TW202006320A - High-precision, wireless and energy-saving tilt sensing system and method having advantages of requiring no periodic manual meter-reading, and having less energy consumption and longer service life - Google Patents

High-precision, wireless and energy-saving tilt sensing system and method having advantages of requiring no periodic manual meter-reading, and having less energy consumption and longer service life Download PDF

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TW202006320A
TW202006320A TW107123813A TW107123813A TW202006320A TW 202006320 A TW202006320 A TW 202006320A TW 107123813 A TW107123813 A TW 107123813A TW 107123813 A TW107123813 A TW 107123813A TW 202006320 A TW202006320 A TW 202006320A
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sensing
data
communication module
wireless
tilt
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TW107123813A
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王峻德
王天佑
周柏儀
高憲彰
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財團法人中興工程顧問社
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
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    • Y02DCLIMATE CHANGE MITIGATION TECHNOLOGIES IN INFORMATION AND COMMUNICATION TECHNOLOGIES [ICT], I.E. INFORMATION AND COMMUNICATION TECHNOLOGIES AIMING AT THE REDUCTION OF THEIR OWN ENERGY USE
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Abstract

The present invention discloses a high-precision, wireless and energy-saving tilt sensing system and method. The system includes at least one wireless tilt sensing device, a local data collector, a data receiving server, a database server, and a web server. The wireless tilt sensing device is provided to sense the tilt angle of an object to be measured, which is collected and processed by the local data collector, and transmitted to the web server through the data receiving server and database server, thereby allowing the user to read the relevant information or control the systematic operation in real time through the connection of a wireless electronic device, so as to specifically achieve the functions of biaxial tilt change auto-monitoring, elevation change auto-monitoring, and data transmission enhancement for an object to be measured. In particular, it has the advantages of requiring no periodic manual meter-reading, not being restricted by hardware memory capacity, and having less energy consumption and longer service life.

Description

高精度無線節能傾斜感測系統及方法High-precision wireless energy-saving tilt sensing system and method

本發明係有關於一種高精度無線節能傾斜感測系統及方法,尤其是利用無線傾斜感測裝置感測待測物的傾斜角度,並由現地資料蒐集器蒐集處理後經資料接收伺服器、資料庫伺服器而傳送至網頁伺服器,讓使用者藉無線電子裝置連結而即時讀取相關資訊或控制系統運作,具體達成對待測物的雙軸向傾斜變化自動監測、高程變化自動監測、提升數據傳輸之功能,且無需人工定期抄表,不受硬體記憶容量限制,耗能更少,使用壽命更長等功效。The invention relates to a high-precision wireless energy-saving tilt-sensing system and method, in particular, a wireless tilt-sensing device is used to sense the tilt angle of an object to be measured, collected and processed by a local data collector, processed by a data receiving server, and data The library server is sent to the web server, allowing users to read related information or control system operation in real time through wireless electronic device connection, specifically achieving automatic biaxial tilt change monitoring, automatic elevation change monitoring, and data improvement The function of transmission, without manual meter reading, not limited by hardware memory capacity, less energy consumption, longer service life and other functions.

一般而言,坡地災害發生的自然外在因素很多,包括岩層風化、坡趾支撐不足、地層塌陷、地震、豪雨期間雨水入滲造成孔隙水壓增加,以及表面負載加重等。而人為的不當開發、超限使用與水土保持失當也是坡地災害發生的原因。基本上,在不同岩層材料組合的情形下,山坡地會出現墜落、傾覆、滑動、側滑、流動等不同複合型運動。近年來,不同規模的坡地土砂災害事件時有所聞,對於人類居住社區與建築物安全性影響相當大。Generally speaking, there are many natural external factors for slope disasters, including weathering of rock layers, insufficient support of slope toes, formation collapse, earthquakes, increased pore water pressure due to rain infiltration during heavy rain, and increased surface loads. The artificial improper development, over-use and improper soil and water conservation are also the causes of slope disasters. Basically, in the case of different rock layer material combinations, different compound movements such as falling, overturning, sliding, side slipping, and flow will occur on the hillside. In recent years, different scales of slope soil and sand disasters have been heard, which has a considerable impact on the safety of human communities and buildings.

以坡地災害防治而言,當降雨快速入滲造成地下水位抬升,岩層孔隙水壓增加,坡地剪力強度降低,即有可能觸發一系列包括山崩的大規模坡地災害,如何即時掌握自然邊坡或擋土牆三維的傾斜和變位量,在劇烈滑動徵兆出現時採取應對措施,對於保障人民生命財產之安全相當重要。In terms of slope disaster prevention and control, when rapid rainfall infiltration causes the rise of the groundwater level, the rock pore water pressure increases, and the slope shear strength decreases, that is, it may trigger a series of large-scale slope disasters including landslides. How to immediately grasp the natural slope or The three-dimensional inclination and displacement of the retaining wall, and taking countermeasures when signs of severe sliding occur, are very important to ensure the safety of people's lives and property.

為減緩坡地土砂災害發生所帶來的災害,除了做好水土保持工作,透過排水工法進行整治,減少降雨入滲、加速雨水排出而降低邊坡內之地下水,主動性降低豪大雨導致坡地崩滑之風險以外,也應積極監測邊坡穩定性,掌握觀測滑動區地盤傾斜與變動量隨時間的潛在變化,分析邊坡可能的滑動型態,藉以防範於未然。In order to mitigate the disasters caused by soil and sand disasters on slopes, in addition to doing good soil and water conservation work, remediation is carried out through drainage methods to reduce rainfall infiltration, accelerate rainwater drainage and reduce groundwater in slopes, and actively reduce heavy rains to cause slope collapse In addition to the risks, the slope stability should also be actively monitored, the potential changes of the site tilt and the amount of change in the movement area over time should be observed, and the possible sliding pattern of the slope should be analyzed to prevent it from happening.

傳統監測邊坡穩定性之設備或方法包括使用地表伸縮儀、管內傾斜儀、壓力式水位計與地表傾斜計等,前三者多裝置在鑽孔內埋深於地底下,地表傾斜計則多裝置於地表上或近地表處,單就施作方便性而言,地表傾斜計的裝設有其優勢,目前已在大地工程領域中用於人工構築邊坡或擋土設施的側向變位及變位方向監測方面。Traditional equipment or methods for monitoring slope stability include the use of surface telemeters, in-tube inclinometers, pressure-type water level gauges, and surface inclinometers. The former three devices are buried deep below the ground in the borehole, while surface inclinometers Many devices are installed on the surface or near the surface. In terms of convenience, the installation of the surface inclinometer has its advantages. It has been used in the field of geotechnical engineering to artificially construct lateral changes of slopes or retaining facilities. Position and displacement direction monitoring.

此外,傳統水管式或盤式地表傾斜計的監測方式是屬於手動計讀式傾度計,皆需以人工目視的方式於現地計讀儀器刻度,計算傾斜量與方向,操作相當費時費力,且容易存在人為判斷精準度較差的問題。因此,目前大多以電子式雙軸傾斜計的應用為主,其以電子感測元件製作,在特定之監測頻率下量測待測物之傾斜角度,再藉由電路整合轉成電子式的訊號輸出,因此量測範圍與精度相對較傳統地表傾斜計高In addition, the traditional water pipe or disc type surface inclinometer monitoring method is a manual reading type inclinometer. Both need to manually read the instrument scale on the spot to calculate the amount and direction of the incline. The operation is very time-consuming and easy, and easy There is a problem of poor accuracy of human judgment. Therefore, at present, most of the applications are electronic dual-axis inclinometers, which are made of electronic sensing devices, measure the tilt angle of the object under specific monitoring frequency, and then convert into electronic signals by circuit integration Output, so the measurement range and accuracy are relatively higher than traditional surface inclinometers

然而,目前電子式雙軸傾斜計有若干缺點,造成應用上的限制However, the current electronic dual-axis inclinometer has several shortcomings, which limits the application

首先,目前電子式雙軸傾斜計多無法單獨量測垂直向的位移量,而必須另裝設地表沉陷釘,以水準測量方式量測沉陷釘之垂直位移量,或是於鑽井內安裝沉陷計,量測沉陷計之垂直變化量。或是在監測範圍內設置若干固定觀測點,再於監測範圍外利用光波測距系統量測各觀測點之三維位移變化。然而,光波測距系統測量精度易受天候影響,也需以人工方式於現地操作First of all, the current electronic dual-axis inclinometers cannot measure the vertical displacement alone. Instead, a ground subsidence nail must be installed to measure the vertical displacement of the subsidence nail by leveling, or a subsidence gauge can be installed in the well. , Measure the vertical change of the subsidence meter. Or set a number of fixed observation points within the monitoring range, and then use the optical wave ranging system to measure the three-dimensional displacement changes of each observation point outside the monitoring range. However, the measurement accuracy of the lightwave ranging system is susceptible to weather, and it also needs to be manually operated locally

第二,目前電子式雙軸傾斜計資料擷取系統多採用藍芽或電腦傳輸,雖然無需人工目視計讀刻度,監測人員仍須親赴現地進行資料擷取,應變時效性不佳,當遇緊急狀況時,亦無法於第一時間採取積極行動Second, the current electronic dual-axis inclinometer data acquisition system mostly uses Bluetooth or computer transmission. Although manual visual inspection of the scale is not required, the monitoring personnel must still go to the local site to acquire the data. The response time is not good. In case of emergency, it is not possible to take active action immediately

第三,目前電子式雙軸傾斜計硬體記憶容量有限,必須定期人工移轉資料Third, the current electronic dual-axis inclinometer has limited hardware memory capacity, and data must be transferred manually on a regular basis

第四,目前電子式雙軸傾斜計電源供應多仍仰賴市內電源,對於偏鄉、山區、海濱、田野等缺乏市電網絡的地點來說架設不易,且在電源緊急中斷時無法執行運作。對於具有潛在變位潛勢的邊坡災防工程來說,防護效益受到侷限,亦缺乏完整預警與監測的功效Fourth, the current power supply of electronic dual-axis inclinometers still depends on the city's power supply. It is not easy to set up in places with no city power network, such as rural areas, mountains, seasides, and fields, and it cannot perform operations when the power supply is urgently interrupted. For slope disaster prevention projects with potential displacement potential, the protection benefits are limited, and the effectiveness of complete early warning and monitoring is also lacking

因此,需要一種高精度、可無線傳輸、耗能低的傾斜感測系統,用以提升待測目標物的傾斜和變位之預警與監測的功效,協助試驗人員與決策者更快速與完整掌握土岩邊坡或相關待測目標的滑動與變位徵兆,於異常發生前採取應對措施,藉以解決上述習用技術的問題。Therefore, there is a need for a high-precision, wireless transmission, low-energy tilt sensing system to improve the early warning and monitoring of tilt and displacement of the target to be tested, to help testers and decision makers more quickly and completely master The sliding and displacement signs of the soil and rock slopes or related objects to be tested should be taken before the anomaly occurs to solve the above-mentioned conventional technology problems.

本發明之目的在提供一種高精度無線節能傾斜感測系統,包括至少一無線傾斜感測裝置、現地資料蒐集器、資料接收伺服器、資料庫伺服器以及網頁伺服器,用以提供高精度、無線傳輸且節能的傾斜感測功能。The purpose of the present invention is to provide a high-precision wireless energy-saving tilt sensing system, including at least one wireless tilt sensing device, a local data collector, a data receiving server, a database server, and a web server to provide high precision, Wireless transmission and energy-saving tilt sensing function.

具體而言,每個無線傾斜感測裝置是安裝於支架或容置盒而固定於待測物的預設位置,用以量測待測物在預設位置的傾斜角度,並且包括雙軸傾斜感測元件、第一無線通訊模組以及電源模組,其中雙軸傾斜感測元件是在特定監測頻率下感測待測物而產生並輸出傾斜角度,而第一無線通訊模組是電氣連接至雙軸傾斜感測元件,用以接收傾斜角度,並藉無線區域網路而傳送包含傾斜角度的感測資料,且由電源模組提供電力給傾斜感測元件及無線通訊模組而運作。Specifically, each wireless tilt sensing device is mounted on a bracket or a containing box and fixed to a preset position of the object to be measured, used to measure the tilt angle of the object to be measured at the preset position, and includes a two-axis tilt A sensing element, a first wireless communication module, and a power module, wherein the dual-axis tilt sensing element senses the object to be measured at a specific monitoring frequency and generates a tilt angle, and the first wireless communication module is electrically connected The dual-axis tilt sensing element is used to receive the tilt angle and transmit the sensing data including the tilt angle through the wireless local area network, and the power supply module provides power to the tilt sensing element and the wireless communication module to operate.

現地資料蒐集器是藉無線區域網路而連結至該至少一無線傾斜感測裝置,用以接收、儲存感測資料,並以預先設定之資料回傳頻率透過電信業者提供之廣域網路而傳送感測資料。現地資料蒐集器是藉無線區域網路而連結至該至少一無線傾斜感測裝置,用以接收、儲存感測資料,並以預先設定之資料回傳頻率透過電信業者提供之廣域網路而傳送感測資料。網頁伺服器是連結至資料庫伺服器,接收並依據使用者的查詢要求以擷取出資料庫伺服器中查詢要求所對應的監測資料,並呈現於網頁伺服器的一網頁中。The local data collector is connected to the at least one wireless tilt sensing device through a wireless local area network to receive and store the sensing data, and transmit the sense through the wide area network provided by the telecommunications provider at a preset data return frequency Test data. The local data collector is connected to the at least one wireless tilt sensing device through a wireless local area network to receive and store the sensing data, and transmit the sense through the wide area network provided by the telecommunications provider at a preset data return frequency Test data. The web server is connected to the database server, receives and retrieves the monitoring data corresponding to the query request in the database server according to the user's query request, and presents it in a web page of the web server.

此外,本發明之另一目的在提供一種高精度無線節能傾斜感測方法,包括:備製至少一無線傾斜感測裝置,每個無線傾斜感測裝置包含雙軸傾斜感測元件、第一無線通訊模組以及電源模組,而第一無線通訊模組係電氣連接至雙軸傾斜感測元件,且傾斜感測元件及無線通訊模組是由電源模組提供電力而運作;將每個無線傾斜感測裝置安裝於支架或容置盒而固定於待測物的預設位置;利用雙軸傾斜感測元件以特定監測頻率感測待測物而產生並輸出待測物的傾斜角度至第一無線通訊模組;利用第一無線通訊模組藉無線區域網路而傳送包含傾斜角度的感測資料至現地資料蒐集器;利用現地資料蒐集器以預先設定之資料回傳頻率透過電信業者提供之廣域網路而傳送感測資料至資料接收伺服器;利用資料接收伺服器接收感測資料,且將感測資料整理成具資料庫格式的監測資料,並上傳至資料庫伺服器而儲存; 利用網頁伺服器連結至資料庫伺服器;以及利用網頁伺服器接收並依據使用者的查詢要求,以擷取出資料庫伺服器中查詢要求所對應的監測資料,並呈現監測資料於網頁伺服器的網頁中。In addition, another object of the present invention is to provide a high-precision wireless energy-saving tilt sensing method, including: preparing at least one wireless tilt sensing device, each wireless tilt sensing device including a dual-axis tilt sensing element, a first wireless Communication module and power supply module, and the first wireless communication module is electrically connected to the dual-axis tilt sensing element, and the tilt sensing element and the wireless communication module are operated by the power supply module power supply; each wireless The tilt sensing device is mounted on a bracket or a holding box and is fixed at a preset position of the object to be measured; a dual-axis tilt sensing element is used to sense the object to be measured at a specific monitoring frequency to generate and output the tilt angle of the object to be measured A wireless communication module; using the first wireless communication module to transmit the sensing data including the inclination angle to the local data collector through the wireless local area network; using the local data collector to provide the pre-set data return frequency through the telecommunications provider Send sensing data to the data receiving server through the wide area network; use the data receiving server to receive the sensing data, and organize the sensing data into monitoring data in database format, and upload to the database server for storage; use The web server is connected to the database server; and the web server is used to receive and retrieve the monitoring data corresponding to the query request in the database server according to the user's query request, and present the monitoring data on the web server's web page in.

因此,本發明提供高精度、無線傳輸且節能的傾斜感測功能,並進一步提供遠端控制平台,讓使用者可透過無線電子裝置連結,即時讀取相關資訊或控制系統運作,具體達成待測目標物雙軸向傾斜變化自動監測、高程變化自動監測、提升數據傳輸,尤其,無需人工定期抄表,不受硬體記憶容量限制,耗能更少,使用壽命更長等功效,而依照本發明所揭示的方法,可達到更完整傾斜和變位預警與監測的功效。Therefore, the present invention provides a high-precision, wireless transmission and energy-saving tilt sensing function, and further provides a remote control platform, so that users can connect through wireless electronic devices to read related information or control system operation in real time, specifically to achieve the test Automatic monitoring of biaxial tilt changes of target objects, automatic monitoring of elevation changes, and improved data transmission. In particular, there is no need for manual meter reading, not limited by hardware memory capacity, less energy consumption, longer service life and other functions. The method disclosed in the invention can achieve the effect of more complete tilt and displacement early warning and monitoring.

以下配合圖示及元件符號對本發明之實施方式做更詳細的說明,俾使熟習該項技藝者在研讀本說明書後能據以實施。The embodiments of the present invention will be described in more detail below with reference to icons and component symbols, so that those skilled in the art can implement them after studying this specification.

請參閱第一圖,本發明實施例高精度無線節能傾斜感測系統的示意圖。如第一圖所示,本發明實施例的高精度無線節能傾斜感測系統包括至少一無線傾斜感測裝置10、現地資料蒐集器(On-Site Data Collector)20、資料接收伺服器(Data Receiver)30、資料庫伺服器(Database Server)40以及網頁伺服器(Web Server) 50,用以提供高精度、無線傳輸且節能的傾斜感測功能,適用於天然地面、山體,或人工建築或大型物件。Please refer to the first figure, a schematic diagram of a high-precision wireless energy-saving tilt sensing system according to an embodiment of the present invention. As shown in the first figure, the high-precision wireless energy-saving tilt sensing system according to an embodiment of the present invention includes at least one wireless tilt sensing device 10, an on-site data collector (On-Site Data Collector) 20, and a data receiving server (Data Receiver) ) 30, Database Server (Database Server) 40 and Web Server (Web Server) 50, used to provide high-precision, wireless transmission and energy-saving tilt sensing function, suitable for natural ground, mountain, or artificial buildings or large object.

具體而言,每個無線傾斜感測裝置10是安裝於支架或容置盒S而固定於待測物的不同預設位置,用以量測待測物在預設位置的傾斜角度。舉例而言,待測物可為自然土岩層邊坡,也可為人為的擋土護坡、橋墩、建物、水壩、堤防、連續壁、浮動碼頭、海上鑽探平台、軌道式、迴轉式與吊纜式機械遊樂設施,等等。Specifically, each wireless tilt sensing device 10 is mounted on a bracket or a storage box S and fixed at different preset positions of the object to be measured, for measuring the tilt angle of the object at the preset position. For example, the object to be tested can be a natural soil rock slope, or an artificial earth retaining slope, bridge pier, building, dam, embankment, continuous wall, floating pier, offshore drilling platform, rail type, rotary type and crane Cable mechanical rides, etc.

進一步,每個無線傾斜感測裝置10包含雙軸傾斜感測元件(Dual Axes Inclinemeter)11、第一無線通訊模組(First Wireless Communication Module)12以及電源模組13,其中雙軸傾斜感測元件11是在特定監測頻率下感測並輸出待測物的傾斜角度,第一無線通訊模組12是電氣連接至雙軸傾斜感測元件11,用以接收傾斜角度,並藉無線區域網路(Wireless Local Area Network, WLAN)而傳送至現地資料蒐集器20,並且由電源模組13提供電力給傾斜感測元件11及無線通訊模組12而運作。例如,電源模組13可包含鋰聚合物(Li-poly)電池,而且能提供2至3年的電力。Further, each wireless tilt sensing device 10 includes a dual axis tilt sensing element (Dual Axes Inclinemeter) 11, a first wireless communication module (First Wireless Communication Module) 12 and a power module 13, wherein the dual axis tilt sensing element 11 is to sense and output the tilt angle of the object to be measured at a specific monitoring frequency. The first wireless communication module 12 is electrically connected to the dual-axis tilt sensing element 11 for receiving the tilt angle and borrowing the wireless local area network ( Wireless Local Area Network (WLAN) to the local data collector 20, and the power supply module 13 provides power to the tilt sensing element 11 and the wireless communication module 12 to operate. For example, the power module 13 may include a lithium polymer (Li-poly) battery, and can provide power for 2 to 3 years.

上述的現地資料蒐集器20接收並儲存由每個高精度無線節能傾斜感測系統10的第一無線通訊模組12所傳送的傾斜角度,再以預先設定的資料回傳頻率透過電信業者提供之廣域網路(Wide Area Network)而將感測資料回傳至遠端的資料接收伺服器30。不過要注意的是,現地資料蒐集器20本質上是可同時支援多個高精度無線節能傾斜感測系統10,亦即,能同時接收並傳送不同高精度無線節能傾斜感測系統10的傾斜角度。簡而言之,現地資料蒐集器20可在實際應用上配置多個高精度無線節能傾斜感測系統10,藉以涵蓋較廣大的面積,擴大整個感測範圍,比如可感測超大型建築物、堤壩、地表或山體是否發生傾斜。The above-mentioned local data collector 20 receives and stores the tilt angle transmitted by the first wireless communication module 12 of each high-precision wireless energy-saving tilt sensing system 10, and then provides it through the telecommunications provider at a preset data return frequency The wide area network (Wide Area Network) returns the sensing data to the remote data receiving server 30. However, it should be noted that the local data collector 20 can essentially support multiple high-precision wireless energy-saving tilt sensing systems 10 at the same time, that is, can simultaneously receive and transmit the tilt angles of different high-precision wireless energy-saving tilt sensing systems 10 . In short, the local data collector 20 can be configured with multiple high-precision wireless energy-saving tilt sensing systems 10 in practical applications to cover a wider area and expand the entire sensing range, such as sensing large buildings, Whether the dike, ground or mountain slopes.

此外,資料接收伺服器30將所接收到的感測資料整理成具資料庫格式的監測資料,並上傳至資料庫伺服器40,且由連結至資料庫伺服器40的網頁伺服器50接收使用者的查詢要求,比如由使用者可利用電腦或智慧型手機連結至網頁伺服器50,因而網頁伺服器50可依據查詢要求以擷取出資料庫伺服器40中查詢要求所對應的監測資料,進而呈現於網頁伺服器50的網頁中。較佳的,網頁伺服器50的網頁是以圖形、表格的形式以呈現監測資料。因此,使用者可由網頁伺服器50中網頁所顯示的圖形、表格的形式而即時獲知包含待測物的傾斜角度的完整監測資料。In addition, the data receiving server 30 organizes the received sensing data into monitoring data in a database format and uploads it to the database server 40, and the web server 50 connected to the database server 40 receives and uses The query request of the user, for example, the user can use a computer or a smart phone to connect to the web server 50, so the web server 50 can retrieve the monitoring data corresponding to the query request in the database server 40 according to the query request, and Presented in the web page of the web server 50. Preferably, the web page of the web server 50 presents monitoring data in the form of graphics and tables. Therefore, the user can instantly obtain the complete monitoring data including the tilt angle of the object to be measured in the form of graphics and tables displayed on the web page in the web server 50.

更加具體而言,上述的現地資料蒐集器20主要是包含第二無線通訊模組(Second Wireless Communication Module)21、控制記錄模組22、廣域通信模組23,且是由電源單元PU供應電力而運作,而電源單元PU可為太陽能、電池或市電,其中第二無線通訊模組21是連結至第一無線通訊模組12,並接收第一無線通訊模組12所傳送的監測資料,而控制記錄模組22連結至第二無線通訊模組21,用以接收並控制、儲存監測資料以供讀取,且廣域通信模組23電氣連接至控制記錄模組22以接收監測資料,並利用廣域網路而將監測資料傳送至資料接收伺服器30。More specifically, the aforementioned local data collector 20 mainly includes a second wireless communication module (Second Wireless Communication Module) 21, a control recording module 22, and a wide area communication module 23, and is powered by a power supply unit PU And the power unit PU can be solar energy, battery or commercial power, wherein the second wireless communication module 21 is connected to the first wireless communication module 12 and receives the monitoring data transmitted by the first wireless communication module 12, and The control recording module 22 is connected to the second wireless communication module 21 for receiving and controlling and storing monitoring data for reading, and the wide area communication module 23 is electrically connected to the control recording module 22 to receive monitoring data, and The monitoring data is transmitted to the data receiving server 30 using a wide area network.

此外,為進一步確保對現地資料蒐集器20的電力穩定供應及長期運作,本發明的高精度無線節能傾斜感測系統可進一步包括太陽能板24及太陽能電力控制器25,並由太陽能板24接收太陽光L以產生太陽能電力,當作再生電力,且由太陽能電力控制器25接收太陽能電力而對電源單元PU進行充電。 因此,電源單元PU可在太陽能充電下穩定提供所需電力,改善現地資料蒐集器20的操作穩定性。In addition, to further ensure stable power supply and long-term operation of the local data collector 20, the high-precision wireless energy-saving tilt sensing system of the present invention may further include a solar panel 24 and a solar power controller 25, and the solar panel 24 receives the sun The light L generates solar power as regenerative power, and the solar power controller 25 receives the solar power to charge the power supply unit PU. Therefore, the power supply unit PU can stably provide the required power under solar charging, and improve the operation stability of the local data collector 20.

進一步,控制記錄模組22可包含記憶媒體以及三電源控制模組(圖中未顯示),並由記憶媒體儲存監測資料,且每個電源控制模組可提供12V電源輸出,藉以控制控制記錄模組22的工作時間及休眠時間。例如,可依據實際需要,彈性調整工作時間及休眠時間,藉以控制工作的密集程度,可節電力耗損,優化的電力的使用效率,進而延長運作時間。Further, the control recording module 22 may include a memory medium and three power control modules (not shown in the figure), and the monitoring data is stored by the memory medium, and each power control module may provide a 12V power output to control the control recording module Working time and sleep time of group 22. For example, the working time and sleep time can be flexibly adjusted according to actual needs, so as to control the intensity of the work, which can save power consumption, optimize the efficiency of power usage, and thereby extend the operating time.

此外,廣域通信模組23可包含3G/GPRS通信模組。In addition, the wide area communication module 23 may include a 3G/GPRS communication module.

具體而言,本發明第一實施例的系統可應用於自然或人為坡地三軸向傾斜變化量與高程變化的自動監測,且更為節能省電,可提升坡地傾斜量和變位預警與監測的功效,降低坡地災害所帶來的生命財產損失,此外,還可延伸應用至固定式建築物(房舍、水壩、堤防、浮動碼頭、海上鑽探平台)、暫設工程建物(舞台、工務所、鷹架、預拌混凝土設施、連續壁、倉庫)與非固定式(軌道式、迴轉式與吊纜式) 機械遊樂設施的安全性監控上,透過數據傳輸可實際做到無線傳輸與遠端監控,加上自主電力設計,無須在現場另行架設電力,確實達到節能之目的。Specifically, the system of the first embodiment of the present invention can be applied to automatic monitoring of three-axis tilt changes and elevation changes of natural or man-made slopes, and is more energy-saving and power-saving, which can improve slope tilt and displacement warning and monitoring It can reduce the loss of life and property caused by slope disasters. In addition, it can be extended to fixed buildings (houses, dams, embankments, floating docks, offshore drilling platforms), temporary engineering structures (stages, engineering offices) , Scaffolding, ready-mixed concrete facilities, continuous walls, warehouses) and non-stationary (track, slewing, and cable-cable) safety monitoring of mechanical amusement facilities, data transmission can actually achieve wireless transmission and remote Monitoring, coupled with independent power design, eliminates the need to set up additional power at the site, which truly achieves the purpose of energy saving.

舉例而言,國內針對建築物工程施工損害鄰房之鑑定係依會勘所見標的物結構的傾斜率來計算損害修復費用及補償費用,然而對於傾斜方向及傾斜率量測方式不甚客觀,易產生爭議。本發明的系統除了可掌握施工前後鄰房傾斜動態變化資訊,增加傾斜率量測的合理性,也有助於釐清責任歸屬,減少爭議。For example, the identification of damage to neighboring buildings in the construction of a building project in China is based on the tilt of the target structure of the Institute of Geotechnical Research to calculate the damage repair cost and compensation costs. However, the direction and tilt of the tilt is not very objective and easy to measure Controversy. The system of the present invention can not only grasp the information of the dynamic change of the inclination of the neighboring house before and after construction, increase the inclination measurement, but also help clarify the attribution of responsibility and reduce disputes.

再舉例,水利建造物例如堤防、防洪牆、護岸、丁壩、防砂壩、潛壩、固床工、水門、取水工、隧道、渡槽、管路箱涵、堰、壩、水庫等多半設置於外在邊界條件變動大的環境,用以抵擋外力,其結構勁度會隨環境條件與外力作用而有相對劇烈變化,振動頻率也隨之改變,且不易藉由定期檢測了解結構體劣化的進程。此時,採用本發明的系統將有其建置之價值,可做為損傷診斷之依據,並提早預警。As another example, water conservancy structures such as dikes, flood walls, revetments, spur dams, sand control dams, submarine dams, fixed bed workers, water gates, water intakes, tunnels, aqueducts, pipeline culverts, weirs, dams, reservoirs, etc. are mostly installed outside In an environment with large changes in boundary conditions, to resist external forces, the structural stiffness will change relatively drastically with the environmental conditions and external forces, and the vibration frequency will also change. It is not easy to understand the progress of structural degradation through regular inspection. At this time, the system adopting the present invention will have its construction value, which can be used as a basis for damage diagnosis and early warning.

進一步舉例,碼頭基樁容易受到工址土壤性質、地質條件、地震、波浪、港內盪漾、潮位、水流、氣候、水深件等因素之影響而產生變位,而就碼頭耐震性要求來說,碼頭傾斜度、位移量、變位角等也是定義碼頭結構性能可接受標準的重要參數。本發明的系統可大幅提升檢核的精準度,使設計者、使用者與決策者均能快速掌握碼頭構造物在遭遇不同強度的地震時之結構耐震能力。As a further example, the pier foundation pile is susceptible to displacement due to factors such as soil properties, geological conditions, earthquakes, waves, waves in the harbor, tide level, water flow, climate, water depth and other factors. As far as the seismic resistance requirements of the pier are concerned, Pier tilt 度, displacement, displacement angle, etc. are also important parameters that define acceptable standards for the performance of the wharf structure. The system of the present invention can greatly improve the accuracy of inspection, so that designers, users and decision makers can quickly grasp the structural seismic resistance of the dock structure when it encounters an earthquake of the same strength 度.

此外,本發明的系統也可應用於非固定式(軌道式、迴轉式與吊纜式)機械遊樂設施的安全性監控,軌道式機械遊樂設施係指雲霄飛車、單軌電車、水上飛船及其他循軌道運動之設施。迴轉式機械遊樂設施係指旋轉馬車、咖啡杯、飛行塔、離心輪及其他以單一或多圓心迴轉運動之設施。吊纜式機械遊樂設施係指纜車、覽車及其他以鋼索懸吊運動之設施。透過事先定義傾斜角度或變位量可容許值,在本發明偵測到傾斜度或變位值異常時向管理單位提出警訊。In addition, the system of the present invention can also be applied to the safety monitoring of non-stationary (track, slewing, and cable) mechanical amusement rides. Railroad mechanical amusement rides refer to roller coasters, monorails, water crafts, and other routines. Orbital facilities. Rotary mechanical amusement facilities refer to rotating carriages, coffee cups, flying towers, centrifugal wheels and other facilities that rotate in a single or multiple circle center. Cable-type mechanical amusement rides refer to cable cars, viewing cars and other facilities that are suspended by steel cables. By defining the allowable value of the tilt angle or the displacement amount in advance, the present invention raises a warning signal to the management unit when it detects an abnormal tilt or displacement value.

因此,本發明第一實施例的主要特點在於整合多個無線傾斜感測裝置、現地資料蒐集器、資料接收伺服器、資料庫伺服器以及網頁伺服器,用以提供高精度、無線傳輸且節能的傾斜感測功能,不僅解決習用電子式雙軸傾斜裝置無法量測垂直位移量與高程變化的問題,而且還仍具有高精度和低耗電流的特點,具體實現自動監測現場三軸向變位與高程變化的功效,可單一機體運作也可進行多機系統性網絡串聯監測,實質上大幅提升坡地災害管理單位防災應變能力,因而能有效且具體達成對待測物之雙軸向傾斜變化的自動監測、高程變化自動監測,進而改善數據傳輸效率,達到更完整的傾斜和變位預警與監測之功效。Therefore, the main feature of the first embodiment of the present invention is the integration of multiple wireless tilt sensing devices, local data collectors, data receiving servers, database servers, and web servers to provide high accuracy, wireless transmission, and energy saving The tilt sensing function not only solves the problem that the conventional electronic dual-axis tilting device cannot measure the vertical displacement and elevation change, but also has the characteristics of high precision and low current consumption, and realizes the automatic monitoring of the three-axis displacement in the field. With the effect of elevation change, it can operate in a single body or perform multi-system systematic network series monitoring, which substantially improves the disaster prevention and response capabilities of slope disaster management units, so it can effectively and specifically achieve the automatic biaxial tilt change of the measured object. Monitoring, automatic monitoring of elevation changes, thereby improving data transmission efficiency, to achieve a more complete tilt and displacement warning and monitoring effect.

此外,本發明的系統能提供遠端控制平台,讓使用者可透過無線電子裝置連結,比如智慧型手機或電腦,藉以即時讀取相關資訊或控制系統運作,也可進一步搭配衛星動態定位技術量測高程變化,落實監控智慧化之無線傳輸與遠端監控,而無需人工定期抄表,更不受硬體記憶容量限制,且耗能更少,使用壽命更長。In addition, the system of the present invention can provide a remote control platform, allowing users to connect through wireless electronic devices, such as smart phones or computers, to read related information in real time or control the system to operate, and can also be further equipped with satellite dynamic positioning technology Measuring elevation changes, implementing intelligent wireless transmission and remote monitoring of monitoring, without the need for manual periodic meter reading, and is not limited by hardware memory capacity, and consumes less energy and has a longer service life.

進一步參考第二圖,本發明第二實施例高精度無線節能傾斜感測方法的操作流程示意圖。如第二圖所示,本發明第二實施例的高精度無線節能傾斜感測方法包含步驟S10、S20、S30、S40、S50、 S60、S70以及S80,用以提供對天然地面、山體,或人工建築或大型物件的高精度、無線傳輸及節能省電的傾斜感測功能。With further reference to the second figure, a schematic flowchart of the operation of the high-precision wireless energy-saving tilt sensing method according to the second embodiment of the present invention. As shown in the second figure, the high-precision wireless energy-saving tilt sensing method of the second embodiment of the present invention includes steps S10, S20, S30, S40, S50, S60, S70, and S80 to provide a natural ground, mountain, or High-precision, wireless transmission, energy-saving and power-saving tilt sensing function for artificial buildings or large objects.

首先,本發明第二實施例的高精度無線節能傾斜感測方法是由步驟S10開始,備製至少一無線傾斜感測裝置,其中每個無線傾斜感測裝置包含雙軸傾斜感測元件、第一無線通訊模組以及電源模組,而第一無線通訊模組是電氣連接至雙軸傾斜感測元件,且傾斜感測元件及無線通訊模組是由電源模組提供電力而運作。接著在步驟S20中,將每個無線傾斜感測裝置安裝於支架或容置盒,進而固定於待測物的預設位置,比如自然土岩層邊坡,或是人為的擋土護坡、橋墩、建物、水壩、堤防、連續壁、浮動碼頭、海上鑽探平台、軌道式、迴轉式與吊纜式機械遊樂設施等等的待測物。First, the high-precision wireless energy-saving tilt sensing method of the second embodiment of the present invention starts with step S10 and prepares at least one wireless tilt sensing device, where each wireless tilt sensing device includes a dual-axis tilt sensing element, a A wireless communication module and a power supply module, and the first wireless communication module is electrically connected to the dual-axis tilt sensing element, and the tilt sensing element and the wireless communication module are operated by power provided by the power supply module. Next, in step S20, each wireless tilt sensing device is installed on a bracket or a containing box, and then fixed to a predetermined position of the object to be measured, such as a natural soil rock slope, or an artificial earth retaining slope, bridge pier, Objects to be tested for buildings, dams, embankments, continuous walls, floating piers, offshore drilling platforms, rail-type, rotary and cable-type mechanical amusement devices, etc.

進入步驟S30,利用雙軸傾斜感測元件以特定監測頻率感測待測物,進而產生並輸出待測物的傾斜角度至第一無線通訊模組,在步驟S40中,利用第一無線通訊模組藉無線區域網路而傳送包含傾斜角度的感測資料至現地資料蒐集器,再於步驟S50中,利用現地資料蒐集器以預先設定之資料回傳頻率透過電信業者提供之廣域網路而傳送感測資料至資料接收伺服器。Go to step S30, use the dual-axis tilt sensing element to sense the object to be measured at a specific monitoring frequency, and then generate and output the tilt angle of the object to the first wireless communication module. In step S40, use the first wireless communication module The group transmits the sensing data including the inclination angle to the local data collector through the wireless local area network, and then in step S50, the local data collector is used to transmit the sense through the wide area network provided by the telecommunications provider at the preset data return frequency Test data to the data receiving server.

進入步驟S60,利用資料接收伺服器將所接收到的感測資料整理成具資料庫格式的監測資料,並上傳至資料庫伺服器而儲存,且在步驟S70中,利用網頁伺服器連結至資料庫伺服器,最後進入步驟S80,利用網頁伺服器接收使用者的查詢要求,且依據查詢要求以擷取出該資料庫伺服器中查詢要求所對應的監測資料,並將監測資料呈現於網頁伺服器的網頁中。Go to step S60, use the data receiving server to organize the received sensing data into database format monitoring data, and upload to the database server for storage, and in step S70, use the web server to link to the data The database server finally enters step S80, uses the web server to receive the user's query request, and retrieves the monitoring data corresponding to the query request in the database server according to the query request, and presents the monitoring data to the web server Page.

因此,本發明的方法具體實現自動化且高精度的感測、儲存、傳送並呈現待測物之傾斜資料的功能,並達到無線傳輸及節能、省電的功效,無需人工定期抄表,更不受硬體記憶容量限制,進而提升待測物傾斜和變位預警與監測的功效,協助試驗人員與決策者更快速與完整掌握土岩邊坡或相關待測物的滑動與變位徵兆,而在異常發生前,先採取應對措施,防患於未然。Therefore, the method of the present invention specifically realizes the functions of automatic, high-precision sensing, storage, transmission, and presentation of the tilt data of the object to be measured, and achieves the functions of wireless transmission, energy saving, and power saving, without the need for manual periodic meter reading, let alone Limited by the memory capacity of the hardware, which further improves the tilting and displacement warning and monitoring of the test object, and helps the testers and decision makers to quickly and completely grasp the sliding and displacement signs of the soil and rock slopes or related test objects, and Before the anomaly occurs, take countermeasures to prevent it from happening.

以上所述者僅為用以解釋本發明之較佳實施例,並非企圖據以對本發明做任何形式上之限制,是以,凡有在相同之發明精神下所作有關本發明之任何修飾或變更,皆仍應包括在本發明意圖保護之範疇。The above are only for explaining the preferred embodiments of the present invention, and are not intended to limit the present invention in any form, so that any modifications or changes made to the present invention under the same spirit of the invention , Should still be included in the scope of protection of the present invention.

10‧‧‧無線傾斜感測裝置11‧‧‧雙軸傾斜感測元件12‧‧‧第一無線通訊模組13‧‧‧電源模組20‧‧‧現地資料蒐集器21‧‧‧第二無線通訊模組22‧‧‧控制記錄模組23‧‧‧廣域通信模組24‧‧‧太陽能板25‧‧‧太陽能電力控制器30‧‧‧資料接收伺服器40‧‧‧資料庫伺服器50‧‧‧網頁伺服器L‧‧‧太陽光PU‧‧‧電源單元S‧‧‧容置盒S10~S80‧‧‧步驟10‧‧‧Wireless tilt sensing device 11‧‧‧ Dual axis tilt sensing element 12‧‧‧First wireless communication module 13‧‧‧Power module 20‧‧‧Local data collector 21‧‧‧Second Wireless communication module 22‧‧‧Control recording module 23‧‧‧ Wide area communication module 24‧‧‧Solar panel 25‧‧‧Solar power controller 30‧‧‧Data receiving server 40‧‧‧Data base servo 50‧‧‧Web server L‧‧‧Sunlight PU‧‧‧Power supply unit S‧‧‧Container box S10~S80‧‧‧Step

第一圖顯示依據本發明第一實施例高精度無線節能傾斜感測系統的示意圖。 第二圖顯示依據本發明第二實施例高精度無線節能傾斜感測方法的操作流程示意圖。The first figure shows a schematic diagram of a high-precision wireless energy-saving tilt sensing system according to the first embodiment of the present invention. The second figure shows the operation flow diagram of the high-precision wireless energy-saving tilt sensing method according to the second embodiment of the present invention.

S10~S80‧‧‧步驟 S10~S80‧‧‧Step

Claims (10)

一種高精度無線節能傾斜感測系統,包括: 至少一無線傾斜感測裝置,是分別安裝於一支架或一容置盒而固定於一待測物的一預設位置,用以量測該待測物在該預設位置的一傾斜角度,並包括一雙軸傾斜感測元件、一第一無線通訊模組以及一電源模組,且該雙軸傾斜感測元件是以一特定監測頻率感測待測物而產生並輸出該傾斜角度,該第一無線通訊模組係電氣連接至該雙軸傾斜感測元件,用以接收該傾斜角度,並藉一無線區域網路而傳送包含該傾斜角度的一感測資料,該電源模組提供電力給該傾斜感測元件及該無線通訊模組而運作; 一現地資料蒐集器,是藉該無線區域網路而連結至該至少一無線傾斜感測裝置,用以接收、儲存該感測資料,並以預先設定之一資料回傳頻率透過一電信業者提供之一廣域網路而傳送該感測資料; 一資料接收伺服器,是藉該廣域網路而連結至該現地資料蒐集器,用以接收該感測資料,且將該感測資料整理成具一資料庫格式的一監測資料,並上傳; 一資料庫伺服器,是連結至該資料接收伺服器,用以接收並儲存該監測資料以供讀取;以及 一網頁伺服器,是連結至該資料庫伺服器,且接收並依據一使用者的一查詢要求以擷取出該資料庫伺服器中該查詢要求所對應的該監測資料,並呈現於該網頁伺服器的一網頁中。A high-precision wireless energy-saving tilt-sensing system includes: at least one wireless tilt-sensing device, which is respectively installed on a bracket or a containing box and fixed to a preset position of an object to be measured, for measuring the object A tilt angle of the measured object at the preset position, and includes a dual-axis tilt sensing element, a first wireless communication module, and a power module, and the dual-axis tilt sensing element is sensed at a specific monitoring frequency The tilt angle is generated and output by measuring the object to be measured. The first wireless communication module is electrically connected to the dual-axis tilt sensing element to receive the tilt angle and transmit the tilt including the tilt through a wireless local area network Angle of sensing data, the power module provides power to the tilt sensing element and the wireless communication module to operate; a local data collector is connected to the at least one wireless tilt sensor via the wireless local area network A testing device for receiving and storing the sensing data, and transmitting the sensing data through a wide area network provided by a telecommunications provider at a preset data return frequency; a data receiving server is borrowed from the wide area network And link to the local data collector to receive the sensing data, and organize the sensing data into a monitoring data in a database format, and upload; a database server is linked to the data receiving A server for receiving and storing the monitoring data for reading; and a web server connected to the database server and receiving and retrieving the database server according to a query request of a user The monitoring data corresponding to the query request is presented in a web page of the web server. 依據申請專利範圍第1項所述之高精度無線節能傾斜感測系統,其中該現地資料蒐集器包含: 一第二無線通訊模組,係用以連結至該第一無線通訊模組,並接收該第一無線通訊模組所傳送的該監測資料; 一第二無線通訊模組,係連結至該第二無線通訊模組,用以接收該監測資料,並控制及儲存該監測資料以供讀取;以及 一廣域通信模組,係電氣連接至該控制記錄模組以接收該監測資料,並利用該廣域網路而將該監測資料傳送至該資料接收伺服器,且該第二無線通訊模組、該第二無線通訊模組、該廣域通信模是由一電源單元供應電力而運作。The high-precision wireless energy-saving tilt sensing system according to item 1 of the patent application scope, wherein the local data collector includes: a second wireless communication module for connecting to the first wireless communication module and receiving The monitoring data transmitted by the first wireless communication module; a second wireless communication module connected to the second wireless communication module for receiving the monitoring data, and controlling and storing the monitoring data for reading Fetch; and a wide area communication module, which is electrically connected to the control recording module to receive the monitoring data, and uses the wide area network to transmit the monitoring data to the data receiving server, and the second wireless communication module The group, the second wireless communication module, and the wide area communication module are operated by a power supply unit. 依據申請專利範圍第2項所述之高精度無線節能傾斜感測系統,其中電源單元為一市電或一電池,而該電池是由一太陽能板搭配一太陽能電力控制器以接收太陽光並產生太陽能電力而進行充電。According to the high-precision wireless energy-saving tilt sensing system described in item 2 of the patent application scope, wherein the power supply unit is a mains or a battery, and the battery is a solar panel with a solar power controller to receive sunlight and generate solar energy Power to charge. 依據申請專利範圍第2項所述之高精度無線節能傾斜感測系統,其中該控制記錄模組包含一記憶媒體以及三電源控制模組,並由該記憶媒體儲存該監測資料,且每個該電源控制模組提供12V電源輸出以控制該控制記錄模組的一工作時間及一休眠時間。According to the high-precision wireless energy-saving tilt sensing system described in item 2 of the patent application scope, wherein the control recording module includes a memory medium and three power control modules, and the memory medium stores the monitoring data, and each of the The power control module provides 12V power output to control a working time and a sleep time of the control recording module. 依據申請專利範圍第2項所述之高精度無線節能傾斜感測系統,其中該廣域通信模組包含一3G/GPRS通信模組。According to the high-precision wireless energy-saving tilt sensing system described in item 2 of the patent application scope, wherein the wide area communication module includes a 3G/GPRS communication module. 依據申請專利範圍第1項所述之高精度無線節能傾斜感測系統,其中該電源模組包含一鋰聚合物(Li-poly)電池。According to the high-precision wireless energy-saving tilt sensing system described in item 1 of the patent application scope, wherein the power module includes a lithium polymer (Li-poly) battery. 依據申請專利範圍第1項所述之高精度無線節能傾斜感測系統,其中該網頁是以圖形、表格的形式而呈現該監測資料。According to the high-precision wireless energy-saving tilt sensing system described in item 1 of the scope of patent application, wherein the web page presents the monitoring data in the form of graphics and tables. 一種高精度無線節能傾斜感測方法,包括: 備製至少一無線傾斜感測裝置,每個該無線傾斜感測裝置包含一雙軸傾斜感測元件、一第一無線通訊模組以及一電源模組,而該第一無線通訊模組係電氣連接至該雙軸傾斜感測元件,且該傾斜感測元件及該無線通訊模組是由該電源模組提供電力而運作; 將每個該無線傾斜感測裝置安裝於一支架或一容置盒而固定於一待測物的一預設位置; 利用該雙軸傾斜感測元件以一特定監測頻率感測該待測物而產生並輸出該待測物的一傾斜角度至該第一無線通訊模組; 利用該第一無線通訊模組藉一無線區域網路而傳送包含該傾斜角度的一感測資料至一現地資料蒐集器; 利用該現地資料蒐集器以預先設定之一資料回傳頻率透過一電信業者提供之一廣域網路而傳送該感測資料至一資料接收伺服器; 利用該資料接收伺服器接收該感測資料,且將該感測資料整理成具一資料庫格式的一監測資料,並上傳至一資料庫伺服器而儲存; 利用一網頁伺服器連結至該資料庫伺服器;以及 利用該網頁伺服器接收並依據一使用者的一查詢要求,以擷取出該資料庫伺服器中該查詢要求所對應的該監測資料,並呈現該監測資料於該網頁伺服器的一網頁中。A high-precision wireless energy-saving tilt sensing method includes: preparing at least one wireless tilt sensing device, each of which includes a dual-axis tilt sensing element, a first wireless communication module, and a power module Group, and the first wireless communication module is electrically connected to the dual-axis tilt sensing element, and the tilt sensing element and the wireless communication module are powered by the power supply module to operate; each of the wireless The tilt sensing device is mounted on a bracket or a containing box and fixed at a preset position of an object to be measured; the dual-axis tilt sensing element is used to sense the object to be tested at a specific monitoring frequency to generate and output the An inclination angle of the object to be measured to the first wireless communication module; using the first wireless communication module to transmit a sensing data including the inclination angle to a local data collector via a wireless local area network; using the The local data collector transmits the sensing data to a data receiving server through a wide area network provided by a telecommunications provider at a preset data return frequency; the data receiving server is used to receive the sensing data, and the Sensing data is organized into a monitoring data in a database format and uploaded to a database server for storage; using a web server to link to the database server; and using the web server to receive and according to a usage A query request of the author to retrieve the monitoring data corresponding to the query request in the database server and present the monitoring data in a web page of the web server. 依據申請專利範圍第8項所述之高精度無線節能傾斜感測方法,其中該現地資料蒐集器包含: 一第二無線通訊模組,係用以連結至該第一無線通訊模組,並接收該第一無線通訊模組所傳送的該監測資料; 一控制記錄模組,係連結至該第二無線通訊模組,用以接收該監測資料,並控制及儲存該監測資料以供讀取;以及 一廣域通信模組,係電氣連接至該控制記錄模組以接收該監測資料,並利用該廣域網路而將該監測資料傳送至該資料接收伺服器。According to the high-precision wireless energy-saving tilt sensing method described in item 8 of the patent application scope, wherein the local data collector includes: a second wireless communication module for connecting to the first wireless communication module and receiving The monitoring data transmitted by the first wireless communication module; a control recording module connected to the second wireless communication module for receiving the monitoring data, and controlling and storing the monitoring data for reading; And a wide area communication module, which is electrically connected to the control recording module to receive the monitoring data, and uses the wide area network to transmit the monitoring data to the data receiving server. 依據申請專利範圍第9項所述之高精度無線節能傾斜感測方法,其中該控制記錄模組包含一記憶媒體以及三電源控制模組,並由該記憶媒體儲存該監測資料,且每個該電源控制模組提供12V電源輸出以控制該控制記錄模組的一工作時間及一休眠時間。According to the high-precision wireless energy-saving tilt sensing method described in item 9 of the patent application scope, wherein the control recording module includes a memory medium and three power control modules, and the memory medium stores the monitoring data, and each of the The power control module provides 12V power output to control a working time and a sleep time of the control recording module.
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