M419065 五、新型說明: 【新型所屬之技術領域】 [0001] 本創作涉及一種模組化資料中心節能系統。 【先前技術】 [0002] 目前隨著模組化資料中心,如模組化資料中心資料中心 之發展趨向靈活化,模組化資料中心之散熱設計方式也 曰趨靈活化,如此龐大之模組化資料中心之機房設備往 往需要相當大之電力去冷卻發熱源。常見之散熱方式係 於資料令心内部設置空調末端,雖然空調末端可以提供 較低之冷氣流給資料中心内部之伺服器系統進行散熱, 但空調末端不利於節能減排。 【新型内容】 [0003] 鑒於以上内容,有必要提供一種能有效節能之模組化資 料中心節能系統。 [0004] 一種模組化資料中心節能系統,包括一模組化資料中心 及設置於模組化資料中心内之空調末端,空調末端設有 出入口,賴組化資料巾心節能系統還包括製冷系統及 設於地下水層之埋管系統,該製冷系統包括有蒸發器、 壓縮機及枝H ’該壓縮機㈣相連接冷凝器與蒸發 器,空調末端出人口分別與蒸發器連接,該埋管系統與 冷凝器連接’隨流經整個模組化⑽中心節能系統之循 環介質輸人紐n,壓縮機使蒸發器吸收循環介質之熱 量並使熱量經冷凝器進人埋管系統,進而將熱量傳入地 下水層。 表單编號A0101 第3頁/共9頁 M419065 [0005] 優選地,該埋管系統包括埋於地下水層之多個管形換熱 器,用於將熱水轉入地下水層並抽取冷水。 [0006] 優選地,該埋管系統還包括輔助換熱器供水給製冷系統 之集水器及將製冷系統輸出之循環介質分流進入多個換 熱器之分水器,該多個管形換熱器並行設置並與集水器 及分水器連接。 [0007] 優選地,模組化資料中心節能系統還包括第一循環泵及 第二循環泵,該第一循環泵設置於該蒸發器與空調末端 之間,用以控制蒸發器與空調末端之間循環介質之循環 ;該第二循環泵設置於該冷凝器與集水器之間,輔助集 水器對冷凝器供水。 [0008] 所述模組化資料中心藉由其上之節能系統將空調排出之 熱量引入地下,並將地下冷水冷凝後用於輔助空調之製 冷,如此,大大節省了電能,符合當今社會節能減排之 需求。 【實施方式】 [0009] 請一併參閱圖1,本創作模組化資料中心節能系統之較佳 實施方式包括一模組化資料中心10,如集裝箱資料中心 (container data center,簡稱CDC)、設於模組化 資料中心10内之各種資料終端(如伺服器)、設有出入 口之空調末端20、製冷系統30、埋管系統40、第一循環 泵50及第二循環泵60。空調末端20、製冷系統30及埋管 系統40之間均由管道,如銅管連接,空調末端20出口排 出之熱量於管道内藉由流經整個模組化資料中心節能系 統之循環介質(如製冷劑)輸入製冷系統30,經製冷系 表單編號A0101 第4頁/共9頁 M419065 統30及埋管系統4〇將熱量排入地下。 [0010] 該製冷系統30包括冷凝器31、壓縮機32、節流閥33及暮 發器34。該壓縮機32及節流閥33均與冷凝器31及蒸發器 34相連接〇該冷凝器31將蒸發器34吸收循環介質熱量過 程中散發出之熱量及壓縮機32於壓縮循環介質過程中所 產生之熱量藉由循環介質送到該埋管系統4〇。壓縮機32 用於壓縮及輸送循環介質。節流閥33對循環介質起到節 流降壓作用’並調節進入蒸發器34之循環介質單位時間 内之流量。蒸發器34係將經節流閥33流入之循環介質蒸 發’以吸收被壓縮氣化之循環介質之熱量,達到製冷目 的。空調末端20之出口與入口均與蒸發器34相連接。 [0011] 該第二循環泵60裝設於蒸發器34與空調末端2〇入口之間 ,用於輔助循環介質於蒸發器34與空調末端20之間之循 環流通。 [0012] 該埋管系統40包括多個埋於地下之管形換熱器41、集水 器42、分水器43及與集水器42、分水器43連接之排氣間 (圖未示)。本實施例中,換熱器41係樁埋管式之兩個 管形換熱器並埋於地下水層。換熱器41用於將熱水轉入 地下水層並抽取冷水’該兩個換熱器41以並聯形式連接 該集水器42及分水器43。該分水器43藉由銅管連接該製 冷系統30之冷凝器31,用於將冷凝器31輸出之循環介質 分流進入多個換熱器41内。該第一循環泵5〇連接冷凝器 31與集水器42。該換熱器41也可以係水準埋管或暨直《υ ”型埋管之多個換熱器41並聯或串聯。 [0013] 藉由模組化資料中心節能系統對各種資料終端(如祠服 表單編號A0101 第5頁/共9頁 M419065 器)及空調末端20進行散熱時,該載有空調末端20散出 之熱量之循環介質從模組化資料中心10之空調末端20出 口流向蒸發器34,壓縮機32又工作使循環介質於該蒸發 器34内氣化,使該蒸發器34吸收循環介質内之熱量,再 將熱量傳送給冷凝器31,另壓縮機32工作使冷凝器31將 蒸發器34中散出之熱量及壓縮機32消耗功能所轉化之熱 量隨循環介質進入該埋管系統4 0内直接藉由分水器4 3進 入換熱器41管道,進而將熱量釋放到地下水中,如此就 實現模組化資料中心節能系統對該模組化資料中心1 0之 散熱,避免熱量散發到空氣中。 [0014] 另外,藉由模組化資料中心節能系統輔助空調末端20對 各種資料終端(如伺服器)進行製冷之過程中,第一循 環泵50使兩俩換熱器41抽取之地下冷水經集水器42匯總 與循環介質混合進入冷凝器31,壓縮機32工作使冷凝器 31内之循環介質及冷水之混合物之熱量經第一循環泵50 輸入地下,另壓縮機32使該蒸發器34吸收循環介質及冷 水之混合物之熱量,進而對循環介質冷卻,啟動第二循 環泵60使被冷卻後之循環介質進入空調末端20入口,輔 助空調製冷之效果,達到節省能源之作用。 [0015] 本創作模組化資料中心1 0内之空調末端20與埋管系統40 連接,藉由製冷系統30對循環介質之循環排熱來實現散 熱製冷之目的,如此,大大節省了電能,符合當今社會 節能減排之需求。 【圖式簡單說明】 [0016] 圖1為本創作模組化資料中心節能系統之較佳實施方式之 表單編號A0101 第6頁/共9頁 M419065 模組框圖。 【主要元件符號說明】M419065 V. New Description: [New Technology Field] [0001] This creation involves a modular data center energy-saving system. [Previous Technology] [0002] At present, with the development of modular data centers, such as modular data center data centers, the thermal design of modular data centers is also becoming more flexible. Equipment room equipment in the data center often requires considerable power to cool the heat source. The common way of dissipating heat is to set the end of the air conditioner inside the data. Although the end of the air conditioner can provide a lower cold air flow to the server system inside the data center to dissipate heat, the end of the air conditioner is not conducive to energy saving and emission reduction. [New content] [0003] In view of the above, it is necessary to provide a modularized material center energy-saving system that can effectively save energy. [0004] A modular data center energy-saving system includes a modular data center and an air-conditioning end disposed in the modular data center, and an air-conditioning end has an entrance and exit, and the data-saving system includes a refrigeration system. And a buried pipe system disposed in the groundwater layer, the refrigeration system includes an evaporator, a compressor, and a branch H'. The compressor (4) is connected to the condenser and the evaporator, and the outlet of the air conditioner is connected to the evaporator respectively, and the buried pipe system Connected to the condenser 'with the circulation of the entire modular (10) central energy-saving system, the compressor allows the evaporator to absorb the heat of the circulating medium and allow the heat to enter the buried system through the condenser, thereby transferring heat Into the groundwater layer. Form No. A0101 Page 3 of 9 M419065 [0005] Preferably, the buried pipe system includes a plurality of tubular heat exchangers buried in a groundwater layer for transferring hot water into the groundwater layer and extracting cold water. [0006] Preferably, the buried pipe system further comprises a water collector for assisting the heat exchanger to supply water to the refrigeration system, and a water separator for dividing the circulating medium outputted by the refrigeration system into the plurality of heat exchangers, the plurality of tubular shapes The heaters are placed in parallel and connected to the sump and the water separator. [0007] Preferably, the modular data center energy-saving system further includes a first circulation pump and a second circulation pump, the first circulation pump is disposed between the evaporator and the air conditioner end to control the evaporator and the air conditioner end The circulation of the circulating medium; the second circulating pump is disposed between the condenser and the sump, and the auxiliary sump supplies water to the condenser. [0008] The modular data center introduces the heat discharged from the air conditioner into the underground by the energy-saving system thereon, and condenses the underground cold water to assist the refrigeration of the air conditioner, thereby greatly saving the electric energy and conforming to the energy saving of the current society. Demand for the row. [Embodiment] [0009] Please refer to FIG. 1 together, a preferred embodiment of the creative modular data center energy-saving system includes a modular data center 10, such as a container data center (CDC), Various data terminals (such as servers) disposed in the modular data center 10, an air conditioning terminal 20 having an entrance and exit, a refrigeration system 30, a buried pipe system 40, a first circulation pump 50, and a second circulation pump 60. The air conditioner terminal 20, the refrigeration system 30 and the buried pipe system 40 are connected by a pipe, such as a copper pipe, and the heat discharged from the outlet of the air conditioner terminal 20 flows through the circulating medium of the energy saving system of the entire modular data center in the pipeline (for example) The refrigerant is supplied to the refrigeration system 30, and the heat is discharged into the ground via the refrigeration system form No. A0101, page 4/9, M419065 system 30, and the buried pipe system. [0010] The refrigeration system 30 includes a condenser 31, a compressor 32, a throttle valve 33, and a damper 34. The compressor 32 and the throttle valve 33 are both connected to the condenser 31 and the evaporator 34. The condenser 31 absorbs the heat emitted by the evaporator 34 during the heat of the circulating medium and the compressor 32 in the process of compressing the circulating medium. The generated heat is sent to the buried pipe system through the circulating medium. Compressor 32 is used to compress and deliver the circulating medium. The throttle valve 33 acts to throttle the circulating medium and to regulate the flow rate of the circulating medium entering the evaporator 34 per unit time. The evaporator 34 evaporates the circulating medium flowing through the throttle valve 33 to absorb the heat of the compressed vaporized circulating medium to achieve the refrigeration purpose. Both the outlet and the inlet of the air conditioner terminal 20 are connected to the evaporator 34. [0011] The second circulation pump 60 is disposed between the evaporator 34 and the inlet end of the air conditioner 2 for assisting circulation of the circulating medium between the evaporator 34 and the air conditioner terminal 20. [0012] The buried pipe system 40 includes a plurality of underground tubular heat exchangers 41, a water collector 42, a water separator 43 and an exhaust gas connected to the water collector 42 and the water separator 43. Show). In the present embodiment, the heat exchanger 41 is a tubular heat exchanger of the pile-buried type and buried in the groundwater layer. The heat exchanger 41 is for transferring hot water into the groundwater layer and extracting cold water. The two heat exchangers 41 connect the water collector 42 and the water separator 43 in parallel. The water separator 43 is connected to the condenser 31 of the refrigeration system 30 by a copper pipe for splitting the circulating medium output from the condenser 31 into the plurality of heat exchangers 41. The first circulation pump 5 is connected to the condenser 31 and the sump 42. The heat exchanger 41 can also be connected in parallel or in series with a plurality of heat exchangers 41 of a horizontal buried pipe or a straight "υ" type buried pipe. [0013] By modularizing the data center energy saving system for various data terminals (such as 祠When the service form number A0101 page 5/9 M419065 device and the air conditioner terminal 20 perform heat dissipation, the circulating medium carrying the heat radiated from the air conditioner terminal 20 flows from the outlet of the air conditioning terminal 20 of the modular data center 10 to the evaporator. 34, the compressor 32 is operated to vaporize the circulating medium in the evaporator 34, so that the evaporator 34 absorbs heat in the circulating medium, and then transfers the heat to the condenser 31, and the compressor 32 operates to make the condenser 31 The heat dissipated in the evaporator 34 and the heat converted by the function of the compressor 32 are discharged into the heat exchanger 41 through the water separator 4 as the circulating medium enters the buried pipe system 40, thereby releasing heat to the groundwater. In this way, the modular data center energy-saving system is used to dissipate heat from the modular data center 10 to prevent heat from being dissipated into the air. [0014] In addition, the module 20 is assisted by the modular data center energy-saving system. Various funds During the cooling process of the material terminal (such as the server), the first circulating pump 50 combines the underground cold water extracted by the two heat exchangers 41 through the sump 42 and mixes with the circulating medium into the condenser 31, and the compressor 32 works to condense. The heat of the mixture of the circulating medium and the cold water in the unit 31 is input to the underground through the first circulation pump 50, and the compressor 32 causes the evaporator 34 to absorb the heat of the mixture of the circulating medium and the cold water, thereby cooling the circulating medium to start the second cycle. The pump 60 allows the cooled circulating medium to enter the inlet of the air conditioner terminal 20, and assists the effect of air conditioning cooling to save energy. [0015] The air conditioning terminal 20 in the present modular data center 10 is connected to the buried pipe system 40. The refrigeration system 30 recycles the circulating medium to achieve the purpose of heat dissipation and cooling, thus greatly saving the electric energy and meeting the needs of energy conservation and emission reduction in today's society. [Simplified illustration] [0016] FIG. Form No. A0101 of the preferred embodiment of the modular data center energy-saving system Page 6 of 9 M419065 Module block diagram. [Main component symbol description]
[0017] 模組化資料中心:10 [0018] 空調末端:20 [0019] 製冷系統:30 [0020] 冷凝器:31 [0021] 壓縮機:32 [0022] 節流閥:33 [0023] 蒸發器:34 [0024] 埋管系統:40 [0025] 換熱器:41 [0026] 集水器:42 [0027] 分水器:43 [0028] 第一循環泵:50 [0029] 第二循環泵:60 表單編號A0101 第7頁/共9頁[0017] Modular Data Center: 10 [0018] Air Conditioning End: 20 [0019] Refrigeration System: 30 [0020] Condenser: 31 [0021] Compressor: 32 [0022] Throttle: 33 [0023] Evaporation Device: 34 [0024] Buried pipe system: 40 [0025] Heat exchanger: 41 [0026] Water collector: 42 [0027] Water separator: 43 [0028] First circulating pump: 50 [0029] Second cycle Pump: 60 Form No. A0101 Page 7 of 9