1375019 九、發明說明 【發明所屬之技術領域】 ' 本發明關於一種工廠之壓力傳送檢測系統,用以檢測 工廠之諸如壓力、液位等主要控制程序値。 【先前技術】 通常’在工廠裝置之中傳送壓力、液壓、流率及類似 # 者的壓力系統的場所安裝型壓力傳送裝置中,操作者將壓 力產生源、參考壓力表或電流測量表連接到該裝置以便對 週期性的檢測的資料收集實施檢測。 於此情形中,操作者的經驗是產生該參考壓力的技術 的重要因數,且有時候,於檢測時間中可能會產生問題, 袠規的校正準確度、資料準確度及類似者,且可能會進一 步在資料轉移到記錄單時發生錯誤。 然而,對於傳統技術中,對於壓力系統而言,並不存 • 在自動化表規檢測系統,而其並不依賴操作者經驗及技術 〇 能診斷差壓感測器及壓力傳送裝置的系統業已提出( 例如’見日本專利申請案公開第8 - 2 4 7 8 8 1號)。 在上述壓力傳送裝置的檢測方法中,檢測的時間效率 及檢測資料的準確度可受到檢測者的能力、經驗及技術的 影響。再者,並不存在會參照包括過去時間的檢測資料方 面的改變的檢測歷史,以及自動判定場所的檢測結果的系 統。 -5- 1375019 【發明內容】 本發明己考量到上述環境且本發明之目的在於提供不 依賴檢測者經驗及技術的檢測資料收集方法,且提供透過 資料庫中央控制資料以使電子資料被檢視及自動收集的工 廠之壓力傳送裝置檢測系統。 上述及其它目的可根據本發明藉由在較佳態樣中提供 一種工廠之壓力傳送裝置檢測系統而達成,其包括用於工 廠之壓力傳送裝置的檢測的表規校正終端機;自動下載該 壓力傳送裝置之表規規格、監控施加的壓力、自動收集檢 測資料並自動判定檢測結果的判定單元;基於該判定結果 產生結果單的表規校正用之遠端伺服器;以及中央控制該 表規規格、該檢測結果及檢測歷史的之控制單元。 於較佳實施例中,可結合用於工廠之壓力傳送裝置之 檢測的該表規校正終端機及多通道數位萬用表(multimeter) 以便全 部一次 檢測多 數個該 表規。 用於工廠之壓力傳送裝置之檢測的表規校正終端機、 流體壓力計(manometer )以及數位萬用表可結合以便監 控施加的壓力並當被施加的壓力到達量測點(measuring point )時自動收集被測量的値。 工廠之壓力傳送裝置檢測系統可進一步包括移動單元 ’其包括用於該工廠之壓力傳送裝置之檢測之表規校正終 端機、位準及位準調整機構。 根據本發明,在不依賴檢測者的經驗及技術的檢測資 料收集中,資料可透過資料庫被中央控制並檢視及當成電 -6- 1375019 子資料被自動收集。 本發明的本質及進一步特性將由以下參照附圖的說明 而更清楚。 【實施方式】 下文將參照附圖說明本發明工廠之壓力傳送裝置檢測 系統的實施例。 # 圖1及圖2係顯示根據本發明第一實施例之工廠之壓 力傳送裝置檢測系統的架構圖。於此實施例中,描述用以 實施檢測的系統,在當壓力傳送裝置8在工廠10中受檢 測之時,透過在表規校正終端機la (個人電腦)與表規校 正伺服器lb (個人電腦)之間的無線電通訊,使用壓力傳 送裝置檢測系統或透過以記憶卡1 1更新檢測資料。 圖1顯示工作場所或辦公室9的內部,其中在工廠內 的測量表規的所有規格及測量資料被儲存。且圖2顯示在 ^ 工廠內的壓力傳送裝置8的檢測狀態或是在監控壓力値時 表規校正終端機la自動測量該壓力傳送裝置8的輸出値 時的狀態。 _ 根據本實施例,如圖2所示,壓力導管連接到壓力傳 送裝置8,其係安裝於工廠10內場地的表規。在檢測此壓 力傳送裝置8之際,壓力產生源5使用軟管14或類似者 連接到壓力傳送裝置 8的施壓點(pressure application point ),且軟管I4接著連接到數位流體壓力計2。 電流電壓轉換器4安裝於壓力傳送裝置8的電信號取 1375019 出電路(take-out circuit) 15,且施加電壓到數位萬用表 3»數位流體壓力計2與數位萬用表3透過安裝於各測量 裝置上的介面將數位値傳送到表規校正終端機1。 使用利用臨時電話線的廠內PHS (個人行動通訊系統 )、無線區域網路(wireless LAN)或DSL-LAN(數位用 戶迴路區域網路),表規校正終端機la連接到發送/接收 單元(PHS、無線區域網路、DSL-LAN),該臨時電話線 與傳統技術有關,以便能確保通訊功能。再者,表規校正 終端機la使用記億卡11在一通訊不可能狀態與表規校正 伺服器lb交換資料。此一結構係建構於托架7上以便容 易移動。 在工作場所或辦公室9中,如圖1所示,發送/接收 單元6使用利用臨時電話線的廠內PHS線、無線區域網路 或DSL-L AN連接到表規校正伺服器lb,以便確保通訊功 能。再者,表規校正伺服器lb可使用記憶卡11以表規校 正終端機1 a更新資料。 在實際測量中,各單元能達到以下功能。 例如,當操作者以視覺及聽覺上操作壓力產生源5時 ’表規校正終端機la自數位流體壓力計2下載壓力値並 通知操作者壓力上升、量測點及在限時漸快下的最佳操作 速度。 當到達量測點時,來自數位萬用表3的壓力傳送裝置 輸出信號自動被下載。在資料被下載後,在該終端機實施 判定。在測試開始之前,要被測量的各表規的規格使用通 -8 - 1375019 訊功能自表規校正伺服器lb被下載。因此,最好自動設 定測量範圍。再者,表規校正終端機la具有監控功能, ' 當測量開始時,數位流體壓力計2的零點藉由該監控功能 而加以確定。 表規校正伺服器lb以資料庫的形式管理表規規格, 諸如標籤號碼、類型、測量範圍、溫度修正値( temperature correction value )、密度修正値(density _ correction value)、比重(specific gravity)、設定値、 精確度容差(accuracy tolerance)、用於工廠10之各表 規的安裝地點。表規校正伺服器1 b具有自諸如檢測歷史 、檢測資料及用過的表規資訊的資料產生被檢測的壓力傳 送裝置8的結果單的功能。 數位流體壓力計2係一種能夠以數位値指示出壓力信 號的表規,且在本實施例的結構中,數位流體壓力計2裝 備有介面卡並透過發送/接收單元6發送壓力測量値到表 • 規校正終端機1 a當作無線電信號。 數位萬用表3透過電流電壓轉換器4接收並指示出壓 力傳送裝置8的輸出信號當作數位値。數位萬用表3裝備 ·· 有介面卡並發送壓力傳送裝置輸出信號値到表規校正終端 機la»同時,最好是使用高速多通道型表規當作表規。 電流電壓轉換器4將壓力傳送裝置8的電流輸出信號 (4m A-2 0mA )轉換成電壓,並將此電壓施加到數位萬用 表3。 壓力產生源5包括手動栗(manual pump)、氮氣槽 -9- 1375019 、調整閥單元等類似物,且在檢測時壓力的產生會透過如 傳統方式的操作來實施。 發送/接收單元6包括通訊介面,其採用如傳統方式 實施般利用臨時電話線的廠內PHS線 '無線區域網路或 DSL-LAN。 托架7承載所有用於上述場所中的裝置,以便節省場 所來回移動的勞力,以及取決於場所的情況,可使用盤式 托架。無論如何,最好是托架具有位準及位準調整機構( 調整腳),以便固定測量條件而不會有任何錯誤。在本實 施例中,壓力傳送裝置8係一用以偵測諸如壓力、液位、 流率或類似者的工廠主要控制程序値的表規。 如圖1所示,工作場所或辦公室9係用作爲表規校正 伺服器1 b的安裝地點。表規校正伺服器1 b作爲伺服器處 理多數個表規規校正終端機la的同時操作。由於資料能 透過LAN架構接替,因此可實現遠端控制。 倘若在表規校正終端機la與表規校正伺服器lb之間 的通訊依工廠10的場所的壓力傳送裝置的檢測狀態而被 失能(disabled ),則資料在個別裝置之間使用記億卡1 1 被更新。 根據本發明第一實施例,當檢測壓力傳送裝置8時, 攜帶上面印有個別規格(範圍、溫度修正、頭修正、被測 量物體的重力)的紙張的需要便可消除,且在傳輸資料時 的失誤及輸入資料的錯誤便可消除,從而建立能夠節省勞 力的維修支援系統。 -10- 1375019 圖3及圖4顯示本發明第二實施例。詳而言之,圖4 顯示當檢測安裝於工廠10內之場所的壓力傳送裝置8的 * 壓力時,在相同時間相同範圍內藉著施加壓力到壓力傳送 裝置8來全部一次實施檢測。再者,在此實施例中,顯示 於圖1及2之代表第一實施例的類似的參考標號代表被加 到圖3及圖4中的對應組件或元件,而此處排除重複的說 明。 # 圖3及圖4顯示當使用壓力傳送裝置檢測系統檢測安 裝於工廠內之場所的壓力傳送裝置8時的組態,該檢測資 料係透過在表規校正終端機la與表規校正伺服器lb之間 的無線通訊或透過記憶卡11而被更新。 圖3顯示工作場所或辦公室9,其中工廠內之表規的 所有規格及測量資料被儲存。圖4顯示當工廠內的壓力傳 送裝置8被檢測時,多數個壓力傳送裝置8的輸出値在壓 力値的表規校正終端機la監控被施加的壓力値的相同時 • 間被自動測量。 根據本發明第二實施例,在壓力傳送裝置8的同時檢 測中,不需要攜帶上面印有個別規格(範圍、溫度修正、 頭修正、被測量物體的重力)的紙張,且在傳輸資料時的 失誤及輸入資料的錯誤便可消除,且多數個壓力傳送裝置 8能自動被測量。結果,欲提供能夠大幅節省勞力的壓力 傳送裝置檢測系統係可能的。 圖5及圖6顯示根據本發明第三實施例的一種使用壓 力傳送裝置檢測系統檢測工廠10內壓力傳送裝置8的方 -11 - 1375019 法,其係藉著透過在表規校正終端機la與表規校正伺服 器1 b之間的無線通訊或記億卡1 1更新檢測資料。 圖5係顯示工作場所或辦公室9內部的架構圖,其中 工廠內的所有規格及測量資料被儲存,且圖6係架構圖, 說明當在工廠內的壓力開關13被檢測時,壓力開關13之 接觸點輸出在表規校正終端機la監控被施加的壓力値時 的自動測量。 圖6表示在實施本實施例時有壓力開關13的檢測狀 態。藉同時施加壓力而對多數個壓力傳送裝置8同時檢測 如圖3及圖4般被致能(enabled )。接觸點電壓轉換器 12將壓力開關13的接觸點輸出.信號轉換成電壓且連接到 數位萬用表3。壓力開關1 3係一用以偵測諸如壓力、液位 等類似者的工廠主要控制程序値。 根據本發明第三實施例,當檢測壓力開關1 3時,不 需要攜帶上面印有個別規格(範圍、溫度修正、頭修正、 被測量物體的重力)的紙張,且在傳輸資料時的失誤及輸 入資料的錯誤便可消除,從而建立能夠節省勞力的維修支 援系統。 根據本發明,如上述,提供一種壓力傳送裝置檢測系 統。在此系統中,在檢測壓力傳送裝置8之時,表規規格 自動被下載,被施加的壓力被監控,檢測資料被自動收集 ’以及使用表規校正終端機la (個人電腦)檢測結果自動 被判定,壓力傳送裝置8係一種場所安裝型表規,用來測 量工廠10的裝置之中的壓力 '液位或流率。再者,使用 -12- 137.5019 遠端表規校正伺服器lb (個人電腦)產生結果單以便中央 控制表規規格、檢測結果及檢測歷史》 在檢測壓力開關13時使用表規校正終端機ia來實施 自動下載表規的規格、監控施加的壓力、自動收集檢測資 料以及自動判定檢測結果,該壓力開關13係一種場所安 裝型表規,用以測量工廠10的裝置之中的壓力、液位或 流率。換言之,結果單係以遠端個人電腦伺服器所產生, Φ 以便中央控制表規的規格、檢測結果及檢測歷史。 再者’根據本發明’提供一種工廠壓力傳送裝置檢測 系統,用以藉著在檢測場所安裝型表規的壓力、液位或流 率時結合表規校正終端機la與多通道數位萬用表3來全 部一次檢測多數個表規。 再者,提供一種工廠壓力傳送裝置檢測系統,其具有 當到達測量(校準)點時,藉著在工廠10的裝置之中檢 測場所安裝型表規的壓力、液位或流率之時,結合表規校 • 正終端機la、數位流體壓力計2及數位萬用表3監控被施 加壓力及自動收集被測量値的功能。 再者,提供一種工廠壓力傳送裝置檢測系統,其中校 正終端機1 a、數位流體壓力計2及數位萬用表3被結合。 在該系統中,在工廠1〇的裝置之中檢測場所安裝型表規 的壓力、液位或流率之時,監控被施加的壓力,且直到到 達測量(校準)點,以壓力上升/下降速度方面而論,被 施加的壓力以視覺或聽覺方式指示給操作。當操作不與測 量條件符合時,系統便致動以警告防止不當的操作。 -13- 1375019 當工廠ίο的裝置之中的場所安裝型表規被檢 —組用於場所中的檢測裝置被安裝於托架7上,托 有位準及位準調整機構(調整腳),使得測量中不 誤。因此,該檢測裝置能輕易移動於該場所中。 根據本發明的實施例,使用表規校正終端機1Σ 下載表規規格、自動收集檢測資料及自動判定檢測 實施於工廠10的幾乎所有的表規。結果,提供一 壓力傳送裝置檢測系統,其能藉遠端表規校正伺月 產生結果單並儲存表規規格、檢測結果及檢測歷史 再者,對於在用於檢測工廠10之裝置的表規 端機la與遠端表規校正伺服器lb之間的表規規格 歷史及檢測收集資料的通訊,可使用現存的PHS系 線或無線區域網路系統、以及可致能在檢測工廠1 使用臨時電話線與來自DSL模組的有線或無線區域 通訊。 記億卡Π能用來更新用於檢測構成工廠10之 表規校正終端機la以及遠端表規校正伺服器lb中 規格、檢測歷史及檢測收集資料。 【圖式簡單說明】 於附圖中: 圖1係顯示根據本發明第一實施例的工作場所 室的系統架構圖; 圖2係顯示根據本發明第一實施例的工廠的系 測時, 架7具 發生錯 ,自動 結果係 種工廠 I器 lb 〇 校正終 、檢測 統及有 0之際 網路的 裝置的 的表規 或辦公 統架構 -14- 1375019 圖; 圖3係顯示根據本發明第二實施例的工作場所或辦八 室的系統架構圖; & 圖4係顯示根據本發明第二實施例的工廠的系統架構 |,g I · 圖, 圖5係顯示根據本發明第三實施例的工作場所或辦公 室的系統架構圖:以及 圖6係顯示根據本發明第三實施例的工廠的系統架構 圖; 【主要元件符號說明】 1 a :表規校正終端機 1 b :表規校正伺服器 2 :數位流體壓力計 3 :數位萬用表 ® 4:電流電壓轉換器 5 :壓力產生源 6:發送/接收單元 ,· , 7 :托架 8 :壓力傳送裝置 9 :辦公室 10 :工廠 11 :記憶卡 12:接觸點電壓轉換器 -15- 1375019 1 3 :壓力開關 1 4 :軟管 15 :電信號取出電路1375019 IX. Description of the Invention [Technical Field of the Invention] The present invention relates to a factory pressure transmission detecting system for detecting major control procedures such as pressure and liquid level in a factory. [Prior Art] Generally, in a site-mounted pressure transmitting device that transmits pressure, hydraulic pressure, flow rate, and a pressure system like the one in a factory device, an operator connects a pressure generating source, a reference pressure gauge, or a current measuring meter to The device is configured to perform detection of data collection for periodic detection. In this case, the operator's experience is an important factor in the technique of generating the reference pressure, and sometimes, problems may occur during the detection time, correction accuracy of the gauge, data accuracy, and the like, and may Further, an error occurred when the data was transferred to the ticket. However, in the conventional technology, for the pressure system, it does not exist in the automatic gauge inspection system, and the system that does not rely on the operator's experience and technology to diagnose the differential pressure sensor and the pressure transmission device has been proposed. (For example, see 'Japanese Patent Application Publication No. 8 - 2 4 7 8 8 1'). In the above-described method of detecting a pressure transmitting device, the time efficiency of detection and the accuracy of the detected data can be affected by the ability, experience, and technique of the tester. Furthermore, there is no detection history that refers to changes in the detection data including the past time, and a system that automatically determines the detection result of the place. -5- 1375019 SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances and the object of the present invention is to provide a method for collecting test data that does not rely on the experience and technology of the tester, and provides central control data through the database to enable electronic data to be viewed and Automatically collected factory pressure transmitter inspection system. The above and other objects are achieved in accordance with the present invention by providing a factory pressure transfer device detection system in a preferred embodiment, comprising a gauge correction terminal for inspection of a factory pressure delivery device; the pressure is automatically downloaded a specification of the transmission device, a pressure for monitoring the application, a determination unit for automatically collecting the detection data and automatically determining the detection result; a remote server for correcting the calibration of the result sheet based on the determination result; and centrally controlling the specification of the gauge The control unit of the test result and the test history. In a preferred embodiment, the meter can be calibrated in conjunction with the meter for the detection of pressure transmitters in the factory and a multi-channel digital multimeter to detect a plurality of such gauges at a time. A gauge correction terminal, a fluid manometer, and a digital multimeter for testing the pressure transmitter of the factory can be combined to monitor the applied pressure and automatically collect when the applied pressure reaches the measuring point. Measured flaws. The factory pressure transfer device detection system may further comprise a mobile unit' which includes a gauge correction terminal, level and level adjustment mechanism for the detection of the pressure delivery device of the factory. According to the present invention, in the collection of test data that does not rely on the experience and technology of the tester, the data can be centrally controlled and viewed through the database and automatically collected as a sub-data. The nature and further features of the invention will be apparent from the description and appended claims. [Embodiment] Hereinafter, an embodiment of a pressure transmitting device detecting system of a factory of the present invention will be described with reference to the drawings. Fig. 1 and Fig. 2 are structural views showing a pressure transmitting device detecting system of a factory according to a first embodiment of the present invention. In this embodiment, a system for performing detection is described, when the pressure transmitting device 8 is detected in the factory 10, through the meter correction terminal (personal computer) and the gauge correction server lb (personal The radio communication between the computers, using the pressure transmitter detection system or by updating the detection data with the memory card 11. Figure 1 shows the interior of a workplace or office 9 in which all specifications and measurement data of the measurement gauges in the factory are stored. Further, Fig. 2 shows the state of the pressure transmitting device 8 in the factory or the state in which the gauge correcting terminal 5 automatically measures the output 値 of the pressure transmitting device 8 when the pressure is monitored. According to the present embodiment, as shown in Fig. 2, the pressure conduit is connected to a pressure transmitting device 8, which is mounted on the gauge of the site in the factory 10. At the time of detecting this pressure transmitting device 8, the pressure generating source 5 is connected to the pressure application point of the pressure transmitting device 8 using the hose 14 or the like, and the hose I4 is then connected to the digital fluid pressure gauge 2. The electrical signal of the current-to-voltage converter 4 mounted on the pressure transmitting device 8 takes a 1375019 take-out circuit 15, and applies a voltage to the digital multimeter 3»the digital fluid pressure gauge 2 and the digital multimeter 3 through the mounting on each measuring device. The interface transfers the digits to the gauge correction terminal 1. Using an in-plant PHS (Personal Mobile Communication System), wireless LAN (wireless LAN) or DSL-LAN (digital subscriber loop area network) using a temporary telephone line, the meter calibration terminal is connected to the transmitting/receiving unit ( PHS, wireless local area network, DSL-LAN), this temporary telephone line is related to traditional technology in order to ensure communication functions. Further, the gauge correction terminal unit 1 uses the card 1 to exchange data with the gauge correction server lb in a communication impossible state. This structure is constructed on the bracket 7 for easy movement. In the workplace or office 9, as shown in Fig. 1, the transmitting/receiving unit 6 is connected to the gauge correction server lb using an in-plant PHS line, a wireless local area network, or a DSL-L AN using a temporary telephone line to ensure Communication function. Further, the gauge correction server lb can update the data by using the memory card 11 to correct the terminal 1a. In the actual measurement, each unit can achieve the following functions. For example, when the operator visually and audibly operates the pressure generating source 5, the meter calibration terminal unit la downloads the pressure from the digital fluid pressure gauge 2 and notifies the operator of the pressure rise, the measurement point, and the most rapid decrease in time limit. Good operating speed. When the measurement point is reached, the pressure transmitter output signal from the digital multimeter 3 is automatically downloaded. After the data is downloaded, a decision is made at the terminal. Prior to the start of the test, the specifications of the gauges to be measured were downloaded using the -8 - 1375019 function self-meter calibration server lb. Therefore, it is best to set the measurement range automatically. Furthermore, the gauge correction terminal la has a monitoring function, 'When the measurement starts, the zero point of the digital fluid pressure gauge 2 is determined by the monitoring function. The gauge correction server lb manages gauge specifications in the form of a database, such as label number, type, measurement range, temperature correction value, density _ correction value, specific gravity, Set 値, accuracy tolerance, installation location for each gauge of the plant 10. The gauge correction server 1b has a function of generating a result list of the detected pressure transmitting device 8 from data such as the detection history, the detection data, and the used gauge information. The digital fluid pressure gauge 2 is a gauge capable of indicating a pressure signal in a digital position, and in the configuration of the present embodiment, the digital fluid pressure gauge 2 is equipped with an interface card and transmits a pressure measurement through the transmitting/receiving unit 6 to the table. • The calibration terminal 1 a is treated as a radio signal. The digital multimeter 3 receives and indicates through the current-voltage converter 4 that the output signal of the pressure transmitting device 8 is treated as a digital 値. The digital multimeter 3 is equipped with an interface card and sends the pressure transmitter output signal to the meter calibration terminal la» at the same time, it is best to use the high-speed multi-channel meter as a gauge. The current-to-voltage converter 4 converts the current output signal (4m A - 2 0mA ) of the pressure transmitting device 8 into a voltage and applies this voltage to the digital multimeter 3. The pressure generating source 5 includes a manual pump, a nitrogen tank -9-1375019, a regulating valve unit, and the like, and the generation of pressure at the time of detection is performed by a conventional operation. The transmitting/receiving unit 6 includes a communication interface which employs an in-plant PHS line 'wireless area network or DSL-LAN using a temporary telephone line as implemented in a conventional manner. The cradle 7 carries all of the devices used in the above locations in order to save labor for moving back and forth, and depending on the location, a disc tray can be used. In any case, it is preferable that the bracket has a level and level adjustment mechanism (adjustment foot) to fix the measurement conditions without any error. In the present embodiment, the pressure transmitting device 8 is a gauge for detecting a factory main control program such as pressure, liquid level, flow rate or the like. As shown in Fig. 1, the workplace or office 9 is used as the installation location of the gauge correction server 1b. The gauge correction server 1b operates as a server for processing a plurality of table gauges to correct the terminal la. Remote control is possible because the data can be relayed through the LAN architecture. If the communication between the gauge correction terminal unit 1a and the gauge correction server lb is disabled according to the detection state of the pressure transmitting device at the location of the factory 10, the data is used between the individual devices. 1 1 was updated. According to the first embodiment of the present invention, when the pressure transmitting device 8 is detected, the need to carry the paper on which the individual specifications (range, temperature correction, head correction, gravity of the object to be measured) are printed can be eliminated, and when the data is transmitted The mistakes and errors in the input data can be eliminated, thereby establishing a maintenance support system that can save labor. -10- 1375019 Figures 3 and 4 show a second embodiment of the invention. In detail, Fig. 4 shows that when the pressure of the pressure transmitting device 8 at the place installed in the factory 10 is detected, the detection is performed all at once by applying pressure to the pressure transmitting device 8 in the same range of the same time. Further, in this embodiment, like reference numerals designating the first embodiment shown in Figs. 1 and 2 represent corresponding components or elements added to Figs. 3 and 4, and the duplicated description is omitted here. # Figure 3 and Figure 4 show the configuration when using the pressure transmitter detection system to detect the pressure transmitter 8 installed in the factory. The test data is corrected by the meter calibration terminal and the gauge correction server lb. The wireless communication between them is updated by the memory card 11. Figure 3 shows the workplace or office 9 in which all specifications and measurements of the gauges in the factory are stored. Fig. 4 shows that when the pressure transmitting device 8 in the factory is detected, the output of the plurality of pressure transmitting devices 8 is automatically measured at the same time when the gauge calibrating terminal la of the pressure 监控 monitors the applied pressure 値. According to the second embodiment of the present invention, in the simultaneous detection of the pressure transmitting device 8, it is not necessary to carry the paper on which the individual specifications (range, temperature correction, head correction, gravity of the object to be measured) are printed, and when the data is transmitted Errors and errors in the input data can be eliminated, and most of the pressure transmitting devices 8 can be automatically measured. As a result, it is possible to provide a pressure transmitting device detecting system capable of greatly saving labor. 5 and 6 show a method of using the pressure transmitting device detecting system to detect the pressure transmitting device 8 in the factory 10 according to the third embodiment of the present invention, which is corrected by the terminal device la The gauge calibrates the wireless communication between the server 1 b or the check card to update the detection data. Figure 5 is a block diagram showing the interior of the workplace or office 9, in which all specifications and measurement data in the factory are stored, and Figure 6 is an architectural diagram illustrating the pressure switch 13 when the pressure switch 13 in the factory is detected. The contact point output is an automatic measurement when the gauge correction terminal la monitors the applied pressure 値. Fig. 6 shows the detection state of the pressure switch 13 when the present embodiment is implemented. Simultaneous detection of a plurality of pressure transmitting devices 8 by simultaneous application of pressure is enabled as shown in Figs. 3 and 4. The contact point voltage converter 12 converts the contact point output signal of the pressure switch 13 into a voltage and is connected to the digital multimeter 3. The pressure switch 13 is a factory main control program for detecting pressure, liquid level, and the like. According to the third embodiment of the present invention, when the pressure switch 13 is detected, it is not necessary to carry the paper on which the individual specifications (range, temperature correction, head correction, gravity of the object to be measured) are printed, and the error in transmitting the data and Errors in entering data can be eliminated, creating a maintenance support system that saves labor. According to the present invention, as described above, a pressure transmitting device detecting system is provided. In this system, when the pressure transmitting device 8 is detected, the gauge specifications are automatically downloaded, the applied pressure is monitored, the detected data is automatically collected, and the test results are automatically corrected using the gauge correction terminal (personal computer). It is determined that the pressure transmitting device 8 is a site-mounted type gauge for measuring the pressure 'level or flow rate' in the apparatus of the plant 10. Furthermore, use the -12- 137.5019 remote gauge calibration server lb (personal computer) to generate a result list for central control gauge specifications, test results and test history. When using the gauge switch to correct the terminal ia Implementing the specification of the automatic download gauge, monitoring the applied pressure, automatically collecting the test data, and automatically determining the test result, the pressure switch 13 is a site-mounted gauge for measuring the pressure, liquid level or the device in the plant 10 Flow rate. In other words, the results are generated by a remote PC server, Φ for central control of the gauge specifications, test results and test history. Furthermore, according to the present invention, a factory pressure transmitting device detecting system is provided for correcting the terminal unit la and the multi-channel digital multimeter 3 by combining the gauges at the pressure, liquid level or flow rate of the type-mounted gauge at the inspection site. Most of the gauges are tested at once. Furthermore, a factory pressure transfer device detection system is provided which, when reaching a measurement (calibration) point, combines the pressure, liquid level or flow rate of the site-mounted gauge in the device of the plant 10, Table Regulations • The positive terminal la, the digital fluid pressure gauge 2, and the digital multimeter 3 monitor the function of applying pressure and automatically collecting the measured flaws. Further, a factory pressure transmitting device detecting system is provided in which a calibration terminal 1a, a digital fluid pressure gauge 2, and a digital multimeter 3 are combined. In this system, when the pressure, liquid level or flow rate of the site-mounted gauge is detected in the factory, the applied pressure is monitored, and until the measurement (calibration) point is reached, the pressure rises/falls. In terms of speed, the applied pressure is visually or audibly indicated to the operation. When the operation does not comply with the measurement conditions, the system is activated to warn against improper operation. -13- 1375019 The installation type gauge in the device of the factory ίο is inspected - the detection device used in the location is mounted on the bracket 7, and the level and level adjustment mechanism (adjustment foot) is supported. Make the measurement is not wrong. Therefore, the detecting device can be easily moved in the place. According to an embodiment of the present invention, the meter is used to calibrate the terminal unit 1 to download the gauge specifications, automatically collect the test data, and automatically determine the detection of almost all of the gauges implemented in the factory 10. As a result, a pressure transmitting device detection system is provided which is capable of correcting the monthly production result list by the remote gauge and storing the gauge specification, the detection result and the detection history, and for the gauge end of the apparatus for detecting the factory 10. The specification of the gauge specification between the machine la and the remote gauge calibration server lb and the communication of the detected data can be used by using the existing PHS line or wireless local area network system, and can use the temporary telephone at the inspection factory 1. The line communicates with the wired or wireless area from the DSL module. The E-card can be used to update the specifications, inspection history, and test collection data used to detect the gauge calibration terminal la and the remote gauge calibration server lb that constitute the factory 10. BRIEF DESCRIPTION OF THE DRAWINGS In the drawings: FIG. 1 is a system architecture diagram showing a workplace chamber according to a first embodiment of the present invention; FIG. 2 is a diagram showing a racking of a factory according to a first embodiment of the present invention. 7 errors occurred, the automatic results are the factory lb 〇 〇 终 、 、 检测 检测 检测 检测 检测 或 或 或 或 或 或 或 或 或 或 或 或 或 或 或 或 或 或 或 或 或 或 或 或 或 或 ; ; ; ; ; ; ; ; ; System architecture diagram of the workplace or office of the second embodiment; & Figure 4 is a system architecture of a factory according to a second embodiment of the present invention, i I diagram, and diagram 5 shows a third embodiment according to the present invention. System architecture diagram of a workplace or office: and FIG. 6 is a system architecture diagram of a factory according to a third embodiment of the present invention; [Key element symbol description] 1 a : gauge correction terminal 1 b: gauge correction Server 2: Digital Fluid Pressure Gauge 3: Digital Multimeter® 4: Current-to-Voltage Converter 5: Pressure Generating Source 6: Transmitting/Receiving Unit, ·, 7: Bracket 8: Pressure Transmitter 9: Office 10: Factory 11: Memory card 12: connected Contact Voltage Converter -15- 1375019 1 3 : Pressure Switch 1 4 : Hose 15 : Electrical Signal Removal Circuit
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