TWI522625B - The Layout Management System of Wisdom Meter and Its Record Media - Google Patents
The Layout Management System of Wisdom Meter and Its Record Media Download PDFInfo
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Description
本發明是有關於一種智慧電表的管理系統與其紀錄媒體,特別是有關於管理智慧電表的佈建情形與維持通信的智慧電表的佈建管理系統與其紀錄媒體。 The invention relates to a management system of a smart meter and a recording medium thereof, in particular to a deployment management system for managing a smart meter and a smart meter for maintaining communication and a recording medium thereof.
先進讀表基礎建設(Advanced Metering Infrastructure,AMI;也稱作智慧電表系統),基本是由智慧型電表、通訊系統、電表資訊管理系統所組成。主要的架構包括以下數種: The Advanced Metering Infrastructure (AMI) is basically composed of a smart meter, a communication system, and an electric meter information management system. The main architecture includes the following:
(1)「後端伺服器-集中器-智慧電表」的主從式架構(Server-Master-Slave)。其中,後端伺服器(Server)與集中器(Concentrator)之間是藉由廣域網路(Wide area network,WAN)進行連接,連接的方式包括行動通訊技術(3G,3.5G,4G);實體網路線連接(如光纖通訊);或是異質通訊連接技術,例如後端伺服器連接一電力線網路裝置,電力線網路裝置再透過電力線載波(Power Line Carrier,PLC)等相關的電力線通訊(Power Line Communication)手段來連接集中器。 (1) The master-slave architecture of the "back-end server-concentrator-smart meter" (Server-Master-Slave). The back end server (Server) and the concentrator (Concentrator) are connected by a Wide Area Network (WAN), and the connection method includes mobile communication technology (3G, 3.5G, 4G); Route connection (such as fiber-optic communication); or heterogeneous communication connection technology, such as back-end server connection to a power line network device, power line network device and then through Power Line Carrier (PLC) and other related power line communication (Power Line Communication) means to connect the concentrator.
集中器與智慧電表之間是藉由區域網路(Local Area Network,LAN)進行連接。連接的方式包括無線通訊與有線通訊,無線通訊如:ZigBee、近場通訊(Near Field Communication,NFC)、藍芽(Bluetooth)、Wi-Fi、射頻(Radio Frequency,RF)傳輸;有線通訊如:電力線通訊,其為窄頻電力線通訊(Narrowband PLC,NPL)或寬頻電力線通訊(Broadband PLC,BPL)。 The concentrator and the smart meter are connected by a local area network (LAN). Connection methods include wireless communication and wired communication, wireless communication such as: ZigBee, Near Field Communication (NFC), Bluetooth, Wi-Fi, Radio Frequency (RF) transmission; wired communication such as: Power line communication, which is narrow-band power line communication (Narrowband PLC, NPL) or broadband power line communication (Broadband PLC, BPL).
(2)與第(1)種架構不同在於,集中器與智慧電表之間更包括一橋接裝置。橋接裝置是透過有線通訊連接集中器,透過無線通訊連接鄰接、或是同一區域、電表群組的智慧電表。有線通訊如光纖或是BPL 等寬頻通訊方式,無線通訊即如前述的近場通訊、藍芽、Wi-Fi、射頻傳輸…等。 (2) The difference from the (1) architecture is that a concentrator is included between the concentrator and the smart meter. The bridge device is connected to the concentrator through a wired communication, and is connected to the smart meter in the same area or the electric meter group through the wireless communication. Wired communication such as fiber optic or BPL Such as broadband communication, wireless communication is as described above for near field communication, Bluetooth, Wi-Fi, RF transmission, etc.
然而,不論就第(1)種架構或第(2)種架構,工作人員必定要具備現場勘測(site survey)能力或對應環境的勘測工具,不然工作人員難以尋得佈建環境的通訊品質影響因素,若是強制安裝,避免會產生多處通訊斷點,造成整體通訊效率大幅下降。而且若是勘測工具並非是專屬於勘測佈建環境的勘測器具,測試結果的參考性相對也較低,最終實地佈建成效果與現場勘測、及其預定策略的預期效果,兩者會形成相當大的落差。 However, regardless of the (1) structure or the (2) structure, the staff must have a site survey capability or a survey tool for the environment, otherwise it is difficult for the staff to find the communication quality impact of the deployment environment. Factors, if forced installation, avoid multiple communication breakpoints, resulting in a significant drop in overall communication efficiency. Moreover, if the surveying tool is not a surveying tool that is exclusively for the surveying and laying environment, the reference value of the test result is relatively low, and the final effect of the field construction and the site survey, and the expected effect of the predetermined strategy, will form a considerable Drop.
其次,第(1)種架構並無法適用於較為複雜的佈建環境。當集中器與智慧電表是無線通訊連接,若兩者之間具有障礙物時,或是集中器與智慧電表的佈建地點不佳時,像是智慧電表配置於鐵製的電表箱、智慧電表配置於房屋深處、智慧電表設置位置太高、或是被屋牆、招牌或是等障礙物所遮蔽,即會影響集中器與智慧電表之間的通訊品質,甚至於造成通訊中斷。再加上有些國家的制度中,禁止改造電表,因此用户或工作人員無法設置電表天線外引介面,以讓智慧電表與集中器之間形成無障礙通訊,無線通訊的功能即等同無用。 Second, the (1) architecture does not apply to more complex deployment environments. When the concentrator and the smart meter are connected by wireless communication, if there is an obstacle between the two, or when the location of the concentrator and the smart meter is not good, the smart meter is arranged in the iron meter box and the smart meter. When it is placed in the depth of the house, the location of the smart meter is too high, or it is obscured by the wall, signboard or other obstacles, it will affect the communication quality between the concentrator and the smart meter, and even cause communication interruption. In addition, in some countries' systems, the meter is forbidden to be modified. Therefore, the user or the staff cannot set the external interface of the meter antenna to form a barrier-free communication between the smart meter and the concentrator. The function of the wireless communication is equivalent.
又,當集中器與智慧電表是採用有線通訊(常見為窄頻電力線通訊)連接時,從屬電表有可能會被集中安裝於主控裝置的電力迴路,再加上禁止改造電表的原因,用戶或工作人員被無法設置NPL整合多變壓器以調整電力訊號,故容易造成主控裝置所連接電力迴路的負載不平衡的情形,進而影響通訊穩定性。 Moreover, when the concentrator and the smart meter are connected by wired communication (commonly for narrow-band power line communication), the slave meter may be centrally installed in the power circuit of the master device, plus the reason for prohibiting the modification of the meter, the user or The staff is unable to set up the NPL integrated multi-transformer to adjust the power signal, so it is easy to cause the load imbalance of the power circuit connected to the main control device, thereby affecting the communication stability.
其三,在佈建環境複雜,又缺乏完整佈建策略的情形下,部分場域在佈建、測試結果很可能不如預期。佈建人員僅能選擇「能安裝」、「效果不彰但適用性還可以」的方式進行佈建,但也容易產生前述的通訊斷點,造成日後大量的維護工作。 Third, in the case of a complicated deployment environment and a lack of a complete deployment strategy, some of the fields are being built and the test results are likely to be less than expected. The construction personnel can only choose to install the "can be installed", "the effect is not good, but the applicability is OK", but it is also easy to produce the aforementioned communication breakpoints, resulting in a lot of maintenance work in the future.
其四,就第(2)種架構而言,橋接裝置或電路的設置位置、空間必須被預先保留,而且設置時必須配合各電表的位置與佈線設計,不但提升電路配置的複雜性,設置的方式亦有所受限。再者,橋接裝置或電 路必須現場施工且施工位置通常鄰接於電表所在,也容易造成當地住戶的困擾與為何要更動電表迴路的疑慮。 Fourthly, in terms of the (2) architecture, the installation position and space of the bridge device or circuit must be reserved in advance, and the position and wiring design of each meter must be matched when setting, which not only enhances the complexity of the circuit configuration, but also sets The method is also limited. Furthermore, bridging devices or electricity The road must be constructed on site and the construction location is usually adjacent to the meter. It is also likely to cause problems for local residents and why they should change the circuit loop.
為解決上述問題,本發明係揭露一種智慧電表的佈建管理系統,用以管理佈建線路的佈建情形並保持主、從裝置之間的通訊路徑的暢通。 In order to solve the above problems, the present invention discloses a deployment management system for a smart meter for managing the deployment of the deployment line and maintaining the smooth communication path between the master and the slave.
本發明揭露的智慧電表的佈建管理系統,包括一電表群組與一主控裝置,電表群組包括一橋接電表與一從屬電表。主控裝置透過無線通訊連接從屬電表及橋接電表。當主控裝置判斷無法連接從屬電表與橋接電表之至少其一時,橋接電表啟動有線通訊與該主控裝置連接,且橋接電表則透過無線通訊供從屬電表連接。 The deployment management system of the smart meter disclosed in the present invention comprises a meter group and a master device, and the meter group comprises a bridge meter and a slave meter. The master device connects the slave meter and the bridge meter via wireless communication. When the master device determines that at least one of the slave meter and the bridge meter cannot be connected, the bridge meter initiates wired communication to connect with the master device, and the bridge meter is connected to the slave meter via wireless communication.
於另一實施態樣,本案所揭露的智慧電表的佈建管理系統,包括複數個從屬電表與一主控裝置。主控裝置透過無線通訊與各從屬電表連接。當主控裝置判斷從屬電表裡存在一問題電表,其無法透過無線通訊方式與主控裝置相互通訊時,主控裝置會先設定從屬電表之一為橋接電表,且令橋接電表改以有線通訊與主控裝置連接。橋接電表透過無線通訊供問題電表連接,透過橋接電表使問題電表與主控裝置連通。 In another embodiment, the smart meter deployment management system disclosed in the present disclosure includes a plurality of slave meters and a master device. The master device is connected to each slave meter via wireless communication. When the main control device determines that there is a problem meter in the slave meter, and the wireless device cannot communicate with the master device through the wireless communication mode, the master device first sets one of the slave meters to bridge the meter, and changes the bridge meter to wired communication and The main control unit is connected. The bridge meter is connected to the problem meter through wireless communication, and the problem meter is connected to the main control unit through the bridge meter.
本發明所揭露的紀錄媒體,儲存有電腦可讀取之程式碼,由一主控裝置、一橋接電表與一從屬電表讀取程式碼時執行一智慧電表的佈建管理方法,其包括以下步驟:由主控裝置與橋接電表及從屬電表進行無線連接;以及,當主控裝置判斷無法連接至從屬電表與橋接電表之至少其一時,令橋接電表改以有線通訊與主控裝置連接,橋接電表啟用無線通訊以供從屬電表連接。 The recording medium disclosed in the present invention stores a computer readable code, and a smart meter setting management method is executed when a master device, a bridge meter and a slave meter read the code, and the following steps are included. : the main control device wirelessly connects with the bridge meter and the slave meter; and when the master device determines that it cannot connect to at least one of the slave meter and the bridge meter, the bridge meter is connected to the master device by wired communication, and the bridge meter is connected Enable wireless communication for slave meter connections.
於另一實施態樣,本案所揭露的紀錄媒體,儲存有電腦可讀取之程式碼,由一主控裝置與複數個從屬電表讀取程式碼時執行一智慧電表的佈建管理方法,其包括以下步驟:由主控裝置與各從屬電表進行無線連接;以及,當主控裝置判斷從屬電表存在無法連接之一問題電表時,設定從屬電表之一為橋接電表,且令橋接電表改以有線通訊與主控裝置連接,並透過無線通訊供問題電表連接。 In another embodiment, the recording medium disclosed in the present invention stores a computer readable code, and a smart meter setting management method is executed when a master device and a plurality of slave meters read the code. The method includes the following steps: the main control device wirelessly connects with each slave meter; and when the master device determines that the slave meter has a problem meter that cannot be connected, set one of the slave meters to bridge the meter, and change the bridge meter to wired The communication is connected to the main control device and connected to the problem meter via wireless communication.
本發明所揭系統,其具有以下特點: The system disclosed in the present invention has the following characteristics:
(1)從屬電表除能透過無線通訊直接連接主控裝置外,橋接電表亦提供另一條間接性的通訊路徑,較能維持從屬電表與主控裝置之間的連繫,具較佳的應用性與便利性。 (1) In addition to being able to directly connect the main control device through wireless communication, the bridge meter also provides another indirect communication path, which can maintain the connection between the slave meter and the master device, and has better applicability. And convenience.
(2)當工作人員並未具有現場勘測(site survey)的能力或是對應工具時,系統可依據當時的佈建情形,自發性的調整較適用的通訊模式,亦能更進一步的提供無法連接之裝置的資訊,不但具較高的參考價值,亦能作為工作人員後續作業或是調整佈建方式之依據資料。 (2) When the staff does not have the capability of the site survey or the corresponding tools, the system can adjust the more suitable communication mode according to the current deployment situation, and can further provide the connection. The information of the device not only has a high reference value, but also serves as a basis for the follow-up work of the staff or the adjustment of the deployment method.
(3)透過橋接電表與異質通訊的佈建架構,從屬電表可直接或間接的與主控裝置通訊,較不受住宅型態、房屋結構、地形結構與環境因素的影響,各類裝置的設置點所受限制相對也較低,不但具較佳的適用性,也相對的提升整體系統的佈建彈性。 (3) Through the construction structure of bridged electricity meters and heterogeneous communication, the subordinate electricity meters can directly or indirectly communicate with the main control device, which is less affected by the residential type, house structure, terrain structure and environmental factors, and the setting of various devices. The restrictions on the points are relatively low, which not only has better applicability, but also enhances the flexibility of the overall system.
(4)系統可依據當時的佈建情形,自發性的調整較適用的通訊模式,除較能維持從屬電表與主控裝置之間的連繫外,相對較能降低工作人員對系統維護的工作量。 (4) The system can adjust the more suitable communication mode according to the current deployment situation. In addition to maintaining the connection between the subordinate meter and the main control device, the system can relatively reduce the staff's work on system maintenance. the amount.
(5)在一些實施例中,主控裝置並非是與全數的從屬電表有線連接,而是有線連接至橋接電表,橋接電表再與相鄰接或是同一電表群組的從屬電表無線連接,因此佈建實體線路的複雜度相對較低,同時也較能避免從屬電表集中安裝於主控裝置的電力迴路,導致主控裝置所連接電力迴路的負載不平衡的情形,進而保持通訊穩定性。 (5) In some embodiments, the master device is not wired to all of the slave meters, but is wired to the bridge meter, and the bridge meter is wirelessly connected to the adjacent meter or the slave meter of the same meter group. The complexity of the built-in physical circuit is relatively low, and it is also possible to avoid the situation that the slave electric meter is installed in the power circuit of the main control device, and the load of the power circuit connected to the main control device is unbalanced, thereby maintaining communication stability.
(6)橋接電表在未啟用橋接功能時,其功用等同於從屬電表,在啟用橋接功能時,即化作其它從屬電表的協調器(Coordinator)的角色,協助傳輸其它從屬電表的電力資料回主控裝置。不但兼助多通訊路徑的切換與選用,亦不需另行設置橋接裝置,因此得以降低線路配置的複雜度。而且橋接電表具有從屬電表的功能,故可在較低的硬體設備成本與軟體設計成本的前提,將現今的智慧電表系統,轉化為本案所揭露的系統。再者,橋接電表是將橋接組件內建其中,因此不需要另外預留空間供配置橋接器,因此沒有現場施工的問題,也不會令當地住戶的困擾與為何要更動電表迴路的疑慮。 (6) When the bridge meter is not enabled with the bridge function, its function is equivalent to the slave meter. When the bridge function is enabled, it becomes the role of the coordinator of other slave meters, and assists in transmitting the power data of other slave meters. Control device. It not only helps the switching and selection of multiple communication paths, but also eliminates the need to set up a bridge device separately, thus reducing the complexity of the line configuration. Moreover, the bridge meter has the function of the slave meter, so that the current smart meter system can be transformed into the system disclosed in the case on the premise of lower hardware equipment cost and software design cost. Furthermore, the bridge meter is built into the bridge assembly, so there is no need to reserve space for the bridge, so there is no problem of on-site construction, and it will not bother the local residents and why they have to worry about the meter circuit.
(7)橋接電表在未啟用橋接功能時,其功用等同於從屬電表,在啟用橋接功能時,即化作其它從屬電表的協調器,但是從屬電表的無線通訊功能仍被維持使用。就整體系統而言,可以相當高比例發揮系統原有的無線通訊效能,因此不會有組件或功能無用,造成系統硬件效益大幅下降的情形。 (7) When the bridge meter is not enabled for bridging, its function is equivalent to the slave meter. When the bridge function is enabled, it becomes the coordinator of other slave meters, but the wireless communication function of the slave meter is still maintained. As far as the overall system is concerned, the original wireless communication performance of the system can be exerted at a relatively high proportion, so that no component or function is useless, resulting in a significant drop in system hardware efficiency.
100‧‧‧後端伺服器 100‧‧‧Backend server
200‧‧‧主控裝置 200‧‧‧Master control unit
210‧‧‧主控運算單元 210‧‧‧Master computing unit
220‧‧‧主控有線連接單元 220‧‧‧Master wired connection unit
230‧‧‧主控無線連接單元 230‧‧‧Master wireless connection unit
300‧‧‧電表群組 300‧‧‧Electric meter group
310‧‧‧橋接電表 310‧‧‧Bridge meter
311‧‧‧第一控制單元 311‧‧‧First Control Unit
312‧‧‧第一有線連接單元 312‧‧‧First wired connection unit
313‧‧‧第一無線連接單元 313‧‧‧First wireless connection unit
320‧‧‧從屬電表 320‧‧‧Subordinate electricity meter
322‧‧‧從屬有線連接單元 322‧‧‧Subordinate wired connection unit
323‧‧‧從屬無線連接單元 323‧‧‧Subordinate wireless connection unit
330‧‧‧橋接備用電表 330‧‧‧Bridged standby meter
331‧‧‧第二控制單元 331‧‧‧Second Control Unit
332‧‧‧第二有線連接單元 332‧‧‧Second wired connection unit
333‧‧‧第二無線連接單元 333‧‧‧Second wireless connection unit
340,340a,340b‧‧‧問題電表 340, 340a, 340b‧‧‧ problem meter
340c,340d,340e‧‧‧問題電表 340c, 340d, 340e‧‧‧ problem meter
340f,340g,340h‧‧‧問題電表 340f, 340g, 340h‧‧‧ problem meter
350‧‧‧測試橋接電表 350‧‧‧Test bridge meter
S110~S125‧‧‧步驟 S110~S125‧‧‧Steps
S210~S230‧‧‧步驟 S210~S230‧‧‧Steps
S310~S327‧‧‧步驟 S310~S327‧‧‧Steps
圖1A繪示本發明實施例之智慧電表的佈建管理系統之第一種系統架構圖。 FIG. 1A is a first system architecture diagram of a deployment management system for a smart meter according to an embodiment of the present invention.
圖1B繪示本發明實施例之智慧電表的佈建管理系統之第一種硬體配置圖。 FIG. 1B is a first hardware configuration diagram of a deployment management system for a smart meter according to an embodiment of the present invention.
圖2A繪示本發明實施例之智慧電表的佈建管理系統之第二種系統架構圖。 2A is a second system architecture diagram of a deployment management system for a smart meter according to an embodiment of the present invention.
圖2B繪示本發明實施例之智慧電表的佈建管理系統之第二種硬體配置圖。 2B is a second hardware configuration diagram of a deployment management system for a smart meter according to an embodiment of the present invention.
圖3A繪示本發明實施例之智慧電表的佈建管理系統之第三種系統架構圖。 FIG. 3A is a third system architecture diagram of a deployment management system for a smart meter according to an embodiment of the present invention.
圖3B繪示本發明實施例之智慧電表的佈建管理系統之第三種硬體配置圖。 FIG. 3B is a third hardware configuration diagram of the deployment management system of the smart meter according to the embodiment of the present invention.
圖4繪示本發明實施例之智慧電表的佈建管理系統之第四種系統架構圖。 4 is a fourth system architecture diagram of a deployment management system for a smart meter according to an embodiment of the present invention.
圖5繪示本發明實施例之智慧電表的佈建管理系統之問題電表修正佈建圖。 FIG. 5 is a diagram showing the problem meter layout of the problem of the deployment management system of the smart meter according to the embodiment of the present invention.
圖6繪示本發明實施例之智慧電表的佈建管理系統之第五種系統架構圖。 6 is a fifth system architecture diagram of a deployment management system for a smart meter according to an embodiment of the present invention.
圖7繪示本發明實施例之智慧電表的佈建管理系統之現場佈建圖。 FIG. 7 is a diagram showing the site layout of the deployment management system of the smart meter according to the embodiment of the present invention.
圖8繪示本發明實施例之智慧電表的佈建管理系統之大場域佈建圖。 FIG. 8 is a diagram showing a large field area layout of a deployment management system for a smart meter according to an embodiment of the present invention.
圖9繪示本發明實施例之智慧電表的佈建管理方法之第一種流程圖。 FIG. 9 is a first flowchart of a method for managing the deployment of a smart meter according to an embodiment of the present invention.
圖10繪示本發明實施例之智慧電表的佈建管理方法之第二種流程圖。 FIG. 10 is a second flowchart of a method for constructing a smart meter according to an embodiment of the present invention.
圖11繪示本發明實施例之智慧電表的佈建管理方法之第三種流程圖。 FIG. 11 is a third flowchart of a method for managing the deployment of a smart meter according to an embodiment of the present invention.
圖12繪示本發明實施例之智慧電表的佈建管理方法之第四種流程圖。 FIG. 12 is a fourth flow chart of a method for constructing a smart meter according to an embodiment of the present invention.
圖13繪示本發明實施例之智慧電表的佈建管理方法之佈建修正流程圖。 FIG. 13 is a flow chart showing the modification of the deployment management method of the smart meter according to the embodiment of the present invention.
圖14繪示本發明實施例之智慧電表的佈建管理方法之第五種流程圖。 FIG. 14 is a fifth flowchart of a method for constructing a smart meter according to an embodiment of the present invention.
圖15繪示本發明實施例之智慧電表的佈建管理方法之第六種流程圖。 FIG. 15 is a sixth flowchart of a method for constructing a smart meter according to an embodiment of the present invention.
圖16繪示本發明實施例之智慧電表的佈建管理方法之第七種流程圖。 FIG. 16 is a seventh flowchart of a method for constructing a smart meter according to an embodiment of the present invention.
圖17繪示本發明實施例之智慧電表的佈建管理方法之第八種流程圖。 FIG. 17 is a flowchart of an eighth embodiment of a method for managing the deployment of a smart meter according to an embodiment of the present invention.
茲配合圖式將本發明實施例詳細說明如下。 The embodiments of the present invention are described in detail below with reference to the drawings.
請參閱圖1A繪示本發明實施例之智慧電表的佈建管理系統之第一種系統架構圖,及圖1B繪示本發明實施例之智慧電表的佈建管理系統之第一種硬體配置圖。此系統的架構為:「後端伺服器100-主控裝置200-電表群組300」。主控裝置200即如前述的集中器,此處是為方便示例說明,暫採用「主控裝置(Master Device)」元件名稱。如先前所述,後端伺服器100與主控裝置200之間是採用廣域網路(WAN),或是廣域網路(WAN)與電力線通訊技術組成的複合式異質網路,來進行通訊連接;主控裝置200與電表群組300則是採用區域網路(LAN)進行通訊連接。 1A is a first system architecture diagram of a deployment management system for a smart meter according to an embodiment of the present invention, and FIG. 1B illustrates a first hardware configuration of a deployment management system for a smart meter according to an embodiment of the present invention. Figure. The architecture of this system is: "Backend Server 100 - Master Device 200 - Meter Group 300". The main control device 200 is the concentrator as described above. Here, for convenience of description, the "Master Device" component name is temporarily used. As described above, the back end server 100 and the main control device 200 are connected by a wide area network (WAN) or a wide heterogeneous network (WAN) and power line communication technology for communication connection; The control device 200 and the meter group 300 are connected by a local area network (LAN).
主控裝置200包括一主控運算單元210、一主控有線連接單元220與一主控無線連接單元230。主控運算單元210可為嵌入式系統(Embedded System)、處理器(Processor,如中央處理器、微處理器)、運算晶片(Calculator Chip)、積體電路(integrated circuit,IC)、韌體(Firmware)…等硬體、軟體、或軟體與硬體之組合中的任一種實施模式。 The main control device 200 includes a main control computing unit 210, a main control wired connection unit 220 and a main control wireless connection unit 230. The main control unit 210 can be an embedded system, a processor (such as a central processing unit, a microprocessor), a computing chip (Calculator Chip), an integrated circuit (IC), and a firmware ( Firmware, etc. Any of a combination of hardware, software, or a combination of software and hardware.
主控有線連接單元220為可傳輸資料的網路介面,或是運用電力線載波技術的電力線網路介面,或是相類似資料傳輸介面。此處暫以電力波網路介面作說明,並以寬頻電力線通訊為例。 The master wired connection unit 220 is a network interface for transmitting data, or a power line network interface using power line carrier technology, or a similar data transmission interface. Here is a description of the power wave network interface, and broadband power line communication as an example.
主控無線連接單元230用以進行無線通訊連接,如前述的近場通訊、藍芽、Wi-Fi、射頻…等。此處暫以射頻(RF)通訊為例。 The master wireless connection unit 230 is configured to perform a wireless communication connection, such as the aforementioned near field communication, Bluetooth, Wi-Fi, radio frequency, and the like. Take radio frequency (RF) communication as an example here.
電表群組300包括一橋接電表(First Bridge Meter)310與一從屬電表(Slave Meter)320。 The meter group 300 includes a first bridge meter 310 and a slave meter 320.
橋接電表310包括一第一控制單元311、一第一有線連接單元312與一第一無線連接單元313。第一控制單元311除用以取得電力資料外,亦用以控制第一有線連接單元312與一第一無線連接單元313的運作與資料傳輸方式。第一有線連接單元312是與主控有線連接單元220為實體線路連接,因此需為相同或是相容的硬體規格,此處以寬頻電力線通訊為例。第一無線連接單元313是具與主控無線連接單元230無線相互連接的能力,故亦需具相同或是相容的硬體規格,此處以射頻通訊為例。 The bridge meter 310 includes a first control unit 311, a first wired connection unit 312, and a first wireless connection unit 313. The first control unit 311 is used to control the operation and data transmission mode of the first wired connection unit 312 and the first wireless connection unit 313 in addition to the power data. The first wired connection unit 312 is connected to the main wired connection unit 220 as a physical line, and therefore needs to be the same or compatible hardware specifications. Here, broadband power line communication is taken as an example. The first wireless connection unit 313 has the capability of wirelessly interconnecting with the master wireless connection unit 230. Therefore, the same or compatible hardware specifications are required. Here, radio frequency communication is taken as an example.
從屬電表320具有從屬無線連接單元323,其是與第一無線 連接單元313及主控無線連接單元230為相同或是相容的硬體規格,此處同樣以射頻通訊為例。 The slave meter 320 has a slave wireless connection unit 323 that is associated with the first wireless The connection unit 313 and the master wireless connection unit 230 are the same or compatible hardware specifications, and RF communication is also taken as an example here.
主控裝置200、橋接電表310與從屬電表是320位於彼此之間的無線通訊範圍。系統啟動時,主控裝置200、橋接電表310與從屬電表320會進行相互之間的連線作業。從屬電表320啟用從屬無線連接單元323進行無線訊號的發送,以尋找可連線且可協助登入網路的協調器。第一控制單元311亦是啟用第一無線連接單元313進行無線訊號的發送,以尋找可連線且可協助登入網路的協調器。主控運算單元210則啟用主控無線連接單元230。主控裝置200是作為連接後端伺服器100與電表群組300的中心連接點設備。 The master device 200, the bridge meter 310, and the slave meter are 320 wireless communication ranges between each other. When the system is started, the master device 200, the bridge meter 310, and the slave meter 320 perform a connection operation with each other. The slave meter 320 enables the slave wireless connection unit 323 to transmit wireless signals to find a coordinator that is connectable and can assist in logging into the network. The first control unit 311 also enables the first wireless connection unit 313 to transmit wireless signals to find a coordinator that can be connected and can assist in logging into the network. The master computing unit 210 then enables the master wireless connection unit 230. The master device 200 is a central point of attachment device that connects the backend server 100 to the meter group 300.
在一些實施例中,主控裝置200會與橋接電表310與從屬電表320建立無線連接,並取得橋接電表310與從屬電表320提供的電力資訊。無線連接的成功與否,在於橋接電表310與從屬電表320是否能在預設的時間內,透過主控裝置200完成網路登入作業。更進一步者,可將資料傳輸錯誤的次數、訊號干擾程度、訊號無回應次數等因素考量其中。其中,主控裝置200若能與橋接電表310無線連接,橋接電表310與從屬電表320的作用並沒有差別。 In some embodiments, the master device 200 establishes a wireless connection with the bridge meter 310 and the slave meter 320, and obtains the power information provided by the bridge meter 310 and the slave meter 320. The success of the wireless connection is whether the bridge meter 310 and the slave meter 320 can complete the network login operation through the master device 200 within a preset time. Further, factors such as the number of data transmission errors, the degree of signal interference, and the number of times the signal is not responded can be considered. Wherein, if the master device 200 can be wirelessly connected to the bridge meter 310, there is no difference between the function of the bridge meter 310 and the slave meter 320.
主控裝置200內儲有橋接電表310與從屬電表320的裝置資訊,而橋接電表310與從屬電表320是相互鄰近配置。當主控運算單元210判斷出無法與從屬電表320與橋接電表310之至少其一建立連線時,會啟用主控有線連接單元220,改以有線連接方式連接橋接電表310,並命令橋接電表310啟用橋接功能。第一控制單元311在取得主控裝置200的命令時,會啟用第一有線連接單元312的相關功能。第一有線連接單元312會與主控有線連接單元220形成有線連接,使得主控裝置200與橋接電表310之間形成有線通訊,以此例而言,即是寬頻電力線載波通訊。另一方面,第一控制單元311會調整第一無線連接單元313的運作方式,切斷與主控裝置200的無線連接,且形成如無線存取點(Wireless Access Point)或集中器的運作方式,以供從屬電表320連接。從屬無線連接單元323在尋找到橋接電表310時,即會與橋接電表310進行無線連接。橋接電表310即成為主控裝置 200與從屬電表320之間的橋接器,以建立主控裝置200與從屬電表320之間的間接通訊路徑。 The main control device 200 stores device information of the bridge meter 310 and the slave meter 320, and the bridge meter 310 and the slave meter 320 are disposed adjacent to each other. When the main control unit 210 determines that the connection between the slave meter 320 and the bridge meter 310 cannot be established, the master wired connection unit 220 is enabled, the bridge meter 310 is connected in a wired manner, and the bridge meter 310 is commanded. Enable bridging. When the first control unit 311 obtains the command of the master device 200, the related function of the first wired connection unit 312 is enabled. The first wired connection unit 312 forms a wired connection with the master wired connection unit 220, so that wired communication is formed between the master device 200 and the bridge meter 310, which is, for example, broadband power line carrier communication. On the other hand, the first control unit 311 adjusts the operation mode of the first wireless connection unit 313, cuts off the wireless connection with the main control device 200, and forms a mode of operation such as a wireless access point or a concentrator. For the slave meter 320 to connect. When the slave wireless connection unit 323 finds the bridged power meter 310, it will wirelessly connect with the bridge meter 310. The bridge meter 310 becomes the master device A bridge between the slave 200 and the slave meter 320 establishes an indirect communication path between the master device 200 and the slave meter 320.
在一些實施例中,橋接電表310可進行主動判斷連線狀態,即當第一控制單元310判斷出無法與主控裝置200無線連線時,亦會直接啟用前述的橋接功能,以藉由有線方式連線主控裝置200。 In some embodiments, the bridge meter 310 can actively determine the connection state, that is, when the first control unit 310 determines that the master device 200 cannot be wirelessly connected, the bridge function is directly enabled to be wired. The main control device 200 is connected in a manner.
此外,續請參閱圖1B,電表群組300之間的橋接電表310亦得利用有線通訊或無線通訊進行連接。換言之,主控裝置200可以經過一個以上的橋接電表310而與從屬電表320建立通訊路徑。 In addition, referring to FIG. 1B, the bridge meter 310 between the meter groups 300 may also be connected by wired communication or wireless communication. In other words, the master device 200 can establish a communication path with the slave meter 320 via more than one bridge meter 310.
續請參閱圖2A繪示本發明實施例之智慧電表的佈建管理系統之第二種系統架構圖,及圖2B繪示本發明實施例之智慧電表的佈建管理系統之第二種硬體配置圖。前述的電表群組300更包括一橋接備用電表330,其包括一第二控制單元331、一第二有線連接單元332與一第二無線連接單元333,元件功能與運作方式等同於橋接電表310。 2A is a second system architecture diagram of a deployment management system for a smart meter according to an embodiment of the present invention, and FIG. 2B is a second hardware diagram of a deployment management system for a smart meter according to an embodiment of the present invention. Configuration diagram. The foregoing meter group 300 further includes a bridge standby meter 330, which includes a second control unit 331, a second wired connection unit 332 and a second wireless connection unit 333. The component functions and operates in the same manner as the bridge meter 310.
當主控裝置200判斷出無法與橋接電表310及從屬電表320建立連線時,會命令橋接備用電表330啟用橋接功能。第二控制單元331在取得主控裝置200的命令時,會啟用第二有線連接單元332。第二有線連接單元332會與主控有線連接單元220形成有線連接,使得主控裝置200與橋接備用電表330之間形成有線通訊。另一方面,第二控制單元331會調整第二無線連接單元333的運作方式,切斷與主控裝置200的無線連接,且形成如無線存取點或集中器的運作方式,以供橋接電表310與從屬電表320連接。第一無線連接單元313與從屬無線連接單元323在尋找到橋接備用電表330時,即會與橋接備用電表330進行無線連接。橋接備用電表330即成為主控裝置200與其它電表之間的橋接器。 When the master device 200 determines that the connection between the bridge meter 310 and the slave meter 320 cannot be established, the bridged standby meter 330 is commanded to enable the bridge function. The second control unit 331 activates the second wired connection unit 332 when acquiring the command of the master device 200. The second wired connection unit 332 forms a wired connection with the master wired connection unit 220 such that wired communication is formed between the master device 200 and the bridged standby meter 330. On the other hand, the second control unit 331 adjusts the operation mode of the second wireless connection unit 333, cuts off the wireless connection with the main control device 200, and forms a mode of operation such as a wireless access point or a concentrator for bridging the electric meter. 310 is connected to the slave meter 320. When the first wireless connection unit 313 and the slave wireless connection unit 323 find the bridged standby power meter 330, they are wirelessly connected to the bridged standby power meter 330. The bridged standby meter 330 becomes a bridge between the master device 200 and other meters.
續請參閱圖3A繪示本發明實施例之智慧電表的佈建管理系統之第三種系統架構示意圖,與圖3B繪示本發明實施例之智慧電表的佈建管理系統之第三種硬體配置圖。從屬電表320更包括一從屬有線連接單元322,其規格是與主控有線連接單元220對應,並形成實體線路的連接。在一些實施例中,從屬有線連接單元322與主控有線連接單元220的規格符合電力線載波通訊,如寬頻電力線載波通訊或窄頻電力線載波通訊,然常見 者為窄頻電力線載波通訊。因此,結合前述等實施例,主控裝置200與從屬電表320之間至少包括下列數種互動形式: 3A is a third system architecture diagram of the deployment management system of the smart meter according to the embodiment of the present invention, and FIG. 3B is a third hardware diagram of the deployment management system of the smart meter according to the embodiment of the present invention. Configuration diagram. The slave meter 320 further includes a slave wired connection unit 322 having a specification corresponding to the master wired connection unit 220 and forming a connection of the physical line. In some embodiments, the specifications of the slave wired connection unit 322 and the master wired connection unit 220 conform to power line carrier communication, such as broadband power line carrier communication or narrow frequency power line carrier communication, but common It is a narrow-band power line carrier communication. Therefore, in combination with the foregoing embodiments, the master device 200 and the slave meter 320 include at least the following forms of interaction:
(1)當主控裝置200可透過無線連接至從屬電表320時,就直接以無線連接進行通信。 (1) When the master device 200 can wirelessly connect to the slave meter 320, it communicates directly with the wireless connection.
(2)當主控裝置200判斷無法無線連接從屬電表320時,改以主控有線連接單元220與從屬有線連接單元322形成有線通訊。 (2) When the master device 200 determines that the slave meter 320 cannot be wirelessly connected, the master wired connection unit 220 and the slave wired connection unit 322 form wired communication.
(3)當主控裝置200判斷透過橋接電表310仍無法連通從屬電表320時,改用主控有線連接單元220與從屬有線連接單元322形成有線通訊。 (3) When the master device 200 determines that the slave meter 320 is still unable to communicate with the slave meter 320, the master wired connection unit 220 is used to form wired communication with the slave wired connection unit 322.
(4)當從屬電表320持續判斷無法找到任何裝置可以進行無線通訊時,啟用從屬有線連接單元322以與主控有線連接單元220形成有線通訊。 (4) When the slave meter 320 continues to judge that no device can be found for wireless communication, the slave wired connection unit 322 is enabled to form wired communication with the master wired connection unit 220.
(5)從屬電表320透過從屬無線連接單元323在同一工作時間找到主控裝置200與橋接電表310時,會判斷與橋接電表310的連線品質,及與主控裝置200的連線品質,兩者何為優劣。當從屬電表320判斷與橋接電表310的連線品質高於與主控裝置200的連線品質時,連接橋接電表310。 (5) When the slave meter 320 finds the master device 200 and the bridge meter 310 at the same working time through the slave wireless connection unit 323, it determines the connection quality with the bridge meter 310 and the connection quality with the master device 200, What are the advantages and disadvantages. When the slave meter 320 determines that the connection quality with the bridge meter 310 is higher than the connection quality with the master device 200, the bridge meter 310 is connected.
(6)相對於第(5)點,當從屬電表320判斷與橋接電表310的連線品質低於與主控裝置200的連線品質時,連接主控裝置200。 (6) With respect to the point (5), when the slave meter 320 determines that the connection quality with the bridge meter 310 is lower than the connection quality with the master device 200, the master device 200 is connected.
(7)主控裝置200預設就是以有線連接至從屬電表320,進行有線通訊。如落單的從屬電表320即可以此方式佈建。 (7) The main control device 200 presets to connect to the slave electric meter 320 by wire to perform wired communication. The slave meter 320, such as a single order, can be deployed in this manner.
(8)當主控裝置200判斷無法無線連接橋接電表310時,改以有線連接橋接電表310,橋接電表310則供其它的從屬電表320進行無線連接,形成主控裝置200與從屬電表320的間接通訊。 (8) When the main control device 200 determines that the bridge meter 310 cannot be wirelessly connected, the bridge is connected to the meter 310, and the bridge meter 310 is connected to the other slave meters 320 to form an indirect connection between the master device 200 and the slave meter 320. communication.
(9)當橋接電表310判斷無法無線連接主控裝置200時,改以有線連接主控裝置200,橋接電表310則供其它的從屬電表200進行無線連接,形成主控裝置200與從屬電表320的間接通訊。 (9) When the bridge meter 310 determines that the master device 200 cannot be wirelessly connected, the master device 200 is wired, and the bridge meter 310 is wirelessly connected to the other slave meters 200 to form the master device 200 and the slave meter 320. Indirect communication.
在一些實施例中,圖1A至圖3B所揭系統中,主控裝置200記載有電表群組的硬體資訊。當主控裝置200有線連接橋接電表310,仍未 能與從屬電表320通信時,主控運算單元210會標示從屬電表320的硬體資訊(後述的問題電表)。主控裝置200可將標記過的從屬電表320的硬體資訊傳輸至後端伺服器100,作為佈建人員調整佈建方式的參考資訊。相類似的,當主控裝置200無法與橋接電表310通信時,主控運算單元210會標示橋接電表310的硬體資訊(後述的問題電表)。主控裝置200可將標記過的橋接電表310的硬體資訊傳輸至後端伺服器100,作為佈建人員調整佈建方式的參考資訊。 In some embodiments, in the system disclosed in FIG. 1A to FIG. 3B, the main control device 200 records the hardware information of the electric meter group. When the main control device 200 is wired to connect the bridge 310, it is still not When communicating with the slave meter 320, the master computing unit 210 will indicate the hardware information of the slave meter 320 (a problem meter to be described later). The main control device 200 can transmit the hardware information of the marked slave electric meter 320 to the backend server 100 as reference information for the deployment personnel to adjust the deployment mode. Similarly, when the master device 200 is unable to communicate with the bridge meter 310, the master computing unit 210 will indicate the hardware information of the bridge meter 310 (a problem meter to be described later). The main control device 200 can transmit the hardware information of the marked bridged electrical meter 310 to the backend server 100 as reference information for the deployment personnel to adjust the deployment mode.
續請參閱圖4繪示本發明實施例之智慧電表的佈建管理系統之第四種系統架構示意圖。此電表群組300包括複數個從屬電表320,此等從屬電表320中包括多個如先前所述的問題電表340。每一個問題電表340可被置換為測試橋接電表350(功能如前述的橋接電表310,此處為說明而採用不同元件名稱),更換方式亦不受限,可為從屬電表320皆屬於橋接電表310的電表類型,或是由佈建人員逐一置換而進行測試。主控裝置200依據每一處測試橋接電表350與鄰接、或同一電表群組300中的問題電表340的連線情形,各別的產生一連線狀態資訊,並將所有連線狀態資訊提供予後端伺服器100。後端伺服器100即會依據此等連線狀態資訊,計算出何處的問題電表340需被取代為橋接電表310,藉此產生一個以上的佈建修正方案以供佈建人員參考,或是由後端伺服器依據預定設計而選擇適當的方案。然而,佈建修正方案的條件包括:(1)在置換橋接電表310後,所有問題電表340皆能直接或間接的與主控裝置200進行通訊;(2)各問題電表340能穩定的進行資料傳輸,至少在預設的時間內,能透過主控裝置200完成網路登入作業;(3)橋接電表310的取代數量為最少者;(4)當橋接電表310的取代數量為相同時,選擇資料傳輸效能最佳的方案。 Continuing to refer to FIG. 4 is a schematic diagram of a fourth system architecture of a deployment management system for a smart meter according to an embodiment of the present invention. The meter group 300 includes a plurality of slave meters 320, and the slave meters 320 include a plurality of problem meters 340 as previously described. Each of the problem meters 340 can be replaced with a test bridge meter 350 (functioning as described above for the bridge meter 310, here using different component names), and the replacement method is also not limited, and the slave meter 320 can belong to the bridge meter 310. The type of meter is either tested by the fabric personnel one by one. The main control device 200 separately generates a connection status information according to the connection condition of the bridged electric meter 350 and the adjacent problem meter 340 in the same electric meter group 300, and provides all the connection status information to the rear. End server 100. Based on the connection status information, the backend server 100 calculates where the problem meter 340 needs to be replaced with the bridge meter 310, thereby generating more than one deployment modification scheme for the reference personnel, or The appropriate solution is selected by the backend server in accordance with the predetermined design. However, the conditions for the installation modification scheme include: (1) after the replacement bridge meter 310, all the problem meters 340 can directly or indirectly communicate with the main control device 200; (2) each problem meter 340 can stably perform data Transmission, at least for a preset time, can complete the network login operation through the master device 200; (3) the number of replacements of the bridge meter 310 is the least; (4) when the number of replacements of the bridge meter 310 is the same, The best solution for data transmission.
請同時參閱圖5繪示的問題電表修正佈建示意圖。其中,此電表群組具有8個問題電表(340a,340b,340c,340d,340e,340f,340g,340h)。每一個問題電表(340a,340b,340c,340d,340e,340f,340g,340h)會被逐步置換為測試橋接電表350,一次置換一個或多個。主控裝置200會將測試橋接電表350與其它問題電表的連線情形,回傳至後端伺服器100,供後端伺服器100產生多個佈建修正方案。而方案建構時,會以橋接電表310可涵蓋最 多問題電表者為首選,例如:問題電表340b、問題電表340f。然而,當某一問題電表皆無法與其它替換點的測試橋接電表350所連接時,如問題電表340d,則單獨將問題電表340d作為必定替代為橋接電表310的選擇之一。 Please also refer to Figure 5 for a schematic diagram of the problem meter layout. Among them, this meter group has 8 problem meters (340a, 340b, 340c, 340d, 340e, 340f, 340g, 340h). Each problem meter (340a, 340b, 340c, 340d, 340e, 340f, 340g, 340h) is gradually replaced with a test bridge meter 350, one or more at a time. The master device 200 transmits the connection condition of the test bridge meter 350 to the other problem meter to the backend server 100 for the backend server 100 to generate a plurality of deployment correction schemes. When the scheme is constructed, the bridge meter 310 can cover the most The multi-issue meter is preferred, for example, the problem meter 340b and the problem meter 340f. However, when a problem meter cannot be connected to the test bridge meter 350 of other replacement points, such as the problem meter 340d, the problem meter 340d is separately replaced as one of the choices of the bridge meter 310.
然而,在一些實施例中,佈建人員亦可以將同一電表群組300中,沒有問題的從屬電表320作為替代選擇,並不受限於圖4與圖5所示之技術施行方式。 However, in some embodiments, the deployer can also use the slave meter 320 in the same meter group 300 as an alternative, and is not limited to the technical implementation shown in FIGS. 4 and 5.
圖6繪示本發明實施例之智慧電表的佈建管理系統之第五種系統架構示意圖。與圖1所示不同在於電表群組300包括複數個從屬電表320,從屬電表320的功能皆等同或相近於前述的橋接電表310,於此為方便說明,故仍以從屬電表320作為元件名稱進行說明。此例中,每一從屬電表320包括從屬無線連接單元323與一從屬有線連接單元322。 6 is a schematic diagram showing a fifth system architecture of a deployment management system for a smart meter according to an embodiment of the present invention. The difference between that shown in FIG. 1 is that the meter group 300 includes a plurality of slave meters 320. The functions of the slave meters 320 are identical or similar to those of the bridge meter 310. For convenience of explanation, the slave meter 320 is still used as the component name. Description. In this example, each slave meter 320 includes a slave wireless connection unit 323 and a slave wired connection unit 322.
其中,系統運行時,主控裝置200與從屬電表320之間,是先以主控無線連接單元230與從屬無線連接單元323進行無線通訊。當主控裝置200判斷從屬電表320中存在一問題電表340,即無法進行與問題電表340無線通訊時,啟用主控有線連接單元220,並擇一從屬電表320(亦可以是上述的問題電表340),其與從屬有線連接單元322進行實體線路的連接,被選擇的從屬電表320即作為前述實施例的橋接電表310。其中,主控裝置200與從屬電表320之間是透過窄頻電力線通訊方式或寬頻電力線通訊方式進行有線通訊。然而,除由主控裝置200指定有線連接的從屬電表320外,亦可以是從屬電表320中被預設橋接功能之一者,一旦被預設功能的從屬電表320判斷無法連接主控裝置200時,即改以有線方式連接主控裝置200,並作為其它從屬電表320的橋接裝置。 When the system is running, between the master device 200 and the slave meter 320, the master wireless connection unit 230 and the slave wireless connection unit 323 perform wireless communication first. When the main control device 200 determines that there is a problem meter 340 in the slave meter 320, that is, wireless communication with the problem meter 340 is not possible, the master wired connection unit 220 is enabled, and the slave meter 320 is selected (may also be the problem meter 340 described above). It is connected to the physical line by the slave wired connection unit 322, and the selected slave meter 320 is the bridge meter 310 of the foregoing embodiment. The main control device 200 and the slave electric meter 320 communicate with each other through a narrow-band power line communication method or a broadband power line communication method. However, in addition to the slave meter 320 that is wired by the master device 200, it may also be one of the preset bridge functions in the slave meter 320. Once the slave meter 320 of the preset function determines that the master device 200 cannot be connected, That is, the master device 200 is connected in a wired manner and serves as a bridge device for the other slave meters 320.
在一些實施例中,主控裝置200判斷無法與問題電表340連接時,會有至少下列幾種運作方式: In some embodiments, when the master device 200 determines that it cannot connect to the problem meter 340, there are at least the following modes of operation:
(1)當主控裝置200判斷無法透過無線通訊與問題電表340連接時,先試著從其它從屬電表320擇一設定為橋接電表310,且令橋接電表310改以有線通訊與主控裝置200連接。橋接電表310透過無線通訊供問題電表340連接。 (1) When the main control device 200 determines that the problem cannot be connected to the problem meter 340 through the wireless communication, first try to set the bridge meter 310 from the other slave meters 320, and change the bridge meter 310 to the wired communication and the master device 200. connection. The bridge meter 310 is connected to the problem meter 340 via wireless communication.
(2)當主控裝置200判斷無法透過無線通訊與問題電表340 連接時,會先以有線通訊與問題電表340連接。在一些實施例中,主控裝置200設定問題電表340為橋接電表310,且令橋接電表310透過無線通訊供各從屬電表320連接。 (2) When the master device 200 determines that the wireless communication and the problem meter 340 cannot be transmitted When connected, it will be connected to the problem meter 340 by wired communication. In some embodiments, the master device 200 sets the problem meter 340 to bridge the meter 310 and causes the bridge meter 310 to be connected to the slave meters 320 via wireless communication.
(3)當主控裝置200判斷無法透過有線通訊與問題電表340連接時,再從其它從屬電表320擇一設定為橋接電表310,且令橋接電表310改以有線通訊與主控裝置200連接,並透過無線通訊供問題電表340連接。與先前差異在於,啟用橋接模式的時間點。 (3) When the main control device 200 determines that the problem cannot be connected to the problem meter 340 through the wired communication, the other slave meter 320 is alternatively set to the bridge meter 310, and the bridge meter 310 is connected to the master device 200 by wired communication. The problem meter 340 is connected via wireless communication. The difference from the previous one is when the bridge mode is enabled.
(4)當主控裝置200設定各從屬電表320為橋接電表310,皆無法連通問題電表340時,主控裝置200再改以有線通訊與問題電表340連接。 (4) When the master device 200 sets each of the slave meters 320 to be the bridge meter 310 and cannot connect to the problem meter 340, the master device 200 is further connected to the problem meter 340 by wired communication.
然而,各從屬電表320判斷可同時連接至主控裝置200與橋接電表310時,會先判斷兩通訊路徑的品質。當從屬電表320判斷與橋接電表310的連線品質高於與主控裝置200的連線品質時,即連接橋接電表310。相反的,當從屬電表320判斷與橋接電表310的連線品質低於與主控裝置200的連線品質時,即連接主控裝置200。此適用於上述圖1至圖6的從屬電表320。 However, when the slave meters 320 determine that they can be simultaneously connected to the master device 200 and the bridge meter 310, the quality of the two communication paths is first determined. When the slave meter 320 determines that the quality of the connection with the bridge meter 310 is higher than the quality of the connection with the master device 200, the bridge meter 310 is connected. Conversely, when the slave meter 320 determines that the quality of the connection with the bridge meter 310 is lower than the quality of the connection with the master device 200, the master device 200 is connected. This applies to the slave meter 320 of FIGS. 1 through 6 described above.
相近似的,當電表群組300具有多個問題電表340時,可依據圖4與圖5所示來產生佈建修正方案,在此即不贅述。 Similarly, when the meter group 300 has a plurality of problem meters 340, the layout modification scheme can be generated according to FIG. 4 and FIG. 5, which will not be described herein.
此外,前述的橋接電表310與從屬電表320的類型並沒有設限,可採用單相、三相、高壓、低壓…等相同、相類似或是相異電表類型之組合。 In addition, the foregoing type of the bridge meter 310 and the slave meter 320 are not limited, and a combination of the same, similar or different meter types of single phase, three phase, high voltage, low voltage, etc. may be employed.
請參閱圖7繪示本發明實施例之智慧電表的佈建管理系統之現場佈建示意圖。請同時配合圖1至圖6以利於了解。現場佈建分為兩種,一為具現場勘測,一為不具現場勘測。 Please refer to FIG. 7 , which is a schematic diagram of the site layout of the deployment management system of the smart meter according to the embodiment of the present invention. Please also cooperate with Figure 1 to Figure 6 to facilitate understanding. There are two types of on-site deployment, one for site survey and one for site survey.
當具現場勘測時,佈建人員即使用與環境對應的勘測工具進行現場勘測,例如:判斷第4、5、6區域的從屬電表320使用有線通訊較為適當,即採用窄頻電力線通訊(以實線表示)。第1、2、3區域的從屬電表320不適合採用無線通訊連接,即將各區域的從屬電表320逐步更替,選擇出適當的橋接電表310更替方案。如圖7繪示,第3區域需獨立配置一橋接 電表310,第1、2區域僅需在第2區域中配置一橋接電表310,以供第1、2區域的其它從屬電表320無線連接(以虛線表示)。 When a site survey is carried out, the deployer uses the survey tool corresponding to the environment for site survey. For example, it is more appropriate to determine that the slave meter 320 in the 4th, 5th, and 6th regions uses wired communication, that is, using narrow-band power line communication. Line representation). The slave meters 320 of the first, second, and third regions are not suitable for wireless communication, that is, the slave meters 320 of the respective regions are gradually replaced, and an appropriate bridge meter 310 replacement scheme is selected. As shown in FIG. 7, the third area needs to be independently configured with a bridge. In the electric meter 310, the first and second regions only need to arrange a bridge meter 310 in the second region for wireless connection (indicated by a broken line) of the other slave meters 320 of the first and second regions.
另一方面,當不具現場勘測時,佈建人員可依據圖1或圖6所示系統架構,依據自身的經驗進行佈建。系統在啟用時,會自發性的,在盡可能達到最多路徑連通的方式,建構出適當的通訊路徑,並將完全無法連接的電表標記而出。佈建人員僅需針對問題電表建立解決方案。 On the other hand, when there is no site survey, the deployers can build according to their own experience according to the system architecture shown in Figure 1 or Figure 6. When the system is enabled, it will spontaneously construct the appropriate communication path in the way that the maximum path is connected as much as possible, and mark the meter that cannot be connected at all. The construction personnel only need to establish a solution for the problem meter.
請參閱圖8繪示本發明實施例之智慧電表的佈建管理系統之大場域佈建示意圖。請同時參閱圖1至圖6以利於了解。 Please refer to FIG. 8 , which is a schematic diagram of a large field deployment of a deployment management system for a smart meter according to an embodiment of the present invention. Please also refer to Figure 1 to Figure 6 for easy understanding.
如圖8繪示,每一個區域所具有一個電表群組300,各電表群組300具有相同或不同數量的電表,但皆具有一個橋接電表310對應各電表群組的首位編號,其它編號代表從屬電表320。如先前所述,當主控裝置200判斷無法與某一電表群組300的從屬電表320連接時,會命令同一電表群組300的橋接電表310啟用橋接模式,使得主控裝置200與從屬電表320之間可以透過一個或多個橋接電表310進行間接通訊。然而,當仍無法通訊時,依據線路設計,主控裝置200可令橋接備用電表啟用橋接模式,或是直接有線連接至從屬電表320。然而,上述通訊方式皆無法使用時,佈建人員才需至現場進行檢測、維修。此外,橋接電表310亦可以是對應群組中的任意編號,並不設限。再者,若是配合圖6,電表群組300亦可為具橋接功能的從屬電表320所組成,主控裝置200只需在必要時,指定其中一者啟用橋接功能,以作為橋接電表310及橋接備用電表之用。 As shown in FIG. 8 , each area has an electric meter group 300. Each electric meter group 300 has the same or different number of electric meters, but each has a bridge electric meter 310 corresponding to the first digit of each electric meter group, and other numbers represent subordinates. Electric meter 320. As previously described, when the master device 200 determines that it is unable to connect to the slave meter 320 of a certain meter group 300, the bridge meter 310 of the same meter group 300 is commanded to enable the bridge mode, such that the master device 200 and the slave meter 320 Indirect communication can occur between one or more bridged meters 310. However, when communication is still not possible, depending on the line design, the master device 200 can enable the bridged standby meter to enable the bridge mode or directly connect to the slave meter 320. However, when the above communication methods are not available, the construction personnel need to go to the site for testing and maintenance. In addition, the bridge meter 310 can also be any number in the corresponding group, and is not limited. Furthermore, if it is combined with FIG. 6, the meter group 300 can also be composed of a slave meter 320 having a bridge function. The master device 200 only needs to specify one of the bridge functions to be used as the bridge meter 310 and bridge when necessary. Used for backup meters.
請參閱圖9繪示本發明實施例之智慧電表的佈建管理方法之第一種流程圖。請同時參閱圖1以利於了解。此方法包括:由主控裝置200與橋接電表310及從屬電表320進行無線連接(步驟S110)。 Please refer to FIG. 9 , which is a first flowchart of a method for managing the deployment of a smart meter according to an embodiment of the present invention. Please also refer to Figure 1 for your understanding. The method includes: wirelessly connecting the master meter 200 to the bridge meter 310 and the slave meter 320 (step S110).
主控裝置200會先判斷是否能連接從屬電表320(步驟S120)。當主控裝置200判斷可連接至從屬電表320,即進行無線通訊(步驟S121)。而當主控裝置200判斷無法連接至橋接電表310與從屬電表320中任一者時,令橋接電表310改以有線通訊與主控裝置200連接,橋接電表310啟用無線通訊以供從屬電表320連接(步驟S122)。 The main control device 200 first determines whether the slave electric meter 320 can be connected (step S120). When the master device 200 determines that it is connectable to the slave meter 320, wireless communication is performed (step S121). When the master device 200 determines that it is unable to connect to any of the bridge meter 310 and the slave meter 320, the bridge meter 310 is connected to the master device 200 by wired communication, and the bridge meter 310 enables wireless communication for the slave meter 320 to connect. (Step S122).
相類似的,步驟S120亦能適用為主控裝置200僅判斷橋接電表310是否能無線連接。或者,步驟S120亦能適用為主控裝置200僅判斷從屬電表320是否能無線連接。 Similarly, step S120 can also be applied to the master device 200 to determine only whether the bridge meter 310 can be wirelessly connected. Alternatively, step S120 can also be applied to the master device 200 to determine only whether the slave meter 320 can be wirelessly connected.
此外,在一些實施例,步驟S122中,可以改由橋接電表310進行主動判斷連線狀態,即當第一控制單元310判斷出無法與主控裝置200無線連線時,亦會直接啟用前述的橋接功能,以藉由有線方式連線主控裝置200。後續流程所示步驟S122皆可以此方式施行,在此即不贅述。 In addition, in some embodiments, in step S122, the bridged power meter 310 can be used to actively determine the connection state, that is, when the first control unit 310 determines that the main control device 200 cannot be wirelessly connected, the foregoing The bridging function is to connect the main control device 200 by wire. Step S122 shown in the subsequent process can be performed in this manner, and is not described here.
請參閱圖10繪示本發明實施例之智慧電表的佈建管理方法之第二種流程圖。請配合參閱圖2以利於了解。 Please refer to FIG. 10, which is a second flowchart of a method for managing the deployment of a smart meter according to an embodiment of the present invention. Please refer to Figure 2 for your understanding.
與圖9繪示流程圖不同在於,當主控裝置200無法有線通訊與無線通訊連接至橋接電表310時,令橋接備用電表330改以有線通訊與主控裝置200連接,且橋接備用電表330啟用無線通訊以供橋接電表310與從屬電表320連接(步驟S123)。 The difference from the flow chart shown in FIG. 9 is that when the main control device 200 cannot connect to the bridged electric meter 310 by wired communication and wireless communication, the bridged standby electric meter 330 is connected to the main control device 200 by wired communication, and the bridged standby electric meter 330 is enabled. The wireless communication is connected to the slave meter 320 by the bridge meter 310 (step S123).
請參閱圖11繪示本發明實施例之智慧電表的佈建管理方法之第三種流程圖。請配合參閱圖3以利於了解。 Please refer to FIG. 11 , which is a third flowchart of a method for managing the deployment of a smart meter according to an embodiment of the present invention. Please refer to Figure 3 for your understanding.
與圖9繪示流程圖不同在於,當主控裝置200判斷無法透過橋接電表310連通從屬電表320時,改以有線通訊連接從屬電表320(步驟S124)。然而,此步驟中,亦可以反過來以從屬電表320作為主動通訊方,當從屬電表320判斷未有裝置可進行無線通訊時,改以有線通訊與主控裝置200連接。 The difference from the flowchart shown in FIG. 9 is that when the master device 200 determines that the slave meter 320 cannot be communicated through the bridge meter 310, the slave meter 320 is connected by wired communication (step S124). However, in this step, the slave meter 320 can also be used as the active communication party. When the slave meter 320 determines that there is no device for wireless communication, it is connected to the master device 200 by wired communication.
請參閱圖12繪示本發明實施例之智慧電表的佈建管理方法之第四種流程圖。請配合參閱圖4以利於了解。 Please refer to FIG. 12, which is a fourth flowchart of a method for managing the deployment of a smart meter according to an embodiment of the present invention. Please refer to Figure 4 for your understanding.
與先前實施例不同在於,當主控裝置200未能與從屬電表320及橋接電表之至少其一通信時,則標示問題電表的硬體資訊(步驟S125)。然而,此圖12所示流程可與圖9至圖11的流程結合。然而,步驟S122之後,可以依據佈建環境的不同,而對應施行步驟S123與步驟S124。而步驟S125則需施行於步驟S123與步驟S124之後。 The difference from the previous embodiment is that when the master device 200 fails to communicate with at least one of the slave meter 320 and the bridge meter, the hardware information of the question meter is indicated (step S125). However, the flow shown in this FIG. 12 can be combined with the flow of FIGS. 9 to 11. However, after step S122, step S123 and step S124 may be performed according to different deployment environments. Step S125 is performed after step S123 and step S124.
請參閱圖13繪示本發明實施例之智慧電表的佈建管理方法之佈建修正流程圖。請配合參閱圖4與圖5以利於了解。此佈建修正方式 如下所述:將各問題電表340逐次設定為測試橋接電表350(步驟S210)。由主控裝置200透過測試橋接電表350,取得測試橋接電表350每次與各問題電表340的連線狀態資訊(步驟S220)。由後端伺服器100依據各連線狀態資訊計算出問題電表340中,需被取代為橋接電表310者(步驟S230)。 Please refer to FIG. 13 , which is a flow chart of the construction modification of the smart meter setting management method according to the embodiment of the present invention. Please refer to Figure 4 and Figure 5 for easy understanding. This layout modification method As described below, each problem electric meter 340 is successively set as the test bridge electric meter 350 (step S210). The main control device 200 transmits the connection status information of the test bridge meter 350 to each problem meter 340 through the test bridge meter 350 (step S220). The backend server 100 calculates the problem meter 340 based on the connection status information, and needs to be replaced with the bridge meter 310 (step S230).
在一些實施例中,佈建修正流程中,步驟S210中的問題電表340,可改為從屬電表320,也就是每一從屬電表320皆可作為測試橋接電表350的替代選擇。 In some embodiments, in the deployment modification process, the problem meter 340 in step S210 can be changed to the slave meter 320, that is, each slave meter 320 can be used as an alternative to the test bridge meter 350.
請參閱圖14繪示本發明實施例之智慧電表的佈建管理方法之第五種流程圖。請配合參閱圖6以利於了解。此方法包括:由主控裝置200與從屬電表320進行無線連接(步驟S310)。主控裝置200會先判斷是否連接至各從屬電表320(步驟S320)。當主控裝置200判斷可連接至從屬電表320,即進行無線通訊(步驟S321)。相反的,當主控裝置200判斷從屬電表320存在無法連接之一問題電表340時,先試著從其它從屬電表320擇一設定為橋接電表310,且令橋接電表310改以有線通訊與主控裝置200連接。橋接電表310透過無線通訊供問題電表340連接(步驟S324)。 Please refer to FIG. 14 , which is a fifth flowchart of a method for managing the deployment of a smart meter according to an embodiment of the present invention. Please refer to Figure 6 for your understanding. The method includes wirelessly connecting to the slave meter 320 by the master device 200 (step S310). The main control device 200 first determines whether or not it is connected to each of the slave meters 320 (step S320). When the master device 200 determines that it can be connected to the slave meter 320, wireless communication is performed (step S321). Conversely, when the master device 200 determines that the slave meter 320 is unable to connect to the problem meter 340, it first tries to select the slave meter 310 from the other slave meters 320, and changes the bridge meter 310 to wired communication and master control. The device 200 is connected. The bridge meter 310 is connected to the problem meter 340 via wireless communication (step S324).
請參閱圖15繪示本發明實施例之智慧電表的佈建管理方法之第六種流程圖。與圖14不同在於,當主控裝置200判斷無法透過無線通訊與問題電表340時,會先改以有線通訊與問題電表連接(步驟S325)。在一些實施例後,當主控裝置200再進一步判斷無法透過有線通訊與問題電表340連接時,才自從屬電表320中擇一設定為橋接電表310,且令橋接電表310改以有線通訊與主控裝置200連接,橋接電表310啟用無線通訊以供問題電表340連接(步驟S326)。 Please refer to FIG. 15 , which is a sixth flowchart of a method for managing the deployment of a smart meter according to an embodiment of the present invention. The difference from FIG. 14 is that when the main control device 200 determines that the wireless communication and the problem meter 340 cannot be transmitted, the wired communication is first connected to the problem meter (step S325). After some embodiments, when the main control device 200 further determines that the problem cannot be connected to the problem meter 340 through wired communication, the slave meter 320 is alternatively set to the bridge meter 310, and the bridge meter 310 is changed to wired communication and the master. The control device 200 is connected, and the bridge meter 310 enables wireless communication for connection to the problem meter 340 (step S326).
請參閱圖16繪示本發明實施例之智慧電表的佈建管理方法之第七種流程圖。與圖14不同在於,步驟S324後,當主控裝置200判斷仍存在無法連接問題電表340時,才改以有線通訊與問題電表340連接(步驟S325)。 Please refer to FIG. 16 , which is a seventh flowchart of a method for managing the deployment of a smart meter according to an embodiment of the present invention. The difference from FIG. 14 is that, after step S324, when the main control device 200 determines that there is still a problem that the problem meter 340 cannot be connected, the wired communication is connected to the problem meter 340 (step S325).
請參閱圖17繪示本發明實施例之智慧電表的佈建管理方法之第八種流程圖。與圖15不同在於,當主控裝置200判斷無法透過無線通 訊與問題電表340連接時,除改以有線通訊與問題電表340連接外(步驟S325),更設定問題電表340為橋接電表310,且令橋接電表310透過無線通訊供各從屬電表320連接(步驟S327)。 Please refer to FIG. 17 , which illustrates an eighth flowchart of a method for managing the deployment of a smart meter according to an embodiment of the present invention. The difference from FIG. 15 is that when the main control device 200 determines that the wireless communication cannot be passed When the signal is connected to the problem meter 340, in addition to being connected to the problem meter 340 by wired communication (step S325), the problem meter 340 is set as the bridge meter 310, and the bridge meter 310 is connected to the slave meters 320 by wireless communication (steps). S327).
然而,步驟S320之後,可以依據佈建環境的不同,而自步驟S324至步驟S327中選擇性的對應施行。 However, after step S320, it may be selectively performed from step S324 to step S327 depending on the layout environment.
此外,圖6所示系統架構,其佈建修正方案之建立係相近於圖13繪示的佈建修正流程圖,在此即不贅述。 In addition, the system architecture shown in FIG. 6 is constructed to be similar to the layout modification flowchart shown in FIG. 13 and will not be described herein.
綜上所述之,乃僅記載本發明為呈現解決問題所採用的技術手段之實施或實施例而已,並非用來限定本發明專利實施之範圍。即凡與本發明專利申請範圍文義相符,或依本發明專利範圍所做的均等變化與修飾,皆為本發明專利範圍所涵蓋。 In the above, it is merely described that the present invention is an implementation or an embodiment of the technical means for solving the problem, and is not intended to limit the scope of the invention. That is, the equivalent changes and modifications made in accordance with the scope of the patent application of the present invention or the scope of the invention are covered by the scope of the invention.
100‧‧‧後端伺服器 100‧‧‧Backend server
200‧‧‧主控裝置 200‧‧‧Master control unit
300‧‧‧電表群組 300‧‧‧Electric meter group
310‧‧‧橋接電表 310‧‧‧Bridge meter
320‧‧‧從屬電表 320‧‧‧Subordinate electricity meter
Claims (20)
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TW103139537A TWI522625B (en) | 2014-11-14 | 2014-11-14 | The Layout Management System of Wisdom Meter and Its Record Media |
CN201410718094.6A CN105592128B (en) | 2014-11-14 | 2014-12-01 | Intelligent electric meter deployment management system |
PH12015000191A PH12015000191A1 (en) | 2014-11-14 | 2015-06-04 | Construction management system for smart meter and record medium thereof |
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US11250523B2 (en) | 2019-07-26 | 2022-02-15 | Chicony Power Technology Co., Ltd. | Expandable combination electric meter |
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TWI579791B (en) | 2015-11-30 | 2017-04-21 | 財團法人資訊工業策進會 | Advanced metering infrastructure system |
CN107656116A (en) * | 2017-09-15 | 2018-02-02 | 国网辽宁省电力有限公司锦州供电公司 | The important active and standby metering method of Electricity customers kilowatt-hour meter |
TWI801592B (en) * | 2019-06-04 | 2023-05-11 | 德鋐科技有限公司 | Remote monitoring power billing control device |
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US7852837B1 (en) * | 2003-12-24 | 2010-12-14 | At&T Intellectual Property Ii, L.P. | Wi-Fi/BPL dual mode repeaters for power line networks |
CN2886715Y (en) * | 2005-12-23 | 2007-04-04 | 纳天集成电路(上海)有限公司 | Net bridge electric power meter |
CN101236693B (en) * | 2007-02-01 | 2011-08-10 | 上海久隆电力(集团)有限公司 | Intelligent meter reading system |
CN101931435A (en) * | 2010-07-30 | 2010-12-29 | 北京航空航天大学 | Low-voltage power line bandwidth carrier concentrator |
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US11250523B2 (en) | 2019-07-26 | 2022-02-15 | Chicony Power Technology Co., Ltd. | Expandable combination electric meter |
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