JP3236615U - Generator using solenoid and crank - Google Patents
Generator using solenoid and crank Download PDFInfo
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- JP3236615U JP3236615U JP2021003792U JP2021003792U JP3236615U JP 3236615 U JP3236615 U JP 3236615U JP 2021003792 U JP2021003792 U JP 2021003792U JP 2021003792 U JP2021003792 U JP 2021003792U JP 3236615 U JP3236615 U JP 3236615U
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Abstract
【課題】ソレノイドの機能を活用しクランクを回しそれをもってモーターを回転させる、発電機を提供する。【解決手段】ソレノイドa1b~a4bを利用しフォトセンサーE1~E4などのスイッチにより順番に瞬時通電しクランクを回転させ、直接または回転伝達装置によりオルタネーターまたは発電モーターを回転させ適正な発電量を得るものである。【選択図】図1PROBLEM TO BE SOLVED: To provide a generator which utilizes a function of a solenoid to rotate a crank and rotate a motor with the crank. SOLUTION: Solenoids a1b to a4b are used to instantly energize in order by switches such as photosensors E1 to E4 to rotate a crank, and an alternator or a power generation motor is rotated directly or by a rotation transmission device to obtain an appropriate amount of power generation. Is. [Selection diagram] Fig. 1
Description
ソレノイドを利用しフォトセンサーなどのスイッチにより順番に瞬時通電しクランクを回転させ、直接または回転伝達装置によりオルタネーターまたは発電モーターを回転させ適正な発電量を得るものである。 Using a solenoid, a switch such as a photosensor is used to instantly energize the crank in order to rotate the crank, and the alternator or power generation motor is rotated directly or by a rotation transmission device to obtain an appropriate amount of power generation.
太陽光・風力などの自然環境での不確定な発電と違い一日中発電出来、化石燃料・火力などのCo2排出もなく、小規模な発電が可能であり家庭の天井などに取り付けられるので邪魔にもならず工事も簡単であり、また大規模な発電も可能。Unlike uncertain power generation in the natural environment such as solar and wind power, it can generate power all day long, does not emit Co2 such as fossil fuels and thermal power, and can generate small-scale power generation. Construction is easy, and large-scale power generation is possible.
各電力会社および新規参画電力企業は大規模な電力供給を目指し、売電により収入を得また送電線を利用しています。また電力不足も懸念されるように温暖化が進みCo2削減が叫ばれるようになりました。さらに今般の世界情勢、東北の地震等で原子力発電停止または廃棄にも言及されています。災害時には電力会社からの電線による切断で停電が起こっています。太陽光発電および水力・風力発電はCo2を出しませんが、太陽光発電は高価で太陽が出ていないときは発電しないのと発電中余った電力を蓄電し使用しますが利用できる電力量は少なく、災害時には壊れたパネルは発電し続け火災の原因にもなり、また大量の電力を発電する場合は大規模な設置面積が必要となり送電方法に難点があり、また風力発電は小規模の家庭用だと賄えるほどの発電はせずまた風が無ければ発電はしないのでやはり蓄電しても効果が無いのが現状で、さらに大型の場合は風力・設置場所および騒音並びに高周波・費用・送電方法に難点がある。水力発電はいろいろな要素で大規模になりがちでさらには自然任せとなる。 Each electric power company and new participating electric power companies aim to supply large-scale electric power, earn income from selling electric power, and use transmission lines. In addition, global warming has progressed and CO2 reduction has come to be called for, as there are concerns about power shortages. Furthermore, it is mentioned that nuclear power generation is stopped or abandoned due to the recent world situation, the Tohoku earthquake, etc. In the event of a disaster, a power outage has occurred due to the disconnection of the electric wire from the electric power company. Solar power generation and hydropower / wind power generation do not emit Co2, but solar power generation is expensive and does not generate power when the sun is not shining. In the event of a disaster, broken panels continue to generate electricity and cause fire, and when generating a large amount of electricity, a large installation area is required and there are difficulties in the transmission method, and wind power generation is a small household. It does not generate enough power to cover it, and it does not generate power if there is no wind, so it is still ineffective to store electricity. Has a drawback. Hydropower tends to be large due to various factors, and it is left to nature.
今回のこの発電装置は安価でなおかつ規模も選べて各家庭に設置すればCo2削減にもなり、電力会社の電力・電気料金は基本料金以外この装置が作動している間は皆無に近くなり、電気料金の削減と電力不足を解消できます。また災害などで電力会社の停電があっても装置や家庭の電気製品が水害に合っていなければ電気製品は使用できます。この装置は水害や使用できなくなったコンセントに接続されているのを外し、個々にコンセントを直接接続できるようにします。また持ち運びもでき必要な場所に必要な電力供給できるものである。 This power generation device is inexpensive and you can choose the scale, and if you install it in each home, you can reduce Co2, and the electricity and electricity charges of the electric power company will be almost none while this device is operating except for the basic charge. You can reduce electricity charges and eliminate power shortages. In addition, even if there is a power outage at the electric power company due to a disaster, etc., the electric appliances can be used if the equipment and household electric appliances are not suitable for flood damage. This device disconnects from flooded or unusable outlets, allowing individual outlets to be connected directly. It is also portable and can supply the required power to the required location.
電力供給不足を解消し、家庭の場合は電気料金を無料近くに出来なおかつCo2を排出しない。さらに大規模な電力量を作り出すこともできるため企業・工場などへの設置も可能である。 It solves the power supply shortage, and in the case of households, the electricity charge can be made close to free and CO2 is not emitted. Since it can also generate a large amount of electricity, it can be installed in companies and factories.
この例図の場合ではソレノイドのプルを4個利用しフォトセンサーと通電用基盤および蓄電池・発電した電力でクランクが90度以内の時に順番に瞬時通電し、シャフトを活用しプランジャ引き込みクランクを回転させ、オルタネーターまたは発電モーターを必要な回転伝達装置で回転し発電、使用する電力量および電圧にさせ、ソレノイドに供給蓄電池に充電しそれ以外は外部の電力として活用する。ソレノイドに使用する電力は少量のため、発電した電力は外部での使用が主体となるため十分必要な電力量を供給できます。In the case of this example figure, four solenoid pulls are used to instantly energize the photo sensor, the energizing board, the storage battery, and the generated power when the crank is within 90 degrees, and the shaft is used to rotate the plunger pull-in crank. , The alternator or power generation motor is rotated by the necessary rotation transmission device to generate power, the amount of power to be used and the voltage are used, the solenoid is supplied, the storage battery is charged, and the rest is used as external power. Since the power used for the solenoid is small, the generated power is mainly used outside, so it is possible to supply a sufficient amount of power.
添付図1は全体図として各部位の名称を記載しています。最初はバッテリーからの通電でソレノイドを作動させクランクを回転させて回転伝達装置などでオルタネーターまたは発電モーターを回転させて発電する。その後発電させた電力でソレノイドと外部への電力供給およびバッテリーへの充電となります。コントローラーはソレノイドへの電力の調整を行いますスターターは必要に応じ設置します。Attached Figure 1 shows the names of each part as an overall view. At first, the solenoid is operated by energizing from the battery to rotate the crank, and the alternator or the power generation motor is rotated by the rotation transmission device to generate electricity. After that, the generated power is used to supply power to the solenoid and the outside and to charge the battery. The controller adjusts the power to the solenoid. Install the starter as needed.
図2はオルタネーターまたは発電モーターを回転させるまでの各部位の説明図で、G内のバッテリーでÅのソレノイドに電圧を通電し、Bのプランジャを引き込みCのシャフトでDのクランクを回転させる。Eのフォトセンサーが次のソレノイドに順番に作動させる。Fはフライホイールで回転の持続を助ける役目です。Hはソレノイドに供給する電圧のスピードコントローラーです。FIG. 2 is an explanatory diagram of each part until the alternator or the power generation motor is rotated. The battery in G applies a voltage to the solenoid of Å, the plunger of B is pulled in, and the crank of D is rotated by the shaft of C. The photo sensor of E activates the next solenoid in order. F is a flywheel that helps maintain rotation. H is a speed controller of the voltage supplied to the solenoid.
図3はソレノイド4個を順番にフォトセンサーで制御して通電させるための基盤です。基盤に関しては電圧・電流測定および作動状態・電力量などをモニターなどに表示するときは半導体などを利用し変更できる。Fig. 3 shows the base for energizing four solenoids in order by controlling them with a photo sensor. The board can be changed by using semiconductors when measuring voltage / current and displaying the operating status / power amount on a monitor or the like.
化石燃料で物作りをしている企業には大規模な当システムで電力を供給出来、現状に取って代われると思います。また電気で作動する物のバッテリーに常に電力を充電および供給させる事ができる。For companies that make things with fossil fuels, this large-scale system can supply electricity, and I think it will replace the current situation. In addition, it is possible to constantly charge and supply electric power to the battery of an electrically operated object.
a 配線
b 配線
a1b ソレノイド1
a2b ソレノイド2
a3b ソレノイド3
a4b ソレノイド4
A ソレノイド電磁石部
B プランジャ
C シャフト
D クランク
E フォトセンサー
F フライホイール
G バッテリー・基盤・コンバーター・インバーター等
H スピードコントローラーa wiring b wiring a1b solenoid 1
a2b Solenoid 2
a3b Solenoid 3
a4b Solenoid 4
A Solenoid electromagnet part B Plunger C Shaft D Crank E Photosensor F Flywheel G Battery, board, converter, inverter, etc. H Speed controller
Claims (3)
ソレノイドでクランクを引き込む角度はソレノイドの数量によるが、クランクの遠い位置でソレノイドが1個の場合は180度またはソレノイドが4個の場合は90度その他もよりそれ以下の位置に近いところで作動させる。クランクの回転半径はソレノイドの引き込みとほぼ同程度とする。このシステムでソレノイドを作動させる電力は直流または交流で、最初のソレノイドを作動させる方法はスターターまたは手動で蓄電池からの通電となり、それ以降発電した電力を直接およびインバーターまたはコンバーターで通電する。
使用するオルタネーターまたは発電モーターはDC12VからAC500V以上の物を使用し、ソレノイドの作動に使用する以上の電力量を送出し、DCの場合はインバーターでAC100Vおよび必要な電力を発生させ、AC100V以上の場合はAC100V等必要な電力になるようコンバーターまたは可変抵などで調整し、家庭・簡易発電機・工場などで使用できるようにブレーカーに接続する場合とリレーなどを設置し、電力会社と発電したものとを切り替える方法で給電、または直接給電で使用します。The type of solenoid differs depending on the energized voltage, rotation speed, and power, and the alternator or power generation motor is selected according to the rotation speed, power, and power generation amount. The number of solenoids should be 1 or more, and the solenoid should be selected because pulling is more effective. Then, the plunger is pulled in and the electromotive force is consumed by a capacitor or the like.
The angle at which the crank is pulled in by the solenoid depends on the number of solenoids, but it is operated at a position far from the crank, 180 degrees when there is one solenoid, 90 degrees when there are four solenoids, and other positions closer to the position below that. The radius of gyration of the crank should be about the same as the pull-in of the solenoid. The power to actuate the solenoid in this system is direct current or alternating current, the first method of actuating the solenoid is energization from a starter or manually stored battery, and the power generated thereafter is energized directly and by an inverter or converter.
The alternator or power generation motor to be used uses a DC12V to AC500V or higher, and sends out more power than used to operate the solenoid. In the case of DC, the inverter generates AC100V and required power, and in the case of AC100V or higher. Is adjusted with a converter or variable power so that the required power is AC100V, etc., and is connected to a breaker so that it can be used in homes, simple generators, factories, etc. It is used by power supply by switching method or direct power supply.
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Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH02136544A (en) * | 1988-11-17 | 1990-05-25 | Nec Corp | Fuel injection controller |
JPH0650118A (en) * | 1992-07-31 | 1994-02-22 | Nissan Motor Co Ltd | Lubricating device for internal combustion engine |
JP2014120714A (en) * | 2012-12-19 | 2014-06-30 | Denso Corp | Solenoid |
JP2015039253A (en) * | 2012-02-27 | 2015-02-26 | 時男 山海 | Air-cored coil and engine using repulsion of air-cored coil and permanent magnet |
JP2020126993A (en) * | 2019-02-06 | 2020-08-20 | デンソー インターナショナル アメリカ インコーポレーテッド | Solenoid device |
-
2021
- 2021-08-30 JP JP2021003792U patent/JP3236615U/en active Active
Patent Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH02136544A (en) * | 1988-11-17 | 1990-05-25 | Nec Corp | Fuel injection controller |
JPH0650118A (en) * | 1992-07-31 | 1994-02-22 | Nissan Motor Co Ltd | Lubricating device for internal combustion engine |
JP2015039253A (en) * | 2012-02-27 | 2015-02-26 | 時男 山海 | Air-cored coil and engine using repulsion of air-cored coil and permanent magnet |
JP2014120714A (en) * | 2012-12-19 | 2014-06-30 | Denso Corp | Solenoid |
JP2020126993A (en) * | 2019-02-06 | 2020-08-20 | デンソー インターナショナル アメリカ インコーポレーテッド | Solenoid device |
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