a magnetic spring structure is made up of at least two spaced permanent magnets with the same magnetic poles opposed to each other, the two spaced permanent magnets are held in non-contact with each other. Furthermore, negative damping can be easily produced by changing the static magnetic field (the arrangement of the magnets) with a small amount of input utilizing the degree of freedom peculiar to the non-contact pair and the instability of the float control system.

The present invention has been developed taking note of this fact. At the time of input (go) and at the time of output (return), the geometric dimensions between the two permanent magnets are changed by a mechanism inside a kinetic system in which the permanent magnets are placed or by an external force. The change in geometric dimensions is converted into a repulsive force in the kinetic system to make the repulsive force from the balanced position of the two permanent magnets greater at the time of output than at the time of input.

The fundamental principle is explained hereinafter.

FIG. 1

schematically depicts balanced positions of two permanent magnets

2

and

4

on the input side and on the output side, while

FIG. 2

depicts the fuundamental characteristics of the magnetic spring structure indicating a relationship between the load applied to one of the two permanent magnets and the deflection thereof from the balanced position.

As shown in

FIG. 1

, when the balanced position of the permanent magnet

4

on the input side relative to the permanent magnet

2

and the spring constant of the magnetic spring are x

0

and k1, respectively, and the balanced position thereof on the output side and the spring constant are x

1

and k2, respectively, an area conversion is performed between x

0

and x

1

, and the following relations hold at respective balanced positions.

−k

1/

x

0

+mg=

0

−k

2

/x

1

+mg=

0

k

2>

k

1

Accordingly, the static characteristics indicate negative damping characteristics, as shown in

FIG. 2

, and it is conceivable that the potential difference between the position x

1

and the position x

0

corresponds to the potential energy for oscillation.

A model of

FIG. 1

was made and a relationship between the load and the deflection was measured by changing the time during which the load was applied. As a result, a graph shown in

FIG. 3

was obtained, which can be interpreted as meaning that when the two permanent magnets

2

and

4

approach their closest position, a great repulsive force is produced, and that when the amount of deflection from the balanced position changes slightly, a friction loss is produced by a damper effect of the magnetic spring, thus creating a damping term.

In

FIG. 3

, (a) is a curve obtained when a constant load was applied, and the time during which the load was being applied becomes shorter in the order of (a), (b) and (c). In other words, the static characteristics vary according to the manner in which the load is applied, and the longer the time during which the load is applied, the greater the impulse.

As for rare-earth magnets, the strength of magnetization does not depend upon the magnetic field. More specifically, because the internal magnetic moment is not easily influenced by the magnetic field, the strength of magnetization on a demagnetization curve hardly changes, and the value is kept almost the same as that of saturation magnetization. Accordingly, in the case of rare-earth magnets, the force can be calculated using a charge model assuming that the magnetic load is uniformly distributed on its surfaces.

FIG. 4

depicts the way of thinking in which a magnet is defined as a set of smallest unit magnets. The relationship of forces acting among the unit magnets was calculated by classifying it into three.

(a) Attraction (because the unit magnets are identical in both r and m, two types are defined by one)

f

(1)

=(

m

2

r

2

)

dx

1

dy

1

dx

2

cy

2

f

x

(1)

=f

(1)

cos θ

f

z

(1)

=f

(1)

sin θ

(b) Repulsion

f

x

(2)

=f

(2)

cos θ

f

z

(2)

=f

(2)

sin θ

(c) Repulsion

f

x

(3)

=f

(3)

cos θ

f

z

(3)

=f

(3)

sin θ

Accordingly,

−

f

x

=2

f

x

(1)

−f

x

(2)

−f

x

(3)

−

f

z

=2

f

z

(1)

−f

z

(2)

−f

z

(3)

Hereupon, the Coulomb's law is expressed by:

F = k(q

1

q

2

/r

2

)

r: distance

q = MS

q1, q2: magnetic charge

M(m): strength of magnetization

S: area

The forces can be obtained by integrating the above (−f

x

) and (−f

z

) with respect to the range of the magnet size.

As shown in

FIG. 5

, calculation was carried out for each magnetic gap by moving one of two opposing magnets relative to the other from the condition in which they are completely lapped (the length of movement x=0 mm) to the condition in which one of them is completely slipped (the length of movement x=50 mm). The results of calculation are shown in FIG.

6

. Although the internal magnetic moment is defined as being constant, it is somewhat corrected because disorder is caused around the magnets when the magnetic gap is small.

The above results of calculation are generally in agreement with the results of actual measurement. The force required for moving the point (a) to the point (b) in

FIG. 2

is the x-axis load, while the output is represented by the z-axis load. The relationship of input<output caused by instability is statically clarified.

FIG. 7

is a graph indicating a relationship between the x-axis load and the z-axis load when the distance between the magnets is kept 3 mm, and the condition of the magnets is changed from the completely slipped condition to the completely lapped one, and again to the completely slipped one. This graph is a characteristic curve indicating that the absolute value of the x-axis load is the same but the direction of output is reversed. When one of the magnets is moved relative to the other to approach the completely lapped condition, the former receives a resistance, resulting in damping. On the other hand, when one of the magnets is moved relative to the other from the completely lapped condition to the completely slipped condition, the former is accelerated. These characteristics can be used in a non-contact damper to reduce the vibration energy or to improve the transmissibility in the low, middle and high frequency region (0-50 Hz) which human beings can sense, though conventional dampers could not achieve this.

When the rotational angle of the opposing magnets is changed as shown in

FIG. 8

, a graph shown in

FIG. 9

was obtained. As a matter of course, the maximum load decreases as the opposing area decreases. This graph indicates that the output can be changed through an area conversion which can be performed by applying a predetermined input.

FIG. 10

is a graph indicating a relationship between the load and the distance between the magnets when neodymium-based magnets are employed.

The repulsive force increases with an increase in mass. The repulsive force F is given by:

fαBr

2

×(geometric dimensions)

Br

: strength of magnetization

The geometric dimensions mean the size determined by the distance between the opposing magnets, the opposing area, the magnetic flux density, the strength of the magnetic field or the like. If the magnet material is the same, the strength of magnetization (Br) is constant and, hence, the repulsive force of the magnets can be changed by changing the geometric dimensions.

FIG. 11

depicts a rotary mechanism wherein the geometric dimensions are changed by rotating one of two permanent magnets

2

,

4

relative to the other to change the opposing area thereof, while

FIG. 12

depicts a mechanical model of the rotary mechanism of FIG.

11

.

As shown in

FIG. 11

, the permanent magnet

2

is rotatably mounted on a base

6

to which a linear slider

8

is secured so as to extend vertically. An L-shaped member

10

is vertically slidably mounted on the linear slider

8

. A weight

12

is placed on an upper surface of the L-shaped member

10

, while the permanent magnet

4

is secured to a lower surface of the L-shaped member

10

so as to confront the permanent magnet

2

with the same magnetic poles opposed to each other.

In the rotary mechanism of the above-described construction, when permanent magnets of a size of 49 mmL×25 mmW×11 mmH (Trade name: NEOMAX-39SH) and a weight weighing 6.5 kg (total weight: about 7.33 kg including the L-shaped member

10

and the permanent magnet

4

) were used for the permanent magnets

2

,

4

and the weight

12

, respectively, and when a torque was applied to the permanent magnet

2

, the following results were obtained.

TABLE 1

X

F

Z

0°

0

0

15°

0.45 kgf

1.18 mm

30°

0.56 kgf

2.80 mm

45°

0.51 kgf

4.52 mm

60°

0.40 kgf

5.70 mm

75°

0.20 kgf

6.37 mm

90°

0

6.65 mm

Hereupon, X is the rotational angle measured from the condition of

FIG. 11

in which the opposing area of the permanent magnets

2

,

4

is minimum, F is the load applied to the permanent magnet

2

at a location apart a distance r from the center thereof in a direction longitudinally thereof, and Z is the deflection measured from the balanced position (G=7.5 mm) of the permanent magnets

2

,

4

.

FIGS. 13 and 14

depict input/output characteristics of the rotary mechanism referred to above.

As can be seen from these figures, when X=0°, F=0, and the torque to be inputted increases abruptly until X=30° and decreases gradually after the rotational angle exceeds X=30°. These figures also reveal that a great output work can be extracted from a relatively small input work by making use of negative damping characteristics of the magnetic spring or by changing the static magnetic energy. The input work and the output work can be derived from the following formulas.

N

(torque)=

rF

P=mv P

: momentum of permanent magnet 4

, F=dP/dt

L=mθL

: angular momentum of permanent magnet 2

, N=dL/dt

W

(output work)=∫

Fdx

=∫(

dP/dt

)

dx=d/dt∫Pdx

W

′(input work)=∫

Nd

θ=∫(

dL/dt

)

dθ=d/dt∫Ldθ

FIG. 15

is a graph indicating a relationship between the input load and the output load when one of two permanent magnets of a 50 mmL×25 mmW×10 mmH size is rotated relative to the other by 0° (50% lapping) to 90° (100% lapping) with the same magnetic poles opposed to each other.

The graph of

FIG. 15

reveals that a great output can be obtained from a relatively small input by the conversion of potential energy in a magnetic field. Accordingly, the rotary mechanism of

FIG. 11

can be employed not only in a vertical exciter or vibration generator but also in a horizontal exciter by moving the weight

12

horizontally. If the weight

12

is used as a ram, the rotary mechanism of

FIG. 11

can be employed in an upstroke press.

FIG. 16

depicts a rotary mechanism of a construction more concrete than that of FIG.

11

.

As shown in

FIG. 16

, the permanent magnet 2 has a rotary shaft

2

a

rotatably mounted on the base

6

. A large-diameter gear

14

is rigidly secured to the rotary shaft

2

a

for rotation together therewith, while a small-diameter gear

16

in mesh with the large-diameter gear

14

is rigidly secured to a rotary shaft

18

a

of a drive motor

18

.

In this rotary mechanism, when the small-diameter gear

16

is rotated by means of a rotational force of the drive motor

18

, the permanent magnet

2

together with the large-diameter gear

14

rotates at a speed smaller than that of the small-diameter gear

16

. As a result, an area conversion is conducted between the two permanent magnets

2

,

4

, moving the permanent magnet

4

vertically along the near slider

8

. Hereupon, it is sufficient if the drive motor

18

for rotating the mall-diameter gear

16

has a relatively small torque.

FIG. 17

depicts a reciprocating mechanism wherein an area conversion is conducted by sliding the permanent magnet

2

relative to the permanent magnet

4

.

More specifically, the permanent magnet

2

is coupled to a drive shaft

20

a

of a drive source

20

such as, for example, a VCM (voice coil motor) and is slidably mounted on a linear slider

22

secured to the base

6

. The permanent magnet

2

is caused to slide horizontally along the linear slider

22

by means of a drive force of the drive source

20

. When the permanent magnet

2

slides, an area conversion is conducted between the two permanent magnets

2

,

4

to thereby move the permanent magnet

2

vertically.

Furthermore, in the rotary mechanism of

FIG. 11

, when the permanent magnet

4

is on the input side, while the permanent magnet

2

is on the output side, a vertical movement can be converted into rotational energy. That is, when the permanent magnet

4

is coupled to a drive source via, for example, a cam mechanism and when an input of a predetermined frequency is applied to the cam mechanism, the permanent magnet

4

repeats a vertical oscillation, resulting in rotation of the permanent magnet

2

. Accordingly, electromagnetic induction can be caused by rotating, for example, a coil together with the permanent magnet

2

. More specifically, when potential energy is imparted to the permanent magnet

4

by applying a load thereto and when the permanent magnet

4

is oscillated with a small input at the balanced point thereof with the permanent magnet

2

, the permanent magnet

2

is rotated continuously by means of a force acting thereon to return it to the position where the potential energy thereof is minimum, an inertial moment thereof, and kinetic energy thereof obtained by the oscillation of the potential energy of the weight

12

. The aforementioned predetermined frequency depends on the strength of magnetic force, and the magnitude of input energy is inversely proportional to the magnitude of the load applied (weight

12

). The permanent magnet

2

can be rotated at a high speed with a relatively small input by applying an oscillating input to the permanent magnet

4

, making it possible to apply this mechanism to a dynamo or the like.

FIG. 18

depicts a rotational-energy extracting mechanism wherein a permanent magnet

2

is rotatably mounted on a base

6

and an L-shaped member

10

having a permanent magnet

4

secured thereto is rigidly connected to a drive shaft

24

a

of a drive source

24

such as, for example, a VCM for rotation together therewith.

In the rotational-energy extracting mechanism as shown in

FIG. 18

, when the permanent magnet

4

together with the L-shaped member

10

is moved vertically along a linear slider

8

at a predetermined frequency by means of a drive force of the drive source

24

, the permanent magnet

2

which confronts the permanent magnet

4

with the same magnetic poles opposed to each other rotates at a high speed, making it possible to extract rotational energy.

Hereupon, electric current generated in a coil was investigated by rotating the coil together with the permanent magnet

2

. Two permanent magnets of the same size as that used to obtain the graph of

FIG. 15

were used for the permanent magnets

2

,

4

.

FIG. 19

is a graph indicating the electric current generated in the coil. The coil used had 50 turns of a sectional area of 1 mm

2

, and the speed of movement of the permanent magnet

4

was set to 100 mm/min., 500 mm/min., and 1000 mm/min.

This graph reveals that the current value increases substantially in proportion to the speed of movement of the permanent magnet

4

and that a desired output (current) can be obtained by appropriately setting the magnitude of an input.

FIGS. 20

to

22

depict a rotational-energy extracting mechanism of a construction more concrete than that of FIG.

18

. The rotational-energy extracting mechanism shown therein includes a generally rectangular lower plate

30

, a generally rectangular upper plate

32

spaced a predetermined distance from the lower plate

30

and extending parallel thereto, and two rectangular frames

34

to which the upper and lower plates

32

,

30

are secured. Four vertically extending pillars

36

are secured at opposite ends thereof to respective corners of the upper plate

32

and those of the lower plate

30

, while a floating table

38

is vertically movably mounted to the four vertically extending pillars

36

. The floating table

38

is coupled to a drive shaft

39

a

of a drive source

39

such as a VCM or the like secured to the upper plate

32

and is vertically moved by a drive force of the drive source

39

.

A pair of flywheels

42

are rotatably mounted on a base

40

secured to the lower plate

30

. Each of the flywheels

42

is coupled on one side thereof to one end of a connecting shaft

44

, the other end of which is coupled to a slider

46

slidably mounted on the base

40

. A disc-shaped permanent magnet

48

, disposed above the flywheels

42

, is secured to an upper one of them for rotation together therewith. A disc-shaped permanent magnet

50

is secured to a lower surface of the floating table

38

so as to confront the permanent magnet

48

with the same magnetic poles opposed to each other.

As shown in

FIG. 23

, each of the two permanent magnets

48

,

50

has a round hole

48

a

,

50

a

defined therein and having an eccentric center relative to the center thereof.

In

FIGS. 24 and 25

, a position where the magnetic flux of the lower permanent magnet

48

is maximum, a position where that of the upper permanent magnet

50

is maximum, and a position where the inertia forces of the pair of flywheels

48

are maximum are indicated. In these figures, the upper permanent magnet

50

secured to the floating table

38

is positioned at a bottom dead point (the lowest point) closest to the lower permanent magnet

50

. When the lower permanent magnet

48

is rotated 180° from this position in a direction shown by an arrow, the upper permanent magnet

50

moves upwardly and reaches a top dead point. When the lower permanent magnet

48

is further rotated about 90°, it reaches a change point where it is still rotated in the same direction by means of rotational inertia of the flywheels

42

.

In the above-described construction, when the drive force of the drive source

39

is transmitted to the floating table

38

at a balanced position of the two permanent magnets

48

,

50

, the floating table

38

and the upper permanent magnet

50

are oscillated vertically at a predetermined frequency. Because the rotatable lower permanent magnet

48

confronts the upper permanent magnet

50

with the same magnetic poles opposed to each other, the lower permanent magnet

4

is rotated continuously by means of a force acting to return it to a place where the potential energy thereof is minimum, kinetic energy thereof, an inertia force thereof, and an inertial force of the flywheels

42

. That is, a relatively small oscillating input applied to the upper permanent magnet

50

rotates the lower permanent magnet

48

at a high speed, making it possible to extract rotational energy.

FIG. 26

depicts an energy extracting mechanism including, in addition to the mechanism of

FIG. 20

, a weight

52

placed on the floating table

38

and a drive source

54

such as, for example, a VCM coupled to the slider

46

.

In this construction, when the drive force of the drive source

54

is transmitted to the slider

46

, the lower permanent magnet

48

together with the flywheels

42

is rotated via the connecting shaft

44

at a predetermined frequency. As a result, an area conversion is caused between the two permanent magnets

48

,

50

, and converts energy inputted by the drive source

54

into potential energy of the weight

52

. This potential energy is in turn converted into a torque (rotational energy) by the two permanent magnets

48

,

50

and is stored as an inertia force of the flywheels

42

, which can be extracted as rotational energy.

The dynamic characteristics of the magnetic spring referred to above are explained hereinafter using a characteristic equation of a simplified fundamental model shown in FIG.

27

.

In

FIG. 27

, an input F is the force produced by a change in geometric dimensions caused by, for example, the area conversion of the permanent magnets. When the spring constant, the damping coefficient, and a harmonic excitation inputted to a mass m are represented by k, r, and F(t), respectively, the characteristic equation is given by:

\begin{matrix} m \ddot{x} + r \ddot{x} - \frac{k}{x} + m g = F (t) & (1) \end{matrix}

When the balanced position is expressed as x

0

and the deflection from the balanced position is expressed as y,

\begin{matrix} - \frac{k}{x_{0}} + m g = 0, x_{0} = \frac{k}{m g} x = x_{0} + y \dot{x} = \dot{y} \ddot{x} = \ddot{y} \begin{matrix} \frac{k}{x} = \frac{k}{x_{0} + y} = \frac{k}{x_{0} (1 + \frac{y}{x_{0}})} \approx \frac{k}{x_{0}} (1 - \frac{y}{x_{0}}) \\ = \frac{k}{x_{0}} - \frac{k}{x_{0}^{2}} y \end{matrix} [∵ y ⪡ x_{0}] \begin{matrix} m \ddot{x} + r \dot{x} - \frac{k}{x} + m g = m \ddot{y} + r \dot{y} - \frac{k}{x_{0} + y} + m g \\ = m \ddot{y} + r \dot{y} - \frac{k}{x_{0}} + \frac{k}{x_{0}^{2}} y + \frac{k}{x_{0}} \\ = m \ddot{y} + r \dot{y} + \frac{k}{x_{0}^{2}} y \end{matrix} & (2) \end{matrix}

If k/x

0

2

=k′,

mÿ+r{dot over (y)}+k′y=F

(

t

)

If the harmonic excitation F(t)=Fe

iωt

and y=xe

iωt

,

\begin{matrix} \dot{y} = ⅈ ω x ⅇ^{ⅈ ω t} \\ \ddot{y} = ⅈ^{2} ω^{2} x ⅇ^{ⅈ ω t} \\ - m ω^{2} x ⅇ^{ⅈ ω t} + r ⅈ ω x ⅇ^{ⅈ ω t} + k^{'} x ⅇ^{ⅈ ω t} = F ⅇ^{ⅈ ω t} \\ (- m ω^{2} x + r ⅈ ω x + k^{'} x) ⅇ^{ⅈ ω t} = F ⅇ^{ⅈ ω t} \\ x (k^{'} - m ω^{2} + r ⅈ ω) = F \\ \begin{matrix} x = \frac{F}{k^{'} - m ω^{2} + r ⅈ ω} \\ = \frac{F (k^{'} - m ω^{2} - r ⅈ ω)}{(k^{'} - m ω^{2} + r ⅈ ω) (k^{'} - m ω^{2} - r ⅈ ω)} \\ = \frac{F}{\sqrt{{(k^{'} - m ω^{2})}^{2} + {(r ω)}^{2}}} [\frac{k^{'} - m ω^{2}}{\sqrt{{(k^{'} - m ω^{2})}^{2} + {(r ω)}^{2}}} - ⅈ r \frac{ω}{\sqrt{{(k^{'} - m ω^{2})}^{2} + {(r ω)}^{2}}}] \\ = \frac{F}{\sqrt{{(k^{'} - m ω^{2})}^{2} + {(r ω)}^{2}}} (\cos φ - ⅈ \sin φ) \\ = \frac{F}{\sqrt{{(k^{'} - m ω^{2})}^{2} + {(r ω)}^{2}}} ⅇ^{- ⅈ φ} \end{matrix} \\ \begin{matrix} y = x ⅇ^{ⅈ ω t} = \frac{F}{\sqrt{{(k^{'} - m ω^{2})}^{2} + {(r ω)}^{2}}} ⅇ^{ⅈ (ω t - φ)} \\ = \frac{F}{\sqrt{{k^{′2} [1 - {(\frac{ω}{ω_{0}})}^{2}]}^{2} + {(2 ρ \frac{ω}{ω_{0}})}^{2}}} ⅇ^{ⅈ (ω t - φ)} \end{matrix} \end{matrix}

where φ represent the phase angle.

ρ = r / 2 \sqrt{{mk}^{'}}

ω_{o}^{2} = \frac{k^{'}}{m} = \frac{k}{{mx}_{0}^{2}} = \frac{k}{m} {(\frac{m g}{k})}^{2} = \frac{m}{k} g^{2}

Accordingly, the natural frequency (resonant frequency) ω

0

is given by:

ω_{o} \propto \sqrt{\frac{m}{k}}

The equation (2) can be expresses as follows.

\begin{matrix} \frac{k}{x} = \frac{k}{x_{0} + y} = \frac{k}{x_{0} (1 + \frac{y}{x_{0}})} = \frac{k}{x_{0}} (\frac{1}{1 + \frac{y}{x_{0}}}) \\ = \frac{k}{x_{0}} {1 - \frac{y}{x_{0}} + {(\frac{y}{x_{0}})}^{2} - {(\frac{y}{x_{0}})}^{3} + \dots {(- 1)}^{n} {(\frac{y}{x_{0}})}^{n} + \dots} \end{matrix}

\begin{matrix} m \ddot{x} + r \dot{x} - \frac{k}{x} + m g = m \ddot{y} + r \dot{y} + \frac{k}{x_{0}} - \frac{k}{x_{0}} {1 - \frac{y}{x_{0}} + {(\frac{y}{x_{0}})}^{2} - {(\frac{y}{x_{0}})}^{3} + \dots} \\ = m \ddot{y} + r \dot{y} + \frac{k}{x_{0}} {\frac{y}{x_{0}} - {(\frac{y}{x_{0}})}^{2} + {(\frac{y}{x_{0}})}^{3} - \dots} \end{matrix}

Let y be x and when the equation having up to a term of the third degree is considered,

\begin{matrix} m \ddot{x} + r \dot{x} + \frac{k}{x_{0}^{2}} x - \frac{k}{x_{0}^{3}} x^{2} + \frac{k}{x_{0}^{4}} x^{3} = F (t) m \ddot{x} + r \dot{x} + ax - {bx}^{2} + {cx}^{3} = F (t) a = \frac{k}{x_{0}^{2}} = {(\frac{m g}{k})}^{2} k = \frac{{(m g)}^{2}}{k} b = \frac{k}{x_{0}^{3}} = {(\frac{m g}{k})}^{3} k = \frac{{(m g)}^{3}}{k^{2}} c = \frac{k}{x_{0}^{4}} = {(\frac{m g}{k})}^{4} k = \frac{{(m g)}^{4}}{k^{3}} & (3) \end{matrix}

The equation (3) has a damping term of −bx

2

in the term of the second degree. When the equation (3) is further simplified,

m{umlaut over (x)}+r{dot over (x)}+ax−bx

2

=F

(

t

)

When x=x

0

cos ωt,

\begin{matrix} x^{2} = x_{0}^{2} \cos^{2} ω t = x_{0}^{2} (1 - \sin^{2} ω t) \\ = x_{0}^{2} (1 - \frac{1 - \cos 2 ω t}{2}) = x_{0}^{2} (\frac{1 + \cos 2 ω t}{2}) \\ \approx \frac{x_{0}^{2}}{2} \end{matrix}

m \ddot{x} + r \dot{x} + ax - b \frac{x_{0}^{2}}{2} = F (t)

m \ddot{x} + r \dot{x} + ax = F (t) + \frac{b}{2} x_{0}^{2}

In a vibration region with a small amplitude, a constant repulsive force ((b/2)x

0

2

) is continuously applied to a periodic external force to attenuate it.

In the equation (1), when the geometric dimensions between the opposing permanent magnets are changed by an internal kinetic mechanism (mechanism for moving the permanent magnets within a repulsion system) or by an external force, the spring constant k is a square wave k(t) changing with time, as shown in

FIG. 28

, and takes a value of +k′ or −k′ alternately in one half of a period of T=2π/ω. Accordingly, the equation (1) can be expressed as follows.

\begin{matrix} m \ddot{x} + r \dot{x} + m g - \frac{k (t)}{x} = F (t) & (4) \end{matrix}

(i) When 0<t<π/ω,

m \ddot{x} + r \dot{x} + m g - \frac{n - k^{'}}{x} = F (t)

(ii) When π/ω≦t<2π/ω,

m \ddot{x} + r \dot{x} + m g - \frac{n + k^{'}}{x} = F (t)

When 0<t<π/ω and when the balanced position is represented by x

0

and the deflection from the balanced position is represented by y

1

,

- \frac{n - k^{'}}{x_{0}} + m g = 0, x_{0} = \frac{n - k^{'}}{m g}

x = x_{0} + y_{1}

\dot{x} = {\dot{y}}_{1}

\ddot{x} = {\ddot{y}}_{1}

\begin{matrix} \frac{n - k^{'}}{x} = \frac{n - k^{'}}{x_{0} + y_{1}} = \frac{n - k^{'}}{x_{0} (1 + \frac{y_{1}}{x_{0}})} \approx \frac{n - k^{'}}{x_{0}} (1 - \frac{y_{1}}{x_{0}}) [∵ y_{1} ⪡ x_{0}] \\ = \frac{n - k^{'}}{x_{0}} - \frac{n - k^{'}}{x_{0}^{2}} y_{1} \end{matrix}

\begin{matrix} m \ddot{x} + r \dot{x} - \frac{n - k^{'}}{x} + m g = m {\ddot{y}}_{1} + r {\dot{y}}_{1} - \frac{n - k^{'}}{x_{0} + y_{1}} + m g \\ = m {\ddot{y}}_{1} + r {\dot{y}}_{1} - \frac{n - k^{'}}{x_{0}} + \frac{n - k^{'}}{x_{0}^{2}} y_{1} + \frac{n - k^{'}}{x_{0}} \\ = m {\ddot{y}}_{1} + r {\dot{y}}_{1} + \frac{n - k^{'}}{x_{0}^{2}} y_{1} \end{matrix}

When (n−k′)/x

0

2

=k

1

′,

mÿ

1

+r{dot over (y)}

1

+k

1

′y

1

=F

(

t

)

When the harmonic excitation F(t)=Fe

iωt

and y

1

=xe

iωt

,

\begin{matrix} {\dot{y}}_{1} = ⅈ ω x ⅇ^{ⅈ ω t} \\ {\ddot{y}}_{1} = ⅈ^{2} ω^{2} x ⅇ^{ⅈ ω t} \\ - m ω^{2} x ⅇ^{ⅈ ω t} + r ⅈ ω x ⅇ^{ⅈ ω t} + k_{1}^{'} x ⅇ^{ⅈ ω t} = F ⅇ^{ⅈ ω t} \\ (- m ω^{2} x + r ⅈ ω x + k_{1}^{'} x) ⅇ^{ⅈ ω t} = F ⅇ^{ⅈ ω t} \\ x (k_{1}^{'} - m ω^{2} + r ⅈ ω) = F \\ \begin{matrix} x = \frac{F}{k_{1}^{'} - m ω^{2} + r ⅈ ω} \\ = \frac{F (k_{1}^{'} - m ω^{2} - r ⅈ ω)}{(k_{1}^{'} - m ω^{2} + r ⅈ ω) (k_{1}^{'} - m ω^{2} - r ⅈ ω)} \\ = \frac{F}{\sqrt{{(k_{1}^{'} - m ω^{2})}^{2} + {(r ω)}^{2}}} [\frac{k_{1}^{'} - m ω^{2}}{\sqrt{{(k_{1}^{'} - m ω^{2})}^{2} + {(r ω)}^{2}}} - ⅈ r \frac{ω}{\sqrt{{(k_{1}^{'} - m ω^{2})}^{2} + {(r ω)}^{2}}}] \\ = \frac{F}{\sqrt{{(k_{1}^{'} - m ω^{2})}^{2} + {(r ω)}^{2}}} (\cos φ - ⅈ \sin φ) \\ = \frac{F}{\sqrt{{(k_{1}^{'} - m ω^{2})}^{2} + {(r ω)}^{2}}} ⅇ^{- ⅈ φ} \end{matrix} \\ \begin{matrix} y_{1} = x ⅇ^{ⅈ ω t} = \frac{F}{\sqrt{{(k_{1}^{'} - m ω^{2})}^{2} + {(r ω)}^{2}}} ⅇ^{ⅈ (ω t - φ)} \\ = \frac{F}{\sqrt{{k_{1}^{′2} [1 - {(\frac{ω}{ω_{0}})}^{2}]}^{2} + {(2 ρ \frac{ω}{ω_{0}})}^{2}}} ⅇ^{ⅈ (ω t - φ)} \end{matrix} \end{matrix}

Here, φ indicates the phase angle.

ρ = r / 2 \sqrt{{mk}_{1}^{'}}

ω_{o}^{2} = \frac{k_{1}^{'}}{m} = \frac{n - k^{'}}{{mx}_{0}^{2}} = \frac{n - k^{'}}{m} {(\frac{m g}{n - k^{'}})}^{2} = \frac{m}{n - k^{'}} g^{2}

Accordingly, the resonant frequency ω

0

is given by:

ω_{o} \propto \sqrt{\frac{m}{n - k^{'}}}

Similarly, when π/ω≦t<2π/ω,

y_{2} = \frac{F}{\sqrt{{k_{2}^{′2} [1 - {(\frac{ω}{ω_{o}})}^{2}]}^{2} + {(2 ρ \frac{ω}{ω_{o}})}^{2}}} ⅇ^{ⅈ (ω t - φ)}

k_{2}^{'} = \frac{n - k^{'}}{x_{1}^{2}} ρ = \frac{r}{\sqrt[2]{m \frac{n + k^{'}}{x_{1}^{2}}}}

Hence, when y

1

>y

2

, it diverges.

In general, a self-excited vibration system can be replaced with a spring-mass system having negative damping characteristics, and energy of vibration is introduced thereinto from outside during vibration. The actual vibration, however, loses energy because air resistance or various resistances act on the mass point.

However, if the energy of vibration is introduced as an external force into the magnetic spring having negative damping characteristics, it diverges in the case of y

1

>y

2

, as described above. If it continues diverging, the amplitude is gradually increased to thereby destroy the system. Otherwise, positive damping is caused to act on the system by adding a damping term, which increases with deflection, to the above characteristic equation. In this case, when the positive damping is balanced with the negative damping, steady-state vibration occurs in the system. In other words, as is the case with the spring constant k(t), the damping coefficient is variable and, hence, the equation (1) can be rewritten as follows.

\begin{matrix} m \ddot{x} + r (x) \dot{x} + m g - \frac{k (t)}{x} = F (t) & (5) \end{matrix}

The vibration system having the magnetic spring of the present invention includes an energy conversion system inducing continuous oscillation or diverging vibration. Adding a positive damping term to the above characteristic equation results in the following equation.

\begin{matrix} m \ddot{x} + (r_{2} x^{2} - r) \dot{x} + m g - \frac{k (t)}{x} = F (t) & (6) \end{matrix}

In this characteristic equation, when r

2

≠0, three terms on the left side become greater with x, and the term of spring acts as a positive damping term. Accordingly, in the internal exciting characteristics by the permanent magnets, a small deflection causes negative damping, while an increase in deflection results in positive damping, and the vibration become steady at an amplitude where the positive damping and the negative damping are balanced.

In the case where the magnitude of at least one of the mass, damping coefficient, and spring constant in a vibration system changes with time, the vibration caused thereby is referred to as coefficient exciting vibration. Each of the equations (7), (8), and (9) indicates the coefficient exciting vibration in which an exciting source itself vibrates and generates vibration by converting non-vibrating energy within the system to vibratory excitation.

Because supply energy is generally converted from part of dynamic energy, when the dynamic energy has an upper limit, the supply energy is limited, and the amplitude is restrained when this energy becomes equal to energy to be consumed. The potential energy by the permanent magnets is independent of the dynamic energy within the system. The difference between the potential energy from the permanent magnets and the energy to be consumed can be increased by increasing the maximum energy product per unit mass of the permanent magnets. Because of this, the amount of energy converted to vibration energy in one cycle can be increased by making, the supply energy produced by negative damping greater than the energy consumed by the damping in the particular cycle.

As described above, it is possible to freely control the damping coefficient r and the spring constant (coefficient) k in the equation (1). In the schematic diagram of

FIG. 1

, for example, the amplitude can be attenuated by maximizing the opposing area of the permanent magnets

2

and

4

when the permanent magnet

4

is positioned at its lower end. This feature is applicable to a magnetic brake, dynamic damper or the like. On the other hand, the repulsive force can be increased by maximizing the opposing area when the permanent magnet

4

is moved from its lower end towards it upper end. This feature is applicable to a generator, amplifier or the like.

Although the present invention has been fully described by way of examples with reference to the accompanying drawings, it is to be noted here that various changes and modifications will be apparent to those skilled in the art. Therefore, unless such changes and modifications otherwise depart from the spirit and scope of the present invention, they should be construed as being included therein.

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Number	Date	Country
3117377	Dec 1982	DE
36 01 182	Jul 1987	DE
0 393 492	Oct 1990	EP
2 006 958	May 1979	GB
2222915	Mar 1990	GB
2 296 068	Jun 1996	GB
58-89077	May 1983	JP
61-231871	Mar 1985	JP
63-149446	Jun 1988	JP
1-16252	Jan 1989	JP
434246	Feb 1992	JP
7217687	Aug 1995	JP
9738242	Oct 1997	WO

Energy extracting mechanism having a magnetic spring

Information

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Date Filed

Date Issued

Inventors

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Agents

CPC

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Abstract

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US Referenced Citations (43)

Foreign Referenced Citations (13)