JP2010242636A - Nature-friendly power generation house - Google Patents
Nature-friendly power generation house Download PDFInfo
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- JP2010242636A JP2010242636A JP2009092835A JP2009092835A JP2010242636A JP 2010242636 A JP2010242636 A JP 2010242636A JP 2009092835 A JP2009092835 A JP 2009092835A JP 2009092835 A JP2009092835 A JP 2009092835A JP 2010242636 A JP2010242636 A JP 2010242636A
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B10/00—Integration of renewable energy sources in buildings
- Y02B10/30—Wind power
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/70—Wind energy
- Y02E10/74—Wind turbines with rotation axis perpendicular to the wind direction
Abstract
Description
本発明は森林資源を活用したエコ発電機かんするものである。 The present invention relates to an eco-generator utilizing forest resources.
今までの風力発電機は無風、微風時には発電が停止する事が多かった。
1)森林資源を活用したエコ発電装置。
2)庭先、ビルの屋上、住宅の置屋根、野池の湖上、海上、畑の隅など、何処でも設置が可能である。
3)現在、多く市販されている風車型に比べ騒音が非常に少ない(ほとんど無い)。
4)森林事業の短期サイクル(20年)以内での利用と間伐材を利用促進。
5)自然にやさしくハウスの部品(風向調整翼板)などを短期交換し出た廃材をバイオチップとして再利用する方式を採用し、資源としての高効率活用する事が出来る。CO2削減に貢献する発電装置です(CO2削減を森林育成で発電装置でバイオチップで利用しCO2を3度削減出来る装置である)
6)木材主体で建設すると、森林、製材業の復活と設備、加工、建設事業の場で雇用の促進に寄与する。
7)発電した電力をバッテリーに蓄電し、太陽光発電と併用で生活に利用し余剰電力を温水器の保温、加熱に利用し、環境(送電設備等)が許せば売電が出来る。
6)発電用モーターの増産に寄与。
7)蓄電用バッテリー増産の寄与。
8)天水を水槽に確保し植木、草花、家庭菜園の散水に利用し、浄水器、温水器、併設で生活用水として活用する。。
9)上記施設建設で、山間地などの不効率なインフラ設備が不要になり、多大なCO2削減に寄与する事ができる。
Until now, wind power generators were not windy, and power generation often stopped when the wind was light.
1) Eco-power generation equipment using forest resources.
2) It can be installed anywhere, such as in the garden, on the roof of a building, on the roof of a house, on the lake of a wild pond, on the sea, or in the corner of a field.
3) The noise level is very low (almost no) compared to the wind turbine types that are currently on the market.
4) Promote use within the short-term cycle (20 years) of forest business and use of thinned wood.
5) Adopting a method of reusing waste materials produced by short-term replacement of house parts (wind direction adjusting slats) etc. in a natural and gentle manner as biochips, it can be used efficiently as resources. This is a power generation device that contributes to CO2 reduction (CO2 reduction is a device that can reduce CO2 three times by using a biochip with a power generation device for forest growth)
6) Construction based on timber will contribute to the promotion of employment in the forest, lumbering industry revival and facilities, processing and construction business.
7) Electricity generated can be stored in a battery, used in daily life in combination with solar power generation, and surplus power can be used for warming and heating water heaters, and can be sold if the environment (power transmission equipment, etc.) permits.
6) Contributing to increased production of power generation motors.
7) Contribution of increased production of storage battery.
8) Secure rain water in the aquarium and use it for watering plants, flowers, and kitchen gardens, and use it as water for daily use in water purifiers and water heaters. .
9) The above-mentioned facility construction eliminates the need for inefficient infrastructure facilities such as mountainous areas, and can contribute to a great reduction in CO2.
1)森林資源を活用したエコ発電装置開発する。
2)庭先、ビルの屋上、住宅の置屋根、野池の湖上、海上、畑の隅など、何処でも設置が可能である。
3)現在、多く市販されている風車型に比べ騒音が非常に少ない(ほとんど無い)。
4)森林事業の短期サイクル(20年)以内での利用と間伐材を利用促進。、
5)自然にやさしくハウスの部品(風向調整翼板)などを短期交換し出た廃材をバイオチップとして再利用する方式を採用し、資源としての高効率活用する事が出来る。CO2削減に貢献する発電装置です(CO2削減を森林育成で発電装置でバイオチップで利用しCO2を3度削減出来る装置である)
6)木材主体で建設すると、森林、製材業の復活と設備、加工、建設事業の場で雇用の促進に寄与する。
7)発電した電力をバッテリーに蓄電し、太陽光発電と併用で生活に利用し余剰電力を温水器の保温、加熱に利用し、環境(送電設備等)が許せば売電が出来る。
6)発電用モーターの増産に寄与。
7)蓄電用バッテリー増産の寄与。
8)天水を水槽に確保し植木、草花、家庭菜園の散水に利用し、浄水器、温水器、併設で生活用水として活用する。
9)上記施設建設で、山間地などの不効率なインフラ設備が不要になり、多大なCO2削減に寄与する事ができる。
1) Develop eco-power generation equipment that utilizes forest resources.
2) It can be installed anywhere, such as in the garden, on the roof of a building, on the roof of a house, on the lake of a wild pond, on the sea, or in the corner of a field.
3) The noise level is very low (almost no) compared to the wind turbine types that are currently on the market.
4) Promote use within the short-term cycle (20 years) of forest business and use of thinned wood. ,
5) Adopting a method of reusing waste materials produced by short-term replacement of house parts (wind direction adjusting slats) etc. in a natural and gentle manner as biochips, it can be used efficiently as resources. This is a power generation device that contributes to CO2 reduction (CO2 reduction is a device that can reduce CO2 three times by using a biochip with a power generation device for forest growth)
6) Construction based on timber will contribute to the promotion of employment in the forest, lumbering industry revival and facilities, processing and construction business.
7) Electricity generated can be stored in a battery, used in daily life in combination with solar power generation, and surplus power can be used for warming and heating water heaters, and can be sold if the environment (power transmission equipment, etc.) permits.
6) Contributing to increased production of power generation motors.
7) Contribution of increased production of storage battery.
8) Secure rain water in the aquarium and use it for watering plants, flowers, and kitchen gardens, and use it as water for daily use in water purifiers and water heaters.
9) The above-mentioned facility construction eliminates the need for inefficient infrastructure facilities such as mountainous areas, and can contribute to a great reduction in CO2.
上記課題を解決するため、従来に無い手法で(スリーウエイ方式)で発電する
方法で、地球にやさしい森林のサイクル利用で多大なCO2削減と、エコエネ
ルギーが利用できる(エコハウス型、垂直軸風力発電機) 設備である。
In order to solve the above-mentioned problems, a method of generating electricity using an unprecedented method (three-way method), it is possible to use a large amount of CO2 and to use eco-energy through eco-friendly forest cycle use (eco-house type, vertical axis wind power) Generator) equipment.
今までの風力発電装置は微風時と強風時の発電が停止する事が多かったが、この装置は、微風時は風車の慣性を活用し発電し、強風時には併設の第二発電モーター稼働させ風力を無駄なく利用し高効率発電が可能にしたものであり、この発電ハウスは発電だけでなく、CO2削減に寄与する事が出来る、また、さまざまな設備を併設すると、規模にもよるが、送電設備や水道設備などインフラ整備費用の削減につながる設備となる。また、建設資材が木材の場合、森林産業(植林、伐採、育成)と製材産業と木材加産業にエコハウス建設業などの分野に新規事業立ち上げも含め新たなる雇用の促進に貢献できる。そしてすでに開発されている、発電用モーターとバッテリー(両分野共まだ研究開発の余地があるが)の新たな利用分野が開かれその分野の業界の活性化にもつながる事となり、これからのこの地球に求められているエコ社会に大きく貢献できる発明である。
Until now, wind power generators often stopped generating power during light winds and strong winds. The power generation house can contribute not only to power generation, but also to CO2 reduction. Also, depending on the scale, depending on the scale, power transmission can be achieved. It will be equipment that leads to reduction of infrastructure development costs such as equipment and water supply equipment. In addition, when the construction material is wood, it can contribute to the promotion of new employment, including the start-up of new businesses in fields such as the forest industry (planting, logging, and nurturing), the lumber industry and the timber processing industry as well as the eco house construction industry. And, a new field of use of power generation motors and batteries (although there is still room for research and development in both fields) will be opened, leading to the activation of the industry in that field. It is an invention that can greatly contribute to the eco-society required by
この設備は外周(風向調整板翼4−1−2を取り付けたパネル)3で構成し、中心に回転シャフト14を取り付け、シャフトに腕木を付けその先端に風受け翼19を取り付けた建築物である。外周に風向調整翼板を木材、鉄、アルミ、FRP,などの素材で出来る(固定、動式)を取り付け、風力を回転装置の先端翼19に集めること5で風力の高活用7にした装置である(回転翼中心部付近に当たる風力はテストの結果、余り強い回転力にならないのでそれを風向調整板で風向を変え回転シャフトに取り付けた先端翼に無駄なくなく風力を伝え風力のロスを防ぐ事とした)。 This facility consists of an outer periphery (panel with wind direction adjusting plate blades 4-1-2) 3 attached to a rotating shaft 14 at the center, a arm attached to the shaft, and a wind receiving blade 19 attached to the tip. is there. A wind direction adjustment blade plate made of wood, iron, aluminum, FRP, etc. (fixed, dynamic) is attached to the outer periphery, and the wind power is collected on the tip blade 19 of the rotating device 5 to make the wind power highly utilized 7 (The wind force that hits the center of the rotor blade does not become a very strong rotational force as a result of the test. )
また、あらゆる方向からの風力の半分は回転風車に対し抵抗となります、ここの抵抗となる風力を風力調整翼板6で全てを防ぐ役目も果たす装置である(試作品で証明済みです)。
この建物の中心シャフトに生まれた回転を連結ギャー12を使い回転を増幅させ発電モーターを高回転で回し発電するものである。
In addition, half of the wind force from all directions becomes resistance to the rotating wind turbine, and it is a device that also serves to prevent all the wind force that becomes resistance here with the wind adjustment blade 6 (provided in the prototype).
The rotation generated in the central shaft of this building is amplified by using the connecting gear 12 and the power generation motor is rotated at a high speed to generate electric power.
風向調整板翼パネルを構成している調整板翼の風流入口側の調整翼板小口断面を図の様に加工4−1.2し風がスムースに通過できることで、約2割〜3割の風力量の流入量増加を図ることができ、風車の回転トルクが上がりより高効率発電効果が得られる(パネル1枚に付き10枚の風向調整板翼で巾1cmで合計10cm高さ2mの風入量が遮られることになる、風向によるがパネル3枚分の風量30cmX2mの増量なる)この増量分回転トルクに大いに寄与する。
As shown in the figure, the cross section of the adjusting blade plate on the wind flow inlet side of the adjusting plate blade that constitutes the wind direction adjusting plate blade panel is processed as shown in the figure, and the wind can pass smoothly. Increases the amount of wind power inflow and increases the rotational torque of the windmill, resulting in a more efficient power generation effect (10 wind direction adjusting plate wings per panel with a width of 1 cm and a total of 10 cm height 2 m This will greatly contribute to the increased rotational torque. This will increase the amount of air flow of 30cmX2m for three panels.
風向調整翼板パネルは2段、3段、と重ねて建設しより多くの発電ができる設計されている。
The wind direction adjusting vane panel is constructed by stacking two or three stages and is designed to generate more power.
パネル交換で外周のメンテナンスを簡単に実行しやすくした。
Panel replacement makes it easier to perform maintenance on the outer periphery.
風力調整翼板交換を調整翼板の角度に合わせ加工した木製パッキンをビスで固定することで交換を簡単にすることとした。
The replacement of the wind power adjustment blade plate was made simple by fixing the wooden packing processed according to the angle of the adjustment blade plate with screws.
今までの風力発電機は微風時と強風時の発電が停止する事が多かったが、この装置は、無風、微風時はガソリン、軽油、バイオジィーゼルエンジン13等を作動させ発電し、風車が高回転達した時点でエンジン停止し風車の慣性(回転惰力)を利用して発電を継続させる、風車の回転が落ち発電不能状態の場合はエンジン再稼働の繰り返しでさらなる発電を継続する、)。 Until now, wind power generators often stopped generating power during light winds and strong winds, but this device operated gasoline, light oil, biodiesel engine 13 etc. when there was no wind and light winds, When the engine reaches a high speed, the engine is stopped and power generation is continued using the inertia (rotational repulsion) of the windmill. If the windmill has stopped rotating and power generation is not possible, further power generation is continued by restarting the engine.) .
また強風時には併設の第二発電モーター稼働11させ風力を無駄なく利用し高効率
発電が可能にしたものである。
In addition, when the wind is strong, the second power generation motor is operated 11 so that high-efficiency power generation is possible by using wind power without waste.
設備の屋根に太陽光発電、太陽光温水器を併設しさらなるクリーンエネルギー活用を併用する事も出来る施設である。
雨水を活用した設備を併設すれば、生活用水確保する設備(浄水器など)する事ができる、CO2削減効果の大きなインフラ総合設備機器施設を目的したものであるで。
It is a facility where solar power generation and solar water heaters are installed on the roof of the equipment, and it is possible to use more clean energy.
If the facility that uses rainwater is added, it can be used as facilities (water purifiers, etc.) for securing water for daily life, and it is aimed at an integrated infrastructure equipment facility with a large CO2 reduction effect.
1建物側面図
2風車と風向板翼パネル12枚の取り付け図
3風向調整板翼の側面図
4風向調整板翼パネルの風向調整板翼取り付け図(この取り付け角度で風向が回転翼先端に集まるよう調整している)。
4〜1,2風向調整板翼の風入流口側の風向調整板翼小口の加工図。
5が示す風向を風向調整板翼で風向を変えNO7回転翼先端に集め、より高トルクを得るようにした。
6この位置よりの風向調整板翼にあたる風が風車内に入るのを防ぐ役目を果たす装置になり、風車の回転の妨げになる風を防ぐ。
8風車のシャフト。
9風車の腕木。
10回転腕木の取り付けた先端翼。
11発電モーター(通常発電用)。
12ギャーボックス。
13緊急時発電エンジン。
14風車シャフトに連結のシャフト。
15強風時と緊急時作動の発電用モーター。
16貯水タンク(ろ過機付き)。
17太陽光発電、太陽熱温水器(単独又は併設)。
18余剰電力利用の温水器。
19回転シャフト腕木に取り付けた先端部の風受け翼。
20配電、売電併用機器。
21売電用配線。
22バッテリー(蓄電用)。
23配線図。
1 Building side view 2 Wind turbine and 12 wind direction plate wing panel installation 3 Wind direction adjustment plate wing side view 4 Wind direction adjustment plate wing panel wind direction adjustment plate wing installation view (The wind direction gathers at the tip of the rotor blade at this mounting angle) Adjusting).
Process drawing of the wind direction adjusting plate blade edge on the air inlet / outlet side of the 4-1 and 2 wind direction adjusting plate blades.
The wind direction indicated by No. 5 was collected at the tip of the NO7 rotor blade by changing the wind direction with the wind direction adjusting plate blade to obtain higher torque.
6 It becomes a device that plays a role of preventing the wind corresponding to the wind direction adjusting plate blades from this position from entering the windmill, and prevents the wind that hinders the rotation of the windmill.
8 windmill shaft.
Nine windmill braces.
Tip wing with 10 rotating brace attached.
11 power generation motor (for normal power generation).
12 gearbox.
13 emergency power generation engine.
14 shaft connected to windmill shaft.
15 Power generation motor for strong wind and emergency operation.
16 water storage tank (with filter).
17 Solar power generation, solar water heater (single or attached).
Water heater using 18 surplus power.
A wind vane at the tip attached to a 19-turn shaft arm.
20 power distribution and sale equipment.
21 Wiring for power sale.
22 batteries (for power storage).
23 wiring diagram.
Claims (7)
(図1)
This facility is a building with an outer periphery (panel with wind direction adjusting plate wings), a rotating shaft attached to the center, arms to the shaft, and wind vanes attached to the tip. A wind direction adjustment blade plate made of any material such as wood, iron, aluminum, FRP, etc. (fixed, dynamic panel) is attached to the outer periphery, and wind power is collected on the tip blade of the rotating device, making use of high torque of wind power. Yes (we decided to change the wind direction near the center of the rotor blade and transmit it to the tip blade attached to the rotor shaft without waste to prevent the maximum loss of wind power). In addition, this wind power adjustment blade plate also serves to prevent all of the wind power that resists the rotor blades (proven with a prototype). The rotation generated in the central shaft of the building is amplified by using a connecting gear to rotate the generator motor at high speed to generate electricity.
(Figure 1)
図4〜1、2) Increased inflow of wind power by about 20-30% by processing the cross-section of the adjustment blade plate on the wind flow inlet side of the adjustment plate blades that make up the wind direction adjustment plate blade panel as shown in the figure. We decided to plan.
(Figs. 4-1, 2)
(図6) Conventional wind power generators often stopped generating power when there was no wind or light wind, but this device operated gasoline, light oil, biodiesel engine, etc. when there was no wind or light wind, and the windmill reached high speed. At this point, the engine is stopped and the power generation is continued using the inertia of the windmill. When the windmill falls and power generation is disabled, the power generation is continued by restarting the engine.
(Fig. 6)
(図6) In strong winds, it can be connected to the second generator motor to generate more energy (Fig. 6).
(図7)
The facility is also equipped with facilities that utilize rainwater, and is intended to be an infrastructure equipment facility that has a large CO2 reduction effect by installing facilities for securing water for daily use (such as water purifiers).
(Fig. 7)
Combined with solar power generation, surplus power can be sold if the environment (such as power transmission facilities) permits.
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JP2009092835A JP2010242636A (en) | 2009-04-07 | 2009-04-07 | Nature-friendly power generation house |
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JP2009092835A JP2010242636A (en) | 2009-04-07 | 2009-04-07 | Nature-friendly power generation house |
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JP2010242636A5 JP2010242636A5 (en) | 2012-05-31 |
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JP2009092835A Pending JP2010242636A (en) | 2009-04-07 | 2009-04-07 | Nature-friendly power generation house |
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Citations (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS6133980U (en) * | 1984-07-31 | 1986-03-01 | 浩 蓮井 | windmill equipment |
JP2001193629A (en) * | 2000-01-13 | 2001-07-17 | Tootasu:Kk | Wind-power control device |
JP2004027864A (en) * | 2002-06-21 | 2004-01-29 | Taisei Corp | Generator |
JP2006042425A (en) * | 2004-07-23 | 2006-02-09 | Yoshinobu Hayashi | Generator |
JP2006105117A (en) * | 2004-10-07 | 2006-04-20 | Victory:Kk | Wind power generation device |
JP2006291791A (en) * | 2005-04-08 | 2006-10-26 | Ichiro Tomobe | Wind force prime mover |
-
2009
- 2009-04-07 JP JP2009092835A patent/JP2010242636A/en active Pending
Patent Citations (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS6133980U (en) * | 1984-07-31 | 1986-03-01 | 浩 蓮井 | windmill equipment |
JP2001193629A (en) * | 2000-01-13 | 2001-07-17 | Tootasu:Kk | Wind-power control device |
JP2004027864A (en) * | 2002-06-21 | 2004-01-29 | Taisei Corp | Generator |
JP2006042425A (en) * | 2004-07-23 | 2006-02-09 | Yoshinobu Hayashi | Generator |
JP2006105117A (en) * | 2004-10-07 | 2006-04-20 | Victory:Kk | Wind power generation device |
JP2006291791A (en) * | 2005-04-08 | 2006-10-26 | Ichiro Tomobe | Wind force prime mover |
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