201008074 九、發明說明: 【發明所屬之技術領域】 —本發明係有_—種電力供應裝置,尤指—種將複數個儲能 元件整合至一機箱裡的電力供應裝置。 【先前技術】 、般說來傳統電力供應系統係由多個錯酸電池堆叠而成(串 ❹聯或並聯)安裝於機房内,由於錯酸電池具有重量重且體積大等 缺點,使得整個電力供應系統不僅笨重且佔空間。 【發明内容】 因此’本發明的目的之一在於提供一種將複數個儲能元件(磁 性電容電池)整合至一電力供應模組,以及將複數個電力供應模 組整合至一機箱裡的電力供應裝置,以解決上述問題。 依據本發明之申睛專利範圍,其係揭露一種電力供應模組。 該電力供應模組包含有:一母板(motherboard);至少一儲能元 件,文裝於該母板上;以及一連接埠,固定於該母板上並電連接 於該儲能元件;其中該儲能元件係透過該連接埠而輸出其所儲存 之電力。 依據本發明之申請專利範圍,其亦揭露一種電力供應裝置。 δ玄電力供應裝置包含有:一機箱(rackm〇Unt),包含有一連接座; 201008074 以及至少-電力供應模組,以一可插拔之方式安裝於該連接座 上。該電力供應模組包含有:—母板;至少-儲能元件,安裝於 該母板上;以及一連接埠,固定於該母板上並電連接於該儲能元 件,其中該儲能元件係透過該連接槔而輸出其所儲存之電力。 【實施方式】 在本專利說明書及後續的申請專利範圍#中使用了某些詞棄 ❹來彳日稱特定的元件。所屬領域巾具有财知識者應可理解,硬體 製造商可能賴不_糊來稱销—個元件。本制書及後續 的巾料鄉圍並砂名稱縣異㈣為區分元件財式,而是 以元件在功上的差異來作為區分的物。在通篇綱書及後續 的請求項當中所提及的「包含」係為—開放式的用語,故應解釋 成「包含但不限定於」。此外,「柄接」—詞在此係包含任何直接 及間接的電氣連接手段。因此,若文中描述一第—裝置耗接於一 第—裝置’賊表該第_裝置可直接電氣連接於該第二裝置,或 透過其他裝置或連接手段間接地電氣連接至該第二裝置。 凊參考第1圖,第1圖為本發明電力供應模組1〇〇之一實施 例的示意圖。如第1圖所示,電力供應模組100包含有一母板11〇、 至少一儲能元件120以及一連接埠13〇。儲能元件12〇係安裝於母 板110之上;連接埠130係固定於母板11〇上並電連接於儲能元 件120;其中儲能元件120係透過連接埠13〇而輸出其所儲存之電 力,此外,儲能元件120亦可透過連接埠13()來進行充電。以下 201008074 將對電力供應模組100做進一步的說明,然而,此僅作為範例說 明,而並非為本發明之限制。 在電力供應模組100中,母板110係為一刀鋒板(b]ade),儲 能兀件120係設置於一子板(daughterb〇ard)上,該子板係以一可 插拔的方式安褒於母板110上,因此,儲能元件120亦以一可插 拔的方式安裝於母板110上。此外,在電力供應模組1〇〇中儲 ❹能元件120係為-磁性電容電池,其包含有至少一磁性電容 (magnetic capacitor) ’以下將對磁性電容電池做進一步的說明。 w參閱第2圖’第2圖為本發明之—磁性電容2⑻的結構示 意圖。如第2圖所示,磁性電容綱包含有一第—磁性電極加、 一第二磁性電極22〇以及位於其間之一介電層23〇。第一磁性_ 210與第一磁性電極22〇均係由具有磁性的導電材料所構成,包含 有雖導電材質(例如:稀土元素),並藉由適當的外加電場對 第—、第二磁性電極21〇、22〇進行磁化使第一、第二磁性電極 210 220内分別形成磁偶極(magnetic dipole) 215、225,磁偶極 犯、225能於磁性電容2⑽内部形成一磁場,該磁場可影響帶電 =的移動,從而抑制磁性電容200之漏電流;介電層230係由 "電材質(例如·氧化欽(Ti〇3)、氧化舰伽了⑽)或一半導 體材料(例如·氧化石夕(siHc〇n〇xide))所構成,用來分隔第一磁性 電極210與第二磁性電極22〇,以於第一雜電極21〇與第二磁性 電極220處累積電荷而儲存電位能。以下將針對磁性電容之操作 201008074 原理作進一步說明。 磁性電容200主要利用整齊排列的磁偶極犯、225來形成磁 場,使第-磁性電極⑽與第二雜電極挪内部所儲存的電子 各自朝-自旋方向轉動而整齊排列,故可儲存大量的電荷進而 大幅增加能量儲存密度。請注意,第2圖所示之磁偶極犯、奶 係分別指向相反的方向,然而,此並非為本發明之限制,實作上, ❹磁偶極215與225的方向並無限定,舉例來說,磁偶極215與奶 亦可指向一相同方向。 習知電容之電容值C係由f容之面積a、介電層之介電常數 e〇、er及厚度d決定,請參考下式: (1) Q _ £g£jr^ ~~d~ 相較於習知電容,磁性電容200相當於藉由磁場之作用來改 變介電層23G之介電常數以提升其電容值;此外,在本發明之一 實施例t,第-磁性電極2iG與介電層⑽間之—第—介面祝 以及第二磁性電極220與介電層23〇間之一第二介面232均為一 不平:L·的表面’ gj而藉由增加表面積A的來進—步提升磁性電容 200之電容值。 π參閱第3圖’第3圖為本發明之磁性電容與其他習知能量 201008074 儲存媒介的味圖。由帛3 ®可知,相較於傳統電容與超級電容, 磁性電容具有相當高的能量儲存密度。 請參閱第4圖,第4圖為第2圖所示之第一磁性電極21〇之 一實施例的結構示意圖。如第4圖所示,第一磁性電極21〇係為 一二層結構,包含有一第一磁性層412、一隔離層414以及一第二 磁性層416 ’其中,_層414係由非磁性材料所構成,而第一磁 ❹性㉟412與第二磁性層416則包含有具磁性的導電材料,並藉由 不同的外加電場對第一、第二磁性層412、416進行磁化使其第 一、第二磁性層412、416内分別形成磁偶極413、417,磁偶極 413、417—起構成第一磁性電極21〇之磁偶極215。在本發明之 -較佳實施例中’磁偶極413、417係分別指向減之方向(如第 4圖所示),以抑制磁性電容2〇〇之漏電流。 ⑩ 凊注意,第一磁性電極210之結構並不限於前述之三層結構 (第一、第二磁性層412、416與一隔離層414),在本發明其他實 施例中’第一磁性電極21〇可係為一多層結構,更明確地說,第 磁性電極21G可由複數個雜層與複數個隔離層不斷交錯堆疊 而組成,再藉由調整各磁性層之磁偶極方向來抑制磁性電容200 之漏電流,甚至達到幾乎無漏電流的效果,而此一設計變化亦隸 屬於本發明的料。此外’第二磁性電極22()之結構可採用上述 任何第一磁性電極210之結構,因此為求說明書内容簡潔起見, 第二磁性電極220之結構的詳細說明便在此省略。 201008074 明參閱第5 ® ’第5圖為本發明之磁性電容電池$⑻之一實 施例的示忍圖。如第5圖所不,磁性電容電池包含有複數個 磁性電容200 ’其係以一陣列的方式而互相電連接,然而,此並非 為本發明之限制,實作上’複數個磁性電容可以串聯或並聯的方 式來互相電連接’以滿足各種的電力供應需求。在本實施例中, 磁性電容電池郷係利用半導體製程於一錄板上製作複數個小 ❹尺寸的磁性電容200’並藉由適當的金屬化製程來電連接複數個磁 性電容200所構成。 請參閱第6圖,第6圖為本發明電力供應模組6〇〇之另一實 施例的示意圖,如第6圖所示,電力供應模組6〇〇包含有一母板 610、至少一儲能元件620、一連接埠630、一監測器(monit〇r) 640以及一控制器(c〇ntr〇Uer) 65〇。由於第6圖之電力供應模組 600與第1圖之電力供應模組1〇〇中具有相同名稱之元件具有類似 ® 的·枝與舰,因此為求制書嶋_起見,詳細說明便 在此省略。第6圖之電力供應模組6〇〇與第1圖之電力供應模組 1 〇〇的主要不同之處在於電力供應模組600另具有監測器64〇與控 制器650 ’其均安裝於母板61〇之上’監測器64〇用來監測儲能元 件620之狀態’控制器650用來控制儲能元件620之運作。舉例 來說,監測器640可監測儲能元件620的剩餘能量,而控制器65〇 可控制讓儲能元件620放電或對儲能元件620充電。 201008074 士請注意’在本發财,監測咖㈣均係騎必要(_nal) 70件’換句雜,在本翻魏實施射1力供賴組可包含 監測器而不包含控制器,或包含控制器而不包含監測器,而此設 計變化亦隸屬於本發明之範疇。 ❹ ❹ 請參閱第7圖,第7圖為本發明電力供應裝置700之-實施 例的示意圖。如第7圖所示’電力供應裝置7⑻包含有一機箱顶 以及至少-電力供應模組72〇。機箱71〇 (例如:一刀鋒式機箱 ⑽deraClon〇unt))包含有一連接座711 ;電力供應模組72〇包 含有(但不限於)-母板721 (例如:—刀鋒板)、至少一儲能元 件722以及-連接蟑(未顯示於第7圖中),實作上,電力供應模 組720可採用任何上述電力供應模組之結構(例如:電力供應模 組1〇〇或電力供應歡_)。電力供應模組72〇係以一可插拔的 方式安裝於連接座711上,因此,若電力供應模組72〇發生問題 時’可獨立_並更換電力供賴組72G,而不會影響電力供絲 置700之正常運作。以下將對電力供應系统7〇〇做進一步的說明, 然而,此僅作為範例說明,而並非為本發明之限制。 在電力供應裝置700中,電力供應模組72〇之連接埠係以一 可插拔的方式將電力供應模組720安裝於連接座711上,連接座 711係用以輸出儲能元件722所儲存之電力,換句話說儲能元件 722係透過電力供應模組72〇之連接埠與連接座711而輸出其所儲 存之電力,然而本發明並不以此為限,亦即,電力供應模組72〇 12 201008074 僅以一可插拔的方式安裝於連接座711上,但連接座711並不輸 出儲能兀件722儲存之電力,舉例來說,儲能元件722可能透過 電力供應裝置700之其他接頭或接口來輸出其所儲存之電力,此 外’儲能兀件722亦可透過連接座711與電力供應模組72〇之連 接埠進行充電。電力供應裝置7〇〇另包含有一監測單元(咖加麵 unit)以及-㈣單元(⑺咖㈣她),該監醇元與該控制單 疋均搞接於電力供應模組720’該監測單元係用以監測電力供應模 ❹組720之狀態,該控制單元則用以控制電力供應模組72〇之運作, 舉例來說,該監測單元可監測電力供應裝置7〇〇中之電力供應模 組(例如:電力供應模組72〇)的剩餘電量,該控制單元可控制電 力供應裝置700中之電力供應模組(例如:電力供應模組72〇)來 輸出其所儲存之電力,該控制單元亦可控制—充電電路來對電力 供應裝置700中之電力供應模組(例如:電力供應模組72〇)充電, 其中,該充電電路可設置於電力供應裝置7〇〇内或外接於電力供 ❹應裝置7〇0。請參閲第8圖,第8圖為本發明電力供應裝置700 的另-示意圖。如第8圓所示,該監測單元與該控制單元係由一 =碟730、-中央處理單元(cpu) 以及至少一隨機存取記憶 體(麵)750戶斤組成’並均設置於另一_±,亦以可插拔的 方式安裝於機箱710之中。 在電力供應裝置中,該監測單元與該控制單元均係 於機箱彻t,細’此麟為本發明之_。在本發明電评 應裝置的另〜實_巾,監測單元與控鮮元可經由—網路來分 201008074 別=與控制電力供應模組之狀態與運作,而不需與該電力供應 T組設置於同-機箱中。此外’在本實施例中,電力供應模組顶 係以-直插的方式設置於鋪彻巾,然而,本發明並不僅限於 此丄舉例來說’電力供應模組72〇係亦可以—橫插的方式設置於 機箱no中,而此-設計變化亦隸屬於本發明之範嘴。 相較於習知技術,由於磁性電容電池具有能量密度大、體積 〇小與«輕等特性’耻可賴數個雜電容電雜合至一母板 (例如:刀鋒板),成為—電力供賴組,再將複數㈣力供應模 整口至勸目中,成為-電力供應裝置,進而有效減少電力供 應襄置之體積並w會犧牲其供魏力,以解決習知鑛電池的 問題。 以上所述僅為本發明之較佳實關,凡依本發日种請專利範 圍所做之均特化與修飾,皆應屬本發明之涵蓋範圍。 【圖式簡單說明】 第1圖為本發明電力供麵組之—實施綱示意圖。 第2圖為本發明之—磁性電容的結構示意圖。 第3圖為本發明之磁性電容與其他習知能量儲存齡的比較圖。 第4圖為第2圖所不之第—磁性電極之_實施例的結構示意圖。 第5圖為本發明之磁性電容電池之—實施例的示意圖。 第6圖為本發明電力供應模組之另—實施例的示意圖。 201008074 第7圖為本發明電力供應裝置之一實施例的示意圖。 第8圖為第7圖所示之電力供應裝置的另一示意圖。201008074 IX. Description of the Invention: [Technical Field of the Invention] The present invention relates to a power supply device, and more particularly to a power supply device that integrates a plurality of energy storage components into a single chassis. [Prior Art] Generally speaking, the traditional power supply system is composed of a plurality of wrong acid batteries stacked in series (series or parallel) installed in the equipment room. Due to the heavy weight and large volume of the wrong acid battery, the whole power is made. The supply system is not only cumbersome and takes up space. SUMMARY OF THE INVENTION Therefore, one of the objects of the present invention is to provide a power supply that integrates a plurality of energy storage components (magnetic capacitor batteries) into one power supply module and integrates a plurality of power supply modules into one chassis. Device to solve the above problems. According to the scope of the patent application of the present invention, a power supply module is disclosed. The power supply module includes: a motherboard; at least one energy storage component mounted on the motherboard; and a connection port fixed to the motherboard and electrically connected to the energy storage component; The energy storage component outputs its stored power through the connection port. According to the patent application scope of the present invention, a power supply device is also disclosed. The δ 玄 power supply device comprises: a chassis (rackm 〇 Unt), comprising a connector; 201008074 and at least a power supply module, is mounted on the connector in a pluggable manner. The power supply module includes: a motherboard; at least an energy storage component mounted on the motherboard; and a connector fixed to the motherboard and electrically connected to the energy storage component, wherein the energy storage component The stored power is output through the connection port. [Embodiment] In the present patent specification and the subsequent patent application scope #, certain words are used to refer to a specific component. Those who have financial knowledge in the field of the field should understand that the hardware manufacturer may not be able to sell the components. This book and the subsequent towel materials and the name of the sand and the county (4) are used to distinguish the component financial form, but the difference in the difference in the function of the component. The "contains" mentioned in the general and subsequent claims are open-ended terms and should be interpreted as "including but not limited to". In addition, the term "handle" is used to include any direct and indirect electrical connection. Thus, if a device is described herein as being coupled to a device, the device may be directly electrically coupled to the second device or indirectly electrically coupled to the second device through other devices or connection means. Referring to Fig. 1, Fig. 1 is a schematic view showing an embodiment of a power supply module 1 of the present invention. As shown in FIG. 1 , the power supply module 100 includes a motherboard 11 , at least one energy storage component 120 , and a connection port 13 . The energy storage component 12 is mounted on the motherboard 110; the connector 130 is fixed on the motherboard 11 and electrically connected to the energy storage component 120; wherein the energy storage component 120 is output through the connection port 13 In addition, the energy storage component 120 can also be charged through the connection port 13 (). The power supply module 100 will be further described in the following 201008074, however, this is merely an example and is not a limitation of the present invention. In the power supply module 100, the motherboard 110 is a blade (b) ade, and the energy storage device 120 is disposed on a daughterboard, the daughterboard is pluggable. The method is mounted on the motherboard 110. Therefore, the energy storage component 120 is also mounted on the motherboard 110 in a pluggable manner. Further, in the power supply module 1A, the energy storage element 120 is a magnetic capacitor battery including at least one magnetic capacitor. The magnetic capacitor battery will be further described below. w Referring to Fig. 2, Fig. 2 is a schematic view showing the structure of the magnetic capacitor 2 (8) of the present invention. As shown in Fig. 2, the magnetic capacitor includes a first magnetic electrode, a second magnetic electrode 22, and a dielectric layer 23 therebetween. The first magnetic _ 210 and the first magnetic electrode 22 构成 are both made of a conductive material having magnetic properties, and include a conductive material (for example, a rare earth element), and the first and second magnetic electrodes are applied by an appropriate applied electric field. 21〇, 22〇 are magnetized to form magnetic dipoles 215 and 225 in the first and second magnetic electrodes 210, respectively, and a magnetic dipole 225 can form a magnetic field inside the magnetic capacitor 2 (10). Affecting the movement of the charge=, thereby suppressing the leakage current of the magnetic capacitor 200; the dielectric layer 230 is made of an "electric material (for example, 〇 ( (Ti〇3), oxidized ship gamma (10)) or a semiconductor material (for example, oxidation) The structure is configured to separate the first magnetic electrode 210 and the second magnetic electrode 22〇 to accumulate charges at the first impurity electrode 21〇 and the second magnetic electrode 220 to store potential energy. . The principle of the magnetic capacitor 201008074 will be further explained below. The magnetic capacitor 200 mainly uses a magnetic pole that is arranged neatly, 225 to form a magnetic field, so that the electrons stored in the first magnetic electrode (10) and the second impurity electrode are respectively rotated in the direction of the spin and arranged neatly, so that a large amount of storage can be stored. The charge in turn greatly increases the energy storage density. Please note that the magnetic dipole and the milk system shown in Fig. 2 point in opposite directions. However, this is not a limitation of the present invention. In practice, the directions of the magnetic dipoles 215 and 225 are not limited. In other words, the magnetic dipole 215 and the milk can also point in the same direction. The capacitance value C of the conventional capacitor is determined by the area a of the f-capacitance, the dielectric constant e〇, er and the thickness d of the dielectric layer. Please refer to the following formula: (1) Q _ £g£jr^ ~~d~ Compared with the conventional capacitor, the magnetic capacitor 200 is equivalent to changing the dielectric constant of the dielectric layer 23G by the action of the magnetic field to increase its capacitance value; further, in an embodiment t of the present invention, the first-magnetic electrode 2iG and The first interface 232 between the dielectric layer (10) and the second interface 232 between the second magnetic electrode 220 and the dielectric layer 23 is an uneven surface: the surface 'gj of L· is increased by increasing the surface area A - Step up the capacitance value of the magnetic capacitor 200. π see Fig. 3' Fig. 3 is a scent diagram of the magnetic capacitor of the present invention and other conventional energy 201008074 storage medium. According to 帛3®, magnetic capacitors have a relatively high energy storage density compared to conventional capacitors and supercapacitors. Referring to Fig. 4, Fig. 4 is a schematic view showing the structure of an embodiment of the first magnetic electrode 21A shown in Fig. 2. As shown in FIG. 4, the first magnetic electrode 21 is a two-layer structure including a first magnetic layer 412, an isolation layer 414, and a second magnetic layer 416. The _ layer 414 is made of a non-magnetic material. The first magnetic properties 35412 and the second magnetic layer 416 comprise a magnetic conductive material, and the first and second magnetic layers 412, 416 are magnetized by different applied electric fields to make the first Magnetic dipoles 413 and 417 are formed in the second magnetic layers 412 and 416, respectively, and the magnetic dipoles 413 and 417 together form a magnetic dipole 215 of the first magnetic electrode 21〇. In the preferred embodiment of the invention, the magnetic dipoles 413, 417 are directed in the direction of the subtraction (as shown in Figure 4) to suppress leakage current of the magnetic capacitor 2〇〇. 10 凊 Note that the structure of the first magnetic electrode 210 is not limited to the aforementioned three-layer structure (the first and second magnetic layers 412, 416 and an isolation layer 414), and in other embodiments of the present invention, the first magnetic electrode 21 The 〇 can be a multi-layer structure. More specifically, the magnetic electrode 21G can be formed by continuously stacking a plurality of impurity layers and a plurality of isolation layers, and then suppressing the magnetic capacitance by adjusting the magnetic dipole direction of each magnetic layer. The leakage current of 200 even reaches the effect of almost no leakage current, and this design change is also subject to the material of the present invention. Further, the structure of the second magnetic electrode 22 can adopt the structure of any of the first magnetic electrodes 210 described above, and therefore the detailed description of the structure of the second magnetic electrode 220 will be omitted herein for the sake of brevity of the description. 201008074 See 5 ′′ 5th is a diagram of an embodiment of a magnetic capacitor battery (8) of the present invention. As shown in FIG. 5, the magnetic capacitor battery includes a plurality of magnetic capacitors 200' electrically connected to each other in an array manner. However, this is not a limitation of the present invention. In practice, a plurality of magnetic capacitors can be connected in series. Or electrically connected in parallel to meet each other's power supply needs. In the present embodiment, the magnetic capacitor battery is formed by using a semiconductor process to form a plurality of small-sized magnetic capacitors 200' on a recording board and electrically connecting a plurality of magnetic capacitors 200 by a suitable metallization process. Please refer to FIG. 6. FIG. 6 is a schematic diagram of another embodiment of the power supply module 6 of the present invention. As shown in FIG. 6, the power supply module 6A includes a motherboard 610 and at least one storage. The energy component 620, a connection port 630, a monitor (monit〇r) 640, and a controller (c〇ntr〇Uer) 65〇. Since the power supply module 600 of FIG. 6 and the power supply module 1 of the first figure have the same name and the like, and therefore, for the sake of making a book, the detailed description will be described in detail. It is omitted here. The main difference between the power supply module 6 of FIG. 6 and the power supply module 1 第 of FIG. 1 is that the power supply module 600 further has a monitor 64 〇 and a controller 650 ' both mounted on the mother Above the board 61 'monitor 64 〇 is used to monitor the state of the energy storage element 620 ' the controller 650 is used to control the operation of the energy storage element 620 . For example, monitor 640 can monitor the remaining energy of energy storage component 620, while controller 65 can control discharge of energy storage component 620 or charge energy storage component 620. 201008074 Please note that 'in this fortune, monitoring coffee (four) are necessary to ride (_nal) 70 pieces 'change the sentence, in the implementation of this turn, the force can be included in the monitor without the controller, or contain The controller does not include a monitor, and this design change is also within the scope of the present invention. ❹ ❹ Please refer to FIG. 7, which is a schematic diagram of an embodiment of the power supply device 700 of the present invention. As shown in Fig. 7, the power supply unit 7 (8) includes a chassis top and at least a power supply module 72A. The chassis 71〇 (for example, a blade-type chassis (10) deraClon〇unt) includes a connector 711; the power supply module 72 includes, but is not limited to, a motherboard 721 (eg, a blade), at least one energy storage device The component 722 and the connection port (not shown in FIG. 7), in practice, the power supply module 720 can adopt any of the above power supply module structures (for example, the power supply module 1 or the power supply _ ). The power supply module 72 is mounted on the connection base 711 in a pluggable manner. Therefore, if the power supply module 72 fails, the power supply module 72 can be replaced independently and the power supply group 72G can be replaced without affecting the power. The wire supply 700 is in normal operation. The power supply system 7 will be further described below, however, this is merely illustrative and not a limitation of the present invention. In the power supply device 700, the power supply module 72 is connected to the power supply module 720 in a pluggable manner, and the connection base 711 is used for outputting the energy storage component 722. The power, in other words, the energy storage component 722, outputs the stored power through the connection port 711 of the power supply module 72, but the invention is not limited thereto, that is, the power supply module 72〇12 201008074 is only installed in a pluggable manner on the connector 711, but the connector 711 does not output power stored by the energy storage device 722. For example, the energy storage component 722 may pass through the power supply device 700. The other connector or interface outputs the stored power, and the 'energy storage element 722 can also be charged through the connection between the connection base 711 and the power supply module 72. The power supply device 7 further includes a monitoring unit (Caijiao unit) and a (4) unit ((7) coffee (4) her), and the control unit and the control unit are connected to the power supply module 720'. For monitoring the status of the power supply module 720, the control unit is configured to control the operation of the power supply module 72. For example, the monitoring unit can monitor the power supply module in the power supply device 7 (For example, the power supply module 72A), the control unit can control the power supply module (for example, the power supply module 72A) in the power supply device 700 to output the stored power thereof, the control unit The charging circuit can also be controlled to charge the power supply module (eg, the power supply module 72A) in the power supply device 700, wherein the charging circuit can be disposed in the power supply device 7 or externally connected to the power supply. The device should be 7〇0. Please refer to FIG. 8. FIG. 8 is another schematic view of the power supply device 700 of the present invention. As shown in the eighth circle, the monitoring unit and the control unit are composed of a disk 730, a central processing unit (cpu), and at least one random access memory (surface) of 750 jins and are disposed in another _± is also pluggably mounted in the chassis 710. In the power supply device, the monitoring unit and the control unit are both in the chassis, and the structure is the invention. In the other embodiment of the present invention, the monitoring unit and the control unit can be connected to the state and operation of the power supply module via the network, without the need to cooperate with the power supply T group. Set in the same - chassis. In addition, in the present embodiment, the power supply module is disposed on the top of the power supply module in a straight-line manner. However, the present invention is not limited thereto. For example, the power supply module 72 can also be used. The plug-in mode is set in the chassis no, and this-design change is also subject to the scope of the present invention. Compared with the conventional technology, since the magnetic capacitor battery has a large energy density, a small volume, and a light characteristic, it is possible to electrically mix a plurality of capacitors into a mother board (for example, a blade) to become an electric power supply. Lai group, then the plural (four) force supply model to the mouth to become the power supply device, and thus effectively reduce the size of the power supply and will sacrifice its power for Wei Li to solve the problem of the mine battery. The above is only the preferred embodiment of the present invention, and all the specializations and modifications made by the patent scope according to the present invention should be covered by the present invention. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic view showing the implementation of the power supply panel of the present invention. Fig. 2 is a schematic view showing the structure of a magnetic capacitor of the present invention. Figure 3 is a comparison of the magnetic capacitance of the present invention with other conventional energy storage ages. Fig. 4 is a schematic view showing the structure of the first embodiment of the magnetic electrode. Fig. 5 is a schematic view showing an embodiment of a magnetic capacitor battery of the present invention. Figure 6 is a schematic view showing another embodiment of the power supply module of the present invention. 201008074 FIG. 7 is a schematic diagram of an embodiment of a power supply device of the present invention. Fig. 8 is another schematic view of the power supply device shown in Fig. 7.
【主要元件符號說明】 100、600、720 電力供應模組 110、210、721 母板 120、620、722 儲能元件 130、630 連接埠 200 磁性電容 210、220 磁性電極 215、225、413、417 磁偶極 230 介電層 412、416 磁性層 414 隔離層 500 磁性電容電池 640 監測器 650 控制器 700 電力供應裝置 710 機箱 711 連接座 730 硬碟 740 中央處理單元 750 隨機存取記憶體 15[Main component symbol description] 100, 600, 720 power supply module 110, 210, 721 motherboard 120, 620, 722 energy storage component 130, 630 connection 埠 200 magnetic capacitor 210, 220 magnetic electrode 215, 225, 413, 417 Magnetic Dipole 230 Dielectric Layer 412, 416 Magnetic Layer 414 Isolation Layer 500 Magnetic Capacitor Battery 640 Monitor 650 Controller 700 Power Supply Device 710 Chassis 711 Connector 730 Hard Disk 740 Central Processing Unit 750 Random Access Memory 15