201107594 六、發明說明: 【發明所屬之技術領域】 本發明係關於一種風浪雙效發電裝置,尤指一種可利 用風力以及海浪波動產生電力的風浪雙效發電裝置。 【先前技術】 浪力發電裝置係一種利用海浪波動產生風力,進而推 動渴輪帶動發電機產生電力的發電裝置,請參閱第十— 圖,已知之浪力發電裝置概包含一基座(40)、一涡輪(5〇) 以及一發電機(6),該基座(40)底端形成一進出水口(42), 該基座(4G)近頂側處形成—進出風口(43),該基座(4〇)内部 形成一通道(41)以連通該進出水口(42)以及該進出風口 (43广該發電機(6)設於該基座(4〇)頂側;該渦輪(5〇)設於 該通道⑷)内部該進出風σ(43)處下方,且該渦輪(5〇)的一 軸心部(51)與該發電機(6)的輸出軸相連結。 上述之浪力發電裝置係設於海邊,該基座(4〇)底端沒 入海水中,使該進出水口(42)位於海平面的下方,自該進 出水口(42)處進人基座(4_部的海水氣密於該端的通道 (41)而形成水柱活塞,藉由海浪的波動,該通道(41)内的 水位會上下漲沉,而通道(41)内部上方的空氣便會流動而 推動該渦輪(50)旋轉,進而帶動發電機(6)產生電力。 已知之浪力發電裝置,係利用海水的自然現象來發 電,非以燃燒、核能...等方式來產生電力,因此,除可提 供電力外,對於節能及環境保護實有貢獻,唯該浪力發電 裝置需要利用海浪的波動,因此該進出水口(42)需設置於 海浪起伏較大的海平面處,但若將進出水口(42)的位置設 201107594 置得過高’當海浪波動過大時,海平面容易低於該進出水 口(42),使得海水無法密閉該通道的底端,反而降低發電 效率;其:欠,已知之浪力發電裝置僅利用海浪波動產生電 力’而海面上的風力資源卻未被運用,因&,若能複合一 風力發電裝置有效利用海面上的風力,則可增加發電量。 【發明内容】 發月之主要目的在於提供一種風浪雙效發電裝置, 希望藉^設計,改善水柱活塞的氣密效果以提升發電效 率,其次,複合一風力發電裝置以提升發電量。 為達則揭目的,本發明風浪雙效發電裝置包含: 基座,其内部形成一下凹的弧形通道,該弧形通道 端L伸至該基座—側形成—開口朝上的進出水口該弧 夕通1另糕延伸至該基座頂側之高於進出水口處形成一 進出風口; 一渦輪組件,其設於基座上方,該渦輪組件包含一具 轴、。Ρ的第一渦輪、一第—導流板組、一具有—轉轴 部第二渦輪以及—第二導流板組,該第一渦輪設於基座頂 側近該進出風口處,該第—導流板組設於該第_渦輪外 側該第—導流板組設於該第二渦輪外側;以及 發電裝置,其包含一發電機以及—傳動組件,該第 、渦輪的軸心部與該第二渦輪的轉軸部連結該傳動組件, 並藉該傳動組件連結該發電機。 本發明風浪雙效發電裝置具有以下的優點: 一、該第二滿輪係藉由海面上的風力直接推動旋轉, 並透過聯軸器的連結傳動,帶動發電機產生電力,進 201107594 合一風力發電裝置以提供另一發電來源,提升發電量。 ,二、藉由設置該開口朝上的進出水口,以及下凹的弧 形通道,使得自進出水口流入弧形通道的海水可以留在 弧形通道内側底部,並氣密該端的弧形通道,使水柱活塞 的氣密性*易受海浪波動的影響,進而提升發電效率。 本發明之次一目的係進一步令該傳動組件包含二傘齒 輪以及-聯軸器,該二傘齒輪分別設於該軸心部以及該發 電機之輸出轴’且該二傘齒輪彼此舊合連肖,該聯轴器頂 側固設於該第二渦輪的轉軸部,該傳動組件尚包含一單向 軸承,該單向轴承的外緣卡設於該聯軸器内部,而該單向 軸承的内緣套設於該第一渦輪的軸心部。 藉由該單向輛承的設置’意即該第二渦輪的轉軸部可 以帶動第-渦輪的軸心部旋轉該第一渦輪的軸心部無 法帶動該第二渦輪的轉軸部旋轉,因此,當海面上的風力 不足以帶動該第二渦輪旋轉時,該第一渦輪可獨立旋轉, 該第二渦輪不會成為第一渦輪的負載而增加其轉動慣量, 避免降低第一滿輪的發電效率。 本發明之另一目的係進一步令該弧形通道頂緣底端的 高度等於或低於該進出水口的高度;該弧形通道内部間隔 設有複數隔板,將弧型通道區隔為複數獨立的流道。 因該弧形通道頂緣的底端高度等於或低於該進出水口 的高度,可以進一步降低因海浪波動過大,而使弧形通道 内部的水面低於該頂緣,而造成水柱活塞無法氡密該弧形 通道的情形,進而增加其氣密的效果以提升發電效率;且 該複數隔板將該弧形通道區隔為複數獨立流道,使各獨立 201107594 '流道可獨立作動發電,且因該弧形通道區隔為較小的流 道’減少了因海浪波動不平均所產生的紊流情形,以增加 孤形通道内部近該進出風口處的風力穩定性,更加提升發 電效率。 本發明之再一目的係進一步令該基座一側設有一凸 部’該基座相對該凸部另一側設有一凹部,供基座兩側各 可連結另一基座。藉以利用該凹部與凸部的設置,使得該 基座可側向連結另一基座,進而複數連結而形成一防波堤, 使本發明除了利用自然現象產生電力外,尚具有防波的效 果。 【實施方式】 請參閱第一圖至第六圖所示,為本發明之數種較佳實 施例,並以第一圖至第五圖為第一較佳實施例,其包含一 基座(10)、一渦輪組件(2)以及一發電裝置(3)。 請配合參閱第一圖及第二圖’該基座(1〇)内部形成一 下凹的弧形通道(11),該弧形通道(11) 一端延伸至該基座 (1 〇) —側形成一開口朝上的進出水口( 1 2 ),該弧形通道(11) 另一端延伸至該基座(10)頂側之高於進出水口(12)處形成 一進出風口(13)’在本實施例中,該進出風口(13)方向水 平設置並朝向該進出水口(12)的一側,其中,該弧形通道(n) 頂緣(111)底端的高度可等於或更進一步低於該進出水口 (12)的高度’而該藏形通道(11)内部可進一步間隔設有複 數隔板(14)’將孤形通道(11)區隔為複數獨立的流道;該 基座(10)—侧可設有一凸部(15),該基座(1〇)相對該凸部(15) 另一側可設有一凹部(16),該凹部(16)與凸部(15)係供複數 201107594 基座(1 〇)側向連結時的相卡合處。 請配合參閱第三圖至第五圖’該渦輪組件(2)設於該基 座(1 〇)頂側,該渦輪組件(2)包含一具有一軸心部(22)的第 一渦輪(21) ’以及一具有一轉軸部(25)的第二渦輪(24),該 第一渦輪(21)設於基座(1〇)頂側近該進出風口(13)處,且該 第一渦輪(21)外侧設有一第一導流板組(23),該第二渴輪 (24)外側設有一第二導流板組(26)。 請配合參閱第三圖及第四圖,一發電裝置(3),其包含 一發電機(31)與一傳動組件(32),以及進一步包含一基板(33) 以及一罩體(34)’該基板(33)可設於該第一滿輪(21)頂側, 該罩體(34)設於該基板(33)頂側,該發電機(31)與該傳動組 件(32)設於該基板(33)頂側、並位於該罩體(34)的内側,該 第一渦輪(21)的軸心部(22)向上穿伸該基板(33),而該第二 渦輪(24)可設於該罩體(34)頂側,且該第二渦輪(24)的轉軸 部(25)向下穿伸該罩體(34);該傳動組件(32)可包含二傘齒 輪(321)以及一聯轴裔(322) ’該二伞齒輪(321)分別設於該 第一渦輪(21)的軸心部(22) ’以及該發電機(31)之輸出轴, 且該一傘齒輪(321)彼此唱合連結’該聯軸器(322)兩端分別 連結該第一渦輪(21)的轴心部(22)與該第二渦輪(24)的轉轴 部(25),該第一渴輪(21)的轴心部(22)與該第二渴輪(24)的 轉轴部(25)藉由該傳動組件(32)傳動連結該發電機(31)。 請參閱第六圖所示’為本發明風浪雙效發電裝置之第 一較佳實施例,其除具有上述第一較佳實施例的特徵外, 該傳動組件(32)尚包含一單向軸承(323),在本實施例中, 該聯轴器(322)頂側固δχ於該第二渦輪(24)的轉料部(25), 201107594 該單向軸承(323)外緣卡設於該聯軸器(322)内部近底端處, 而該單向軸承(323)内緣套設於該第一渦輪(21)的軸心部 (22),使得該第一渦輪(21)的軸心部(22)無法帶動該第二渦 輪(24)的轉軸部(25)旋轉’但第二渦輪(24)的轉轴部(25)可 以帶動第一渦輪(21)的軸心部(22)旋轉。 本發明於作動發電時可分為兩個部分,首先第一個部 分疋利用海浪的波動來發電:海浪由該基座的進出水口(12) 進入該弧形通道(1.1)’由於該弧形通道(彳彳)下凹設置使 得自進出水口(12)流入的海水留在該弧形通道(^)的底 部’並形成水柱活塞氣密該弧形通道(11)的一端,請配合 參閱弟七圖及第八圖,當海浪波動上漲時,由於連通管原 理,弧形通道(11)内部的水面也跟著上漲,推動該弧形通 道(11)内部近該進出風口(13)端的空氣,使其形成氣流自 該進出風口(13)流出,自進出風口 〇 3)吹出的風力經由第 一導流板組(23)導流,並推動該第一渦輪(21)旋轉,動力 由軸心部(22)透過傳動組件(32)帶動發電機(3彳)產生電力; 凊配合參閱第九圖及第十圖,當海浪波動下沉時,該弧形 通道内部的水面跟著下沉,使得該弧形通道(彳彳)内部近該 進出風口(13)端形成一負壓,空氣自外部吸入弧形通道 (11),此吸入的風力帶動該第一渦輪(21)旋轉,完成一次 循環。 第二個部分是利用海面上的風力來發電,該吹向第二 渦輪(24)的海風’經由該第二導流板組(26)的導流,推動 該第二渦輪(24)旋轉,並藉由該轉轴部(25)連動與其連結 的軸心部(22),進而帶動發電機(31)產生電力。 201107594 由前揭敘述可知,本發明風浪雙效發電裝置可以利用 海浪以水柱活塞的方彳Λ α J万式來發電,且可直接利用海面上的風201107594 VI. Description of the Invention: [Technical Field] The present invention relates to a wind-wave dual-effect power generation device, and more particularly to a wind-wave dual-effect power generation device that can generate electricity by using wind power and wave fluctuations. [Prior Art] A wave power generation device is a power generation device that generates wind power by wave fluctuations, and then drives a thirteen wheel to drive a generator to generate electric power. Please refer to the tenth-figure, the known wave power generation device includes a base (40). a turbine (5〇) and a generator (6), the bottom end of the base (40) forms an inlet and outlet (42), and the base (4G) forms an inlet and outlet (43) at a near top side, A base (41) is formed inside the base (4) to communicate the inlet and outlet (42) and the inlet and outlet (43) the generator (6) is disposed on the top side of the base (4〇); the turbine 5〇) is disposed below the inlet and outlet σ(43) inside the passage (4), and an axial portion (51) of the turbine (5〇) is coupled to an output shaft of the generator (6). The above-mentioned wave power generating device is disposed at the seaside, and the bottom end of the pedestal (4 〇) is immersed in the seawater, so that the inlet and outlet (42) is located below the sea level, and the pedestal is inserted from the inlet and outlet (42). (The water in the 4th part is airtight to the channel (41) at the end to form a water column piston. By the fluctuation of the waves, the water level in the channel (41) will rise and fall, and the air above the inside of the channel (41) will The flow causes the turbine (50) to rotate, which in turn drives the generator (6) to generate electricity. The known wave power generation device uses the natural phenomenon of seawater to generate electricity, and does not generate electricity by means of combustion, nuclear energy, etc. Therefore, in addition to providing electricity, it contributes to energy conservation and environmental protection. Only the wave power generation device needs to use the fluctuation of the waves, so the inlet and outlet (42) should be placed at a sea level where the waves are undulating, but if Set the inlet and outlet (42) position to 201107594 too high. 'When the wave is too large, the sea level is easily lower than the inlet and outlet (42), so that the seawater cannot seal the bottom end of the channel, but reduce the power generation efficiency; Owe, known The wave power generation device generates electricity by using only wave fluctuations, and the wind resources on the sea surface are not used. If a wind power generation device can effectively utilize the wind power on the sea surface, the power generation amount can be increased. The main purpose of the month is to provide a wind and wave double-effect power generation device. It is hoped that the airtight effect of the water column piston will be improved by the design to improve the power generation efficiency. Secondly, a wind power generation device will be combined to increase the power generation. The invention relates to a wind-wave double-effect power generation device comprising: a base, the inside of which forms a concave curved passage, the curved passage end L extends to the base-side forming-opening upward-facing inlet and outlet port, the arc-shaped passage is extended by another cake An inlet and outlet port is formed at a top side of the base higher than the inlet and outlet; a turbine assembly is disposed above the base, the turbine assembly includes a shaft, a first turbine, and a first deflector group a second turbine having a shaft portion and a second deflector group, wherein the first turbine is disposed at a top side of the base near the inlet and outlet, and the first deflector is disposed at the first turbine a side of the first deflector assembly disposed outside the second turbine; and a power generating device including a generator and a transmission assembly, the shaft portion of the first turbine and the shaft portion of the second turbine coupled to the transmission assembly And the transmission component is connected to the generator. The wind-wave double-effect power generation device of the invention has the following advantages: 1. The second full-wheel train is directly driven to rotate by the wind on the sea surface, and is transmitted through the coupling of the coupling. Drive the generator to generate electricity, enter 201107594 to integrate the wind power generation device to provide another source of power generation, increase the power generation. Second, make the inlet and outlet through the opening, and the concave curved channel, so that the water inlet and outlet The seawater flowing into the curved passage can be left at the bottom of the inner side of the curved passage, and the arc-shaped passage at the end is airtight, so that the airtightness of the water column piston is easily affected by the fluctuation of the wave, thereby improving the power generation efficiency. A second object of the present invention is to further comprise the transmission assembly comprising two bevel gears and a coupling, wherein the two bevel gears are respectively disposed on the shaft center and the output shaft of the generator, and the two bevel gears are connected to each other. Shaw, the top side of the coupling is fixed to the rotating shaft portion of the second turbine, and the transmission assembly further includes a one-way bearing, the outer edge of the one-way bearing is clamped inside the coupling, and the one-way bearing The inner edge is sleeved on the axial center of the first turbine. The arrangement of the one-way bearing means that the shaft portion of the second turbine can rotate the shaft portion of the first turbine and the shaft portion of the first turbine cannot rotate the shaft portion of the second turbine. When the wind on the sea surface is insufficient to drive the second turbine to rotate, the first turbine can rotate independently, and the second turbine does not become the load of the first turbine to increase its moment of inertia, thereby avoiding reducing the power generation efficiency of the first full wheel. . Another object of the present invention is to further make the height of the bottom end of the top edge of the curved channel equal to or lower than the height of the inlet and outlet; the arc channel is internally spaced by a plurality of partitions, and the arc channel is divided into a plurality of independent Flow path. Since the height of the bottom end of the top edge of the curved passage is equal to or lower than the height of the inlet and outlet, the fluctuation of the wave is too large, so that the water surface inside the curved passage is lower than the top edge, and the water column piston cannot be densely closed. The situation of the curved channel further increases the airtight effect to improve the power generation efficiency; and the plurality of partitions divide the curved passage into a plurality of independent flow passages, so that the independent 201107594 'flow passages can independently generate electricity, and Because the arc channel is divided into smaller flow passages, the turbulence caused by the uneven wave fluctuation is reduced, so as to increase the wind stability near the inlet and outlet of the orphan passage, and further improve the power generation efficiency. A further object of the present invention is to further provide a protrusion on one side of the base. The base is provided with a recess on the other side of the protrusion for connecting the other base on each side of the base. By using the recesses and the projections, the pedestal can be laterally coupled to the other pedestal, thereby forming a breakwater by a plurality of connections, so that the present invention has an effect of preventing waves in addition to generating electricity by natural phenomena. [Embodiment] Please refer to the first to sixth embodiments, which are preferred embodiments of the present invention, and the first to fifth figures are a first preferred embodiment, which includes a pedestal ( 10), a turbine assembly (2) and a power generating device (3). Please refer to the first figure and the second figure. The inside of the base (1〇) forms a concave curved passage (11), and one end of the curved passage (11) extends to the base (1 〇) to form a side. An opening and closing opening (1 2 ), the other end of the curved passage (11) extends to a top side of the base (10) higher than the inlet and outlet (12) to form an inlet and outlet (13)' In an embodiment, the inlet and outlet vent (13) is horizontally disposed and faces one side of the inlet and outlet (12), wherein the height of the bottom end of the curved edge (n) of the top edge (111) may be equal to or lower than the height The height of the inlet and outlet (12) is further spaced apart from the inside of the storage passage (11) by a plurality of partitions (14)' to separate the orphan passage (11) into a plurality of independent flow passages; the base (10) The side may be provided with a convex portion (15), and the base (1〇) may be provided with a concave portion (16) on the other side of the convex portion (15), and the concave portion (16) and the convex portion (15) are provided for Plural 201107594 The pedestal (1 〇) is engaged at the side of the joint. Referring to Figures 3 to 5, the turbine assembly (2) is disposed on the top side of the base (1), and the turbine assembly (2) includes a first turbine having an axial center (22) ( 21) 'and a second turbine (24) having a shaft portion (25) disposed at a top side of the base (1) near the inlet and outlet port (13), and the first turbine (21) A first baffle set (23) is disposed on the outer side, and a second baffle set (26) is disposed on the outer side of the second thirsty wheel (24). Please refer to the third and fourth figures, a power generating device (3) comprising a generator (31) and a transmission component (32), and further comprising a substrate (33) and a cover (34) The substrate (33) may be disposed on a top side of the first full wheel (21), the cover body (34) is disposed on a top side of the substrate (33), and the generator (31) and the transmission component (32) are disposed on the substrate a top side of the substrate (33) and located inside the cover (34), the axial portion (22) of the first turbine (21) extends upwardly through the substrate (33), and the second turbine (24) The cover body (34) may be disposed on a top side of the cover body (34), and the rotating shaft portion (25) of the second turbine (24) extends downwardly through the cover body (34); the transmission assembly (32) may include two bevel gears (321) And a coupling shaft (322) 'the two bevel gears (321) are respectively disposed at an axial portion (22) of the first turbine (21) and an output shaft of the generator (31), and the umbrella The gears (321) are singly coupled to each other. The two ends of the coupling (322) respectively connect the axial center portion (22) of the first turbine (21) and the rotating shaft portion (25) of the second turbine (24). The axial portion (22) of the first thirsty wheel (21) and the first The shaft portion (25) of the second thirsty wheel (24) is coupled to the generator (31) by the transmission assembly (32). Referring to FIG. 6 , a first preferred embodiment of the wind-wave dual-effect power generation device of the present invention, in addition to the features of the first preferred embodiment, the transmission assembly (32) further includes a one-way bearing. (323), in this embodiment, the top side of the coupling (322) is fixed to the material of the second turbine (24), and the outer edge of the one-way bearing (323) is The inner end of the coupling (322) is near the bottom end, and the inner edge of the one-way bearing (323) is sleeved on the axial portion (22) of the first turbine (21), so that the first turbine (21) The shaft center portion (22) cannot rotate the shaft portion (25) of the second turbine (24), but the shaft portion (25) of the second turbine (24) can drive the shaft portion of the first turbine (21) ( 22) Rotate. The present invention can be divided into two parts during the operation of power generation. First, the first part 疋 uses the fluctuation of the waves to generate electricity: the waves enter the curved channel (1.1) from the inlet and outlet (12) of the pedestal. The channel (彳彳) is recessed so that the seawater flowing in from the inlet and outlet (12) remains at the bottom of the curved channel (^) and forms one end of the water column piston that is airtight to the curved channel (11). In the seventh and eighth figures, when the wave fluctuations rise, due to the principle of the connecting pipe, the water surface inside the curved channel (11) also rises, pushing the air inside the curved channel (11) near the inlet and outlet (13), The airflow is formed to flow out from the air inlet and outlet (13), and the wind blown from the air inlet and outlet port 3) is guided by the first deflector group (23), and the first turbine (21) is driven to rotate, and the power is controlled by the shaft center. The part (22) drives the generator (3彳) to generate electric power through the transmission component (32); 凊 cooperate with the ninth and tenth figures, when the waves fluctuate and sink, the water surface inside the curved passage follows, so that The curved channel (彳彳) is close to the inside Outlet (13) forming a negative pressure side, air suction from the outside arcuate channel (11), which drives the first intake wind turbine (21) is rotated, to complete a cycle. The second part is to generate electricity by using wind power on the sea surface, and the sea breeze blowing to the second turbine (24) pushes the second turbine (24) to rotate through the diversion of the second baffle group (26). The shaft portion (22) connected thereto is interlocked by the shaft portion (25), thereby driving the generator (31) to generate electric power. 201107594 It can be seen from the foregoing that the wind wave double-effect power generation device of the present invention can use the sea wave to generate electricity by using the water column piston, and can directly utilize the wind on the sea surface.
力來產生電力’進而充分運用大自然的動力資源、;苴次, 因該弧形通道⑴)下凹且其開口向上,使得㈣出:口進 入的海水W形通道⑴)内側底部,保持該端弧形通道 ⑴)的以H且該弧形通道⑴)頂緣⑴彳)的底端高度 荨於或低於該進出水口 (12)的高度’彳降低因海浪大幅波 動’而使弧形通道⑴)㈣的水面低於該頂緣(11彳),造成 :柱活塞無法氣密該弧形通道(11)的情形,進而增加其氣 岔的效果以提升發電效率;而弧形通道⑴)内的複數隔板 (1二,係用以將該狐形通道⑴)内部區隔為複數獨立空間, 使得各個獨立空間可分開獨立作動,由於將該弧形通道。” 區隔為較小的通道,可減少因海浪波動不平均產生的紊流 情,’以增加弧形通道⑴)内部近進出風口(13)處的風力 穩定性,以提升發電效率;並藉由單向軸承(323)的設置, 利用其單向連結的特點,使得當海面上風力不足而無法帶 動第二渴輪(24)時,該第二渦輪(24)不會成為第—滿輪(21) 額外的負載而增加其慣性質量,進而提升其發電效率。 【圖式簡單說明】 第—圖:為本發明風浪雙效發電裝置之第一較佳實施 例的立體分解圖。 第二圖:為本發明風浪雙反裝置之第一較佳實施 例的立體外觀圖。 第三圖:為本發明風浪雙效發電裝置第一較佳實施例 之渴輪組件與發電裝置的立體分解圖。 201107594 '第四圖:為本發明風浪雙效發電裝置第一較佳實施例 之滿輪组件與發電裝置的蚯合剖面圖。 較佳實施例 第五圖··為本發明風浪雙效發電裝置第— 之渦輪組件的俯視示意圖。 ^六圖··為本發明風浪雙效發電農置第二較佳實施例 之/尚輪組件與發電裝置的組合剖面圖。 弟七圖.為本發明風浪雙效發電穸窨坌 之作飭壯u 电装置第-較佳實施例Force to generate electricity' and then make full use of nature's power resources; 苴 times, because the curved channel (1)) is concave and its opening is upward, so that (4) out: the inner bottom of the seawater W-shaped channel (1)), keep the The height of the bottom end of the end curved passage (1)) and the height of the bottom edge (1) of the curved passage (1)) is lower or lower than the height of the inlet and outlet (12). The water surface of channel (1)) (4) is lower than the top edge (11彳), causing: the column piston can not airtight the arc channel (11), thereby increasing its gas venting effect to improve power generation efficiency; and the curved channel (1) The plurality of partitions (1, in order to separate the interior of the fox-shaped channel (1)) into a plurality of independent spaces, so that the individual spaces can be independently operated independently, due to the curved passage. The division is a smaller passage, which can reduce the turbulence caused by uneven wave fluctuations, 'to increase the wind stability at the internal inlet and outlet (13) of the curved passage (1) to improve power generation efficiency; By the arrangement of the one-way bearing (323), the characteristics of the one-way connection make the second turbine (24) not become the first full wheel when the wind is insufficient on the sea surface to drive the second thirsty wheel (24). (21) Increasing the inertia mass of the additional load, thereby increasing the power generation efficiency. [Simplified illustration] Fig.: is an exploded perspective view of the first preferred embodiment of the wind wave double-effect power generation device of the present invention. Figure: is a perspective view of the first preferred embodiment of the wind wave double reverse device of the present invention. The third figure is an exploded perspective view of the thirsty wheel assembly and the power generating device of the first preferred embodiment of the wind wave double effect power generating device of the present invention. 201107594 'Fourth view: a cross-sectional view of the full-wheel assembly and the power generating device of the first preferred embodiment of the wind-wave dual-effect power generating device of the present invention. The fifth embodiment of the present invention is a dual-effect power generation of the present invention. Device number - Schematic diagram of a turbine assembly. Figure 6 is a combined sectional view of a wind turbine dual-effect power planting second preferred embodiment of a still-wheel assembly and a power generating device.穸窨坌 饬 u u 电 电 电 电 电 电 电 电 电 电
作動狀態的剖面示意圖(一)。 第八圖:為第七圖中第-較佳實施例的俯視示音圖。 為本發明風浪雙效發電袭置第—較佳實㈣ 作動狀態的剖面示意圖(二)。Schematic diagram of the active state (1). Figure 8 is a top view of the first preferred embodiment of the seventh embodiment. This is a schematic cross-sectional view of the wind-wave double-effect power generation of the present invention, which is the best (4) active state (2).
第十圖:為第九圖中第一較佳實施例的俯視示意圖 第十-圖:為習知浪力發電裝置的剖面示意圖。 【主要元件符號說明】 (1 〇)基座 (111)頂緣 (1 3)進出風口 (15)凸部 (2) 渦輪组件 (22)轴心部 (24)第二渦輪 (26)第二導流板組 (3) 發電裝置 (32)傳動組件 (322)聯轴器 (11) 弧形通道 (12) 進出水口 (14)隔板 (1 6)凹部 (21)第—渦輪 (23)第—導流板組 (2 5)轉轴部 (31)發電機 (321)傘齒輪 (323)單向軸承 201107594 (33)基板 (40)基座 (42)進出水口 (50)渦輪 (6)發電機 (34)罩體 (41)通道 (43)進出風口 (51)軸心部10 is a top plan view of a first preferred embodiment of the ninth embodiment. FIG. 10 is a schematic cross-sectional view of a conventional wave power generating device. [Main component symbol description] (1 〇) pedestal (111) top edge (1 3) inlet and outlet vent (15) convex part (2) turbine assembly (22) axial part (24) second turbine (26) second Deflector group (3) Power generation unit (32) Transmission unit (322) Coupling (11) Curved passage (12) Inlet and outlet (14) Partition (16) Concave (21) No. - Turbine (23) First - deflector group (2 5) shaft part (31) generator (321) bevel gear (323) one-way bearing 201107594 (33) base plate (40) base (42) inlet and outlet (50) turbine (6 ) generator (34) cover (41) channel (43) inlet and outlet (51) shaft center
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