200937807 九、發明說明: 【發明所屬之技術領域】 本發明係與磁能轉換裝置有關,更詳而言之,特別是 指一種可提供傳動裝置之高效能磁能轉換裝置。 【先前技術】 按,將線圈與磁鐵組成,而由該等磁鐵提供之不同磁 極與該等感應線圈組相互產生感應作用,可產生磁能,早 期即有使用於電刷換向的電動機,例如參看美國專利第 3988024號、第 4361776號、第 4371801 號和第 5146144號, 在這種電動機裡一帶有交替安裝的N極及S極的磁性轉子圓 盤在包含若干扁平的相鄰設置的定子線圈的一個平面之上 和下轉動,在線圈導線裡的電流與圓盤發出的交替的磁通 線相互作用,產生與徑向上的導體垂直,雖然電流通過整 個線圈’但只有導體的徑向延伸部分有助於扭轉轉子,再 參看美國專利US第4068143號、第4420875號、第4551645號 和第4743813號,雖然這種結構之導體緊密安裝,但其轉子 磁鐵和磁通回路之間的間隙約是非重疊線圈厚度的兩倍, 由此降低了磁通密度’進而也降低了電動機效率。 再請參閱美國公報US 5744896號,係排列交錯及重疊 文裝多個線圈形成一薄的盤型線圈陣列,具有非重疊線圈 陣列的雙倍密度,但其相鄰重疊處具有空隙,故也降低了 提供電動機之效率,且該等必須設置預定形狀之導體,然 後分別纏繞設圈,故於加工製程上複雜,且生產成本過高。 【發明内容】 、处,發明係提供一種高效能磁能轉換裝置,係至少由一 磁月b單元組成,該磁能單元係包含有數感應線圈組每一 200937807 、 感應線圈組係將線材沿一預定方向同心纏繞形成數線圈而 成,使其中心具有一中空部,而外周面則形成一導磁部, 該等感應線圈組係連續排列設置,並圍設有一固定件,使 該等感應線圈組相互固定,並於對應該等導磁部一侧面設 有至少一磁性元件。 本發明所提供之高效能磁能轉換裝置,藉由該磁性元 件係設置於對應該等線圈纏繞密度最高之導磁部,使在同 樣單位面積内能產生更高電壓或能以最低電流即能產生動 力’達到高效率使用目的。 ®【實施方式】 首先,請參閱第一圖所示,係為本發明一種高效能磁 能轉換裝置之較佳實施例之立體圖,係由一具有磁能轉換 之磁能單元100與一傳動裝置結合組成,該傳動裝置係藉由 一傳動軸設置於該磁能單元100之中心軸上,而該傳動裝置 可為一電動車,或該傳動裝置係可設置於該磁能單元100之 外周侧上,而該傳動裝置可為一風力發電器,如葉片組, 以利用磁能驅動該傳動裝置作動,該磁能單元丨00係包含有 數感應線圈組10及二磁性元件2 〇 ;其中: 該等感應線圈組10 ’每一感應線圈組1〇係可將線材沿 一徑向方向同心纏繞形成數扁狀之橢圓形或矩形線圈丨1, 於本實施例係纏繞形成數扁狀之橢圓形線圈1丨,使其中心 具有一中空部12,而外周面則形成一導磁部13,該等感應 線圈組10係連續縱向排列設置,其外周面並繞設有一固定 件30,使該等感應線圈組1 〇相互固定。 該等磁性元件20 ’主要包含有數磁性片21連續排列所 200937807 組成,該等磁性片21係分別對應該等感應線圈組10之導磁 部13之相對兩側面,該等磁性片21係由數永久磁鐵構成連 續排列組成。 為供進一步瞭解本發明構造特徵、運用技術手段及所 預期達成之功效,茲將本發明使用方式加以敘述,相信當 可由此而對本發明有更深入且具體之瞭解,如下所述: 於作動時,藉由該等磁性片21對應該等感應線圈組1 〇 最大之線圈11面積之導磁部13’而由該等磁性片21提供之 ❹不同磁極與該等感應線圈組1〇相互產生感應作用,且藉由 該等感應線圈組1 〇線圈密集之纏繞設置’從而增加導磁部 13與該等磁性片21之間交互作用,且使該等磁性片21經過 相鄰之導磁部13間時’減少了該等磁性片21對導磁部丨3產 生磁場造成之換向震動力,而使其平順運作,並在單位時 間内磁性片21和感應線圈組1〇達到最大感應面積,提供該 傳動裝置之尚效能功率變換。 凊參閱第二至三圖所示,係為本發明之第二實施例之 ❹頂視局部剖面圖與立體圖,該磁能單元剛之每一感應線屡 組10係將線材沿徑向方向同心纏繞形成數扁狀之橢圓形鱗 圈11,其軸向之中心則具有該中空部12,而外周面由該考 線圈11形成該導磁部13,該等感應線圈組1〇係分別呈直力 ί L而0=同一中心轴a等距連續環設排列,使該等感應讀 ==細處為中空,該中心轴3可供穿置該傳㈣ 且咱參閱第四至五圖所示 --叫’’丨小,>丨尔冗別兩尽發明第二』 例之局部放大圖與侧視圖’該等感應線圈組1叫周面 200937807 設有一固定件30,使該等感應線圈組10相互固定,而該等 磁性元件20係設置於對應該等感應線肋1G之導磁部】3上 側面及下側面,且每一磁性片21係可對應該等感應線圈組 10纏繞形狀設置,形朗應該料磁部13之雜,使該磁 能单元100形成一環形盤體。 ❹ 请參閱第六圖所示’係為本發明第二實施例之剖視 圖’於本實施例中,該磁能單元丨_與該電動車結合兮 等分別相對位於每一感應線圈組10上、下側面之磁性片^ 另侧面係分別固定於-轉盤40與一第一隔板41侧壁上,而 該等感應線圈組10並固定於一第二隔板5〇上且該轉 40、第-隔板41與第二隔板5〇中心係為中空以供該傳動裝 置之傳動軸60穿置組裝,使該轉盤4〇與該第一隔板4ι可於 該傳動軸60上轉動’而第二隔板5()係固定於該傳動轴⑼ 上,並於該磁性片21於固定前,將其除了對應該導磁部13 側面之外周面固定有一金屬材料製成之遮蔽罩7〇,以使磁 力集中在該等感應線圈組1〇之導磁部13上,於作動 由^等磁性片21對應該等感應線圈組1〇最大之線圈 之導磁部13,而由該等磁性片21提供之不同磁極與該等感 應線圈組ίο相互產生感應作用,而使該等磁性片21帶動該 續向動作’且藉由該等感應線圈組;。 線圈後集之纏如设置,從而增加導磁部13與 之間交互作用。 ^ 請參閱第七至八圖所示,係為本發明第三實施例之立 體圖與侧視圖’本實施例係利用第二實施例之磁能單元⑽ 而設置兩組,該等磁能單元100係沿傳動轴6〇互相重_置 而形成複數層,且該等磁能單元1〇〇之感應線圈組ι〇ς磁性 200937807 片21互相間交錯設置,使該等位於各磁能單元100上之感應 線圈組10與磁性片21互相間形成一適當之交錯角度少,且 該等感應線圈組10之導磁部13四周側面上分別設有對應之 磁性片21,而設置於每一感應線圈組1〇上、下侧面之磁性 元件20係對應其最大面積之導磁部13,且設置於該等導磁 部13上、下側面之該等磁性片21係分別固定於該轉盤4〇及 第隔板41上,而设置於該等導磁部13另兩侧面之磁性片 21係分別固定於該轉盤40上設置之分隔板42上,該等感應 ❹線圈組10係固定於該第二隔板50上,使該等磁性片21形成 一封閉式磁場,對感應線圈組10產生最大的感應作用。 請參閱第九圖所示,係為本發明第四實施例之側視 圖,本實施例係利用第二實施例之磁能單元1〇〇而設置兩 組,該等磁能單元100係可沿其中心軸a環繞設置由小到大 圈而環繞複數圈,形成漸層排列設置。 請參閱第十圖所示,係為本發明第五實施例之側視 圖,本實施例之磁能單元丨〇〇之每一感應線圈組1〇係利用該 等線材沿徑向方向同心連續纏繞形成數扁狀之橢圓形線 圈’該專感應線圈組1 〇係分別縱向設置而圍繞該同一中心 等距連續環設排列,長邊並對應中心軸a,而使設置於 母一感應線圈組1 〇前、後侧面之磁性元件2 〇係對應其最大 面積之導磁部13,於本實施例並設有兩組磁能單元1〇〇,其 係沿中心軸a互相對準重疊設置而形成複數層,且相鄰間係 隔設有該轉盤40,且該等感應線圈組1〇之導磁部13周側面 上分別設有對應之磁性片21,設置於該等導磁部Η上、下 側面之該等磁性片21係分別固定於該轉盤4〇及第一隔板4i 上,而β又置於該專導磁部13另兩侧面之磁性片21係分別固 200937807 定於該轉盤40上設置之分隔板42上,該等感應線圈組l〇係 固定於該第二隔板50上’使該等磁性片21形成一封閉式磁 場’對感應線圈組10產生最大的感應作用,而於本實施利 中’係設置有兩組磁能單元100,該等磁能單元1 〇〇係沿其 中心軸a設置由小到大圈而環繞複數圈,形成漸層排列設 置。 請參閱第Ί—圖所示,係為本發明第六實施例之頂視 圖’每一感應線圈組10係利用數線材沿徑向方向同心連續 ❺纏繞形成數扁狀之橢圓形線圈11,該等感應線圈組10係分 別沿徑向設置而圍繞該傳動軸60連續排列,且該等感應線 圈10組間分別具有一夾角,可供放置一次感應線圈組8〇, 且該等磁性元件20係相對設置於對應該等感應線圈組1 〇與 次感應線圈組80之中空部12、81,而使設置於每一感應線 圈組10及每一次感應線圈組80上、下側面之磁性元件20係 對應其最大面積之導磁部13,且於該等磁性片21外周圍並 一體圍設有該遮蔽罩70。 請參閱第十二圖所示,係為本發明第七實施例之頂視 ❿圖’本實施例係利用第六實施例之磁能單元1 〇 〇而設置兩 組’該等磁能單元100係沿其中心軸a設置由小到大圈而環 繞複數圈,形成漸層排列設置。 請參閱第十三圖所示,係為本發明第八實施例之頂視 圖’該等感應線圈組10係分別沿徑向設置而圍繞該傳動軸 60連續排列,且該等感應線圈組1〇間分別具有一夾角,而 該等磁性片21係設置於對應該等感應線圈組1〇之中空部12 上,且對應每一感應線圈組1 〇形狀亦設有一中空部22,且 每一磁性片21外周圍並分別圍設有該遮蔽罩70。 200937807 茲,再將本發明之特徵及其可達成之預期功效陳述如 下: 1、本發明之該等感應線圈組係連續排列設置,並於 對應該等導磁部一側面設有至少一磁性元件,該磁性元件 係設置於對應該等線圈纏繞密度最高之導磁部位置,藉由 該等感應線圈姐線圈密集之纏繞設置,從而增加導磁部與 該等磁性片之間交互作用,且使該等磁性片經過相鄰之導 磁部間時,減少了該等磁性片對導磁部產生磁場造成之換 ❺向震動力’且’使在同樣單位面積内能產生更高電壓或能 以最低電流即能產生動力’且在最小體積内使線圈的密度 利用率達到最高,而使其平順運作,提供該發電機與電動 機之高效能功率變換。 2、 本發明之磁性片外侧面固定有一金屬材料製成之 遮蔽罩,以使磁力集中在該等感應線圈組之導磁部上。 3、 每一磁性片係與每一感應線圈組成之預定之錯位 角度,以交替之方式緊密重疊,並節省動能。 φ ,综上所述’本發明在同類產品中實有其極佳之進步實 同時遍查國内外關於此類結構之技術資料,文獻中 亦未發現有相同的構造在方尤杰 β 子在在先’疋以’本發明實已且備 發明專利要件,爰依法提出申請。 〜備 淮,以上所述者,僅係本發一 _ 已,故與Π處丄 ^較佳可仃實施例而 結構變I 座發明說明書及申請專利範圍所為之等效 構變化,理應包含在本發明之專利範圍内。 11 200937807 【圖式簡單說明】 第一圖係為本發明較佳實施例之立體圖。 第二圖係為本發明較佳實施例之頂視局部剖面圖。 第二圖係為本發明較佳實施例之立體圖。 第四圖係為本發明第二實施之局部放大圖。 第五圖係為本發明第二實施例之側視圖。 第六圖係為本發明第二實施例之頂視圖。 第七圖係為本發明第三實施例之立體圖。 © 第八圖係為本發明第三實施例之侧視圖。 第九圖係為本發明第四實施例之侧視圖。 第十圖係為本發明第五實施例之侧視圖。 第十一圖係為本發明第六實施例之頂視圖。 第十二圖係為本發明第七實施例之頂視圖。 第十二圖係為本發明第八實施例之頂視圖。 【主要元件符號說明】 ❹〔本發明〕 10 感應線圈組 11 線圈 12 中空部 13 導磁部 20 磁性元件 21 磁性片 22 中空部 30 固定件 40 轉盤 41 第一隔板 42 分隔板 12 200937807 50 60 70 80 81 100 a Φ 第二隔板 傳動轴 遮蔽罩 次感應線圈組 中空部 磁能單元 中心軸 錯位角度 13BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetic energy conversion device, and more particularly, to a high-performance magnetic energy conversion device that can provide a transmission. [Prior Art] Press, the coil and the magnet are composed, and the different magnetic poles provided by the magnets and the induction coils mutually induce each other to generate magnetic energy. In the early stage, there is a motor for brush commutation, for example, see U.S. Patent Nos. 3,984,024, 4,361,776, 4,317,801 and 5,146,144, in which a magnetic rotor disk with alternatingly mounted N and S poles is comprised of a plurality of flat, adjacently disposed stator coils. Rotating above and below a plane, the current in the coil wire interacts with the alternating flux lines from the disk, creating a perpendicular to the conductor in the radial direction, although current flows through the entire coil' but only the radially extending portion of the conductor has For the purpose of twisting the rotor, see U.S. Patent Nos. 4,406,143, 4,420,875, 4,516,445 and 4,743,813. Although the conductor of this structure is closely mounted, the gap between the rotor magnet and the flux loop is approximately non-overlapping. Double the thickness of the coil, thereby reducing the magnetic flux density' and thus the motor efficiency. Referring also to US Pat. No. 5,744,896, a plurality of coils are arranged in a staggered and overlapping manner to form a thin disc-shaped coil array having a double density of non-overlapping coil arrays, but having gaps adjacent to each other, thereby also reducing The efficiency of the motor is provided, and the conductors of a predetermined shape must be disposed, and then the coils are wound separately, so that the processing process is complicated and the production cost is too high. SUMMARY OF THE INVENTION The present invention provides a high-performance magnetic energy conversion device, which is composed of at least one magnetic moon b unit, the magnetic energy unit includes a plurality of induction coil groups each of 200937807, and the induction coil group connects the wires in a predetermined direction. The concentric winding is formed by forming a plurality of coils, such that the center has a hollow portion, and the outer peripheral surface forms a magnetic guiding portion, and the inductive coil groups are arranged in series, and a fixing member is arranged to make the induction coil groups mutually Fixed, and at least one magnetic element is disposed on one side of the corresponding magnetic conductive portion. The high-performance magnetic energy conversion device provided by the present invention can be produced by providing a higher voltage in the same unit area or capable of generating the lowest current in the same magnetic field by the magnetic component of the coil having the highest coil winding density. Power 'to achieve high efficiency use purposes. ® [Embodiment] First, referring to the first figure, a perspective view of a preferred embodiment of a high-performance magnetic energy conversion device of the present invention is composed of a magnetic energy conversion unit 100 having magnetic energy conversion and a transmission device. The transmission device is disposed on a central axis of the magnetic energy unit 100 by a transmission shaft, and the transmission device can be an electric vehicle, or the transmission device can be disposed on an outer circumferential side of the magnetic energy unit 100, and the transmission is The device may be a wind power generator, such as a blade group, for driving the transmission device by using magnetic energy. The magnetic energy unit 丨00 includes a plurality of induction coil groups 10 and two magnetic elements 2 〇; wherein: the induction coil groups 10' each An induction coil group 1 can be wound concentrically in a radial direction to form a plurality of flat elliptical or rectangular coils 1 , which are wound in the present embodiment to form a plurality of flat elliptical coils 1 丨 to the center thereof. A hollow portion 12 is formed, and a magnetic conductive portion 13 is formed on the outer peripheral surface. The induction coil groups 10 are continuously arranged in a longitudinal direction, and a fixing member 30 is disposed around the outer peripheral surface to make the senses Group 1 square coil fixed to each other. The magnetic elements 20' mainly comprise a plurality of magnetic sheets 21 which are arranged in a continuous arrangement of 200937807, and the magnetic sheets 21 respectively correspond to opposite sides of the magnetic conductive portion 13 of the induction coil group 10, and the magnetic sheets 21 are numbered The permanent magnets are composed of a continuous arrangement. In order to further understand the structural features, the technical means, and the intended effects of the present invention, the manner of use of the present invention will be described. It is believed that the present invention may be more deeply and specifically understood as follows: By the magnetic sheets 21, the magnetic poles 13 of the area of the coil 11 that are the largest of the induction coil group 1 are aligned, and the different magnetic poles provided by the magnetic sheets 21 and the induction coil groups 1 〇 are mutually induced. The interaction between the magnetic coils 13 and the magnetic sheets 21 is increased by the intensive winding of the coils of the induction coils 1 and the magnetic sheets 21 are passed through the adjacent magnetic portions 13 . During the time period, the reversing vibration force caused by the magnetic field generated by the magnetic sheets 21 on the magnetic conductive portion 丨3 is reduced, so that the smooth operation is performed, and the magnetic sheet 21 and the induction coil group 1 〇 reach the maximum sensing area per unit time. A performance power conversion of the transmission is provided. Referring to the second to third figures, a top cross-sectional view and a perspective view of a second embodiment of the present invention, the magnetic energy unit is formed by a series of 10 series of wires in a radial direction. The flat elliptical scale ring 11 has the hollow portion 12 at the center of the axial direction, and the outer peripheral surface is formed by the test coil 11 to form the magnetic conductive portion 13, and the induction coil group 1 is respectively a direct force ί L and 0 = the same central axis a equidistant continuous ring arrangement, so that the inductive reading == fine is hollow, the central axis 3 can be used to pass the transmission (4) and see the fourth to fifth figures -- Called ''丨小,' 丨 冗 冗 两 两 发明 发明 发明 』 』 』 』 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 局部 该 该 该 该 该 该 该The magnetic elements 20 are fixed to each other, and the magnetic elements 20 are disposed on the upper side and the lower side of the magnetic conductive portion 3 of the sensing line rib 1G, and each of the magnetic sheets 21 can be arranged in a winding shape corresponding to the induction coil group 10. The shape of the magnetic portion 13 is such that the magnetic energy unit 100 forms an annular disk. ❹ Referring to FIG. 6 is a cross-sectional view of a second embodiment of the present invention. In the present embodiment, the magnetic energy unit 丨 _ is coupled to the electric vehicle, and is respectively located on each of the induction coil groups 10 . The magnetic sheets on the side of the other side are respectively fixed on the side surface of the - turntable 40 and a first partition 41, and the inductive coil sets 10 are fixed on a second partition 5, and the turn 40, the first - The partition 41 and the second partition 5 are hollow at the center for the drive shaft 60 of the transmission to be assembled, so that the turntable 4 and the first partition 4 can be rotated on the transmission shaft 60. The two partitions 5 () are fixed on the transmission shaft (9), and before the magnetic sheet 21 is fixed, a shielding cover made of a metal material is fixed on the circumferential surface except for the side surface of the magnetic conductive portion 13. In order to concentrate the magnetic force on the magnetic conductive portion 13 of the induction coil group 1 ,, the magnetic sheet 21 corresponding to the largest coil of the induction coil group 1 is operated by the magnetic sheet 21 such as ^, and the magnetic sheets are The different magnetic poles provided by 21 and the induction coils ίο mutually induce each other, and the magnetic sheets 21 are brought The operation continued to 'and by those of induction coils;. The windings of the coils are arranged such that the interaction between the magnetically permeable portions 13 is increased. Referring to the seventh to eighth embodiments, which are perspective views and side views of a third embodiment of the present invention, the present embodiment is provided with two sets of magnetic energy units (10) of the second embodiment, and the magnetic energy units 100 are along the line. The drive shafts 6 重 are mutually placed to form a plurality of layers, and the induction coil groups ι〇ς magnetic 200937807 pieces 21 of the magnetic energy units 1 are interleaved with each other to make the induction coil groups located on the respective magnetic energy units 100 10 and the magnetic sheets 21 are formed with a suitable interlacing angle, and the corresponding magnetic sheets 21 are respectively disposed on the side surfaces of the magnetic conductive portions 13 of the inductive coil groups 10, and are disposed on each of the induction coil groups 1 The magnetic element 20 on the lower side corresponds to the magnetic conductive portion 13 of the largest area, and the magnetic sheets 21 disposed on the lower side of the magnetic conductive portion 13 are respectively fixed to the turntable 4 and the partition 41 The magnetic sheets 21 disposed on the other two sides of the magnetic conductive portions 13 are respectively fixed to the partition plates 42 disposed on the turntable 40, and the inductive coil groups 10 are fixed to the second partition 50. The magnetic sheets 21 are formed into a closed magnetic field. The induction coil group 10 is maximally inductive. Referring to FIG. 9 , which is a side view of a fourth embodiment of the present invention, the present embodiment is provided with two sets of magnetic energy units 1 第二 according to the second embodiment, and the magnetic energy units 100 can be along the center thereof. The axis a wraps around a plurality of circles from small to large, forming a gradual arrangement. Referring to FIG. 10, which is a side view of a fifth embodiment of the present invention, each of the induction coil groups 1 of the magnetic energy unit of the present embodiment is concentrically and continuously wound in the radial direction by the wires. The flat-shaped elliptical coils 'the special induction coil group 1 are respectively arranged longitudinally and arranged equidistantly around the same center, and the long sides correspond to the central axis a, so that they are disposed on the mother-inductive coil group 1 〇 The magnetic elements 2 on the front and rear sides are the magnetic conductive portions 13 corresponding to the largest area thereof. In this embodiment, two sets of magnetic energy units 1 are provided, which are arranged in an overlapping manner along the central axis a to form a plurality of layers. And the corresponding magnetic strips 21 are respectively disposed on the circumferential sides of the magnetic conductive portions 13 of the inductive coil groups 1 , and are disposed on the upper and lower sides of the magnetic conductive portions The magnetic sheets 21 are respectively fixed on the turntable 4A and the first partition 4i, and the magnetic sheets 21 which are placed on the other two sides of the special magnetic portion 13 are respectively fixed on the turntable 40. On the partition plate 42 provided, the induction coil groups are fixed The second spacer 50 is configured to cause the magnetic sheets 21 to form a closed magnetic field to generate the maximum inductive effect on the induction coil assembly 10. In the present embodiment, the two magnetic energy units 100 are disposed. The unit 1 〇〇 is arranged along its central axis a from small to large circle and surrounds a plurality of turns to form a gradation arrangement. Referring to FIG. 3, a top view of a sixth embodiment of the present invention is characterized in that each of the induction coil assemblies 10 is concentrically and continuously twisted in a radial direction by a plurality of wires to form a plurality of flat elliptical coils 11, which The inductive coil sets 10 are respectively arranged in the radial direction and are arranged continuously around the drive shaft 60, and the induction coils 10 respectively have an angle between the groups, and the first inductive coil group 8〇 can be placed, and the magnetic elements 20 are The magnetic elements 20 are disposed on the upper and lower sides of each of the induction coil assembly 10 and each of the induction coil assemblies 80, respectively, corresponding to the hollow portions 12 and 81 of the induction coil group 1 and the secondary induction coil assembly 80. The shielding portion 70 is integrally formed around the outer periphery of the magnetic sheets 21 corresponding to the magnetic conductive portion 13 having the largest area. Referring to FIG. 12, it is a top view of a seventh embodiment of the present invention. In this embodiment, two sets of magnetic energy unit 100 are provided by using the magnetic energy unit 1 of the sixth embodiment. Its central axis a is set from small to large circle and surrounds a plurality of circles to form a gradual arrangement. Referring to the thirteenth embodiment, in a top view of the eighth embodiment of the present invention, the inductive coil sets 10 are respectively arranged radially and arranged around the drive shaft 60, and the inductive coil sets are arranged. Each of the magnetic sheets 21 is disposed on the hollow portion 12 corresponding to the induction coil group 1 ,, and a hollow portion 22 is also provided corresponding to each of the induction coil groups 1 and each magnetic The mask 70 is surrounded by the outer periphery of the sheet 21. 200937807 Hereafter, the features of the present invention and the achievable expected effects thereof are as follows: 1. The inductive coil sets of the present invention are arranged in series, and at least one magnetic element is disposed on one side of the corresponding magnetic conducting portion. The magnetic component is disposed at a position corresponding to a magnetic pole portion having the highest coil winding density, and is densely wound by the induction coils, thereby increasing the interaction between the magnetic conductive portion and the magnetic sheets, and When the magnetic sheets pass between the adjacent magnetic conducting portions, the magnetic shocking force caused by the magnetic fields generated by the magnetic sheets to the magnetic conductive portions is reduced and the higher voltage can be generated in the same unit area. The lowest current is the ability to generate power' and maximizes the density utilization of the coil in the smallest volume, allowing it to operate smoothly, providing a high-performance power conversion of the generator and the motor. 2. The outer surface of the magnetic sheet of the present invention is fixed with a mask made of a metal material to concentrate the magnetic force on the magnetic conductive portions of the induction coil groups. 3. The predetermined misalignment angle of each magnetic film and each induction coil is closely overlapped in an alternating manner, and kinetic energy is saved. φ , in summary, the invention has its excellent progress in the same kind of products, and at the same time, it has also checked the technical information about such structures at home and abroad. The same structure was not found in the literature. In the first place, the invention has been prepared and the patent requirements have been made. ~ 备华, the above mentioned, only the original _ has been, so it is better to use the 仃 丄 ^ 仃 仃 而 而 而 结构 结构 结构 结构 发明 发明 发明 发明 发明 发明 发明 发明 发明 发明 发明 发明 发明 发明 发明Within the scope of the patent of the present invention. 11 200937807 BRIEF DESCRIPTION OF THE DRAWINGS The first drawing is a perspective view of a preferred embodiment of the present invention. The second drawing is a top partial cross-sectional view of a preferred embodiment of the invention. The second drawing is a perspective view of a preferred embodiment of the invention. The fourth figure is a partial enlarged view of the second embodiment of the present invention. The fifth drawing is a side view of the second embodiment of the present invention. The sixth drawing is a top view of the second embodiment of the present invention. The seventh drawing is a perspective view of a third embodiment of the present invention. © Figure 8 is a side view of a third embodiment of the present invention. The ninth drawing is a side view of a fourth embodiment of the present invention. The tenth figure is a side view of a fifth embodiment of the present invention. The eleventh drawing is a top view of a sixth embodiment of the present invention. Figure 12 is a top plan view of a seventh embodiment of the present invention. Figure 12 is a top plan view of an eighth embodiment of the present invention. [Description of main component symbols] ❹ [Invention] 10 Induction coil group 11 Coil 12 Hollow portion 13 Magnetic conductive portion 20 Magnetic member 21 Magnetic sheet 22 Hollow portion 30 Fixing member 40 Turntable 41 First partition plate 42 Partition plate 12 200937807 50 60 70 80 81 100 a Φ Second diaphragm drive shaft shield cover secondary induction coil group hollow magnetic energy unit central axis misalignment angle 13