KR101179934B1 - Rotation speed controller of rotator - Google Patents

Abstract

The present invention relates to a rotation speed control device for a rotating body, the end of which is provided with a rotating shaft 402 rotatably installed on the base 401; A fixed plate body 403; Upper and lower movable plates 404 and 405; A moving disk 406; An elastic spring 407; A plurality of support rods 408; A plurality of centrifugal force generating bars 409; A weight 410; A link 411; A switch mounting plate 413 vertically fixed to an inner side of the vertical frame 412 toward the rotation shaft 402; Upper and lower limit switches 414 and 414 '; Switch lever plates 415 and 415 '; It is composed of rotary roller 416, which is easy to adopt to various kinds of rotating bodies, and has a high economic efficiency due to the reduction of the cost required for the production of the product due to the compact structure of the simple structure, and the rotating body can be rotated. Rotor control means for rotating while moving up and down according to the rotational speed of the rotating body by using the centrifugal force generated at the time intermittently limit the limit switch installed at the top and bottom to maintain a constant rotational speed of the rotor, in particular wind power In the case of adopting the generator rotor of the generator, in order to improve the power generation efficiency of the generator can not only automatically control the rotation speed of the generator rotor within a certain range, but also in the automatic control to maintain the rotation speed of the rotor within a certain range Easily change the range of automatically controlled rotation speed It is a useful invention that has particular advantage.

Description

Rotation speed controller of rotator

The present invention relates to a rotational speed control device for a rotating body to control the rotational speed of the rotating body to maintain a constant rotational speed, more specifically, the rotation of the rotating body using the centrifugal force generated when the rotating body rotates It relates to a rotational speed control device for a rotating body to maintain a constant rotational speed of the rotating body by rotating the rotation control means to rotate while moving up and down in accordance with the speed, respectively, the limit switch installed up and down.

In general, the rotating body is not only widely used in various industries and machinery, appliances, etc., but also used in computers, home appliances, automobiles, and the like in homes and businesses, and is often used as a motor or a fan.

The rotational speed control device for the rotational body to limit the rotational speed of the rotating body in a certain range has been developed and utilized conventionally by the type of the rotating body.

For example, the "rotational speed control device using magnetic flux" of Patent Publication No. 1984-0002543, when braking is applied to a rotating rotating device to control the rotational speed, separate from the magnetic flux and the magnetic material wound on the magnetic flux The interaction with the magnetic flux is used for braking, the strength of the magnetic flux is changed to arbitrarily change the braking force, and thus the rotation speed is controlled, and the "engine rotation speed automatic control device" of Patent Publication No. 1997-0070504 is connected to the engine. Engine pressure is converted from the operating pressure discharged from the driven hydraulic pump into an electrical signal by the controller, and driven according to the signal applied by the controller to adjust the engine throttle lever position to automatically adjust the engine speed. An automatic control device, which is installed in a flow path branched from the flow path of the hydraulic pump and applied from the controller. An electromagnetic proportional pressure reducing valve for converting an ordinary signal into a hydraulic signal, a pressure sensitive piston for detecting that a signal pressure through the electromagnetic proportional pressure reducing valve flows into a first pressure chamber formed in a body of a control device, and the pressure sensitive piston Fixing means for interlocking the servo piston to adjust the throttle lever position of the engine by linear movement according to the flow, and a flow path for supplying operating pressure from the hydraulic pump to the servo piston by interlocking when the pressure-sensitive piston is driven. It is composed of an opening and closing means for opening and closing the device, and the "rotational speed control device of a brushless DC motor" of Japanese Patent Laid-Open No. 1998-076396 smoothed when the control element outputs a pulse signal to control the rotational speed of the brushless DC motor The resistance and the capacitor of the circuit apply a voltage value corresponding to the duty of the pulse signal output from the control element. The output is smoothed by direct current, and this DC signal is converted into a more stable DC signal through the capacitor and applied to the driving element. Therefore, the configuration is simple and it takes up less space in the circuit design. It is possible to obtain the effect of improving the competitiveness, and Patent Publication No. 2008-0017059 of "Apparatus and method for controlling the rotational speed of an optical disk" in the first speed range, using a first sensor, for example an EMF sensor Controlling the commutation moments of the turntable motor, and for speeds outside the first range, the mapping between the first and second periodic signals and the periodic control signal based on the second periodic signal generated by the second sensor a method and apparatus for controlling the rotational speed of the optical disk in a wide speed range including a low speed by using, for ever LightScribe ^TM applications One will.

As described above, a number of devices for controlling the rotational speed of the rotating body have been developed and used according to the type of the rotating body. However, a device for controlling the rotating speed of the rotating body by employing various kinds of rotating bodies regardless of the type of the rotating body is known. There is no situation.

The present invention has been invented to solve various drawbacks and problems caused by the conventional rotational speed control apparatus in view of the above circumstances, the purpose of which is easy to adopt to various kinds of rotating bodies, as well as high compatibility The compact structure of a simple structure provides a cost-effective rotational speed control device for reducing the cost of manufacturing a product.

Another object of the present invention is to use the centrifugal force generated when the rotating body rotates to move up and down in accordance with the rotating speed of the rotating body to control the rotation speed of the rotating body by intermittently limiting the limit switches installed above and below. Rotational speed control device that can be automatically controlled to maintain the rotational speed of the generator rotor within a certain range to improve the power generation efficiency of the generator when it is employed in the rotor of the generator, in particular, the generator rotor of the wind power generator by maintaining a constant To provide.

Still another object of the present invention is to provide a rotation speed control apparatus for a rotating body which can be easily changed and changed in a range of automatically controlled rotation speed in automatically controlling the rotation speed of the rotating body to be maintained within a certain range. There is.

Rotational speed control apparatus of the present invention for achieving the above object is a rotational axis of the rotating body is installed vertically installed, the rotating shaft 402 and the end is rotatably installed in the base (401); A square fixed plate body 403 having a central portion fitted to the rotary shaft 402 and fixed thereto; A rectangular upper movable plate body 404 fitted with a central portion at the upper portion of the fixed plate body 403 and freely moving up and down; A rectangular lower movable plate body 405 fitted with a central portion at the lower portion of the fixed plate body 403 to freely move up and down; A moving disk 406 attached to and fixed to a lower surface of the lower movable plate body 405 and fitted with a central portion of the rotating shaft 402 to allow vertical movement; An elastic spring 407 fitted to a rotating shaft 402 between the fixed plate body 403 and the upper movable plate body 404; It is movable up and down through the edge of the fixed plate body 403, the upper end is penetrated through the edge of the upper movable plate body 404 is fixed to the corner of the upper movable plate body 404 by the fastening of the nut, and the lower portion is the lower movable plate body A plurality of support rods 408 fixed to the edges of the lower movable plate body 405 through the fastening of the nuts through the edges of the 405; A plurality of centrifugal force generating bars 409 each having a predetermined length rotatably provided at one end of each of the side center portions of the upper movable plate body 404; A weight 410 fixed to the other end of the centrifugal force generating bar 409; A connection link 411 having one end rotatably connected to the central portion of the centrifugal force generating bar 409 and the other end rotatably connected to each of the side center portions of the fixed plate body 403; A switch mounting plate 413 vertically fixed to an inner surface of the vertical frame 412 installed at one end of the base 401 toward the rotation shaft 402; Upper and lower limit switches 414 and 414 'installed at a predetermined distance up and down on the switch mounting plate 413; A switch lever plate 415 which is fixed at one end to a lower surface of the upper limit switch 414 and whose other end is positioned above the moving disk 406 and is displaced up and down; A switch lever plate 415 'having one end fixed to an upper surface of the lower limit switch 414' and the other end positioned below the moving disk 406 to be displaced up and down; The switch lever plate (415, 415 ') is characterized in that consisting of a rotary roller 416 installed on the other end.

The present invention is not only easy to adopt to various types of rotating body, but also has a high economic efficiency due to the reduction of the cost required for the production of the product due to the compact structure of a simple structure, and the centrifugal force generated when the rotating body rotates. Rotation control means for rotating while moving up and down according to the rotational speed of the rotating body by intermittently limiting the limit switch installed up and down to maintain the rotational speed of the rotating body to the rotor of the generator, in particular to the generator rotor of the wind turbine When not only can be automatically controlled to maintain the rotational speed of the generator rotor within a certain range to improve the power generation efficiency of the generator, but also automatically controlled to maintain the rotational speed of the rotor within a certain range, Specially changeable range of rotation speed There is an advantage.

1 is a perspective view showing a rotation speed control apparatus of the present invention,
2 is a view showing an installation state of the centrifugal force generating bar according to the present invention,
3 is a view showing the installation state of the upper and lower limit switches according to the present invention,
4a and 4b is a view showing an operating state of the rotation speed control apparatus of the present invention,
5 is a perspective view of a wind power generator filed by the applicant of the present invention,
Figure 6a is a perspective view showing a windmill blade installation state of the wind power generator rotates in a clockwise direction,
Figure 6b is a perspective view showing the windmill blade installation state of the wind turbine rotating in the counterclockwise direction,
7 is an exploded perspective view of main parts of a wind turbine having a fixing means driving device of a first embodiment;
8A is a view showing an operating state of the fixing means driving device of the first embodiment when the rotation of the windmill blade,
8b is a view showing an operating state of the fixing means driving device of the first embodiment when the rotation stop of the windmill blade,
Figure 9a is a view for explaining the operating state of the windmill blade fixing means during the rotation operation of the windmill blade,
Figure 9b is a view for explaining the operating state of the windmill blade fixing means when the rotation stop of the windmill blade,
Figure 10a is a view showing the operating state of the windmill blade fixing means and the displacement state of the windmill blade according to the operation of the rotation of the windmill blade,
10b is a view showing the operation state of the windmill wing fixing means and the displacement state of the windmill blade according to the rotation stop of the windmill blade,
11 is an exploded perspective view of main parts of a wind turbine having a fixing means driving device of a second embodiment;
12 is an exploded perspective view of the fixing means driving device of the second embodiment;
Figure 13a is a view showing the operating state of the fixing means driving device of the second embodiment when the rotation of the windmill blade,
Figure 13b is a view showing the operating state of the fixing means driving device of the second embodiment when the rotation stop of the windmill blade,
14 is a perspective view of a wind turbine power generation efficiency increasing means,
15a to 15c is a plan view showing a gear arrangement state of the power generation efficiency increasing means of the wind power generator,
16a and 16b are views for explaining the operation of the power generation efficiency increasing means of the wind power generator,
Figure 17a is a view showing the power generation efficiency according to the wind speed of the conventional wind power generator,
17B is a view showing power generation efficiency according to the wind speed of the variable windmill blade wind power generator having power generation efficiency increasing means.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the rotational speed control apparatus of the present invention.

1 is a perspective view showing a rotational speed control apparatus of the present invention, Figure 2 is a view showing the installation state of the centrifugal force generating bar according to the present invention, Figure 3 is a view showing the installation state of the upper and lower limit switches according to the present invention. 4A and 4B are views illustrating an operating state of the rotational speed control device of the rotating body of the present invention, the rotational speed control device of the rotating body of the present invention is vertically erected with a rotational axis of the rotating body installed at an end thereof with a base 401. A rotating shaft 402 rotatably installed at the head); A square fixed plate body 403 having a central portion fitted to the rotary shaft 402 and fixed thereto; A rectangular upper movable plate body 404 fitted with a central portion at the upper portion of the fixed plate body 403 and freely moving up and down; A rectangular lower movable plate body 405 fitted with a central portion at the lower portion of the fixed plate body 403 to freely move up and down; A moving disk 406 attached to and fixed to a lower surface of the lower movable plate body 405 and fitted with a central portion of the rotating shaft 402 to allow vertical movement; An elastic spring 407 fitted to a rotating shaft 402 between the fixed plate body 403 and the upper movable plate body 404; It is movable up and down through the edge of the fixed plate body 403, the upper end is penetrated through the edge of the upper movable plate body 404 is fixed to the corner of the upper movable plate body 404 by the fastening of the nut, and the lower portion is the lower movable plate body A plurality of support rods 408 fixed to the edges of the lower movable plate body 405 through the fastening of the nuts through the edges of the 405; A plurality of centrifugal force generating bars 409 each having a predetermined length rotatably provided at one end of each of the side center portions of the upper movable plate body 404; A weight 410 fixed to the other end of the centrifugal force generating bar 409; A connection link 411 having one end rotatably connected to the central portion of the centrifugal force generating bar 409 and the other end rotatably connected to each of the side center portions of the fixed plate body 403; A switch mounting plate 413 vertically fixed to an inner surface of the vertical frame 412 installed at one end of the base 401 toward the rotation shaft 402; Upper and lower limit switches 414 and 414 'installed at a predetermined distance up and down on the switch mounting plate 413; A switch lever plate 415 which is fixed at one end to a lower surface of the upper limit switch 414 and whose other end is positioned above the moving disk 406 and is displaced up and down; A switch lever plate 415 'having one end fixed to an upper surface of the lower limit switch 414' and the other end positioned below the moving disk 406 to be displaced up and down; It is composed of a rotary roller 416 provided at the other end of each of the switch lever plate (415, 415 ').

The centrifugal force generating bar 409 is bolted to the bolt 404b inserted into the protrusion of the bracket 404a fixed to each of the outer surfaces of the upper movable plate body 404, and is installed by tightening the nut 404b. The centrifugal force generating bar 409 has a central axis so that one end thereof is rotatably installed, and a weight 410 is fixed to the other end thereof, and one end of the connecting link 411 is attached to the bolt 409a fitted to the center. Is inserted into the nut, and one end of the connection link 411 is rotatably installed with the bolt 409a as a central axis, and the other end of the connection link 411 is outside the fixed plate body 403. The bolts 403b inserted into the protrusions of the brackets 403a fixed to the side surfaces are installed by tightening the nuts, and the centrifugal force generating bars 409 are rotatable at the other end with the bolts 403b as the central axis. It is installed.

The upper limit switch 414 is installed by fastening a nut to a bolt inserted into upper cutting holes 413a and 413a 'which are cut through the upper and lower sides of the switch mounting plate 413 and penetrated thereto. 414 ′ is installed by fastening nuts to bolts inserted into upper cut-out holes 413b and 413b ′ which are cut along the upper and lower sides of the lower part of the switch mounting plate 413 and are inserted into the upper limit switches 414 and 414 ′. The space between them can be adjusted freely.

Next, the operation of the rotation speed control device of the rotating body of the present invention configured as described above will be described in detail.

When the rotational speed of the rotating body is increased, the rotational speed of the fixed plate body 403 fixed to the rotating shaft 402 to rotate with the rotation of the rotating body is increased to be connected to the fixed plate body 403 by a link link 411 The rotational speed around the rotating shaft 402 of the centrifugal force generating bar 409 is also increased.

Accordingly, the lower end of the centrifugal force generating bar 409 in which the weight 410 is installed is applied to the weight 410 provided at the tip of the centrifugal force generating bar 409 to move away from the center of the rotation shaft 402. Depending on the speed of rotation will be more and more wide open.

The operation of the centrifugal force generating bar 409 compresses the elastic spring 407 to move the upper movable plate body 404, the lower movable plate body 405, and the movable disc 406 downward on the rotating shaft 402. Since the downwardly moving disk 406 pushes the rotary roller 416 downward as shown in FIG. 4B to displace the switch lever plate 415 'downward to connect the switch contact of the lower limit switch 414'. The lower limit switch 414 'is switched on.

The switching-on of the lower limit switch 414 'operates a separate deceleration means (not shown) so that the deceleration means slows down the rotational speed of the rotating body.

When the rotational speed of the rotating body is gradually reduced in this manner, the rotational speed of the fixed plate body 403 fixed to the rotating shaft 402 rotating with the rotation of the rotating body decreases, thereby connecting the link plate to the fixed plate body 403. The rotation speed around the rotation axis 402 of the centrifugal force generating bar 409 connected to 411 is also reduced.

Accordingly, the centrifugal force acting on the weight 410 provided at the tip of the centrifugal force generating bar 409 gradually decreases, so that the lower end of the centrifugal force generating bar 409 on which the weight 410 is installed decreases more and more as the centrifugal force decreases. The gap between the weight 410 and the weight 410 is narrowed by moving in the direction of the rotation axis 402.

The operation of the centrifugal force generating bar 409 moves the upper movable plate body 404, the lower movable plate body 405, and the movable disc 406 upward on the rotating shaft 402 by the elastic force of the elastic spring 407. And the upwardly moving disk 406 pushes the rotary roller 416 upwards to displace the switch lever plate 415 upward to connect the switch contact of the upper limit switch 414 as shown in FIG. 4A. The switch 414 is switched on.

The switching on of the upper limit switch 414 stops the operation of a separate deceleration means not shown so that the deceleration means cannot slow down the rotational speed of the rotating body.

Therefore, the rotational speed control of the rotating body increases until the moving disk 406 moves downward and the lower limit switch 414 'is switched on and the moving disk 406 moves upward and the upper limit switch 414 is switched on. It can be maintained at a rotational speed within the range to decrease.

Next, the rotation speed control device of the rotating body of the present invention is employed in the "wind power generator" (hereinafter referred to as "prescribed invention") of the patent application Nos. 2010-23951 and 2010-74721 filed by the applicant of the present invention. The case of increasing the power generation efficiency by controlling the rotational speed of the generator rotor within a certain range will be described in detail as an embodiment.

The present invention is a wind power generator is configured as shown in Figures 5 to 17b, the rotation speed control device of the rotating body of the present invention is the upper and lower limit switches 314, 314 when the vertical rotation shaft 20 shown in Figure 5 is a generator rotor Except for '), all the components are installed on the vertical rotation shaft 20, and when a plurality of generator rotors are geared to the vertical rotation shaft 20 as illustrated in FIGS. 15A to 15C, upper and lower limit switches 314. All components, except for 314 ', are installed on the first generator rotor 20'.

For convenience of description, the operation of the present invention will be described on the assumption that the generator 300 is composed of three generators 301, 302, and 303 and has three generator rotors.

In the wind power generator (A), the windmill blade (70) facing the direction in which the wind blows is pushed by the blowing wind so that the wing piece (72) is caught by the lever (97) and receives the wind and forms a support rod ( 40 ') is pushed by the wing piece 72 receives the wind to rotate the vertical axis of rotation 20 through the blade rotation axis 71 to generate power.

At this time, the wing piece 72 rotated when the vertical axis of rotation 20 rotates by 90 ° from the vertical plane forming the plane perpendicular to the direction of the wind, and the blade piece 72 is rotated horizontally with the force of air as the wing piece 72 further rotates. The rotating shaft 20 is rotated and is not subjected to air resistance so that the vertical rotating shaft 20 is rotated, and the blade piece 72 rotated further by 270 ° from the vertical plane which is further rotated to form a vertical plane with the direction of the wind. The wing spring 73 maintains 45 ° in the horizontal plane, and if it is rotated further in this state, it is pushed again by the blowing wind so that the wing piece 72 is caught by the lever 97 and the wind is vertical. By pushing the blade rotation shaft 71 to receive the vertical rotation shaft 20 is continuously rotated to generate power (see Figs. 5 to 6b).

In addition, the number of generators that generate power increases as the wind strength increases. When the wind strength is normal, as shown in FIG. 15A, the driving gear 206 connected to the vertical rotation shaft 20 is provided. In the state where the first driven gear 207 is gear-coupled, the generator 301 connected to the lower portion of the first driven gear 207 is generated by the rotation of the vertical rotation shaft 20.

When the wind exceeds a certain second in the state of the power generation of the generator 301 only, as shown in Figs. 14 and 16a, the wind blade 204a is pushed backward by the wind of the wind, accordingly The left and right contact rollers 204b 'and 204b are pushed backward together with the switch 203 so that the right contact roller 204b is first pushed downwardly by the right outer periphery of the switch drive means 202. The switch contact is connected by 204b), and the switch contact operates the air compressor 208 so that the linear actuator is operated by the air compressor 208 to push the second driven gear 208 toward the drive gear 206. The drive gear 206 and the second driven gear 208 are gear-coupled. Accordingly, as shown in FIG. 15B, the first and second driven gears 207 and 208 are simultaneously coupled to the driving gear 206 so that the two generators 301 and 302 generate power simultaneously.

As the wind intensity becomes stronger, the wind vane 204a is pushed further backwards by the wind power of the wind, as shown in FIGS. 14 and 16B, and thus the left and right contact rollers 204b together with the switch 203. ', 204b is pushed backward so that the left contact roller 204b' is also connected by the left contact roller 204b 'downwardly by the left outer periphery of the switch drive means 202, At this time, both left and right contact rollers 204b 'and 204b have both switches connected to each other to operate the air compressor 208 so that the linear actuator is operated by the air compressor 208 and the second driven gear 208 together with the second driven gear 208. The third driven gear 209 is pushed toward the driving gear 206 so that all of the first to third driven gears 207, 208, and 209 are gear-coupled to the driving gear 206 as shown in FIG. 16C. Three generators (301, 302, 303) It is the development of the city.

For convenience of explanation, the case where three first to third driven gears 207, 208, and 209 are provided is described and explained. However, three or more driven gears may be provided.

Figure 17a is a view showing the power generation efficiency according to the wind speed of the conventional wind power generator, Figure 17b is a view showing the power generation efficiency according to the wind speed of the present invention.

In the conventional case shown in FIG. 17A, assuming that the wind is blowing for 14 hours at an initial speed of 6 m / s, the effective wind for power generation is 6 × 14, which is 84, and the invalid total wind is 18 + 98 = 116, which is efficient. This becomes 84/200 = 42%. On the other hand, the present invention shown in FIG. 17B assumes that the wind is blowing for 4 hours at 4 m / s per second, 4 hours at 8 m / s per second, 4 hours at 12 m / s per second, and 4 hours at 16 m / s per second. Wind blowing for 4 hours at 4m / s per second is valid for 4 × 4 winds, and 2). Wind blowing for 4 hours at 8m / s per second is 8 x 4 to 32, and 3). When blowing 4 hours at 12m / s per second, the wind effective for the operation of three generators is 12 × 4, which is 46, 4). When blowing 4 hours at 16m / s per second, the effective wind for operating four generators is 16 × 4 and 64, so the total effective wind is 16 + 32 + 48 + 64 = 160, and the invalid total wind is 8 × 5 = Since it is 40, the efficiency is 160/200 = 80%.

In addition, since the wing pieces 72 forming a group up and down are installed in a state of being rotated at a predetermined angle in the rotation direction, when a group of wing pieces 72 are rotated at a predetermined angle to form a plane perpendicular to the wind direction, the other group The wing pieces 72 form a vertical plane with the direction of the wind in such a way that the wing pieces 72 of each group form a vertical plane with the direction of the wind in order to increase the power generation efficiency.

The operation of the windmill wings 70 as described above has a structure (see FIGS. 6A and 6B) in which the wing piece 72 which is subjected to the wind is caught by the lever 97 from the front and rear, and the wing piece 72 is rotated at the opposite side rotated 180 °. It is possible to form a horizontal plane with the ground.

As described above, as the wind speed increases, for example, one generator 301 generates power in the range of 0 m / s <WS <4 m / s, and the generator 301 in the range of 4 m / s ≤ WS <8 m / s. ) And two generators 302 generate power, and in the range of 8m / s≤WS <12m / s, two generators 301, two generators 302, and two generators 303 generate power, and an increase in wind speed is a vertical axis of rotation. By increasing the rotation of the generator rotor 20'of the generator 20 and the generator 301, as shown in Figs. 1 and 4B, the rotor shaft 20 'is a rotor 20' in the rotational speed control apparatus of the present invention. The rotational speed of the fixed plate body 403 fixed to the 402 is increased to increase the rotational speed around the rotation axis 402 of the centrifugal force generating bar 409 connected to the fixed plate body 403 by the connecting link 411. .

Accordingly, the lower end of the centrifugal force generating bar 409 in which the weight 410 is installed is applied to the weight 410 provided at the tip of the centrifugal force generating bar 409 to move away from the center of the rotation shaft 402. Depending on the speed of rotation will be more and more wide open.

The operation of the centrifugal force generating bar 409 compresses the elastic spring 407 to move the upper movable plate body 404, the lower movable plate body 405, and the movable disc 406 downward on the rotating shaft 402. As shown in FIG. 4B, the downwardly moving disk 406 pushes the rotary roller 416 downward to displace the switch lever plate 415 ', and thus the rotor 20 corresponding to the wind speed WS 12 m / s. The lower limit switch 414 'is switched on since the switch lever plate 415' which is displaced downward at the rotational speed of '), that is, the rotational speed of the rotary shaft 402, connects the switch contact of the lower limit switch 414'. .

Here, the lower limit switch 414 'is turned on when the wind speed WS is 12m / s, and the gap between the upper and lower limit switches 414 and 414' is adjusted.

The lower limit switch 414 'rotates the motor 105 of the fixing means driving apparatus 100 forward in the case of the fixing means driving apparatus of the first embodiment shown in FIGS. 7 and 8B. Forward rotation of the worm 104 and the worm hill 103 by rotating the spiral tube 102 is rotated in a clockwise direction to rise, so that the disk 101 also rises while rotating in a clockwise direction is the disc 101 is rising The moving shaft 93 is moved upward.

Accordingly, the moving holes 91a and 91b fixed to the moving shaft 93 are raised along the vertical rotation shaft 20 so that the straight lever 94 is raised, and the straight lever 94 is an L-shaped lever ( 95, the rotary shaft 96 is rotated by pulling upward, so that the lever 97 raises the wing piece 72 of the windmill blade 70 at a horizontal angle as shown in FIG. The amount of wind received by the wing piece 72 of 70 is reduced (FIG. 10B shows the state in which the rotation of the vertical rotation shaft 20 is stopped by completely lifting the wing piece 72 to be in a horizontal state with the ground. have).

In this way, if the amount of wind received by the wing piece 72 of the windmill wings 70 gradually decreases, the rotation speed of the vertical rotor shaft 20 and the generator rotor 20 'of the generator 301 is reduced, thereby fixing the plate. The rotational speed around the rotating shaft 402 of the centrifugal force generating bar 409 connected to the sieve 403 by the connecting link 411 is also reduced.

Accordingly, the centrifugal force acting on the weight 410 provided at the tip of the centrifugal force generating bar 409 gradually decreases, so that the lower end of the centrifugal force generating bar 409 on which the weight 410 is installed decreases more and more as the centrifugal force decreases. The gap between the weight 410 and the weight 410 is narrowed by moving in the direction of the rotation axis 402.

The operation of the centrifugal force generating bar 409 moves the upper movable plate body 404, the lower movable plate body 405, and the movable disc 406 upward on the rotating shaft 402 by the elastic force of the elastic spring 407. And the upwardly moving disk 406 pushes the rotary roller 416 upwards to displace the switch lever plate 415 upward to connect the switch contact of the upper limit switch 414 as shown in FIG. 4A. The switch 414 is switched on.

Here, it is preferable to adjust and set the interval between the limit switches 414 and 414 'so that the upper limit switch 414 is turned on when the wind speed WS is 4 m / s.

When the upper limit switch 414 is switched on, the motor 105 of the fixing means driving apparatus 100 rotates the motor 105 in the case of the fixing means driving apparatus of the first embodiment shown in FIGS. 7 and 8A. do. That is, when the motor 105 rotates in reverse, the worm 104 and the worm hill 103 are rotated so that the helix tube 102 rotates in the counterclockwise direction and the disc 101 also rotates in the counterclockwise direction. As you rotate, you descend.

Accordingly, the moving shaft 93 is also lowered, and the lowering of the moving shaft 93 is until the end of the 'L' shaped lever 95 is caught by the stopper pin 95a and prevents rotation (the lever 97 is prevented from rotating). Down to the vertical downward state), that is, as shown in FIGS. 9A and 10A, that is, the wing piece 72 of the windmill blade 70 receives the wind to the front, and thus the wind generator A normally generates power. The state can be.

On the other hand, the lower limit switch 414 'is switched on in the case of the fixing means driving device of the second embodiment shown in Figs. 11, 12, and 13B by rotating the motor 112' forward to the shaft of the motor 112 '. As the rope 111 is wound and the spring 106 'is compressed, the lower movable plate 105' is raised, thereby raising the upper movable plate 110 'while the moving shaft 107' is raised. .

Ascending of the upper movable plate 110 ′ causes the movable shaft 93 to move upward, thereby causing the movable holes 91a and 91b fixed to the movable shaft 93 to rise along the vertical rotation shaft 20. As the straight lever 94 is raised, the straight lever 94 pulls the 'L' shaped lever 95 upward, thereby rotating the rotation shaft 96 so that the lever 97 is the wing piece of the windmill blade 70. In the horizontal state of the ground 72, as shown in Figure 9b is raised to a certain angle to reduce the amount of wind received by the wing piece 72 of the windmill blade 70 (Fig. 10b shows the wing piece 72) The state of stopping the rotation of the vertical rotation shaft 20 by lifting completely to make a horizontal state with the ground).

In this way, if the amount of wind received by the wing piece 72 of the windmill wings 70 gradually decreases, the rotation speed of the vertical rotor shaft 20 and the generator rotor 20 'of the generator 301 is reduced, thereby fixing the plate. The rotational speed around the rotating shaft 402 of the centrifugal force generating bar 409 connected to the sieve 403 by the connecting link 411 is also reduced.

Accordingly, the centrifugal force acting on the weight 410 provided at the tip of the centrifugal force generating bar 409 gradually decreases, so that the lower end of the centrifugal force generating bar 409 on which the weight 410 is installed decreases more and more as the centrifugal force decreases. The gap between the weight 410 and the weight 410 is narrowed by moving in the direction of the rotation axis 402.

The operation of the centrifugal force generating bar 409 moves the upper movable plate body 404, the lower movable plate body 405, and the movable disc 406 upward on the rotating shaft 402 by the elastic force of the elastic spring 407. And the upwardly moving disk 406 pushes the rotary roller 416 upwards to displace the switch lever plate 415 upward to connect the switch contact of the upper limit switch 414 as shown in FIG. 4A. The switch 414 is switched on.

When the upper limit switch 414 is switched on, the motor 112 'of the fixing means driving device 100' is reversed in the case of the fixing means driving device of the second embodiment shown in FIGS. Since the rope 111 wound around the shaft of 112 'is released, the lower movable plate 105' is lowered by the elastic force of the spring 106 ', and as a result, the upper movable plate (107') is lowered. 110 ') is lowered.

The lowering of the upper movable plate 110 'causes the moving shaft 93 to move downward, and accordingly, the lowering of the moving shaft 93 causes the end of the' L 'shaped lever 95 to hang on the stopper pin 95a. As it is lowered until the rear rotation is prevented (up to the state where the lever 97 is vertically lowered), the state as shown in FIGS. 9A and 10A, that is, the wing piece 72 of the windmill blade 70 blows the wind. The wind generator A is in a state capable of generating power normally.

While the present invention has been described as a preferred embodiment, the present invention is not limited thereto, and various modifications can be made without departing from the gist of the invention.

401: base 402: rotation axis
403: fixed plate body 403a: bracket
403b: bolt 404: upper moving plate
404a: Bracket 404b: Bolt
405: lower moving plate 406: moving disk
407: elastic spring 408: support rod
409 Centrifugal force generating bar 409a Bolt
410: weight 411: connection link
412: vertical frame 413: switch mounting plate
413a, 413a ': Upper incision 413b, 413b': Lower incision
414, 414 ': Upper and lower limit switch 415, 415': Switch lever plate
416: rotary roller

Claims (3)

A rotating shaft 402 of which a rotating shaft of the rotating body installed vertically is extended so that an end thereof is rotatably installed on the base 401; A square fixed plate body 403 having a central portion fitted to the rotary shaft 402 and fixed thereto; A rectangular upper movable plate body 404 fitted with a central portion at the upper portion of the fixed plate body 403 and freely moving up and down; A rectangular lower movable plate body 405 fitted with a central portion at the lower portion of the fixed plate body 403 to freely move up and down; A moving disk 406 attached to and fixed to a lower surface of the lower movable plate body 405 and fitted with a central portion of the rotating shaft 402 to allow vertical movement; An elastic spring 407 fitted to a rotating shaft 402 between the fixed plate body 403 and the upper movable plate body 404; It is movable up and down through the edge of the fixed plate body 403, the upper end is penetrated through the edge of the upper movable plate body 404 is fixed to the corner of the upper movable plate body 404 by the fastening of the nut, and the lower portion is the lower movable plate body A plurality of support rods 408 fixed to the edges of the lower movable plate body 405 through the fastening of the nuts through the edges of the 405; A plurality of centrifugal force generating bars 409 each having a predetermined length rotatably provided at one end of each of the side center portions of the upper movable plate body 404; A weight 410 fixed to the other end of the centrifugal force generating bar 409; A connection link 411 having one end rotatably connected to the central portion of the centrifugal force generating bar 409 and the other end rotatably connected to each of the side center portions of the fixed plate body 403; A switch mounting plate 413 vertically fixed to an inner surface of the vertical frame 412 installed at one end of the base 401 toward the rotation shaft 402; Upper and lower limit switches 414 and 414 'installed at a predetermined distance up and down on the switch mounting plate 413; A switch lever plate 415 which is fixed at one end to a lower surface of the upper limit switch 414 and whose other end is positioned above the moving disk 406 and is displaced up and down; A switch lever plate 415 'having one end fixed to an upper surface of the lower limit switch 414' and the other end positioned below the moving disk 406 to be displaced up and down; Rotational speed control device consisting of a rotary roller (416) provided at the other end of each of the switch lever plate (415, 415 '). The centrifugal force generating bar 409 is fitted to the bolt 404b inserted into the protrusion of the bracket 404a fixed to each of the outer surfaces of the upper movable plate body 404. The centrifugal force generating bar 409 has a bolt 404b as a central axis, and one end thereof is rotatably installed, and a weight 410 is fixed to the other end thereof, and a connection link to the bolt 409a fitted to the center portion thereof. One end of the connection part 411 is installed by tightening the nut, and one end of the connection link 411 is rotatably installed with the bolt 409a as a central axis, and the other end of the connection link 411 is fixed plate. The centrifugal force generating bar 409 is fitted to the bolt 403b inserted into the protrusion of the bracket 403a fixed to each of the outer surfaces of the sieve 403, and is installed by tightening the nut. That the other end is rotatably installed Rotational speed control apparatus in which the gong. According to claim 1, The upper limit switch 414 is installed by fastening the nut to the bolt inserted in the upper cut through holes 413a, 413a 'cut through the upper both sides of the upper portion of the switch mounting plate 413 The lower limit switch 414 'is installed by fastening a nut to a bolt inserted into the lower cutout holes 413b and 413b' which are cut along the upper and lower sides of the lower part of the switch mounting plate 413 and penetrate the upper limit switch ( 414, 414 ') rotational speed control apparatus characterized in that it is possible to freely adjust the gap between.

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