200908860 八、本案若有化學式時,請揭示最能顯示發明特徵的化學式: 九、發明說明: 【發明所屬之技術領域】 本發明係有關於一種熱致發電散熱系統,特別係有關於一種用於筆記型電 腦或其他散熱裝置,以達到散熱和發電節能的效用· 【先前技術】 參照第1圖,其係顯示以低沸點高蒸氣壓液體12(沸點溫度40〜50°C),灌入 導熱腔體11的情形。發熱體1〇藉由導熱腔體11使低沸點高蒸氣壓液體12 變爲蒸氣,該蒸氣經由吸液體海綿16和氣液體分離膜13把乾高壓氣體注 入乾氣體儲存槽14。高壓氣體釋放模組15用乾高壓氣體推動散熱風扇17, 並帶動薄型發電機模組18 ;而導熱腔體11內蒸氣的濕氣被吸液體海綿16 吸收,吸液體海綿16會經由散熱風扇17和散熱麵19何吸入外部冷空氣) 來散熱,並把高溫蒸氣變成低溫低沸點高蒸氣壓液體12 · 【發明内容】 本發明即爲了用於筆記型電腦或其他散熱裝置,以達到散熱和發電節能效 用,而提供之一種熱致發電散熱系統,包括一導熱腔體、一低沸點高蒸氣 壓液體(沸點潇40〜50〇C)、一氣液體分離膜、一乾氣腿存槽——高壓氣 體釋放模組、一吸液體海綿、一散熱模組、一散熱風扇以及一薄型發電機 模組。該低沸點高蒸氣壓液體可至於導熱腔體進行液-氣態轉相,該低沸點 高蒸氣壓蒸氣經過氣液體分離膜把乾熱高壓氣體儲存於乾氣體儲存槽。利 用乾氣體儲存槽的乾熱高壓氣體經過高壓氣體釋放模組推動散熱風扇並帶 動薄型發電機模組。該低沸點高蒸氣壓蒸氣經過氣液體分離膜前,會經由 6 200908860 吸液體海綿吸收濕氣,吸液體海綿經散熱模組和散熱風扇降溫,把濕氣回 歸至低沸點高蒸氣壓液體的狀態。利用此方式循環進行散熱與推動薄型發 電機灘發電· 應用本發明之熱致發電散熱系統,可以透過發熱體來進行循環散熱和 發電,以降低系統溫度和產生電力,方便使用在筆記型電腦和其他散熱節 能的系統•熱致發電散熱系統可持續幫助散熱和提供額外電量,可提升工 作系統的持續使用性。 【實施方式】 [第一實施例] 參照第1圖,其係顯示本發明之熱致發電散熱系統,包括一導熱腔體11、 一低沸點高蒸氣壓液體12(沸點溫度40〜50〇〇、一氣液體分離膜13、一乾 氣體儲存槽14、一高壓氣體釋放模組15、一吸液體麵16、一散謝雖 19(可吸入外部冷空氣)、一散熱風扇17以及一薄型發電機讎18 〇低沸點 高蒸氣壓液體12(沸點溫度40〜50DC)灌入導熱腔體11 〇發熱體1〇藉由導熱 腔體11使低沸點高蒸氣壓液體12變爲蒸氣,該蒸氣經由吸液體海綿16和 氣液體分離膜13把乾熱高壓氣體注入乾氣體儲存槽14。高壓氣體釋放模組 15利用乾熱高壓氣體推動散熱風扇17,並帶動薄型發電機模組18 ;而該蒸 氣的濕氣被吸液體海綿16卩及收,吸液體海綿16會經由散熱風扇17和散熱 模組19(可吸入外部冷空氣)來散熱,並把高溫蒸氣變成低溫低沸點高蒸氣 虜液體12 · 導熱腔體11內部可作成任何易使低沸點高蒸氣壓液體12 的構 造。參照第2圖,導熱腔體11內部可作成間隔狀或柱狀或任何形狀,並使 «薄狀吸液體海綿16,使低沸點高蒸氣壓液體12容易經導熱腔體η受 _而蒸發形成蒸氣,蒸氣會經由上端的薄型吸液體海綿16和氣液體分_ 13把乾熱高壓氣體注入乾氣體儲存槽14,濕氣會經由吸液體海綿16吸收’ 吸收濕氣的吸液體海綿16會經由散熱風扇17和散熱_ 空氣)來散熱降溫’使變成低溫低沸點高蒸氣壓液體12再進入導熱腔體11 200908860 做下-*次循環· 散熱模組19(可吸入外部冷空氣)可作成任何易使吸收低沸點高蒸氣壓 液體12的吸液體海綿16降溫的構造。參照第3圖,散熱模組19可於上端 和側端挖孔洞22,於外殻可利用易於導熱材料製作,洞22外壁可利用氣 液體分離膜13製作,散熱風扇17把冷空氣20經由孔洞22和風擋板21均 勻的吹過散熱_ 19的內部和上下’以達到迅速降溫的目的· 高壓氣體釋放麵15把乾氣體游槽14的乾熱高壓空氣側向推動散 熱風扇17並帶動薄型發電機模組Μ ·參照第4圖,散熱風扇17可連接S 極ϋ型磁鐵32,該S極U型磁鐵32環繞發電線圈30並無互相碰觸,發電 線圈30內有一 Ν極磁鐵31,該Ν極磁鐵31被S極U型磁鐵32包覆,使 Ν極磁鐵31在發電線圈3〇內呈懸空之間並無互相碰觸,S極ϋ型磁鐵32 包覆Ν極磁鐵31可一同帶動Ν極磁鐵31 —起作動’隨著散熱風扇17的 推動,使S極ϋ型磁鐵32和Ν極磁鐵31磁場組繞著發電線圈30使產生 發電效應,該薄型發電機模組18可產生DC直流電· 高壓氣體釋画且15把乾氣體儲存槽14的乾熱高壓空氣側向推賺 熱風扇Π,把乾熱高壓氣翻向排出,並帶動散熱風扇17把上端冷空氣吹 向散熱模組19(可吸人外17 #胃動薄型發電機模組18而產生電力· [第二實施例] 參照第1圖,低沸點高蒸氣壓液體12可依系統所需維持溫度來選擇液 體娜,低沸點高蒸氣壓液體12灌入導熱腔體11之腔體可爲街職計以 利提高液-氣轉換的鄉旨。低沸點高蒸氣壓液體12變爲蒸氣之後經由吸液體 海綿16吸走濕氣,並經過氣液體分離膜13把乾熱高壓氣體奴乾氣讎 存槽14。再利用高壓氣體釋放讎15推動散熱風扇17,並帶動薄型發電 機擬且18產生電力;吸收濕氣的吸液體海綿16會經由散熱風扇17纖熱 模組19(可吸入外部冷空氣)來散熱,把高溫蒸氣變成低溫低沸點驗氣壓 液體12 ;參照第3圖,散顯組19(可吸入外部冷空氣雕易於散熱和吸 8 200908860 入冷空氣來設計和使用特定材料,散19可免除風臟21的設計’ 以增加系統的散謙率·高壓氣體釋15把乾氣讎存槽14的乾熱 高壓空氣側向推動散熱風扇17並帶動薄型發電機模組18 ·散熱風扇17可 模組a胃iw磁反應來產生電力•參照第4圖,s極u型 磁鐵32、N極磁鐵31和發電線圈30可爲不同形狀和設計,使利用推動散 17來胃動薄型發電ϋ胃組18,讓磁場與發電線圈30交互作用產生 發電效力,該發電依不同設計可產生AC交流電或DC直流電· 雖然本發明已以具體之較佳實施例揭露如上,然其並非用以限定本發 明,任何熟習此項技藝者,在不脫離本發明之精神和範圍內,仍可作些許 的更動與潤飾,因此本發明之保護範圍當視後附之申請專利範圍所界定者 爲準。 200908860 【圖式簡單說明】 第1圖係顯示熱致發電散熱系統的外觀圖; 第2圖係顯示導熱腔體的剖面圖; 第3圖係顯示散熱模組的剖面運作圖; 第4圖係顯示薄型發電機|幾且的剖面運作圖; 【主要元件符號說明】 10〜發熱體 11〜導熱腔體 12〜低沸點高蒸氣壓液體(沸點搬40〜50oC) 13〜氣液體分_ 14〜乾氣體游槽 15〜高壓氣體釋放模組 16〜吸液體海綿 17〜散熱風扇 18〜薄型麵機麵 19〜散熱模組(可吸入外部冷空氣) 20〜冷空氣 21〜風擋板 22〜孔洞 3〇〜發電線圈 31〜N極磁鐵 32〜S極U型磁鐵32200908860 VIII. If there is a chemical formula in this case, please disclose the chemical formula that best shows the characteristics of the invention: IX. Description of the invention: [Technical field of the invention] The present invention relates to a thermal power generation heat dissipation system, in particular to a method for Notebook computer or other heat sink to achieve heat dissipation and power generation efficiency. [Prior Art] Referring to Figure 1, it shows a low boiling point high vapor pressure liquid 12 (boiling point temperature 40~50 ° C), and is injected into the heat conduction. The case of the cavity 11. The heat generating body 1 turns the low boiling point high vapor pressure liquid 12 into steam by the heat transfer chamber 11, and the steam injects the dry high pressure gas into the dry gas storage tank 14 via the liquid absorbing sponge 16 and the gas liquid separation film 13. The high-pressure gas release module 15 pushes the heat-dissipating fan 17 with dry high-pressure gas and drives the thin-type generator module 18; and the moisture of the vapor in the heat-conducting cavity 11 is absorbed by the liquid-absorbent sponge 16, and the liquid-absorbent sponge 16 passes through the heat-dissipating fan 17 And the heat dissipating surface 19, which inhales external cold air to dissipate heat, and converts the high temperature vapor into a low temperature, low boiling point, high vapor pressure liquid 12. [Invention] The present invention is used for a notebook computer or other heat sink to achieve heat dissipation and power generation. Energy-saving utility, providing a thermal power generation heat dissipation system, comprising a heat-conducting cavity, a low boiling point high vapor pressure liquid (boiling point 〜40~50〇C), a gas liquid separation membrane, a dry gas leg storage tank-high pressure gas The release module, a liquid suction sponge, a heat dissipation module, a cooling fan and a thin generator module. The low boiling high vapor pressure liquid can be subjected to liquid-gas phase inversion of the heat transfer chamber, and the low boiling high vapor pressure vapor is passed through the gas liquid separation membrane to store the dry heat high pressure gas in the dry gas storage tank. The dry heat and high pressure gas in the dry gas storage tank is used to drive the cooling fan through the high pressure gas release module and drive the thin generator module. Before the low boiling point high vapor pressure vapor passes through the gas liquid separation membrane, it absorbs moisture through the liquid absorption sponge of 6 200908860, and the liquid suction sponge is cooled by the heat dissipation module and the cooling fan to return the moisture to the low boiling point and high vapor pressure liquid state. . Using this method to circulate heat and promote thin-type generator beach power generation. The thermal power generation heat dissipation system of the present invention can be used to perform heat dissipation and power generation through a heating element to reduce system temperature and generate electricity, and is convenient to use in a notebook computer and Other Thermally Efficient Systems • The Thermal Power Generation Cooling System continuously helps to dissipate heat and provide additional power to increase the continued use of your work system. [Embodiment] [First Embodiment] Referring to Fig. 1, there is shown a thermoelectric power generation heat dissipation system of the present invention comprising a heat transfer chamber 11 and a low boiling point high vapor pressure liquid 12 (boiling point temperature 40 to 50 〇〇) , a gas liquid separation membrane 13 , a dry gas storage tank 14 , a high pressure gas release module 15 , a liquid suction surface 16 , a scatter 19 (inhalable external cold air), a cooling fan 17 and a thin generator 雠18 〇 low boiling point high vapor pressure liquid 12 (boiling point temperature 40~50DC) is poured into the heat conducting cavity 11 〇 the heating element 1 使 turns the low boiling high vapor pressure liquid 12 into steam by the heat conducting cavity 11 , the vapor passes through the liquid absorbing liquid The sponge 16 and the gas liquid separation membrane 13 inject dry heat and high pressure gas into the dry gas storage tank 14. The high pressure gas release module 15 uses the dry heat and high pressure gas to push the heat radiating fan 17, and drives the thin generator module 18; and the vapor moisture The liquid sponge 16 is sucked and sucked, and the liquid sponge 16 is dissipated through the heat dissipating fan 17 and the heat dissipating module 19 (inhalable external cold air), and the high temperature vapor is turned into a low temperature, low boiling point, high vapor, liquid 12 • a heat conducting cavity 11 internal The structure of any low-boiling high-vapor pressure liquid 12 can be made. Referring to Fig. 2, the inside of the heat-conducting cavity 11 can be made into a space or a column or any shape, and the thin-like liquid sponge 16 can be made to make the low-boiling high-vapor. The pressurized liquid 12 is easily vaporized by the heat-conducting cavity η to form a vapor, and the vapor is injected into the dry gas storage tank 14 via the thin-type liquid-absorbent sponge 16 at the upper end and the gas-liquid fraction _13, and the moisture passes through the liquid-absorbent sponge. 16 Absorbing 'absorbent liquid-absorbent sponge 16 will dissipate heat through cooling fan 17 and heat-dissipating air> to become low-temperature low-boiling high-vapor pressure liquid 12 and then enter the heat-conducting cavity 11 200908860 Do -4 cycles · Heat dissipation The module 19 (inhalable external cold air) can be constructed to cool any liquid-absorbent sponge 16 that absorbs the low boiling high vapor pressure liquid 12. Referring to FIG. 3, the heat dissipation module 19 can dig the hole 22 at the upper end and the side end, and the outer casing can be made of an easily heat conductive material. The outer wall of the hole 22 can be made by the gas liquid separation film 13, and the cooling fan 17 passes the cold air 20 through the hole. 22 and the wind baffle 21 uniformly blows through the inside and the upper and lower sides of the heat dissipating _ 19 to achieve rapid cooling. The high-pressure gas releasing surface 15 pushes the dry heat high-pressure air of the dry gas trough 14 laterally to push the cooling fan 17 and drive the thin hair Motor Module Μ Referring to FIG. 4, the heat-dissipating fan 17 can be connected to the S-pole type magnet 32. The S-pole U-shaped magnet 32 does not touch the power generating coil 30, and the power generating coil 30 has a drain magnet 31 therein. The gate magnet 31 is covered by the S-pole U-shaped magnet 32 so that the gate magnet 31 does not touch each other in the power generating coil 3, and the S-pole magnet 32 is coated with the gate magnet 31. The buckling magnet 31 acts as the 'power' effect of the heat radiating fan 17, and the magnetic field of the S-pole type magnet 32 and the bungee magnet 31 surrounds the power generating coil 30 to generate a power generation effect, and the thin type generator module 18 can generate DC DC / high pressure gas release and 15 dry gas storage tanks The dry heat and high pressure air of 14 pushes the heat fan 侧 laterally, turns the dry heat and high pressure gas to the discharge, and drives the cooling fan 17 to blow the upper end cold air to the heat dissipation module 19 (the suctionable outside 17 #gastric thin type generator) The module 18 generates electric power. [Second embodiment] Referring to Fig. 1, the low boiling point high vapor pressure liquid 12 can select the liquid Na according to the temperature required by the system, and the low boiling point high vapor pressure liquid 12 is poured into the heat transfer cavity 11 The cavity may be a street job to improve the liquid-gas conversion. The low-boiling high-vapor pressure liquid 12 becomes vapor and then absorbs moisture through the liquid-absorbent sponge 16 and passes through the gas-liquid separation membrane 13 to dry heat. The high-pressure gas slave gas storage tank 14. The high-pressure gas release 雠15 is used to push the heat-dissipating fan 17, and the thin-type generator is driven to generate electricity; the liquid-absorbent liquid sponge 16 that absorbs moisture passes through the heat-dissipating fan 17 19 (inhalation of external cold air) to dissipate heat, turn high-temperature steam into low-temperature and low-boiling test air pressure liquid 12; refer to Figure 3, disperse group 19 (inhalable external cold air engraving is easy to dissipate heat and suck 8 200908860 into cold air to design And using specific materials, scattered 19 Eliminating the design of the wind and dirt 21' to increase the system's sloppy rate and high pressure gas release 15 The dry heat and high pressure air of the dry gas storage tank 14 laterally pushes the cooling fan 17 and drives the thin generator module 18 · The cooling fan 17 can The module a stomach iw magnetically reacts to generate electric power. Referring to Fig. 4, the s-electrode u-type magnet 32, the N-pole magnet 31, and the power generating coil 30 can be of different shapes and designs, so that the use of the push-dissipation 17 can be used to generate a thin stomach. Group 18, causing the magnetic field to interact with the power generating coil 30 to generate power generation efficiency, which may be generated by AC alternating current or DC direct current according to different designs. Although the present invention has been disclosed in the above preferred embodiments, it is not intended to limit the present invention. Any modifications and refinements may be made without departing from the spirit and scope of the invention, and the scope of the invention is defined by the scope of the appended claims. 200908860 [Simple diagram of the diagram] The first diagram shows the appearance of the heat-generating heat dissipation system; the second diagram shows the profile of the heat-conducting cavity; the third diagram shows the profile diagram of the heat-dissipation module; Display thin-type generator|Several section operation diagram; [Main component symbol description] 10~heating body 11~thermal cavity 12~low boiling point high vapor pressure liquid (boiling point 40~50oC) 13~ gas liquid _ 14~ Dry gas trough 15 ~ high pressure gas release module 16 ~ suction liquid sponge 17 ~ cooling fan 18 ~ thin profile surface 19 ~ heat dissipation module (inhalable external cold air) 20 ~ cold air 21 ~ wind baffle 22 ~ hole 3〇~Power generation coil 31~N pole magnet 32~S pole U type magnet 32