TWM518272U - Multi-layer blade type wind power generation device - Google Patents
Multi-layer blade type wind power generation device Download PDFInfo
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- TWM518272U TWM518272U TW104218228U TW104218228U TWM518272U TW M518272 U TWM518272 U TW M518272U TW 104218228 U TW104218228 U TW 104218228U TW 104218228 U TW104218228 U TW 104218228U TW M518272 U TWM518272 U TW M518272U
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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
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/20—Hydro energy
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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
- 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
- Y02E10/72—Wind turbines with rotation axis in wind direction
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Description
本新型是有關於一種發電裝置,特別是指一種利用風力、潮汐、洋流等推力來推動葉片旋轉以產生電力的多層葉片式風力發電裝置。The present invention relates to a power generating device, and more particularly to a multi-layer blade type wind power generating device that uses wind, tide, ocean current and the like to push the blade to rotate to generate electric power.
目前市面上已有相當多種利用風力、潮汐、洋流等推力來產生電力的流力發電裝置。參閱圖1,一般普遍採用的水平軸式的風力發電裝置,包含一個基座90、一支可轉動地水平穿伸入基座90的轉軸91,及一個安裝在該轉軸91前端的葉片模組92。該葉片模組92包括三個彼此角度間隔地連接該轉軸91的葉片921,當該等葉片921受到風力驅動而連動該轉軸91繞其自身軸心旋轉時,該風力發電裝置就能進行發電。At present, there are quite a number of hydropower generating devices that use electric power such as wind, tide, and ocean current to generate electric power. Referring to Fig. 1, a horizontal axis wind power generation device generally used includes a base 90, a rotating shaft 91 rotatably horizontally penetrating into the base 90, and a blade module mounted on the front end of the rotating shaft 91. 92. The blade module 92 includes three blades 921 that are connected to the rotating shaft 91 at an angular interval from each other. When the blades 921 are driven by the wind to rotate the rotating shaft 91 about its own axis, the wind power generating device can generate electricity.
目前全世界的水平軸式風力發電裝置均朝向大型化發展,主要是期望能提供更充足的電力,為了滿足此要求,該等葉片921的葉片長度必須高達50~75公尺,才能使該等葉片921有足夠的受風面積,來提供足夠的旋轉扭力,以帶動該轉軸91達到所需的轉速,也由於該等葉片921的長度較長,使得該風力發電裝置在運轉時,該等葉片921上下橫跨的高度相當大,使得該等葉片921的最高處與最低處的高度差可高達100公尺以上,然而在低空流場下,風的流速在不同高度下是呈現不均勻的分布,且高度差越大流速的差異也越大,若位於高處的葉片921與位於低處的葉片921所受到風力差異大,會導致該葉片模組92傾斜偏擺,運轉不順暢,而容易損壞。At present, the horizontal axis wind power generation devices all over the world are facing large-scale development, and it is mainly expected to provide more sufficient power. In order to meet this requirement, the blade length of the blades 921 must be as high as 50-75 meters. The blade 921 has sufficient wind receiving area to provide sufficient rotational torque to drive the rotating shaft 91 to a desired rotational speed, and also because the length of the blades 921 is long, so that the wind power generating device is in operation, the blades The height of the 921 up and down is quite large, so that the height difference between the highest point and the lowest point of the blades 921 can be as high as 100 meters or more. However, in the low-altitude flow field, the flow velocity of the wind is unevenly distributed at different heights. The greater the difference in height, the greater the difference in the flow rate. If the blade 921 located at a high position and the blade 921 at a lower position are subjected to a large difference in wind force, the blade module 92 may be tilted and yawed, and the operation may be unsmooth and easy. damage.
此外,該等葉片921的葉片長度較長,也使得該等葉片921所承受的風力與力矩較大,往往會導致該等葉片921與該轉軸91的連接處,在長期運轉下容易損壞變形,因此現有的風力發電裝置仍有待改善。In addition, the blades of the blades 921 have a long length, and the winds and moments of the blades 921 are relatively large, which tends to cause the joints of the blades 921 and the rotating shaft 91 to be easily damaged and deformed under long-term operation. Therefore, existing wind power generation devices still need to be improved.
因此,本新型之目的,即在提供一種能提高運轉順暢度且不易損壞變形的多層葉片式風力發電裝置。Therefore, the object of the present invention is to provide a multi-layered blade type wind power generator which can improve the smoothness of operation and is less susceptible to damage.
於是,本新型多層葉片式風力發電裝置,可受沿一個流動方向流動的風所驅動,包含一個基座、一個第一轉軸,及數個第一葉片模組。該第一轉軸沿該流動方向軸向延伸,且可繞自身軸心轉動地安裝於該基座。該等第一葉片模組連接該第一轉軸且沿該第一轉軸之軸向方向間隔排列,每一個第一葉片模組具有數個由該第一轉軸之徑向方向向外延伸且彼此角度間隔的第一葉片,該等第一葉片模組的第一葉片可分別受風力驅動而連動該第一轉軸往一個第一轉動方向旋轉。Thus, the novel multi-blade wind power generator can be driven by wind flowing in a flow direction, and includes a base, a first rotating shaft, and a plurality of first blade modules. The first shaft extends axially in the flow direction and is rotatably mounted to the base about its own axis. The first blade modules are connected to the first rotating shaft and are arranged along the axial direction of the first rotating shaft. Each of the first blade modules has a plurality of angles extending outward from the radial direction of the first rotating shaft and at an angle to each other. The first blades of the first blade module are respectively driven by the wind to rotate the first rotating shaft to rotate in a first rotation direction.
本新型之功效在於:透過該等第一葉片模組的設計,能增加該等第一葉片的數量,並縮短每一個第一葉片的葉片長度。以避免該等第一葉片上下橫跨的高度過大而出現上下受力不均的問題,進而讓該等第一葉片能平均受力地帶動該第一轉軸順暢的運轉。且該等第一葉片所承受的風力與力矩較小,也能使該等第一葉片與該第一轉軸的連接處不易損壞變形。The effect of the present invention is that the number of the first blades can be increased and the blade length of each of the first blades can be shortened by the design of the first blade modules. In order to avoid the problem that the height of the first blade is too large, the upper and lower forces are uneven, and the first blade can smoothly move the first shaft to operate smoothly. Moreover, the first blades are subjected to less wind and torque, and the joints of the first blades and the first rotating shaft are less likely to be damaged and deformed.
在本新型被詳細描述之前,應當注意在以下的說明內容中,類似的元件是以相同的編號來表示。Before the present invention is described in detail, it should be noted that in the following description, similar elements are denoted by the same reference numerals.
參閱圖2、圖3與圖4,本新型多層葉片式風力發電裝置之第一實施例,本新型為水平軸式的風力發電裝置,並可受沿一個流動方向F流動的風所驅動。該風力發電裝置包含一個基座1、一個第一轉軸2、三個第一葉片模組3,及數個單轉發電模組4。Referring to Figures 2, 3 and 4, in a first embodiment of the novel multi-blade wind power generator, the present invention is a horizontal-axis wind power generator and is driven by wind flowing in a flow direction F. The wind power generation device comprises a base 1, a first rotating shaft 2, three first blade modules 3, and a plurality of single forwarding electric modules 4.
該基座1用以支撐該第一轉軸2,在本實施例中,該基座1包括一個支撐柱11,及一個設置於該支撐柱11頂端並可供該第一轉軸2穿設的座體12,該座體12界定出一個第一發電空間13。實施上該基座1可設計成能相對於地面水平轉動,並利用一個導流板來帶動該基座1轉動,使本新型能轉動至正面受風的位置,實施上,該基座1的設計,不以本實施例為限。The base 1 is used to support the first rotating shaft 2. In the embodiment, the base 1 includes a supporting column 11 and a seat disposed at the top end of the supporting column 11 and pierceable by the first rotating shaft 2 The body 12 defines a first power generating space 13. In practice, the base 1 can be designed to be horizontally rotatable relative to the ground, and a baffle is used to drive the base 1 to rotate, so that the present invention can be rotated to the front wind receiving position, and the base 1 is The design is not limited to this embodiment.
該第一轉軸2沿該流動方向F軸向延伸,且可繞自身軸心轉動地穿設於該座體12,並沿著該流動方向F長向延伸。該第一轉軸2包括一個朝向該流動方向F的迎風端21,及一個背向該流動方向F的背風端22。補充說明的是,在本實施例中該座體12是利用數個軸承,以供該第一轉軸2可轉動地穿設,但實施上不以本實施例為限。The first rotating shaft 2 extends axially in the flow direction F, and is rotatably disposed around the shaft 12 around the shaft axis thereof and extends in the longitudinal direction along the flow direction F. The first shaft 2 includes a windward end 21 facing the flow direction F and a leeward end 22 facing away from the flow direction F. It should be noted that, in the embodiment, the seat body 12 utilizes a plurality of bearings for the first rotating shaft 2 to be rotatably disposed, but the implementation is not limited to the embodiment.
該等第一葉片模組3,連接該第一轉軸2且沿該第一轉軸2之軸向方向間隔排列。在本實施例中,該等第一葉片模組3的數量為三,但實施上,該等第一葉片模組3的數量亦可為二、四或五以上,不以本實施例為限。每一個第一葉片模組3具有數個由該第一轉軸2之徑向方向向外延伸且彼此角度間隔的第一葉片31。每一個第一葉片31呈長條板狀,當該等第一葉片31受到沿該流動方向F的風力驅動時,會連動該第一轉軸2往一個第一轉動方向C1旋轉,且該第一轉動方向C1與該流動方向F相互垂直,而成為水平軸式的風力發電裝置。The first blade modules 3 are connected to the first rotating shaft 2 and are arranged at intervals along the axial direction of the first rotating shaft 2. In this embodiment, the number of the first blade modules 3 is three, but in practice, the number of the first blade modules 3 may be two, four or more, not limited to this embodiment. . Each of the first blade modules 3 has a plurality of first blades 31 extending outward from the radial direction of the first rotating shaft 2 and angularly spaced from each other. Each of the first blades 31 has a long strip shape. When the first blades 31 are driven by the wind in the flow direction F, the first rotating shaft 2 is rotated in a first rotational direction C1, and the first The rotation direction C1 and the flow direction F are perpendicular to each other, and become a horizontal axis type wind power generator.
該等第一葉片31能沿著與該流動方向F垂直的第一轉動方向C1轉動的原因在於:每一個第一葉片31具有一個與該流動方向F呈一傾斜角度的風切面311,當風沿該流動方向F流動而與該等第一葉片31的風切面311接觸後,會被該等風切面311引導而改變流動方向F,此時,風對該等風切面311所產生的作用力,就能驅動該等第一葉片31轉動,而將動能傳遞至該等第一葉片31。The reason why the first blades 31 can rotate along the first rotation direction C1 perpendicular to the flow direction F is that each of the first blades 31 has a wind-cut surface 311 at an oblique angle to the flow direction F, when the wind After flowing in the flow direction F and coming into contact with the wind-cut surface 311 of the first blades 31, the wind-cut surface 311 is guided to change the flow direction F. At this time, the wind exerts a force on the wind-cut surface 311. The first blades 31 can be driven to rotate, and kinetic energy can be transmitted to the first blades 31.
每一個第一葉片31的葉片長度L1為該第一葉片31從該第一轉軸2徑向向外延伸的長度,而該等第一葉片模組3之第一葉片31的葉片長度L1,由該第一轉軸2的該迎風端21往該背風端22逐漸增加,也就是說,越靠近該流動方向F的下游處的第一葉片31其葉片長度L1越長,反之越靠近該流動方向F的上游處的第一葉片31其葉片長度L1越短,如此一來,就能避免相對位於上游處的第一葉片31完全遮擋到相對位於下游處的第一葉片31,以增加位於下游處的第一葉片31與風的接觸面積。The blade length L1 of each of the first blades 31 is a length in which the first blades 31 extend radially outward from the first rotating shaft 2, and the blade length L1 of the first blades 31 of the first blade modules 3 is determined by The windward end 21 of the first rotating shaft 2 gradually increases toward the leeward end 22, that is, the closer to the first blade 31 downstream of the flow direction F, the longer the blade length L1, and the closer to the flow direction F The shorter the blade length L1 of the first blade 31 at the upstream, the more the first blade 31 located at the upstream is completely blocked from the first blade 31 located at the downstream to increase the downstream position. The contact area of the first blade 31 with the wind.
此外,該等第一葉片模組3的第一葉片31彼此錯開,在本實例中,該等第一葉片模組3的數量為三,且每一個第一葉片模組3之第一葉片31的數量為三,因此在設計上,是讓每一個第一葉片模組3的第一葉片31彼此呈360/3=120度角度間隔,而每兩相鄰第一葉片模組3的第一葉片31彼此錯開360/(3×3)=40度,也就是說,從圖4的視角來看,該等第一葉片模組3的第一葉片31會呈放射狀的分布,且從葉片長度L1最短之兩相鄰第一葉片31所夾角度間反向沿著該第一轉動方向C1,例如從三點鐘方向沿著逆時針方向C1到十一點鐘方向,依序由葉片長度L1最短的第一葉片31排列到葉片長度L1最長的第一葉片31。透過該等第一葉片模組3的第一葉片31彼此錯開的設計,使風能依序穿過鄰近該迎風端21的第一葉片模組3後,來依序驅動遠離該迎風端21的第一葉片模組3。In addition, the first blades 31 of the first blade modules 3 are offset from each other. In the present example, the number of the first blade modules 3 is three, and the first blades 31 of each of the first blade modules 3 The number is three, so the design is such that the first blades 31 of each first blade module 3 are angularly spaced from each other by 360/3=120 degrees, and the first of each two adjacent first blade modules 3 The blades 31 are offset from each other by 360/(3×3)=40 degrees, that is, from the perspective of FIG. 4, the first blades 31 of the first blade modules 3 are radially distributed, and from the blades. The angle between the two adjacent first blades 31 of the shortest length L1 is reversed along the first rotational direction C1, for example, from the three o'clock direction in the counterclockwise direction C1 to the eleven o'clock direction, sequentially by the blade length. The shortest first blade 31 of L1 is arranged to the first blade 31 having the longest blade length L1. Through the design that the first blades 31 of the first blade modules 3 are offset from each other, the wind energy is sequentially passed through the first blade module 3 adjacent to the windward end 21 to sequentially drive away from the windward end 21 . The first blade module 3.
補充說明的是,在本實例中,該等第一葉片模組3的數量為三,且每一個第一葉片模組3之第一葉片31的數量為三,因此每兩相鄰第一葉片模組3的第一葉片31彼此錯開40度,但實施上,每兩相鄰第一葉片模組3的第一葉片31彼此錯開的角度,會依該等第一葉片模組3的數量以及每一個第一葉片模組3之第一葉片31的數量而定。例如該等第一葉片模組3的數量為四,且每一個第一葉片模組3之第一葉片31的數量為五,則每兩相鄰第一葉片模組3的第一葉片31彼此錯開的角度為360/(4×5)=18度。It should be noted that, in the present example, the number of the first blade modules 3 is three, and the number of the first blades 31 of each of the first blade modules 3 is three, so each two adjacent first blades The first blades 31 of the module 3 are offset from each other by 40 degrees, but in practice, the angle at which the first blades 31 of each two adjacent first blade modules 3 are offset from each other depends on the number of the first blade modules 3 and The number of the first blades 31 of each of the first blade modules 3 depends on the number of the first blades 31. For example, if the number of the first blade modules 3 is four, and the number of the first blades 31 of each of the first blade modules 3 is five, the first blades 31 of each two adjacent first blade modules 3 are mutually The angle of the stagger is 360/(4×5)=18 degrees.
該等單轉發電模組4沿該第一轉軸2間隔設置於該第一發電空間13,每一個單轉發電模組4包括一個安裝在該座體12的普通定子41,及一個安裝在該第一轉軸2的普通轉子42。當該等第一葉片模組3受到風力推動時,會帶動該第一轉軸2轉動,而帶動該普通轉子42相對於該普通定子41旋轉以產生感應電流輸出。實施上,本新型亦可僅包含一個單轉發電模組4,不以本實施例為限The single forwarding electrical modules 4 are spaced apart from the first power generating space 13 along the first rotating shaft 2, and each of the single forwarding electrical modules 4 includes a common stator 41 mounted on the base 12, and one is mounted thereon. The ordinary rotor 42 of the first rotating shaft 2. When the first blade module 3 is pushed by the wind, the first rotating shaft 2 is rotated, and the ordinary rotor 42 is rotated relative to the common stator 41 to generate an induced current output. In practice, the present invention may also include only one single forwarding electrical module 4, not limited to this embodiment.
本新型多層葉片式風力發電裝置,使用時,當風沿該流動方向F流動而到達最靠近該流動方向F上游處的第一葉片模組3時,會驅動最靠近該流動方向F上游處第一葉片模組3產生旋轉扭力,而未觸碰到該第一葉片模組3的風,例如從每兩相鄰之第一葉片31間穿過的風,以及位於以葉片長度L1作為半徑所界定出的圓周區域之外的風,會繼續往該流動方向F流動。The multi-layered blade type wind power generation device of the present invention, when used, flows in the flow direction F to reach the first blade module 3 closest to the upstream of the flow direction F, and drives the upstream of the flow direction F. A blade module 3 generates a rotational torque without touching the wind of the first blade module 3, for example, wind passing between every two adjacent first blades 31, and at a blade length L1 as a radius The wind outside the defined circumferential area will continue to flow in the flow direction F.
由於位於相對下游處的第一葉片模組3與位於相對上游處的第一葉片模組3彼此錯開,且位於相對下游處的第一葉片模組3的葉片長度L1較長,因此繼續往該流動方向F流動的風能順利驅動位於相對下游處的第一葉片模組3產生旋轉扭力,而未觸碰到該第一葉片模組3的風,也就是上述從每兩相鄰的第一葉片31間穿過的風,或者位於以葉片長度L1作為半徑所界定出的圓周區域之外的風,會繼續往該流動方向F流動。Since the first blade module 3 located at the opposite downstream and the first blade module 3 located at the opposite upstream are offset from each other, and the blade length L1 of the first blade module 3 located at the opposite downstream is longer, the continuation The wind energy flowing in the flow direction F smoothly drives the first blade module 3 located at the opposite downstream to generate a rotational torque, and does not touch the wind of the first blade module 3, that is, the first from each of the two adjacent The wind passing between the blades 31, or the wind outside the circumferential area defined by the blade length L1 as a radius, continues to flow in the flow direction F.
依此類推下來,沿該流動方向F的風就能驅動到最下游的第一葉片模組3來產生旋轉扭力,最後,該等第一葉片模組3能相配合帶動該第一轉軸2繞著該第一轉動方向C1轉動。And so on, the wind along the flow direction F can be driven to the most downstream first blade module 3 to generate a rotational torque. Finally, the first blade modules 3 can cooperate to drive the first rotating shaft 2 The first rotational direction C1 is rotated.
由於該等第一葉片模組3都能受到風力驅動,因此在能達到足夠受風面積的情況下,本新型能透過增加該等第一葉片31的數量,來縮短每一個第一葉片31的葉片長度,使得每一個第一葉片模組3的葉片長度L1相較於習知的葉片長度可以縮短許多,而該等第一葉片模組3相配合能仍然能提供足夠的旋轉扭力。Since the first blade modules 3 can be driven by the wind, the present invention can shorten the number of each of the first blades 31 by increasing the number of the first blades 31 when a sufficient wind receiving area can be achieved. The length of the blade is such that the blade length L1 of each of the first blade modules 3 can be shortened much compared to the conventional blade length, and the first blade modules 3 can still provide sufficient rotational torque.
透過上述設計,能縮短該等第一葉片31上下橫跨的高度,就不會出現習知葉片受力不均的問題,使得該等第一葉片31能平均受力地帶動該第一轉軸2順暢的運轉。而且該等第一葉片31的長度較短也能減少所承受的風力與力矩,使該等第一葉片31與該第一轉軸2的連接處不易損壞變形。Through the above design, the height of the first blade 31 can be shortened, and the problem of uneven force of the blade is not caused, so that the first blade 31 can force the first shaft 2 on average. Smooth operation. Moreover, the shorter lengths of the first vanes 31 can also reduce the wind and torque that are received, so that the joints of the first vanes 31 and the first rotating shaft 2 are not easily damaged and deformed.
且將該等第一葉片模組3間隔設置於該第一轉軸2,可將該等第一葉片模組3對該第一轉軸2的扭力均勻分散於該第一轉軸2上,使該第一轉軸2的平均受力轉動,以降低該第一轉軸2扭轉變形的情況。And the first blade modules 3 are spaced apart from the first rotating shaft 2, and the torque of the first blade module 3 to the first rotating shaft 2 is evenly distributed on the first rotating shaft 2, so that the first The average force of a rotating shaft 2 is rotated to reduce the torsional deformation of the first rotating shaft 2.
綜上所述,本新型多層葉片式風力發電裝置,透過該等第一葉片模組3的設計,能避免該等第一葉片31因上下受力不均而傾斜偏擺的問題,讓該等第一葉片31能平均受力地帶動該第一轉軸2順暢的運轉,也能使該等第一葉片31與該第一轉軸2的連接處不易損壞變形,故確實能達成本新型之目的。In summary, the multi-blade-blade wind power generation device of the present invention can avoid the problem that the first blades 31 are tilted and yawed due to uneven force on the upper and lower sides through the design of the first blade modules 3, so that these The first blade 31 can smoothly move the first rotating shaft 2 to operate smoothly, and the joint between the first blade 31 and the first rotating shaft 2 can be easily damaged and deformed, so that the object of the present invention can be achieved.
參閱圖5、圖6與圖7,本新型多層葉片式風力發電裝置之第二實施例,與該第一實施例不同之處在於:本實施例不包含該等單轉發電模組4,而還包含一個第二轉軸5、一個第二葉片模組6,及數個第一雙轉發電模組7。本實施例的該等第一葉片模組3的數量為二,但實施上,該等第一葉片模組3的數量亦可為三、四或五以上,不以本實施例為限。Referring to FIG. 5, FIG. 6, and FIG. 7, the second embodiment of the present invention is different from the first embodiment in that the present embodiment does not include the single forwarding electrical module 4, and A second rotating shaft 5, a second blade module 6, and a plurality of first dual forwarding electrical modules 7 are also included. The number of the first blade modules 3 of the present embodiment is two. However, the number of the first blade modules 3 may be three, four or more, which is not limited to the embodiment.
該第二轉軸5沿該流動方向F軸向延伸,且可繞自身軸心轉動,在本實施例中,該第一轉軸2不穿設於該座體12,改由該第二轉軸5穿設於該座體12,而該第一轉軸2呈中空圓筒狀地間隔套設於該第二轉軸5外。該第二轉軸5的局部區域延伸於外,以供該第二葉片模組6安裝。該第二轉軸5與該第一轉軸2徑向內外間隔而相配合界定出一個第二發電空間50。The second rotating shaft 5 extends axially in the flow direction F and is rotatable about its own axis. In this embodiment, the first rotating shaft 2 is not disposed on the base 12 and is worn by the second rotating shaft 5 The first rotating shaft 2 is disposed outside the second rotating shaft 5 at a distance of a hollow cylindrical shape. A partial area of the second shaft 5 extends outside for the second blade module 6 to be mounted. The second rotating shaft 5 cooperates with the radially inner and outer spaces of the first rotating shaft 2 to define a second generating space 50.
該第二葉片模組6具有數個由該第二轉軸5之徑向方向向外延伸且彼此角度間隔的第二葉片61。每一個第二葉片61呈長條板狀,當該等第二葉片61受到沿該流動方向F的風力驅動時,會連動該第二轉軸5往一個相反於該第一轉動方向C1的第二轉動方向C2旋轉。在本實施例中,由於該第二葉片模組6安裝的位置相對於該等第一葉片模組3是位於該流動方向F的下游處,因此該等第二葉片61的葉片長度L2大於該等第一葉片31的葉片長度L1,以避免相對位於上游處的第一葉片31完全遮擋到相對位於下游處的第二葉片61。The second vane module 6 has a plurality of second vanes 61 extending outward from the radial direction of the second rotating shaft 5 and angularly spaced from each other. Each of the second blades 61 has a long strip shape. When the second blades 61 are driven by the wind in the flow direction F, the second rotating shaft 5 is interlocked to a second opposite to the first rotating direction C1. Rotation in the direction of rotation C2. In this embodiment, since the second blade module 6 is installed at a position downstream of the flow direction F with respect to the first blade modules 3, the blade length L2 of the second blades 61 is greater than the The blade length L1 of the first blade 31 is equal to prevent the first blade 31 located at the upstream from being completely blocked to the second blade 61 located relatively downstream.
該等第一雙轉發電模組7沿著該第二轉軸5之軸向方向排列設置於該第二發電空間50內,每一個第一雙轉發電模組7包括一個安裝在該第一轉軸2的第一轉子71,及一個安裝在該第二轉軸5的第二轉子72。該第一轉子71會被該第一轉軸2帶動而往第一轉動方向C1轉動。該第二轉子72會被該第二轉軸5帶動而往第二轉動方向C2轉動。實施上,本新型亦可僅包含一個第一雙轉發電模組7,不以本實施例為限。The first dual forwarding power modules 7 are arranged in the second power generating space 50 along the axial direction of the second rotating shaft 5, and each of the first dual forwarding power modules 7 includes one mounted on the first rotating shaft. The first rotor 71 of 2, and a second rotor 72 mounted to the second rotating shaft 5. The first rotor 71 is driven by the first rotating shaft 2 to rotate in the first rotational direction C1. The second rotor 72 is driven by the second rotating shaft 5 to rotate in the second rotational direction C2. In practice, the present invention may also include only one first dual forwarding power module 7, which is not limited to this embodiment.
在本實施例中,該第一轉子71與該第二轉子72皆由鐵芯與圈繞於該鐵芯的線圈組成,使用時,會先使該第一轉子71產生磁場,當風沿該流動方向F吹來時,該等第一葉片模組3會帶動該第一轉軸2往第一轉動方向C1轉動;該第二葉片模組6會帶動該第二轉軸5往第二轉動方向C2轉動,此時,該第一轉子71與該第二轉子72會相對旋轉通過,而使該第二轉子72切割該第一轉子71所產生的磁場,並產生感應電流輸出,上述感應電流可利用數個滑環(圖未示)分別將接出。但實施上,該第一轉子71與該第二轉子72亦可相反設計,亦即該第二轉子72會產生磁場,該第一轉子71會產生感應電流,不以本實施例的形式為限。In this embodiment, the first rotor 71 and the second rotor 72 are both composed of a core and a coil wound around the core. In use, the first rotor 71 is first generated with a magnetic field. When the flow direction F is blown, the first blade module 3 drives the first rotating shaft 2 to rotate in the first rotating direction C1; the second blade module 6 drives the second rotating shaft 5 to the second rotating direction C2. Rotating, at this time, the first rotor 71 and the second rotor 72 relatively rotate, and the second rotor 72 cuts the magnetic field generated by the first rotor 71, and generates an induced current output, and the induced current can be utilized. Several slip rings (not shown) will be taken out respectively. In practice, the first rotor 71 and the second rotor 72 may also be oppositely designed, that is, the second rotor 72 generates a magnetic field, and the first rotor 71 generates an induced current, which is not limited to the form of the embodiment. .
由於該第一轉子71與該第二轉子72皆會轉動,且往相反方向轉動,使得該第一轉子71與該第二轉子72之間的相對轉動速度將較於第一實施例的轉子42與定子41之間的相對轉動速度有較佳的提升,進而提升發電效率。也正因為本實施例的設計能提升發電效率,因此在設計上,本實施例可相對減少該等第一雙轉發電模組7的數量,或者相對減少每一個第一轉子71與每一個第二轉子72的線圈數量,來節省材料成本,並提供與該第一實施例相同的發電效率,相當符合經濟效益。Since the first rotor 71 and the second rotor 72 both rotate and rotate in opposite directions, the relative rotational speed between the first rotor 71 and the second rotor 72 will be faster than that of the rotor 42 of the first embodiment. The relative rotational speed with the stator 41 is preferably improved, thereby improving power generation efficiency. Also, because the design of the embodiment can improve the power generation efficiency, in the design, the embodiment can relatively reduce the number of the first dual forwarding power modules 7, or relatively reduce each of the first rotors 71 and each of the first The number of coils of the second rotor 72 saves material costs and provides the same power generation efficiency as the first embodiment, which is quite economical.
如此一來,不僅能改善習知葉片受力不均的問題,也能降低材料成本。當然,實施上,若不減少第一雙轉發電模組7的數量,並維持每一個第一轉子71與每一個第二轉子72的線圈數量,則可相對提高本新型的發電效率。In this way, not only can the problem of the uneven force of the conventional blade be improved, but also the material cost can be reduced. Of course, in practice, if the number of the first dual forwarding electrical modules 7 is not reduced and the number of coils of each of the first rotors 71 and each of the second rotors 72 is maintained, the power generation efficiency of the present invention can be relatively improved.
補充說明的是,實施上該第二轉軸5與該第一轉軸2的樞設結構亦可相反設置,亦即該第二轉軸5呈中空圓筒狀,而該第一轉軸2可轉動地間隔樞設於該第二轉軸5內,另外,該第二葉片模組6也可位於該流動方向F的上游處,且該等第二葉片61的葉片長度L2小於該等第一葉片31的葉片長度L1,不以本實施例為限。It is to be noted that the pivoting structure of the second rotating shaft 5 and the first rotating shaft 2 may be oppositely disposed, that is, the second rotating shaft 5 has a hollow cylindrical shape, and the first rotating shaft 2 is rotatably spaced. The second blade module 6 is located in the second rotating shaft 5, and the second blade module 6 is also located upstream of the flow direction F, and the blade length L2 of the second blades 61 is smaller than the blades of the first blades 31. The length L1 is not limited to this embodiment.
參閱圖8,本新型多層葉片式風力發電裝置之另一實施態樣,與第二實施例不同之處在於,該風力發電裝置還可包含一個第三轉軸80、一個第三葉片模組81,及數個第二雙轉發電模組82。該第二轉軸5不穿設於該座體12,改由該第三轉軸80穿設於該座體12,而該第二轉軸5呈中空圓筒狀地間隔套設於該第三轉軸80外。該第三轉軸80的局部區域延伸於外,以供該第三葉片模組81安裝。Referring to FIG. 8 , another embodiment of the novel multi-blade wind power generation device is different from the second embodiment in that the wind power generation device further includes a third rotating shaft 80 and a third blade module 81 . And a plurality of second dual forwarding electrical modules 82. The second rotating shaft 5 is not disposed on the base body 12, and the third rotating shaft 80 is disposed on the base body 12, and the second rotating shaft 5 is sleeved on the third rotating shaft 80 in a hollow cylindrical shape. outer. A partial area of the third rotating shaft 80 extends outside for the third blade module 81 to be mounted.
該第三葉片模組81受到沿該流動方向F的風力驅動時,會連動該第三轉軸80往一個相反於該第二轉動方向的第三轉動方向旋轉,也就是說,該第三轉動方向與該第一轉動方向同向,此時該第一雙轉發電模組7與第二雙轉發電模組82皆會產生感應電流。When the third blade module 81 is driven by the wind in the flow direction F, the third rotating shaft 80 is linked to rotate in a third rotational direction opposite to the second rotational direction, that is, the third rotational direction. In the same direction as the first rotation direction, the first dual forwarding power module 7 and the second dual forwarding power module 82 generate an induced current.
惟以上所述者,僅為本新型之實施例而已,當不能以此限定本新型實施之範圍,凡是依本新型申請專利範圍及專利說明書內容所作之簡單的等效變化與修飾,皆仍屬本新型專利涵蓋之範圍內。However, the above is only the embodiment of the present invention, and when it is not possible to limit the scope of the present invention, all the simple equivalent changes and modifications according to the scope of the patent application and the contents of the patent specification are still This new patent covers the scope.
1‧‧‧基座
11‧‧‧支撐柱
12‧‧‧座體
13‧‧‧第一發電空間
2‧‧‧第一轉軸
21‧‧‧迎風端
22‧‧‧背風端
3‧‧‧第一葉片模組
31‧‧‧第一葉片
311‧‧‧風切面
4‧‧‧單轉發電模組
41‧‧‧普通定子
42‧‧‧普通轉子
5‧‧‧第二轉軸
50‧‧‧第二發電空間
6‧‧‧第二葉片模組
61‧‧‧第二葉片
7‧‧‧第一雙轉發電模組
71‧‧‧第一轉子
72‧‧‧第二轉子
80‧‧‧第三轉軸
81‧‧‧第三葉片模組
82‧‧‧第二雙轉發電模組
C1‧‧‧第一轉動方向
C2‧‧‧第二轉動方向
F‧‧‧流動方向
L1‧‧‧葉片長度
L2‧‧‧葉片長度1‧‧‧Base
11‧‧‧Support column
12‧‧‧ body
13‧‧‧First generation space
2‧‧‧First shaft
21‧‧‧ Windward end
22‧‧‧ leeward end
3‧‧‧First Blade Module
31‧‧‧First blade
311‧‧‧Wind section
4‧‧‧Single forwarding module
41‧‧‧Ordinary stator
42‧‧‧Ordinary rotor
5‧‧‧second shaft
50‧‧‧Second power generation space
6‧‧‧Second blade module
61‧‧‧second blade
7‧‧‧First dual forwarding module
71‧‧‧First rotor
72‧‧‧second rotor
80‧‧‧ Third shaft
81‧‧‧3rd blade module
82‧‧‧Second dual forwarding module
C1‧‧‧First direction of rotation
C2‧‧‧second direction of rotation
F‧‧‧Flow direction
L1‧‧‧ blade length
L2‧‧‧ blade length
本新型之其他的特徵及功效,將於參照圖式的實施方式中清楚地呈現,其中: 圖1是一個立體圖,說明現有的風力發電裝置; 圖2是一個立體圖,說明本新型多層葉片式風力發電裝置的第一實施例; 圖3是一個剖視側視示意圖,說明該第一實施例的內部結構; 圖4是一個前視圖,說明該第一實施例的運轉過程; 圖5是一個立體圖,說明本新型多層葉片式風力發電裝置的第二實施例; 圖6是一個剖視側視示意圖,說明該第二實施例的內部結構; 圖7是一個前視圖,說明該第二實施例的運轉過程;及 圖8是一個剖視側視示意圖,說明本新型多層葉片式風力發電裝置的另一實施態樣。Other features and effects of the present invention will be apparent from the following description of the drawings, wherein: FIG. 1 is a perspective view illustrating a conventional wind power generator; FIG. 2 is a perspective view showing the novel multi-layer blade wind Fig. 3 is a cross-sectional side elevational view showing the internal structure of the first embodiment; Fig. 4 is a front view showing the operation of the first embodiment; Fig. 5 is a perspective view FIG. 6 is a cross-sectional side elevational view showing the internal structure of the second embodiment; FIG. 7 is a front view showing the second embodiment of the second embodiment; The operation process; and FIG. 8 is a cross-sectional side view showing another embodiment of the novel multi-layer blade type wind power generation device.
1‧‧‧基座 1‧‧‧Base
11‧‧‧支撐柱 11‧‧‧Support column
12‧‧‧座體 12‧‧‧ body
2‧‧‧第一轉軸 2‧‧‧First shaft
21‧‧‧迎風端 21‧‧‧ Windward end
22‧‧‧背風端 22‧‧‧ leeward end
3‧‧‧第一葉片模組 3‧‧‧First Blade Module
31‧‧‧第一葉片 31‧‧‧First blade
311‧‧‧風切面 311‧‧‧Wind section
C1‧‧‧第一轉動方向 C1‧‧‧First direction of rotation
F‧‧‧流動方向 F‧‧‧Flow direction
L1‧‧‧葉片長度 L1‧‧‧ blade length
Claims (6)
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CN201621090159.8U CN206419159U (en) | 2015-11-13 | 2016-09-29 | Multilayer blade type wind power generation device |
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TW104218228U TWM518272U (en) | 2015-11-13 | 2015-11-13 | Multi-layer blade type wind power generation device |
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Legal Events
Date | Code | Title | Description |
---|---|---|---|
MM4K | Annulment or lapse of a utility model due to non-payment of fees |