M334922 八、新型說明: 【新型所屬之技#ί領域】 本創作係關於一種地下埋設之冷熱交換管;具體而言,本創作 係關於一種結合熱交換模組之冷熱交換管,利用地底溫度與外界 溫度之差異與待利用裝置進行熱交換,以達到節能環保之目標。 【先前技術】 i 地表和地殼各點的溫度是不均勻的,據研究顯示係取決於以 下因素··岩漿的侵入、噴出和冷卻過程(内部熱源),太陽輻射的各 種週期性變化(外部熱源),氣候、地下水活動和人為因素,以及地 表和地殼物質的結構及其熱物理參數。一般咸認為地殼的熱狀態 受内部熱源和外部熱源的雙重制約一内部熱源是穩態的,而外部 熱源則是變化的。 太陽輪射源對地球表面溫度影響的程度各不相同。一般係將太 陽輻射對地殼加熱所影響的深度作為一個分界面,稱之為恆溫 層。恆溫層以上為變溫層,以下則為增溫層,增溫層之平均地溫 • 梯度為每公里向下增加攝氏30度,各地恆溫層深度和溫度則需根 據鑽孔長期觀測結果來測定。依據統計資料,各地恆溫層的深度 及其溫度值並不相同,且明顯地與各地區所處之緯度相關,例如 中國已測得的恆溫層深度在15〜30公尺之間,溫度則介於10〜 23 c °就實際應用面來看,不論是汲取井水或於地下室儲物皆有 此種原理之應用一由於地下溫度變化不大,冬季時井水的溫度相 車义地表為高’在地下室貯存蔬果可以防凍;夏季時井水的溫度相 5 M334922 較地表為低,在地下室 之現象。 貯存蔬果财以防腐—賴「冬暖夏涼 【新型内容】 ★本創作之主要目的在於提供—獅下概之冷齡換管,供與 建築、、、。構配合使用’彻地底溫度及外界溫度之差異與待利用裝置 進行熱交換,以達到節能環保之目標。 ▲本創作之另-目的在於提供-種地下埋設之冷熱交換管,冷熱 交換管具有核及触換她,触換敝無水祕可熱傳導地 相連’可賴部分供水管路以節省加熱供水管路_水所需使用之 能源。 本創作之另一目的在於提供一種地下埋設之冷熱交換管,冷熱 交換管具有本體及熱交換模組,熱交換模組與具高熱傳導性之管線 相連,可增加建築結構調節溫度之機能。 本創作地下埋設之冷熱交換管包含本體及熱交換模組。本體具 有笞壁且係部分埋設於地表下,管壁内則具有封閉空間。熱交換模 組包含液態材料、熱分流隔離層以及熱交換裝置。其中,熱分流隔 離層係設置容納於封閉空間中並與管壁具有固定之相對位置,且熱 分流隔離層係區隔封閉空間形成熱交換管道及回流管道彼此首尾 連通;液態材料係設置容納於封閉空間内,並可於熱交換管道及回 流管道間循環流動而與本體進行熱交換。 在較佳實施方式中,熱交換裝置係設置於本體上方,且熱交換 模組係進一步具有壓縮幫浦,供循環熱交換管道内之液態材料與熱 6 M334922 交換裝置進行熱交換後,經喊管道回流至熱交齡道。此外,熱 为流Pm離層較佳係包含熱分制練管,且熱分流循環管具有内管壁 及外管壁包覆圍繞内管壁形成位於内管壁與外管壁間之真空層,其 中外管壁與管壁形成熱交換管道,且熱交換管道係與熱交換裝置可 熱傳導地相連。 【實施方式】 本創作提供-種地下埋設之冷熱交鮮,供與建築結構配合使 用’可利用地底溫度&外界溫度之差I與待利用裝置進行熱交 換以達到郎旎環保之目標。本創作地下埋設之冷熱交換管較佳 係應用於樓房建築結構,例如家用住宅、別墅或宿舍、飯店、旅 館等建築物。然而在不同實施财,本創作地下埋設之冷熱交換 管亦可應用於如商用大樓、廠房建築、倉儲建築、醫院病房、車 站機昜4或其他類型之複合式建築結構。本創作地下埋設之冷熱 父換官較佳係具有本體及熱交賴組彼此可熱傳導軸連,本體 之至少一部分埋設於地表下,熱交換模組則與供水系統可熱傳導 藉自地底溫度及外界溫紅差異,可賴部分供水管路 以喊省加触水管軸肖水所需使狀能源。 此外在其他較佳實施例中,本創作地下埋設之冷熱交換管較佳 亦包^將熱交換模組連接至—具高熱傳雜之熱交換管線,並藉 該^乂,管線與外部之待利用裝置可熱傳導地相連。由於管線本 立/、有而…、傳導性,因此可快速地傳遞熱能並使熱交換模組與外 ^之待利用裝置兩者間達至一熱平衡狀態。當外界溫度低時,熱 祕自熱交換模組傳導至外部待利用裝置,除了維持外部待利用 7 M334922 裝置之溫度’亦領少相源之·;料界 制用裝置開始發散熱能,則熱能將自外部待利用;二: 夕^二Γ提供散熱降溫之功能,亦可減少為降低溫=額 外耗費之Μ。此處所言之待_裝置,係包含如電暖氣管、空 調系統★、冷凝n、保溫裝置如茶壺座、咖啡壺鱗、建築結構外 牆、建祕構地板,或其減置賊齡_部而可增加建築結 構調節溫度機能者。此處所言之高熱傳導性,係指管線具有易^M334922 VIII. New Description: [New Technology] #ί领域 This is a cold and heat exchange tube buried underground; specifically, this creation is about a cold and heat exchange tube combined with a heat exchange module, using the ground temperature and The difference in outside temperature is heat exchanged with the device to be used to achieve the goal of energy saving and environmental protection. [Prior Art] i The temperature at each point of the earth's surface and the crust is uneven. According to research, the following factors are involved: • Magma intrusion, ejection and cooling processes (internal heat source), various periodic changes in solar radiation (external heat source) ), climate, groundwater activities and human factors, as well as the structure of the surface and crustal materials and their thermophysical parameters. It is generally believed that the thermal state of the earth's crust is governed by both internal and external heat sources. The internal heat source is steady state and the external heat source is variable. The extent to which the sun's wheel source has an effect on the Earth's surface temperature varies. Generally, the depth affected by the heating of the earth's crust by solar radiation is taken as an interface, which is called a constant temperature layer. Above the constant temperature layer is the temperature-changing layer, the following is the warming layer, and the average ground temperature of the warming layer • The gradient is increased by 30 degrees Celsius per kilometer. The depth and temperature of the constant temperature layer are determined according to the long-term observation results of the borehole. According to the statistics, the depths of the constant temperature layers and their temperature values are not the same, and are obviously related to the latitude of each region. For example, the measured depth of the constant temperature layer in China is between 15 and 30 meters, and the temperature is From 10 to 23 c ° in terms of practical application, whether it is drawing well water or storing in the basement, there is such a principle. Because the underground temperature does not change much, the temperature of the well water in winter is high. 'Storage of fruits and vegetables in the basement can prevent freezing; in summer, the temperature of the well water is 5 M334922, which is lower than the surface and is in the basement. Storage of fruits and vegetables for anti-corrosion - Lai "Winter and cool summer [new content] ★ The main purpose of this creation is to provide the cold-changing tube of the lion, for use with the building, the construction, and the use of 'the bottom temperature and the outside world The difference in temperature is related to the heat exchange of the device to be used to achieve the goal of energy saving and environmental protection. ▲ Another purpose of this creation is to provide a kind of underground hot and cold exchange tube. The cold and heat exchange tube has a core and touches her, and the contact is replaced with water. The secret can be connected to the heat conduction section to save some of the water supply pipeline to save the energy needed to heat the water supply pipeline _ water. Another object of the present invention is to provide a cold-hot exchange tube buried underground, which has a body and heat exchange. The module and the heat exchange module are connected with the pipeline with high thermal conductivity, which can increase the temperature adjustment function of the building structure. The cold heat exchange tube buried in the creation includes the body and the heat exchange module. The body has a wall and is partially embedded in Under the surface, there is a closed space inside the pipe wall. The heat exchange module comprises a liquid material, a heat splitting isolation layer and a heat exchange device. The flow separation layer is disposed in the closed space and has a fixed relative position with the pipe wall, and the heat splitting separation layer separates the closed space to form a heat exchange pipe and the return pipe are connected to each other end to end; the liquid material is disposed in the closed space. And circulating heat between the heat exchange pipe and the return pipe to exchange heat with the body. In a preferred embodiment, the heat exchange device is disposed above the body, and the heat exchange module further has a compression pump for circulation The liquid material in the heat exchange pipe is heat-exchanged with the hot 6 M334922 exchange device, and then returned to the thermal ageing road through the shouting pipe. In addition, the heat flow Pm separation layer preferably includes a heat splitting pipe, and the heat splitting cycle The tube has an inner tube wall and an outer tube wall covering a vacuum layer formed around the inner tube wall between the inner tube wall and the outer tube wall, wherein the outer tube wall forms a heat exchange tube with the tube wall, and the heat exchange tube system and the heat exchange device It can be connected thermally. [Embodiment] This creation provides a kind of underground hot and cold storage for use with the building structure 'utility underground temperature & outside The temperature difference I is heat exchanged with the device to be used to achieve the goal of Langji Environmental Protection. The cold heat exchange tube buried in the creation of the creation is preferably applied to the building structure, such as a residential house, a villa or a dormitory, a hotel, a hotel, etc. However, in different implementations, the cold and heat exchange tubes buried in the creation of this creation can also be applied to commercial buildings, factory buildings, warehouse buildings, hospital wards, station machinery 4 or other types of composite building structures. The hot and cold father change officer preferably has a body and a heat-distributing group which are mutually heat-conducting, and at least a part of the body is buried under the surface, and the heat exchange module and the water supply system can be thermally transferred by the difference between the ground temperature and the outside temperature red. In some other preferred embodiments, the hot and cold exchange tube buried in the underground is preferably connected to the heat exchange module. The heat exchange pipeline with high heat transfer is used, and the pipeline is thermally conductively connected to the external device to be utilized. Since the pipeline is intrinsic,/or..., conductive, the heat energy can be quickly transferred and the heat exchange module and the device to be used can reach a thermal equilibrium state. When the outside temperature is low, the heat secrets the heat exchange module to the external device to be used, in addition to maintaining the temperature of the externally used 7 M334922 device, which also leads to less phase source; the material boundary device starts to generate heat dissipation, then The heat energy will be used from the outside; 2: Xi ^ 2 Γ provides the function of cooling and cooling, and can also be reduced to reduce the temperature = additional cost. The device to be used here includes, for example, an electric heating pipe, an air conditioning system, a condensation n, a heat preservation device such as a teapot, a coffee pot scale, an exterior wall of a building structure, a secret floor, or a reduction of the age of the thief. And can increase the temperature of the building structure to adjust the function. The high thermal conductivity referred to here means that the pipeline has easy to ^
集熱及散熱之特性,舉凡金屬、合金或高分子材料等具前述特性 者皆屬之。 圖1所示為本創作地下埋設之冷熱交換管之一較佳實施例。如 圖1所示’賴作地下埋設之冷熱交鮮較佳係與絲結構· 配合使用,包含本體300與熱交換模組4〇〇,且彼此係可熱傳導地 相連。在此較佳實施例中,本體300之至少一部份係埋設於地表 100下。換言之,冷熱交換管之本體300係相對於地表1〇〇連結於 建築結構200下方,除伸入地層中與周圍區域達至一熱平衡狀態, 亦可作為建桌結構200之辅助支樓。因此,如圖1之較佳實施例 所示,與本體300相應設置之熱交換模組4〇〇將與本體3〇〇及其 周圍區域具有同樣或相近似之溫度。如圖1所示,本體3QQ較佳 係具有管壁310,管壁310内則具有封閉空間320。管壁31〇較佳 係由一具高熱傳導性之材質所製成,以快速與周圍區域達至熱平 衡狀態。 如圖1所示,熱交換模組400較佳係包含液態材料5〇〇、熱分 流隔離層600與熱交換裝置700。如圖1之較佳實施例所示,液態 材料500係設置容納於封閉空間320内,供與本體3〇〇進行熱交 8 M334922 換。而為提高熱傳導之效率,液態材料500較佳係包含使用冷煤 材料,以快速與本體300及管壁310進行熱交換。然而在其他不 同實施例中,液態材料5〇〇亦包含使用其他替代冷煤或具有低比 熱之液態材質。如圖1所示,熱分流隔離層6〇〇較佳係設置容納 於封閉空間320中並與管壁310具有固定之相對位置。在如圖1 所示之較佳實施例中,熱分流隔離層6〇〇之頂端與本體3〇〇之頂 h係固疋s免置於同一水平面上。較佳之固定方式包含於兩者之頂 端覆設環狀定位蓋,或是以鉚接或焊接之方式於兩者頂端間跨設 定位條,以維持彼此之相對距離。 如圖1所示,熱分流隔離層600較佳係用於區隔封閉空間32〇 形成熱父換管道601及回流管道602彼此首尾連通,且液態材料 500係可於熱交換管道6〇1及回流管道6〇2間循環流動。如圖j之 較佳實施例所示,熱交換裝置700係設置於本體300上方,其中 熱交換模組400進一步具有壓縮幫浦410,供循環熱交換管道6〇1 内之液悲材料500與熱交換裝置700進行熱交換後,經回流管道 602回流至熱交換管道601。此處所言之設置於本體3〇〇上方,如 圖1所示,係指熱交換裝置410設置於本體300與建築結構2〇〇 地板間之區域而言;然而在不同實施例中,熱交換裝置41〇亦可 設置於建築結構200之地下室或是建築結構200外圍區域之地面 100。在較佳實施方式中,當外界溫度係低於本體300所處區域之 地下溫度,回流管道602之溫度係小於熱交換管道601 ;當本體所 處區域之地下溫度係低於外界溫度,回流管道6〇2之溫度係大於 熱交換管道601。 如圖2所示為本創作地下埋設之冷熱交換管其熱分流隔離層 9 M334922 600之一較佳實施例。在此較佳實施例中,係以熱分流循環管610 作為冷熱交換管之熱分流隔離層600。如圖2所示,熱分流循環管 610較佳係具有内管壁611及外管壁612,外管壁612包覆圍繞内 管壁611形成位於内管壁611與外管壁612間之真空層613。如圖 2之較佳實施例所示,外管壁612與管壁310係形成熱交換管道 601 ’且熱交換管道601與熱交換裝置700係可熱傳導地相連。此 外’為固定熱分流循環管610與管壁310間之相對位置,如圖2 所示’熱分流循環管610較佳係於熱交換管道601設有固定支架 616 °固定支架616係連結設置於管壁310内緣及外管壁612之表 面間’以定位熱分流循環管610與管壁310間之相對位置。 在如圖3a及圖3b所示之實施例中,熱分流循環管610較佳係 包含上蓋體614及下蓋體615,上蓋體614密封内管壁011及外管 壁612之頂端,且下蓋體615密封内管壁611及外管壁612之底 鳊以形成真空層613。如圖3b之較佳實施例所示,為便於本體3〇〇 之埋入並有利於液態材料500之回流與循環,管壁310底端係包 含連結有椎狀物311。然而在其他不同實施例中,亦包含直接將管 壁310之底端封平,或是將管壁31〇底端成形為其他有利於液態 材料500循環之形狀。此外,如圖3c之實施例所示,上蓋體614 較佳亦包含連結成形有一液態材料循環管,其中液態材料循環管 係與熱父換裝置700可熱傳導地相連,並直接與管壁31〇互相連 通,以利液態材料500於本體3〇〇及熱交換裝置70〇間之循環與 熱交換。並且,為避免熱傳導時可能造成之逸散與損失,較佳係 於熱分流隔_ 6GG之外表φ覆設―隔熱機。在雜佳實施例 中,隔熱材料即可包覆設置於熱分流循環管61〇外管壁612之外 M334922 表面。 在此,請再次參閱圖2。如圖2之較佳實施例所示,為使熱交 換模組具有多元化應用之可能,本創作地下埋設之冷熱交換管較 佳另包含設有熱交換管線820及集熱裝置710。如圖2所示,熱交 換管線820較佳係分別與集熱裝置710及熱交換裝置700可熱傳 導地相連。如圖2之較佳實施例所示,熱交換管線82〇係具有第 一端821及第二端822,熱交換管線820之第一端821係設置於集 _ 熱裝置710内,第一端822則與熱交換裝置410可熱傳導地相連。 如圖2所示,當熱交換管道601與本體3〇〇間進行熱交換,熱交 換管道601對熱交換裝置700進行熱傳導,且熱交換裝置7〇〇係 分別與熱交換管道601及熱交換管線82〇進行熱交換以達至一熱 平衡狀態;此外,當熱交換裝置700與熱交換管線82〇進行熱交 換,熱交換管線820同時與集熱裝置71〇進行熱交換以達至一熱 平衡狀態。 ^ 在較佳實施方式中,熱交換管線82〇較佳係由具高熱傳導性之 • ㈣所形成,舉凡金屬、合金、高分子材料等具有易於集熱及散 熱特性者皆屬之。因此’為避免熱能之發散逸失或受外界溫度之 ’ 干擾而減低其效果,熱交換管線82G較佳係進-步包含隔熱材料 包覆於熱交換管線82G之外表面。此外,如圖2所示,熱交換管 線82〇較佳亦包含設置有如冷煤等之液態材料(未標示)與循環幫浦 830,於熱交換管線82G内往復循環而與熱錢裝置進行熱交 換。在此難實施射,敏難置進—步包含隔熱材料包 覆熱交換裝置7GG之外表面,且熱交縣置較佳係包含一具 高熱傳導性材質所形成之導熱管線_(未缘示),以利熱能之傳導 M334922 與交換。 如圖2之較佳實施例所示,集熱裝置71〇另包含與熱輪出管路 800可熱傳導地相連’當熱交換管線_對集熱裝f彻進行熱傳 導,熱裝置710與熱輸出管路_進行熱交換以達至_^衡 狀態。如圖2所示’在此較佳實施例中,集熱裳置71〇進二步與 熱輸出管路800可熱傳導地相連,當熱交換管線82〇藉第—端^ 與熱交換裝置7GG間進行熱交換,第二端822對集熱裝置爪進 • 行熱傳導’集熱裝置71G與熱輸出管路_彼此聰熱交換管線 =〇達至-熱平衡狀態,且集熱裝置71〇與熱輸出管路_進二熱 交換。 此外,為加強熱交換之效果,如圖2所示,集熱裝置71〇内較 佳係包含具高熱料性财卿狀導鮮線_,錢—步設置 有,紐料包覆餘裝置之外表面,以防止熱能之發散ς失 或受外界溫度之干擾而減低其效果。如圖2之較佳實施例所示, 集熱裝置71G内裝載之導熱管線_較佳係與熱交換管線820之 ❿ 帛一端幻1以及熱輸出管路_之第-端431彼此交錯設置,藉 自導熱管線900快速集散熱能之特性,使熱交換管線82〇及集熱 裝置710無輸出管路__速達至一熱平衡狀態 。在如圖2 獅之實酬巾,導熱錄_難細齡錢_合金所形 成’然而在不同實施例巾,亦可使用其他金屬、合金或高分子材 料等具高熱傳導性材質形成之。 /如圖2之較佳實施例所示,熱輸出管路43〇包含但不限於供水 系j U卜界處於低溫或高溫狀態,本創作地下埋設之冷熱交 換模、組400與供水系統結合後,皆有其不同之應用·· 12 M334922 其一,當外界低溫時,則地底溫度相對較高,集熱裝置及 熱交換管線82〇能發揮集熱保溫的功能,對熱輸出管路_形成 增溫的效果。如圖2之較佳實施例所示,當熱輸出管路_設置 為供水系統,此時熱輸出管路_之第一端謝即為進水管路, 熱輸出管路800之第二端8〇2則設置為出水管路。如目2所示, 齡管路801較佳係部分與集熱裝置710可熱傳導地相連,當供 水自進水管路801通過集熱裝置71〇進行熱交換而升高溫度,增 • 溫後之供水自出水管路802輸出後可供使用者利用。如圖2之較 佳實施例所*㉟輸出管路_另包含儲水裝置_設置於出水 g路802,供溫水自出水管路8()2輸出後儲存之。儲水裝置議較 佳係進-步設置有輸出管線m及控制閥如,供使用者依需求利 用。此處所έ之依f求利用,係指使用者可將儲水裝置_所儲 存之溫水作為-般清潔洗滌之用。然而在其他較佳實施例中,亦 包含於輸出管線812加裝外部熱源,供使用者進一步加熱自儲水 裝置_輸出之溫水,以作為洗澡或為其他必要之用途。在此較 _ 佳實⑽中’使用者將可節省加熱供水祕管軸用水所需使用之 能源。 ^一/ *外界鬲溫時,則地底溫度相對較低,集熱裝置71〇及 ”、、交換g線82〇能發揮散熱冷卻的功能,對熱輸出管路細形成 降溫的效果。如圖2之較佳實施例所示,當供水自進水管路觀 ,過集熱裝置71〇進行熱交換而降低溫度,降溫後之供水自出水 =路8G2輸出後將可供使用者進—步儀。如圖2所示,自出水 g路:輸出之冷水可進—步連接至空調祕之冷顧,除可吸 收冷U斤發散之熱能,亦可減少冷凝器對外界之排熱,符合環 13 M334922 保之目的與要求。 此外,在其他較佳實施例中,熱輪出管路800亦包含具高熱傳 導性之管線而與待利用裝置相連,熱輪出管路8〇〇藉管線具有之 易於集熱及散熱之特性,可對待利用裝置進行熱交換以發揮調節 溫度之功能。如前所述,待利用裝置包含電暖氣管、空調系統、 冷凝器、保溫裝置如茶壺座、咖啡壺座等、建築結構外牆、建築 結構地板,或其他設置於建築結構内部而可增加建築結構調節溫 # 度機能者皆謂之。當熱輸出管路_為具高熱傳導性之管線,無 渝外界處於低溫或高溫狀態,本創作冷熱交換管之熱交換模組4⑻ 與該管線結合後,皆有其不同之應用: 其一,當外界低溫時,則地底溫度相對較高,集熱裝置71〇及 熱交換管線820能發揮集熱保溫的功能,對熱輸出管路形成 增溫的效果。當待利用裝置為電暖氣管裝設於建築結構2⑻之地 板下方,或是將熱輸出管路_進一步埋設於建築結構2〇〇之外 牆内丄可形成相當於傳統之「炕」結構,除使室内維持溫暖,亦 Φ 可以痛省相關電源之使用與支出。此外,若當地環餅可並發現 地底具有細或地熱射選擇骸數量之本體3⑻深埋入靠^熱 源或地熱處,以操取熱能並做進一步之利用。 其一,當外界高溫時,則地底溫度相對較低,集熱裝置及 熱交換管線820能發揮散熱冷卻的功能,對熱輸出管路_則形 成降溫的效果。此時,熱輸出管路_可與設置於建築物2〇〇夕^ 滅屋狀導歸質管線械,可適度發侧受紼輻射 累積之熱能,除保持建築結構·之涼爽,亦可節省為維^ 涼爽所耗費之空調系統電力使用及相關支出。 、至内 M334922 本創作已由上述相關實施例加以描述,然而上述實施例僅為實 施本創作之範例。必需指出的是,已揭露之實施例並未限制本創作 之範圍。相反地,包含於申請專利範圍之精神及範圍之修改及均等 設置均包含於本創作之範圍内。 【圖式簡單說明】 ® 1所示為本_地下埋設之冷熱交齡之—較佳實施例; • ® 2所示為本創作地下埋設之冷敏換管之-錄實施例; 圖3a所示為本齡地下埋設之冷熱交鮮之—較佳實施例,· 圖3b所示為本創作地下埋設之冷熱交換管之一較佳實施例; 圖3c所示為本創作地下埋設之冷熱交換管之另一較佳實施例。 【主要元件符號說明】 100地表 藝 200建築結構 300本體 310管壁 311椎狀物 320封閉空間 400熱交換模組 410壓縮幫浦 500液態材料 15 M334922 600熱分流隔離層 601熱交換管道 602回流管道 610熱分流循環管 611内管壁 612外管壁 613真空層 614上蓋體 615下蓋體 616固定支架 700熱交換裝置 710集熱裝置 800熱輸出管路、供水系統 801進水管路 802出水管路 810儲水裝置 811控制閥 812輸出管線 820熱交換管線 821第一端 822第二端 830循環幫浦 M334922 900導熱管線The characteristics of heat collection and heat dissipation are common to metals, alloys or polymer materials. Fig. 1 shows a preferred embodiment of a cold heat exchange tube for underground construction. As shown in Fig. 1, the combination of the hot and cold fresh grounding system and the wire structure is included, and the body 300 and the heat exchange module 4 are included, and are thermally conductively connected to each other. In the preferred embodiment, at least a portion of the body 300 is embedded under the surface 100. In other words, the body 300 of the cold heat exchange tube is connected to the lower side of the building structure 200 with respect to the surface of the building. In addition to reaching a thermal equilibrium state in the ground and surrounding areas, it can also serve as an auxiliary branch of the table structure 200. Thus, as shown in the preferred embodiment of Figure 1, the heat exchange module 4, which is disposed corresponding to the body 300, will have the same or similar temperature as the body 3 and its surrounding area. As shown in Fig. 1, the body 3QQ preferably has a tube wall 310, and the tube wall 310 has a closed space 320 therein. The tube wall 31 is preferably made of a material having a high thermal conductivity to quickly reach a thermal equilibrium with the surrounding area. As shown in FIG. 1, the heat exchange module 400 preferably includes a liquid material 5, a heat split isolation layer 600, and a heat exchange device 700. As shown in the preferred embodiment of Fig. 1, the liquid material 500 is disposed in the enclosed space 320 for heat exchange with the body 3 8 8 M334922. To increase the efficiency of heat transfer, the liquid material 500 preferably includes the use of a cold coal material for rapid heat exchange with the body 300 and the tube wall 310. In other various embodiments, however, the liquid material 5〇〇 also includes other alternative cold coal or liquid materials having a low specific heat. As shown in Fig. 1, the heat split isolation layer 6 is preferably disposed in the enclosed space 320 and has a fixed relative position to the tube wall 310. In the preferred embodiment shown in Figure 1, the top end of the thermal shunt isolation layer 6〇〇 is offset from the top of the body 3〇〇 from the same level. Preferably, the fixing means comprises covering the annular positioning cover at the top end of the two, or arranging the positioning strips between the top ends of the two by riveting or welding to maintain the relative distance between each other. As shown in FIG. 1, the heat split isolation layer 600 is preferably used to separate the closed space 32, and the hot parent exchange pipe 601 and the return pipe 602 are connected to each other end to end, and the liquid material 500 is available in the heat exchange pipe 6〇1 and The return pipe flows cyclically between 6 and 2. As shown in the preferred embodiment of FIG. 7, the heat exchange device 700 is disposed above the body 300, wherein the heat exchange module 400 further has a compression pump 410 for the liquid stagnation material 500 in the circulating heat exchange conduit 6〇1. After the heat exchange device 700 performs heat exchange, it is returned to the heat exchange conduit 601 via the return conduit 602. As used herein, it is disposed above the body 3〇〇, as shown in FIG. 1, which means that the heat exchange device 410 is disposed in the region between the body 300 and the floor of the building structure; however, in different embodiments, the heat exchange The device 41 can also be disposed in the basement of the building structure 200 or the ground 100 in the peripheral region of the building structure 200. In a preferred embodiment, when the ambient temperature is lower than the subsurface temperature of the region where the body 300 is located, the temperature of the return conduit 602 is smaller than the heat exchange conduit 601; when the underground temperature of the region where the body is located is lower than the ambient temperature, the return conduit The temperature of 6〇2 is greater than the heat exchange conduit 601. As shown in Fig. 2, a preferred embodiment of the thermal splitter isolation layer 9 M334922 600 for creating a submerged cold heat exchange tube is shown. In the preferred embodiment, the heat split circulation tube 610 is used as the heat split separator 600 of the cold heat exchange tubes. As shown in FIG. 2, the heat split circulation pipe 610 preferably has an inner pipe wall 611 and an outer pipe wall 612. The outer pipe wall 612 is wrapped around the inner pipe wall 611 to form a vacuum between the inner pipe wall 611 and the outer pipe wall 612. Layer 613. As shown in the preferred embodiment of Fig. 2, the outer tube wall 612 and the tube wall 310 form a heat exchange conduit 601' and the heat exchange conduit 601 is thermally conductively coupled to the heat exchange device 700. In addition, the relative position between the fixed heat-distributing circulation pipe 610 and the pipe wall 310 is as shown in FIG. 2. The hot-distribution circulation pipe 610 is preferably provided with a fixing bracket 616 at the heat exchange pipe 601. The inner edge of the pipe wall 310 and the surface of the outer pipe wall 612 are positioned to position the heat-distributing circulation pipe 610 and the pipe wall 310. In the embodiment shown in FIG. 3a and FIG. 3b, the heat split circulation tube 610 preferably includes an upper cover body 614 and a lower cover body 615. The upper cover body 614 seals the top end of the inner tube wall 011 and the outer tube wall 612, and the lower portion The cover 615 seals the inner tube wall 611 and the bottom of the outer tube wall 612 to form a vacuum layer 613. As shown in the preferred embodiment of Fig. 3b, in order to facilitate the embedding of the body 3 and facilitate the reflow and circulation of the liquid material 500, the bottom end of the tube wall 310 includes a vertebral body 311. In other various embodiments, however, it is also contemplated to directly seal the bottom end of the tube wall 310 or to shape the bottom end of the tube wall 31 into other shapes that facilitate circulation of the liquid material 500. In addition, as shown in the embodiment of FIG. 3c, the upper cover body 614 preferably further includes a liquid material circulation pipe formed by joining, wherein the liquid material circulation pipe system is thermally conductively connected to the heat father changing device 700 and directly connected to the pipe wall 31. The two are interconnected to facilitate the circulation and heat exchange of the liquid material 500 between the body 3 and the heat exchange device 70. Moreover, in order to avoid the escape and loss which may be caused by heat conduction, it is preferable to cover the heat-distributing separator _ 6GG and the heat-insulating machine. In a preferred embodiment, the insulating material may be overlaid on the surface of the heat-distributing circulation pipe 61 outside the outer wall 612 of the M334922. Here, please refer to Figure 2 again. As shown in the preferred embodiment of FIG. 2, in order to make the heat exchange module have a diversified application, the cold heat exchange tube buried in the creation of the present invention preferably further comprises a heat exchange line 820 and a heat collecting device 710. As shown in Fig. 2, the heat exchange line 820 is preferably thermally coupled to the heat collecting means 710 and the heat exchange means 700, respectively. As shown in the preferred embodiment of FIG. 2, the heat exchange line 82 has a first end 821 and a second end 822, and the first end 821 of the heat exchange line 820 is disposed in the collector _ thermal device 710, the first end 822 is then thermally conductively coupled to heat exchange device 410. As shown in FIG. 2, when the heat exchange pipe 601 exchanges heat with the body 3, the heat exchange pipe 601 heats the heat exchange device 700, and the heat exchange device 7 is heat exchanged with the heat exchange pipe 601, respectively. The pipeline 82 is subjected to heat exchange to reach a heat balance state; further, when the heat exchange device 700 exchanges heat with the heat exchange line 82, the heat exchange line 820 simultaneously performs heat exchange with the heat collecting device 71 to achieve a heat balance state. . In a preferred embodiment, the heat exchange line 82 is preferably formed of (4) having a high thermal conductivity, such as metals, alloys, and polymer materials having properties that are easy to collect heat and dissipate heat. Therefore, in order to avoid the dissipation of heat energy or to be disturbed by the external temperature, the heat exchange line 82G preferably includes an insulating material covering the outer surface of the heat exchange line 82G. In addition, as shown in FIG. 2, the heat exchange line 82 〇 preferably also includes a liquid material (not labeled) such as cold coal and the circulation pump 830, and reciprocates in the heat exchange line 82G to exchange heat with the hot money device. . It is difficult to carry out the shooting here, and it is difficult to put in. The step includes the heat insulating material covering the outer surface of the heat exchange device 7GG, and the hot junction county preferably comprises a heat conducting pipeline formed by a high thermal conductivity material. Show), to facilitate the transfer of thermal energy M334922 and exchange. As shown in the preferred embodiment of FIG. 2, the heat collecting device 71 further includes a heat conductive connection with the heat wheel outlet pipe 800. When the heat exchange line _ heats the heat collecting device, the heat device 710 and the heat output Pipeline_ performs heat exchange to reach the state of balance. As shown in FIG. 2, in the preferred embodiment, the heat collecting device 71 is connected to the heat output line 800 in a thermally conductive manner, and the heat exchange line 82 is connected to the heat exchange unit 7GG. Heat exchange is performed, and the second end 822 performs heat conduction on the heat collecting device claws. The heat collecting device 71G and the heat output line _ heat exchange line between each other = heat to equilibrium state, and the heat collecting device 71 is hot and heat Output line _ into the second heat exchange. In addition, in order to enhance the effect of heat exchange, as shown in FIG. 2, the heat collecting device 71 preferably includes a high-heating material-like fresh-keeping line _, and the money-step setting is provided, and the new material wrapping device is provided. The outer surface is designed to prevent the divergence of thermal energy from being lost or disturbed by external temperature. As shown in the preferred embodiment of FIG. 2, the heat-conducting line loaded in the heat collecting device 71G is preferably interlaced with the first end 431 of the heat exchange line 820 and the first end 431 of the heat output line _ By utilizing the characteristics of the heat dissipation line 900 to quickly collect heat dissipation, the heat exchange line 82 and the heat collecting device 710 have no output line __ speed up to a thermal equilibrium state. In Fig. 2, the lion's real reward towel, the thermal conductivity record _ difficult to age _ alloy formed 'however, in different embodiments of the towel, other metals, alloys or polymer materials can also be used to form a high thermal conductivity material. / As shown in the preferred embodiment of FIG. 2, the heat output line 43A includes, but is not limited to, a low temperature or high temperature state in the water supply system, and the cold heat exchange mold and the group 400 buried in the ground are combined with the water supply system. There are different applications. · 12 M334922 First, when the outside temperature is low, the temperature of the ground is relatively high, and the heat collecting device and the heat exchange line 82 can function as heat collecting and heat preservation, forming a heat output line. The effect of warming up. As shown in the preferred embodiment of FIG. 2, when the heat output line _ is set as the water supply system, the first end of the heat output line _ is the water inlet line, and the second end of the heat output line 800 is 8 〇2 is set as the outlet pipe. As shown in FIG. 2, the intermediate portion 801 is preferably thermally coupled to the heat collecting device 710. When the water supply is supplied from the water inlet pipe 801 through the heat collecting device 71, the temperature is increased, and the temperature is increased. The water supply is output from the water outlet pipe 802 for use by the user. As shown in the preferred embodiment of Fig. 2, the output line _ further includes a water storage device _ disposed in the effluent g path 802 for storing the warm water from the outlet pipe 8 () 2 for storage. The water storage device is preferably provided with an output line m and a control valve for the user to use according to requirements. The use of the present invention means that the user can use the warm water stored in the water storage device as a general cleaning and washing. In other preferred embodiments, however, an external heat source is included in the output line 812 for the user to further heat the warm water from the water storage device for bathing or other necessary use. In this case, the user will save the energy needed to heat the water supply shaft. ^一/ * When the outside temperature is warm, the temperature of the ground is relatively low, and the heat collecting device 71 and ", the exchange g line 82" can play the function of heat dissipation and cooling, and form a cooling effect on the heat output line. According to the preferred embodiment of the second embodiment, when the water supply is from the water inlet pipe, the heat collecting device 71 is subjected to heat exchange to lower the temperature, and the water supply after the cooling is discharged from the water outlet 8G2 is available for the user to enter the stepper. As shown in Figure 2, the water from the water g: the output of cold water can be connected to the air conditioning secret cold, in addition to the absorption of cold U pounds of heat, can also reduce the condenser to the outside heat, in line with the ring 13 M334922 OBJECT AND REQUIREMENTS. In addition, in other preferred embodiments, the heat wheel outlet pipe 800 also includes a pipeline having high thermal conductivity and is connected to the device to be utilized, and the hot wheel outlet pipe 8 has a pipeline. It is easy to collect heat and dissipate heat, and can exchange heat with the device to adjust the temperature. As mentioned above, the device to be used includes electric heating pipe, air conditioning system, condenser, heat preservation device such as teapot, coffee maker. Block, etc. The building structure floor, or other structure installed inside the building structure can increase the temperature of the building structure. It is said that when the heat output pipe _ is a pipeline with high thermal conductivity, the outside is in a low temperature or high temperature state. The heat exchange module 4 (8) for creating the cold and heat exchange tube has different applications after being combined with the pipeline: First, when the outside temperature is low, the ground temperature is relatively high, and the heat collecting device 71 and the heat exchange line 820 can be utilized. The function of collecting heat and heat insulation has the effect of increasing the temperature of the heat output pipeline. When the equipment to be used is installed under the floor of the building structure 2 (8), or the heat output pipeline is further buried in the building structure. The outer wall of the raft can form a structure equivalent to the traditional "炕". In addition to keeping the room warm, Φ can also alleviate the use and expenditure of related power sources. In addition, if the local ring cake can be found and the bottom of the ground has a fine or hot heat selection, the number of bodies 3 (8) is buried deep in the heat source or geothermal heat to take thermal energy and make further use. First, when the outside temperature is high, the temperature of the ground is relatively low, and the heat collecting device and the heat exchange line 820 can function as a heat dissipation cooling, and the heat output line _ forms a cooling effect. At this time, the heat output pipe _ can be installed in the building 2 ^ ^ 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭 灭The power consumption and related expenses of the air conditioning system consumed for cooling. The present invention has been described by the above related embodiments, but the above embodiments are merely examples for implementing the present invention. It must be noted that the disclosed embodiments do not limit the scope of the present invention. On the contrary, modifications and equivalents of the spirit and scope of the invention are included in the scope of the present invention. [Simple description of the diagram] ® 1 is the _ underground buried cold and hot age - the preferred embodiment; • ® 2 is shown in the creation of the underground cold-change tube - record embodiment; Figure 3a The present invention shows a preferred embodiment of the cold-hot exchange pipe buried in the ground for the first time. Figure 3b shows a preferred embodiment of the cold-heat exchange pipe for underground laying. Figure 3c shows the cold-heat exchange for the underground laying of the creation. Another preferred embodiment of the tube. [Main component symbol description] 100 surface art 200 building structure 300 body 310 pipe wall 311 vertebral 320 closed space 400 heat exchange module 410 compression pump 500 liquid material 15 M334922 600 heat split isolation layer 601 heat exchange pipe 602 return pipe 610 heat split circulation pipe 611 inner pipe wall 612 outer pipe wall 613 vacuum layer 614 upper cover body 615 lower cover body 616 fixed bracket 700 heat exchange device 710 heat collecting device 800 heat output pipe, water supply system 801 water inlet pipe 802 water outlet pipe 810 water storage device 811 control valve 812 output line 820 heat exchange line 821 first end 822 second end 830 cycle pump M334922 900 heat pipe