JP2012021520A - Spindle rotating device - Google Patents
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Abstract
Description
本発明は回転軸を保有する回転体を利用する技術に関するものである。The present invention relates to a technique using a rotating body having a rotating shaft.
従来の回転装置では風力/水力/火力/原子力/電力等の資源を必要としている。Conventional rotating devices require resources such as wind power / hydropower / thermal power / nuclear power / electric power.
従来の回転装置にて利用できる資源には次の課題点が掲げられる。
風力は適切な風を必要とするので常時の安定エネルギー供給に難がある。
水力は大きな設備を必要として最終エネルギーを必要とする場所から遠隔地に離れている。
火力は石油資源を消費することで温暖化等の大きな問題を生み出しており資源には限りがある。
原子力は事故発生時の影響が極端に大きく最終的に後処理の難しい副産物を発生している。
電力は現在上記の何れかを必要としている。Resources that can be used in conventional rotating devices include the following problems.
Since wind power requires an appropriate wind, it is difficult to always supply stable energy.
Hydropower requires large facilities and is far away from where final energy is needed.
Thermal power has created major problems such as global warming by consuming petroleum resources, and resources are limited.
Nuclear power has an extremely large impact at the time of the accident and eventually produces by-products that are difficult to dispose of.
Power currently requires any of the above.
この錘回転装置は常時地球上の地域性によらず普遍的に作用している重力を有効に利用することでこれらの課題を解決するものである。This spindle rotation device solves these problems by effectively utilizing the universally acting gravity regardless of the regional characteristics on the earth.
重力利用にて回転力を得られれば,例えば発電装置に利用することで必要とする各都市や各家庭または個々の機器等それぞれの用途に見合ったサイズの低公害の発電装置の開発が可能となる。If the rotational force can be obtained by using gravity, for example, it is possible to develop a low-pollution power generation device of a size suitable for each city, home, or individual device required by using the power generation device. Become.
■概要
図例のように歯車を組み合わせて各歯車の半径と吊下歯車および上乗歯車重量を適当な値にすると,吊下歯車と上乗歯車をそれぞれ別個にした場合は回転落下力の差異から吊下歯車が回転落下して上乗歯車を転がしながら持上げて,同一棒に乗せて一体化した場合は全体の重心が落下するために回転体全体が回転して吊下歯車を持上げられて上乗歯車が落下するという両者逆の上昇と下降運動を行なう。本装置はこの運動を交互に繰返す機構を組み込むことで装置内の錘を使用して回転運動を永続する。
■装置仕様
水平に置いた台に垂直に支柱を2本立てる。2本の支柱上部の間に自由に回転できるように水平回転棒を装着する。水平回転棒に主円盤大と主円盤小歯車を固定して,伝達歯車大と伝達歯車小は自由に1体化して回転できるように装着する。吊下歯車小は主円盤小に,吊下歯車大は伝達歯車小に接するように吊下棒を使用して水平回転棒に1体化して回転できるように吊下げる。逆回転歯車は伝達歯車大と上乗歯車に接するように上乗棒を使用して水平回転棒に吊下げる。上乗歯車には吊下歯車大小重量を考慮して次に述べる条件を満たした適当な重量の錘円盤を装着する。図例ではそれぞれの歯車半径は,主円盤大200,小80,吊下歯車大100,小80,伝達歯車大120,小60,逆回転歯車20,上乗歯車20としているが,この場合には吊下歯車は自身重量の4倍の上乗歯車重量と回転落下力が同一角度にて均衡するので上乗歯車重量を吊下歯車重量の3倍程度として上記の要件に応える。
吊下棒と上乗棒を別個にするとそれぞれの回転落下力差から吊下歯車が主円盤小まわりを時計回りに回転落下するが,落下を停止する前に切替装置と一体装置にて上乗棒に吊下棒を乗せて一体化する。上乗棒に吊下棒を乗せて一体化すると全体重心が水平回転棒の鉛直線下方に移動するために主円盤全体が反時計回りに回転するが,回転を停止する前に切替装置と分離装置にて上乗棒と吊下棒を分離する。切替装置は吊下棒と上乗棒に装着してそれらの一体化と分離作業を行ない,一体装置と分離装置は支柱に位置を固定して切替装置にこの作業を協力する。
主円盤と上乗歯車には時計回りの回転を防止するために逆回転防止装置を装備して装置回転の初動を容易として,また回転運動が停止することを防止している。
■動作仕様
1.主円盤回転(水平回転棒回転)を手で停止させるとやがて装置全体が静止する。この静止した状態にて手を放すと最初の動作に差異はあるが,やがて次の順序で装置は回転運動を継続する。
2.吊下棒と上乗棒が別個の状態では吊下歯車が主円盤小まわりを時計回りに回転落下して主円盤大に接する上乗歯車を持上げて回転体重心は上昇する。吊下歯車が回転を停止する前に切替装置と一体装置にて上乗棒に吊下棒を乗せて一体化する。
3.一体化した上乗棒と吊下棒は回転体重心が落下移動するために主円盤全体が反時計回りに回転して吊下歯車を持上げる。主円盤全体が回転を停止する前に切替装置と分離装置にて上乗棒と吊下棒を分離する。
4.これにより上乗棒と吊下棒は一体装置と分離装置の間をシーソーのように上下運動を交互に繰返して,吊下歯車は時計回り,上乗歯車と主円盤は反時計回りに回転運動を継続する。
5.この後は2と3の運動を交互に繰返して回転運動を徐々に加速する。
6.水平回転棒に吊下棒と上乗棒を等角度に2個,3個,...と本装置を並べて配置することで回転力を容易に増大できて,また回転運動がより滑らかとなる。■ Summary When the gears are combined and the weights of the gears and the weight of the suspended gear and the upper gear are set to appropriate values as shown in the figure, if the suspended gear and the upper gear are separated, the difference in rotational drop force When the suspension gear is rotated and dropped from the top and the upper gear is rolled while being lifted and integrated on the same rod, the entire center of gravity falls, so the entire rotating body rotates and the suspension gear is lifted. The up and down movements are reversed, in which the upper gear is dropped. This device incorporates a mechanism that repeats this motion alternately, and uses the weight in the device to perpetuate the rotational motion.
■ Equipment specifications Stand up vertically on two stands placed horizontally. A horizontal rotating rod is mounted so that it can freely rotate between the upper portions of the two columns. The main disc large and the main disc small gear are fixed to the horizontal rotating rod, and the large transmission gear and the small transmission gear are mounted so that they can be freely rotated as one body. The hanging gear small is suspended so that it can be rotated as a single unit with a horizontal rotating rod using a hanging rod so as to contact the small main disk and the hanging gear large to the small transmission gear. The reverse rotation gear is suspended from the horizontal rotation rod by using the upper rod so as to contact the large transmission gear and the upper gear. A weight disk with an appropriate weight that satisfies the conditions described below is mounted on the upper gear in consideration of the size of the hanging gear. In the example of the figure, the gear radii are the main disk large 200, small 80, the hanging gear large 100, small 80, the transmission gear large 120, small 60, the counter-rotating gear 20, and the upper gear 20, but in this case The suspension gear meets the above requirements by setting the weight of the upper gear and the rotational drop force at four times the weight of the suspension gear at the same angle so that the weight of the upper gear is about three times the weight of the suspension gear.
If the suspension rod and the upper rod are separated, the suspension gear rotates and rotates clockwise around the main disk small part due to the difference in rotational drop force. Put the hanging rod on the rod and integrate. When the hanging rod is integrated with the upper rod, the entire center of gravity moves below the vertical line of the horizontal rotating rod, so the entire main disk rotates counterclockwise, but before the rotation stops, it is separated from the switching device. Separate the upper and lower rods with the device. The switching device is mounted on the suspension rod and the upper rod to integrate and separate them, and the integrated device and the separation device fix the position on the support column and cooperate with this switching device.
The main disk and the upper gear are equipped with a reverse rotation prevention device to prevent clockwise rotation, facilitating the initial movement of the device and preventing the rotational motion from stopping.
■ Operation specifications When the main disk rotation (horizontal rotation rod rotation) is stopped by hand, the entire device will eventually stop. If you release your hand in this stationary state, there will be a difference in the initial motion, but the device will continue to rotate in the following sequence.
2. In a state where the suspension rod and the upper rod are separate, the suspension gear rotates and falls clockwise around the main disk small part, lifts the upper gear contacting the main disk, and the center of gravity of the rotating body rises. Before the suspension gear stops rotating, the suspension rod and the integral device are integrated by putting the suspension rod on the upper rod.
3. Since the center of gravity of the rotating body falls and moves, the entire upper disk rotates counterclockwise and lifts the suspension gear. Before the whole main disk stops rotating, the upper rod and the suspension rod are separated by the switching device and the separation device.
4). As a result, the upper rod and the suspension rod rotate up and down alternately like a seesaw between the integrated device and the separation device, the suspension gear rotates clockwise, and the upper gear and main disc rotate counterclockwise. Continue.
5. Thereafter, the
6). Two, three, etc. equidistant hanging rods and upper rods on horizontal rotating rods. . . And this device can be arranged side by side to easily increase the rotational force, and the rotational motion becomes smoother.
図1を参照 See Figure 1
本発明は回転軸を保有する回転体を利用する技術に関するものである。The present invention relates to a technique using a rotating body having a rotating shaft.
従来の回転装置では風力/水力/火力/原子力/電力等の資源を必要としている。Conventional rotating devices require resources such as wind power / hydropower / thermal power / nuclear power / electric power.
従来の回転装置にて利用できる資源には次の課題点が掲げられる。
風力は適切な風を必要とするので常時の安定エネルギー供給に難がある。
水力は大きな設備を必要として最終エネルギーを必要とする場所から遠隔地に離れている。
火力は石油資源を消費することで温暖化等の大きな問題を生み出しており資源には限りがある。
原子力は事故発生時の影響が極端に大きく最終的に後処理の難しい副産物を発生している。
電力は現在上記の何れかを必要としている。Resources that can be used in conventional rotating devices include the following problems.
Since wind power requires an appropriate wind, it is difficult to always supply stable energy.
Hydropower requires large facilities and is far away from where final energy is needed.
Thermal power has created major problems such as global warming by consuming petroleum resources, and resources are limited.
Nuclear power has an extremely large impact at the time of the accident and eventually produces by-products that are difficult to dispose of.
Power currently requires any of the above.
この錘回転装置は常時地球上の地域性によらず普遍的に作用している重力を有効に利用することでこれらの課題を解決するものである。This spindle rotation device solves these problems by effectively utilizing the universally acting gravity regardless of the regional characteristics on the earth.
重力利用にて回転力を得られれば,例えば発電装置に利用することで必要とする各都市や各家庭または個々の機器等それぞれの用途に見合ったサイズの低公害の発電装置の開発が可能となる。If the rotational force can be obtained by using gravity, for example, it is possible to develop a low-pollution power generation device of a size suitable for each city, home, or individual device required by using the power generation device. Become.
■概要
図例のように歯車を組み合わせて各歯車の半径と吊下歯車および上乗歯車重量を適当な値にすると,吊下歯車と上乗歯車をそれぞれ分離した場合は回転落下力の差異から吊下歯車が回転落下して上乗歯車を転がしながら持上げて,同一棒に乗せて一体とした場合は全体の重心が落下するために回転体全体が回転することで吊下歯車を持上げられて上乗歯車が落下するという両者逆の上昇と下降運動を行なう。本装置はこの運動を交互に繰返す機構を組み込むことで装置内の錘を使用して回転運動を永続的に加速する。
■装置仕様
水平に置いた台に垂直に支柱を2本立てて支柱上部の間に水平回転棒を固定して装着する。水平回転棒に主円盤歯車は固定して,吊下棒と上乗棒および伝達歯車は自由に回転できるように装着する。吊下棒の一方には吊下歯車大小と逆回転歯車を自由に回転できるように装着して,他方先端には上乗棒を乗せるための突起物を切替装置として装着する。上乗棒の一方には上乗歯車を自由に回転できるように装着する。吊下棒と上乗棒が一直線となるように主円盤と吊下歯車と上乗歯車および逆回転歯車と伝達歯車をかみ合わせる。
上記概要条件から図例ではそれぞれの歯車半径は,主円盤240,伝達歯車大360,吊下歯車大90,小60,逆回転歯車45,上乗歯車60としているが,この場合の分離状態では吊下歯車は自身重量の4倍の上乗歯車重量と回転落下力が同一角度にて均衡するが,上乗歯車重量を吊下歯車重量と同一として楽に持上げられるようにしている。ここでの逆回転歯車は吊下歯車重量の回転落下力を伝達歯車に伝えることを目的としているのでできるだけ軽くすることとしてこの重量は考慮していない。
■動作仕様
1.図1のように吊下歯車が回転軸の右側に位置した状態で手で静止させてから手を離すと,吊下歯車と上乗歯車はそれぞれが独立して回転落下しようとするために切替装置は無関係な分離状態となる。吊下歯車は主円盤との接点を支点として自身重量Wの2倍の回転落下力を逆回転歯車を経由して伝達歯車に時計回りの回転力として伝える。一方上乗歯車は主円盤との接点を支点として自身重量Wの1/2倍の回転落下力を伝達歯車に反時計回りの回転力として伝える。この伝達歯車の回転力の差異から伝達歯車と吊下棒と上乗棒は回転軸を中心として時計回りに回転して吊下歯車はやがて回転軸鉛直線下方に位置付けられる。
2.吊下棒と上乗棒が回転軸鉛直線と一致するときは回転力は無くなるので回転に加速は無くなるが,この時点に達したときの回転運動の慣性力により吊下棒と上乗棒は回転軸鉛直線を超えて少し時計回りに回転してしまい上乗歯車は回転軸の右側まで移動する。
3.図2のように上乗歯車が回転軸の右側に位置した状態では吊下歯車と上乗歯車はそれぞれが同様に独立して回転落下しようとするが,上乗歯車は切替装置に乗せられて吊下歯車と上乗歯車の両者は吊下棒一本に乗せられた一体状態となるので,両者重心位置Gに合算重量2Wの回転力が吊下棒に加わる。この回転力により吊下棒は時計回りに回転を加速して伝達歯車も同様に回転して上乗歯車はやがて回転軸鉛直線下方に位置付けられる。
4.吊下棒と上乗棒が回転軸鉛直線と一致するときは回転力は無くなるので回転に加速は無くなるが,この時点に達したときの回転運動の慣性力により吊下棒と上乗棒は回転軸鉛直線を超えて少し時計回りに回転してしまい吊下歯車は回転軸の右側まで移動する。
5.この後は上記1〜4の運動を繰返して回転運動を徐々に加速する。
6.水平回転棒に吊下棒と上乗棒を等角度に2個,3個,...と増やして配置すると回転力を容易に増大できて,1個の吊下棒と上乗棒が回転軸鉛直線と一致するときは回転力は無くなるときも他のものにて回転力を生じていることから,常時生じる回転力からより力強くスムーズな回転駆動力を得られる。■ As shown in the figure, combining the gears and setting the radius of each gear and the weight of the suspended gear and the upper gear to appropriate values will result in differences in rotational drop force when the suspended gear and the upper gear are separated. When the suspension gear is rotated and dropped and the upper gear is rolled up and lifted and put together on the same rod, the entire center of gravity falls, so the entire rotating body rotates and the suspension gear is lifted. The up and down movements are reversed, in which the upper gear is dropped. The device incorporates a mechanism that repeats this motion alternately to permanently accelerate the rotational motion using the weight in the device.
■ Equipment specifications Stand up vertically on a stand placed horizontally, and attach a horizontal rotating rod between the tops of the supports. The main disc gear is fixed to the horizontal rotating rod, and the suspension rod, upper rod and transmission gear are mounted so that they can rotate freely. A suspension gear is mounted on one of the suspension rods so that the suspension gear size and the reverse rotation gear can rotate freely, and a projection for placing the upper rod on the other end is mounted as a switching device. One of the upper rods is mounted so that the upper gear can freely rotate. The main disk, the suspension gear, the upper gear, the reverse rotation gear, and the transmission gear are meshed so that the suspension rod and the upper rod are aligned.
In the example shown in the figure, the gear radii are the main disk 240, the transmission gear large 360, the suspension gear large 90, the small 60, the reverse rotation gear 45, and the upper gear 60 in the illustrated example. In the hanging gear, the weight of the upper gear and the rotational drop force that are four times the weight of the hanging gear are balanced at the same angle, but the weight of the upper gear is equal to the weight of the hanging gear so that it can be lifted easily. The counter-rotating gear here is intended to transmit the rotational drop force of the weight of the suspended gear to the transmission gear, so this weight is not taken into account to make it as light as possible.
■ Operation specifications As shown in Fig. 1, when the suspension gear is placed on the right side of the rotation shaft and is stopped by hand and then released, the suspension gear and the upper gear are switched to try to rotate and drop independently. The device is in an unrelated separation. The suspension gear transmits a rotational drop force twice its own weight W to the transmission gear as a clockwise rotational force via the reverse rotation gear with the contact point with the main disk as a fulcrum. On the other hand, the upper gear transmits a rotational drop force that is ½ times its own weight W as a counterclockwise rotational force to the transmission gear with a contact point with the main disk as a fulcrum. Due to the difference in rotational force between the transmission gears, the transmission gear, the suspension rod and the upper rod rotate clockwise around the rotation axis, and the suspension gear is eventually positioned below the rotation axis vertical line.
2. When the suspension rod and the upper rod coincide with the vertical axis of the rotation axis, the rotational force is lost, so the rotation is not accelerated. However, when the suspension rod and the upper rod reach this point, the suspension rod and the upper rod are The upper gear moves to the right side of the rotating shaft because it rotates slightly clockwise beyond the rotating shaft vertical line.
3. In the state where the upper gear is located on the right side of the rotating shaft as shown in FIG. 2, the hanging gear and the upper gear are each about to rotate and fall independently, but the upper gear is put on the switching device. Since both the suspension gear and the upper gear are in an integrated state on one suspension rod, a rotational force having a combined weight of 2 W is applied to the suspension rod at the center of gravity G. With this rotational force, the suspension rod accelerates clockwise, the transmission gear rotates in the same manner, and the upper gear is eventually positioned below the vertical axis of the rotation axis.
4). When the suspension rod and the upper rod coincide with the vertical axis of the rotation axis, the rotational force is lost, so the rotation is not accelerated. However, when the suspension rod and the upper rod reach this point, the suspension rod and the upper rod are The shaft rotates slightly clockwise beyond the rotation axis vertical line, and the suspended gear moves to the right side of the rotation shaft.
5. Thereafter, the
6). Two, three, etc. equidistant hanging rods and upper rods on horizontal rotating rods. . . The rotational force can be increased easily by increasing the number, and when one hanging rod and the upper rod coincide with the vertical axis of the rotation axis, the rotational force is lost even when the rotational force is lost. Therefore, a stronger and smoother rotational driving force can be obtained from the constantly generated rotational force.
図1を参照See Figure 1
Claims (1)
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JP2010175779A JP5906564B2 (en) | 2010-07-16 | 2010-07-16 | Spindle rotation device |
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Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH09144647A (en) * | 1994-11-02 | 1997-06-03 | Keiji Takahashi | Permanent engine of the first kind |
JP2005098282A (en) * | 2003-08-28 | 2005-04-14 | Koei Sangyo Kk | Rotary drive unit |
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2010
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Patent Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH09144647A (en) * | 1994-11-02 | 1997-06-03 | Keiji Takahashi | Permanent engine of the first kind |
JP2005098282A (en) * | 2003-08-28 | 2005-04-14 | Koei Sangyo Kk | Rotary drive unit |
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