200423154 (1) 玖、發明說明 【發明所屬之技術領域】 本發明是關於一種複數射頻識別(RFID : Radio Frequency Identification )元件沿著其延伸方向隔著間隔 配置在較長地延伸的構件的連長體,及設有該連長體的電 纜,特別是關於一種較長地延伸的構件爲帶狀構件者。200423154 (1) 发明. Description of the invention [Technical field to which the invention belongs] The present invention relates to a company that has a plurality of radio frequency identification (RFID: Radio Frequency Identification) elements arranged along the extension direction of a member extending longer at intervals. Body, and a cable provided with the extended body, particularly with respect to a long-extending member that is a band-shaped member.
【先前技術】 習知,例如從所舖設的多數金屬電纜或光纖電纜中作 爲僅識別作爲目的的電纜的方法,眾知有在各電纜的外皮 表面施以印字,或是在各電纜安裝標籤,以識別電纜的方 法。[Prior art] Conventionally, for example, as a method of identifying only a cable as a purpose from most of the metal or fiber-optic cables laid, it is known to print on the outer surface of each cable or install a label on each cable. To identify the cable.
在依上述印字的方法中,製造者名稱,製造年月曰, 電纜的品名,電纜的長度等資訊,以油墨或熱轉印雷射等 ,被印字在電纜的外皮表面。在依標籤的方法中,刻印同 樣資訊的標籤,黏貼於電纜外皮,又使用金屬線等吊在電 纜。 在電纜表面施以印字時,沿著電纜的長度方向施以印 字之故,因而若被印的文字數變多,則必須長區間地露出 所舖設的電纜。例如,電纜被舖設在槽內’且在該槽上加 蓋時,則必須將蓋長區間地加以拆除。又,電纜舖設在被 埋設在土砂中的槽內時,則必須長區間地去除土砂。因此 ,爲了露出電纜需要較多工數。 如此地,施以印字時,儘量縮短沿著電纜的長度方向 -5- (2) (2)200423154 所施加的印字長度較理想。但如,如此地限制印字長度, 則有難以將有關於電纜所必須的所有資訊印字在電纜外皮 的問題。 又,作爲文字或記號等被印字在電纜的外皮表面的資 訊’是藉由時間經過或設置電纜時的擦過等而摩損或消失 導致無法判讀之虞。 將標籤設在電纜時,則必須將多數標籤以一定間隔配 置在較長電纜,而有費工數的問題。又,與施以印字時同 樣地’很難將較多資訊寫入標籤。又,若標籤從電纜脫落 ’或被記載於標籤的資訊隨著時間的經過,會擦過而消失 有無法判讀之虞。 代替對於電纜外皮表面的印字或標籤,例如QR碼( 二維條碼)黏貼於電纜外皮表面的電纜被揭示在日本特開 2 00 1 - 2 1 73 0號公報。依照該電纜,有關於電纜的資訊被 QR碼化之故,因而比使用印字或標籤時,可大量地儲存 有關於電纜的資訊。 但是,被QR碼化的資訊,是設於電纜表面之故,因 而與施以印字時同樣地,藉由時間的經過或設置電纜時的 擦過等而摩損或消失,又有從電纜表面剝離而成爲無法判 讀之虞。 【發明內容】 本發明是爲了解決如上述的習知缺點問題而創作者, 其目的是在於提供一種比習知更多量地可儲存有關於電纜 -6 - (3) (3)200423154 的資訊,且設置經過長時間仍儲存的資訊成爲無法判別的 可能性較少的電纜及對於該電纜的設置較容易的連長體。 爲了解決上述課題,依照本發明的一方面,提供一種 連長體,其特徵爲具備:帶狀的保持構件,及朝其延伸方 向隔著間隔配置於上述帶狀保持構件,且被保持在上述帶 狀保持構件的複數射頻識別元件。 依照本發明的另一側面,提供一種連長體,上述帶狀 保持構件是以電纜的撕裂帶子所構成,各射頻識別元件是 使用黏接劑被固定於連續的帶狀保持構件上。 依照本發明的另一方面,提供一種電纜,其特徵爲具 有:電纜心,及 大致沿著上述電纜心所設置的連長體,具備帶子狀的 保持構件,及隔著間隔配置於上述帶狀保持構件的延伸方 向’且被保持在上述帶狀保持構件的複數射頻識別元件的 連長體,及 被覆上述電纜心與上述連長體的護套。 【實施方式】 以下,參照圖式詳述本發明的實施形態。在同一或類 似構件,賦於同一或類似號碼。 第1圖是表示本發明的連長體1的實施形態。 連長體1是具備:帶狀保持構件3,及隔著間隔配置在 該保持構件3的長度方向,且被保持在保持構件3的複數射 頻識別(RFID : Radio Frequency Identification)元件 5。 (4) (4)200423154 保持構件3是可成爲使用於電纜的撕裂帶。保持構件3 是包含如FRP (纖維強化塑膠)。 RFID元件5是在內部具有可儲存資訊的1C晶片(未圖 示),及連接於1C晶片,且使用射頻來發訊被儲存於1C晶 片的資訊的發訊手段。RFID元件5的外廓是以通過電磁波 的硬質構件(例如,玻璃或塑膠)所構成。儲存於RFID 元件5的資訊是例如以電磁波作爲媒體,而可使用RFID讀 取器加以讀取。 RFID元件5是配置於保持構件3,成爲RFID元件5的長 度方向與保持構件3的延伸方向大約一致之狀態。各RFID 元件5是使用黏接劑被固定在連續的保持構件3的中間部。 RFID元件5的間隔是一定値也可以,或是不同也可以。 第2圖是表示用以製造連長體1的連長體製造裝置7。 連長體製造裝置7是隔著所定間隔將黏接劑9塗布在伸 長的帶狀保持構件3,而藉著將RFID元件5—個一個地配 置塗布有黏接劑的部分,而將RFID元件5配設於帶狀保持 構件3。 連長體製造裝置7是具備基台11。在基台11經由未圖 示的連結構件設有儲存設置RFID元件5之前的帶狀保持構 件3的第一儲存手段1 5,及與第一儲存手段1 5隔離地設置 ,且儲存設置RFID元件5後的帶狀保持構件(與被儲存於 第一儲存手段1 5的帶狀保持構件相連續的帶狀保持構件) 3,或是連長體1的第二儲存手段17。 第一儲存手段15與第二儲存手段17是具有藉由捲取而 -8- (5) (5)200423154 可儲存帶狀保持構件的滾筒。第一儲存手段1 5與第二儲存 手段1 7是成爲以互相大約平行而朝水平方向延伸的各旋轉 軸15A,17A爲中可自由旋轉的狀態。如第2圖所示地,在 利用第一儲存手段1 5與第二儲存手段1 7儲存帶狀保持構件 3的狀態下,帶狀保持構件3的一部分是在第一儲存手段1 5 與第二儲存手段1 7之間朝水平方向直線地延伸。例如以作 爲致動器的電動機(未圖示)來旋轉第二儲存手段1 7,則 帶狀保持構件3朝箭頭AR方向移動,而成爲被捲取在第二 儲存手段1 7。 在第一儲存手段1 5與第二儲存手段1 7之間朝水平方向 延長的帶狀保持構件3的上方,設有用以將黏接劑塗布於 帶狀保持構件3的黏接劑塗布手段1 9。該黏接劑塗布手段 1 9是依據藉由移動量檢測手段(未圖示)所檢測的帶狀保 持構件3的移動量,成爲間歇地吐出黏接劑9。由此,黏接 劑9隔著間隔朝其延伸方向地塗布於帶狀保持構件3。 位在第一儲存手段1 5與第二儲存手段1 7之間朝水平方 向延伸的帶狀保持構件3的上部,且在黏接劑塗布手段1 9 與第二儲存手段17之間,設有儲存RFID元件5的RFID元件 儲存手段1 3。 在RFID元件儲存手段13的下部,設有用以將被儲存 於RFID元件儲存手段13的RFID元件5配置於帶狀保持構件 3的供給口 13A。在RFID元件儲存手段13與供給口 13A之間 ,設有間歇地可供給各RFID元件5的供給手段21。 供給手段21是具備在RFID元件儲存手段13與供給口 (6) (6)200423154 1 3 A之間的通路2 3內朝水平方向延伸且朝水平方向移動自 如的平板狀快門2 1 A、2 1 B。各快門2 1 A、2 1 B是藉由設於 快門驅動部21C的致動器(未圖示)成爲可移動之狀態。 在快門2 1 A的上部設有快門2 1 B,而在以快門2 ;[ a與快 門2 1B所圍繞的通路23的空間內,成爲僅可收納一個RFID 元件5。 在表示於第2圖的狀態下,在快門2 1 A與快門2 1 B之間 ,存在著一個RFID元件5A,而在快門21B的上部存在著多 數RFID元件5,而以快門21 A與快門21B堵住通路23。從該 狀態,當以快門21B仍關閉通路23且快門21 A解放通路23 ’則RFID元件5 A經由供給口 1 3 A供給於帶狀保持構件3。 然後,當以快門2 1 A堵住通路2 3,而快門2 1 B解散通路2 3 ,則RFID元件5B掉落在快門21A與快門21B之間。然後, 藉由以快門21B堵住通路23,成爲與表示於第2圖之狀態同 樣的狀態。 藉由各快門21A、21B重複上述動作,成爲可將RFID 元件5—個一個地供給於帶狀保持構件3。 供給手段2 1是藉由依照利用上述移動量檢測手段(未 圖示)所檢測的帶狀保持構件3的移動量來間歇地供給 RFID元件5,成爲可將RFID元件5—個一個地供給於塗布 有帶狀保持構件3的黏接劑9的位置。由此,在帶狀保持構 件3的長度方向隔著間隔地一個一個地黏接RFID元件5。 以下,說明設有連長體1的各種型式的電纜。 第3圖是表示設有連長體1的電纜的第一實施形態的以 -10- (7) (7)200423154 直角於電纜的長度方向的平面切剖的剖視圖。 電纜25是具備電纜心27,及覆蓋電纜心27外側的護套 29 ° 電纜心27是具備:沿著電纜25的長度方向設於中心部 的抗拉力體28,及能圍繞抗拉力體28的周圍地沿著電纜25 的長度方向所設置的大約圓形狀斷面的槽31。 沿著電纜25的長度方向的複數溝33A〜33E,以大約 相等的角度間隔設於槽31的外周。在各構33 A〜33E,例 如配設有複數個4心的光纖帶35。設有溝33 A〜33E的部位 以外,設有連長體1成爲接觸於槽3 1的外周。連長體1是縱 向裝設或橫向捲繞(螺旋狀地捲繞)於槽3 1的外周。 溝33A〜33E是在將電纜25捲繞於滾筒時防止僅延伸 位於外側的光纖帶35,而爲了使各光纖帶35能大約均等地 延伸,而對於朝電纜25的長度方向延伸的中心軸CL,些 微扭轉(螺旋狀地)而朝長度方向延伸。亦即,對於第3 圖的紙面稍傾斜地延伸。 在設有光纖帶35的槽31外周,橫捲繞有將連長體1與 光纖帶35壓入於槽31所用的壓入捲繞體37。捲繞有壓入捲 繞體37的電纜心27的外側是以護套29加以覆蓋。該護套29 是例如由聚乙烯(PE )、聚氯化乙烯(PVC )、非鹵素難 燃材、燃燒時不會發生有毒氣體、或與乙烯樹脂容易分別 的實用材等所構成。 第4圖是表示設有連長體1的電纜的第二實施形態的以 直角於電纜的長度方向的平面切剖的剖視圖。 -11 - (8) (8)200423154 電纜3 9是具備電纜心4 1,及覆蓋電纜心4 1外側的護套 43 ° 電續心41是具備·沿者電續39的長度方向具備設於中 心部的抗拉力體44的圓形狀斷面的拉力構件45、及圍繞拉 力構件45周圍的圓形狀斷面的複數光纖軟線47。光纖軟線 47是沿著電纜39的長度方向所配置。如第4圖所示地,各 光纖軟線4 7接觸於拉力構件4 5的外周,而互相地接觸有相 鄰接的光纖軟線47彼此間。 爲了將光纖軟線47固定在拉力構件45,能覆蓋光纖軟 線4 7地橫捲繞有壓入捲繞體49。 在捲繞有壓入捲繞體49的電纜心41的外側,縱向裝設 或橫向捲繞有連長體1。覆蓋該連長體1與捲繞有壓入捲繞 體49的電纜心41地,橫向捲繞有壓入捲繞體51。捲繞有壓 入捲繞體5 1的電纜心4 1的外側,是以護套4 3所覆蓋。護套 43是與護套29 (第3圖)大約同樣地,由例如聚乙烯、聚 氯化乙烯、非鹵素難燃材、或實用材所構成。 光纖軟線47或連長體1是與電纜25 (第3圖)的情形同 樣地,朝電纜3 9的長度方向稍微扭轉地(螺旋狀地)延伸 〇 第5圖是表示設有連長體1的電纜的第三實施形態的以 直角於電纜的長度方向的平面切剖的剖視圖。 電纜53是將連長體1配設於槽的溝中的一溝,與電纜 25 (第3圖)不相同,而其他之處是與電纜25大約同樣地 被構成。 -12- 200423154 Ο) 電纜5 3是具備電纜心5 5,及覆蓋電纜心5 5外側的護套 57 〇 電纜心5 5是具備:沿著電纜5 3的長度方向具備設於中 心部的抗拉力體5 9,及沿著電纜5 3的長度方向所設置的圍 繞抗拉力體5 9周圍的大約圓形狀斷面的槽6 i。 在槽61的外周,沿著電纜53的長度方向以大約等角度 間隔設有複數溝63A〜63F。在溝63A〜65F中的一個溝63F 設有連長體1。在其他各溝6 3 A〜6 3 E,設有數個如4心的 光纖帶Μ 〇 在配置有連長體1與光纖帶65的槽61外周,橫向捲繞 有將連長體1與光纖帶65壓入於槽61所用的壓入捲繞體67 〇 光纖軟線65或連長體1是與電纜25 (第3圖)的情形同 樣地,朝電纜5 3的長度方向稍微扭轉地(螺旋狀地)延伸 〇 在捲繞有壓入捲繞體67的電纜心55的外側,是以護套 5 7所覆蓋。護套5 7是與電纜2 5 (第3圖)同樣地,由例如 聚乙烯(ΡΕ)、聚氯化乙烯(PVC )、非鹵素難燃材、燃 燒時不會發生有毒氣體、或與乙烯樹脂容易分別的實用材 等所構成。 第6圖是表示設有連長體1的電纜的第四實施形態的以 直角於電纜的長度方向的平面切剖的剖視圖。 電纜69是使用連長體與複數光纖軟線,來圍繞拉力構 件的周圍之處,與電纜39(第4圖)不相同,而其他之處 -13- (10) (10)200423154 與電纜39大約同樣地構成。 電纜69是具備電纜心71,及覆蓋電纜心71外側的護套 73 〇 電纜心7 1是具備:沿著電纜6 9的長度方向具備設於中 心部的抗拉力體75的圓形狀斷面的拉力構件75、及圍繞拉 力構件77周圍,且沿著電纜69的長度方向所設置的連長體 1及圓形狀斷面的複數光纖軟線79。 如第6圖所示地,各光纖軟線79及連長體1 ( RFID 5 ) 接觸於拉力構件7 7的外周,而互相地接觸有相鄰接的各光 纖軟線79彼此間,又互相地接觸有連長體1 ( RFID 5 )及 與連長體1 ( RFID 5 )相鄰接的光纖軟線79。 在第6圖中,沿著連結離連長體1外周的拉力構件77最 遠的部位,及離各光纖軟線79外周的拉力構件77最遠的部 位的包絡線,橫向捲繞有將連長體1與光纖軟線9壓入於拉 力構件77所用的壓入捲繞體81。 各光纖軟線79或連長體1是與電纜25 (第3圖)的情形 同樣地,朝電纜69的長度方向稍微扭轉而延伸。 在捲繞有壓入捲繞體8 1的電纜心7 1的外側,是以護套 73所覆蓋。護套73是與電纜29(第3圖)等同樣地,由例 如聚乙烯、聚氯化乙烯、非鹵素難燃材或實用材所構成。 電纜25(第3圖)或電纜39(第4圖)是連長體1的外 形對於電纜心的外形充分小時爲較理想的實施形態’電纜 53 (第5圖)或電纜69 (第6圖)是連長體1的外形對於電 纜心的外形並不充分小時爲較理想的實施形態。 -14- (11) (11)200423154 由以上說明可知,依本案發明的連長體,使用連長體 的電纜,連長體的製造裝置,及連長體的製造方法的實施 形態,是具有以下特徵。 (1 ) 一種連長體1,其特徵爲具有: 帶狀的保持構件3,及 朝其延伸方向隔著間隔配置於上述帶狀保持構件3, 且被保持於上述帶狀保持構件3的複數射頻識別(RFID ) 元件5。 (2 )上述帶狀保持構件3是以電纜的撕裂帶所構成, 各射頻識別元件5是使用黏接劑固定於連續的帶狀保持構 件3上。 (3 )上述射頻識別元件5是具有:儲存識別資訊的1C 晶片,及連接於上述1C晶片,使用射頻發訊被儲存於上述 晶片的發訊手段。 (4) 一種電纜25、39、53、69,其特徵爲具有: 電纜心2 7、4 1、5 5、7 1,及 大約沿著上述電纜心2 7、4 1、5 5、7 1所設置的連長體 1,具備帶狀保持構件3,與在上述帶狀保持構件3的延伸 方向隔著間隔所配置,被保持於上述帶狀保持構件3的複 數射頻識別元件5的連長體1 ’及 被覆上述電纜心27、41、55、71與上述連長體1的護 套 29、 43、 57、 73° (5 )上述連長體1是螺旋狀地捲繞於上述電纜心2 7、 41、55、71的周圍。 -15- (12) (12)200423154 (6 )上述帶狀保持構件3是配置於護套2 9、4 3、5 7、 7 3內側的護套撕裂用的撕裂帶。 (7)電纜25、39、53、69是又具有捲繞於上述電纜 心2 7、4 1、5 5、7 1與上述連長體1的外側,且成束上述電 纜心27、41、55、71與上述連長體1的壓入捲繞體37、51 、67、 81 〇 (8 )電纜39是又具有: 捲繞於上述電纜心4 1的外側的第一壓入捲繞體4 9,及 捲繞於上述電纜心4 1與上述連長體1外側,且成束上 述電纜心41與上述連長體丨的第二壓入捲繞體51。 (9 )電纜心5 5是包含具有大約沿著電纜5 3的延伸方 向所形成的複數溝6 3 A〜6 3 E的溝6 1 ;上述連長體1是配置 在上述溝63A〜63E之一溝。 (10) —種連長體製造裝置,屬於用以製造具有帶狀 的保持構件3,及朝其延伸方向隔著間隔配置於上述帶狀 保持構件3 ’且被保持於上述帶狀保持構件3的複數射頻識 別元件5的連長體1的連長體製造裝置7,其特徵爲具有: 將帶狀保持構件3的配置有射頻識別元件之前的部分 加以儲存的第一滾筒1 5 ; 與上述第一滾筒15隔離地設置,且捲取配置有上述帶 狀保持構件3的射頻識別元件5的部分並加以儲存的第二滾 筒1 7 ; 檢測因捲取上述第二滾筒1 7所產生的上述帶狀保持構 件3的移動量的移動量檢測手段; -16- (13) (13)200423154 配置於上述第一滾筒1 5與第二滾筒1 7之間,按照藉由 上述移動量檢測手段所檢測的上述帶狀保持構件3的移動 量,將黏接劑朝其延伸方向隔著間隔塗布於上述帶狀保持 構件3的黏接劑塗布手段1 9 ;以及 配置於上述黏接劑塗布手段1 9與第二滾筒1 7之間,按 照藉由上述移動量檢測手段所檢測的上述帶狀保持構件3 的移動量,將射頻識別兀件5 —個一^個地供給於塗布有上 述帶狀保持構件3的黏接劑的位置的射頻識別元件供給手 段21。 (11) 一種連長體製造方法,屬於用以製造具有帶狀 的保持構件3,及朝其延伸方向隔著間隔配置於上述帶狀 保持構件3,且被保持於上述帶狀保持構件3的複數射頻識 別元件5的連長體1的連長體製造方法,其特徵爲具有: 將帶狀保持構件3的配置有射頻識別元件5之前的部分 儲存於第一滾筒1 5的工程; 將上述帶狀保持構件3的配置有射頻識別元件5的部分 ,捲取在與上述第一滾筒15隔離地設置的第二滾筒17並加 以儲存的工程; 檢測因捲取上述第二滾筒1 7所產生的上述帶狀保持構 件3的移動量的工程; 按照上述帶狀保持構件3的移動量’將黏接劑朝其延 伸方向隔著間隔塗布於上述帶狀保持構件3的延伸於上述 第一滾筒15與第二滾筒17之間的部分的工程;以及 按照上述帶狀保持構件3的移動量,將射頻識別元件5 一 -17- (14) (14)200423154 個一個地供給於塗布有上述帶狀保持構件3的黏接劑的位 置的工程。 由如上發明的實施形態的說明可瞭解,依照連長體1 ,複數RFID元件5朝帶狀保持構件3的長度方向隔著間隔 固定地配置於帶狀保持構件3之故,因而利用將連長體1配 置在電纜內使得連長體1(帶狀保持構件3)的長度方向與 電纜的長度方向成爲一致,而可容易地進行朝電纜的長度 方向隔著間隔地設置RFID元件5的作業。 又,依照連長體1,可將電纜上一般所使用的撕裂帶 使用作爲保持構件之故,因而爲了製造連長體1不必製造 用的保持構件。又,將RFID元件5以黏接劑固定於撕裂帶 之故。因而容易地進行連長體1的製造。 依照具備連長體1的電纜25,作爲記憶有關於電纜25 的資訊的記憶媒體採用RFID元件之故,比藉由印字或標 籤來儲存(顯示)資訊,還可儲存大量資訊。而且僅將 RFID讀取器靠電纜25,不必露出電纜25的外皮,就可容 易地讀取有關於被儲存於RFID元件5的電纜25的資訊並加 以顯示。 又,依照具備連長體1的電纜25,作爲記憶有關於電 纜25的資訊的記憶媒體採用RFID元件之故,因而比藉由 印字或標籤來儲存(顯示)資訊,還可儲存大量資訊。而 且僅將FRID讀取器接近於電纜25,不必露出電纜25之外 皮,就可容易地讀取有關於被儲存在RFID元件5的電纜25 的資訊並加以顯示。 -18- (15) (15)200423154 又,依照具備連長體1的電纜25,藉由護套29來被覆 記憶有關於電纜25的資訊的RFID元件5之故,因而藉由舖 設電纜2 5後的經過時間或設置電纜2 5時的擦過等,會擦失 有關於電纜2 5的資訊,而可避免無法判讀的情形。又, RFID元件5以護套29進行被覆之故,因而例如在設置電纜 2 5時即使有外力施加於電纜2 5,則以護套2 9來緩和該外力 ,使得RFID元件5不容易破損。 又,依照具備連長體1的電纜25,RFID元件5不會埋 設在管狀的護套29內,而護套29成爲大約一樣形態之故’ 因而即使爲了設置或保養而折彎電纜25,也不容易在護套 29發生應力集中。因此,藉由依設置或保養所產生的折彎 ,成爲不容易損壞電纜25的護套29° 欲將RFID元件5設於護套29內,則在製造時’必須將 RFID元件5插入在以高溫被熔融狀態的護套29的構成構件 中,而有藉由高溫妨礙RFID元件5的功能之虞。但是’在 電纜25,以護套29被覆電纜心27之際’壓入捲繞體37介設 在連長體1與護套29之間之故,因而連長體1的RFID元件5 不會直接曝露在高溫狀態的護套2 9的構成構件。因此’在 被覆護套29時,較少發生妨礙RFID兀件5的功能之虞。 又,欲將護套29被覆在電纜心27之際’則將斷面圓環 狀護套29被覆在斷面大約圓形狀的電纜心27就可以’而可 容易地進行被覆。 又,依照電續25,在連長體1的長度方向隔著所定間 隔設置各RFID元件5之故’因而在電纜25的長度方向的任 (16) (16)200423154 意位置上可取得有關於電纜2 5的資訊(例如,識別電纜2 5 所用的資訊)。即使電纜2 5被舖設在如槽內而加蓋於該槽 ,又該槽被埋設在土砂中時,也不必長區間地除去土砂’ 僅除去砂的一部分,就可讀取電纜2 5的資訊,而可刪減除 去土砂的工數。 RFID元件5的設置間隔是按照RFID讀取器可讀取被儲 存於R F I D元件5的資訊的距離來決定就可以。例如,可讀 取的距離爲1 m時,若將RFID元件5的設置間隔作成1 m ’ 則將RFID讀取器接近於從電纜25距〇·87 m ( 1 m + 2 W + 0.87 m )以內的距離,就可讀取被儲存在RFID元件5的資 訊。 有關於電纜2 5的資訊,是在連長體1的製造前事先儲 存於RFID元件5也可以。或是在如表示於第2圖的連長體 製造裝置7的RFID元件儲存手段13與第二儲存手段17之間 ,或是在連長體製造裝置7的通路23近旁,設置可將資訊 寫入於RFID元件5的RFID寫入器,而在製造連長體1時’ 將有關於電纜25的資訊寫入於各RFID元件5也可以。又’ 舖設電纜25之後,使用RFID寫入器,重寫各RFID元件5的 資訊也可以。 依照具備連長體1的電纜39、53、69,可大量地儲存 有關於電纜3 9、5 3、6 9的資訊,而且可容易地讀取有關於 電纜39、53、69的資訊加以顯示等,具備與電纜25所具備 的效果大約同樣的效果。 又,在電纜39、53、69中,與電纜25同樣地,朝連長 -20- (17) (17)200423154 體1的長度方向隔著所定間隔設置複數RFID元件5之故’ 因而在電纜39、53、69的長度方向的任意位置’可取得有 關於電纜39、53、69的資訊。 電纜39、53、69的RFID元件5的設置間隔是與電纜25 同樣地決定就可以。 有關於被儲存於RFID元件5的電纜39、53、69的資訊 ,是與電纜2 5的情形可同樣地寫入。 如上所述地,依照本發明,比習知可多量地儲存有關 於電纜的資訊,雖設置後經過長時間,所儲存的資訊也很 少會成爲無法判別,而爲了設置或保養,即使折彎也可提 供不容易破損的電纜及可容易設置於該電纜的連長體。 又,本發明是並不被限定於上述的實施形態,利用進 行適當的變更,可實施在其他形態。 例如,將電纜25、39、53、69作成不是光纖電纜而作 成金屬電纜也可以,作成光纖與金屬線混在的電纜也可以 【圖式簡單說明】 第1圖是表示本發明的連長體的實施形態的立體圖。 第2圖是表示將製造第1圖的連長體所用的連長體製造 裝置的槪略圖。 第3圖是表示設有第1圖連長體的電纜的第一實施形態 的剖視圖。 第4圖是表示設有第丨圖連長體的電纜的第二實施形態 -21 - (18) (18)200423154 的剖視圖。 第5圖是表示設有第1圖連長體的電纜的第三實施形態 的剖視圖。 第6圖是表示設有第1圖連長體的電纜的第四實施形態 的剖視圖。 〔主要元件對照表〕 1 連 長 體 3 帶 狀 保 持 構 件 5 射 頻 m 別 ( RFID )元件 7 連 長 體 製 造 裝 置 9 黏 接 劑 11 基 台 13 RFID 元 件 儲 存 手段 15 第 一 儲 存 手 段 17 第 二 儲 存 手 段 19 黏 接 劑 塗 布 手 段 2 1 供 給 手 段 23 通 路 25 ^ 39、 53 ^ 69 電 纜 27、 41、 55 > 71 電 纜 心 28 ' 59、 75 抗 拉 力 體 29、 43、 5 7、 73 護 套 3 1、6 1 槽 -22- (19) (19)200423154 33A 〜33E、63A 〜63F 溝 35 光纖帶 37、51、67、81 壓入捲繞體 4 5、7 7 拉力構件 47、65、79 光纖軟線In the method of printing according to the above, information such as the name of the manufacturer, the date of manufacture, the name of the cable, the length of the cable, etc. are printed on the outer surface of the cable with ink or thermal transfer laser. In the label-based method, a label with the same information is engraved, adhered to the outer sheath of the cable, and suspended from the cable using a metal wire. When printing is applied to the surface of a cable, it is printed along the length of the cable. Therefore, if the number of characters to be printed increases, it is necessary to expose the laid cable in a long interval. For example, when a cable is laid in a slot 'and a cover is placed on the slot, the cover must be removed in long sections. When the cable is laid in a trench buried in soil and sand, the soil and sand must be removed in a long interval. Therefore, more work is required to expose the cable. In this way, it is desirable to shorten the length of the cable along the length of the cable when printing. -5- (2) (2) 200423154 It is ideal. However, if the printing length is limited in this way, it is difficult to print all the information necessary for the cable on the cable sheath. In addition, information printed on the outer surface of the cable, such as a character or a symbol, is damaged or disappeared due to the passage of time or the rubbing during installation of the cable, which makes it impossible to read. When the labels are set on the cables, most of the labels must be arranged on the longer cables at a certain interval, which is labor-intensive. Also, as in the case of printing, it is difficult to write more information into the label. In addition, if the tag is detached from the cable or the information recorded on the tag is erased over time, it may disappear and may not be read. Instead of printing or labeling on the surface of the cable sheath, for example, a cable with a QR code (two-dimensional bar code) pasted on the surface of the cable sheath is disclosed in Japanese Patent Laid-Open No. 2001-2 1 73 0. According to this cable, the information about the cable is QR coded, so that the information about the cable can be stored in a larger amount than when printing or labeling is used. However, since the QR coded information is provided on the surface of the cable, it is abraded or disappeared by the passage of time or the rubbing when the cable is installed, as in the case of printing, and peeled off from the surface of the cable. Become unreadable. [Summary of the Invention] The present invention was created by the creators to solve the problems of the conventional disadvantages as described above, and its purpose is to provide a larger amount of information about the cables than conventional 6-(3) (3) 200423154 , And the information stored after being set for a long time becomes a cable that has less possibility of being distinguished and a connected body that is easier to set for the cable. In order to solve the above-mentioned problem, according to an aspect of the present invention, there is provided a continuous body including a band-shaped holding member, and the band-shaped holding member is disposed at intervals in the extending direction of the band-shaped holding member, and is held at the above. A plurality of radio frequency identification elements of the band-shaped holding member. According to another aspect of the present invention, there is provided a long body. The above-mentioned strip-shaped holding member is made of a tear tape of a cable, and each RFID element is fixed to a continuous strip-shaped holding member using an adhesive. According to another aspect of the present invention, there is provided a cable comprising: a cable core; and an elongated body provided substantially along the cable core; a belt-shaped holding member; and a belt-shaped holding member disposed at intervals. The extension body of the holding member is held in the extending body of the plurality of radio frequency identification elements of the band-shaped holding member, and a sheath covering the cable core and the extending body. [Embodiment] Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The same or similar components are assigned the same or similar numbers. FIG. 1 shows an embodiment of the connected body 1 of the present invention. The continuous body 1 includes a band-shaped holding member 3 and a plurality of radio frequency identification (RFID) elements 5 arranged in the longitudinal direction of the holding member 3 at intervals and held by the holding member 3. (4) (4) 200423154 The holding member 3 is a tear tape that can be used for a cable. The holding member 3 is contained, for example, FRP (fiber-reinforced plastic). The RFID element 5 has a 1C chip (not shown) capable of storing information inside, and a transmitting means connected to the 1C chip and transmitting information stored in the 1C chip using radio frequency. The outline of the RFID element 5 is made of a rigid member (for example, glass or plastic) that passes electromagnetic waves. The information stored in the RFID element 5 is, for example, an electromagnetic wave as a medium, and can be read using an RFID reader. The RFID element 5 is arranged on the holding member 3, and the length direction of the RFID element 5 and the extending direction of the holding member 3 are approximately the same. Each RFID element 5 is fixed to an intermediate portion of the continuous holding member 3 using an adhesive. The interval of the RFID elements 5 may be fixed or different. FIG. 2 shows a long body manufacturing apparatus 7 for manufacturing the long body 1. The continuous body manufacturing device 7 applies the adhesive 9 to the elongated strip-shaped holding member 3 at a predetermined interval, and arranges the RFID-coated parts with the adhesive-coated parts one by one to form the RFID element. 5 is arranged on the band-shaped holding member 3. The continuous body manufacturing device 7 includes a base 11. The base 11 is provided with a first storage means 15 for storing the band-shaped holding member 3 before the RFID element 5 is stored through a connecting member (not shown), and is provided separately from the first storage means 15 and stores the RFID element. 5 after the belt-shaped holding member (a belt-shaped holding member that is continuous with the belt-shaped holding member stored in the first storage means 15) 3, or the second storage means 17 of the continuous body 1. The first storage means 15 and the second storage means 17 are rollers having a belt-shaped holding member that can be stored by winding. The first storage means 15 and the second storage means 17 are in a state in which each of the rotation shafts 15A and 17A extending in a horizontal direction approximately parallel to each other is freely rotatable. As shown in FIG. 2, in a state where the belt-shaped holding member 3 is stored using the first storage means 15 and the second storage means 17, a part of the belt-shaped holding member 3 is stored in the first storage means 15 and the first storage means 15. The two storage means 17 extend linearly in a horizontal direction. For example, if the second storage means 17 is rotated by a motor (not shown) as an actuator, the band-shaped holding member 3 moves in the direction of the arrow AR, and the second storage means 17 is wound up. Above the band-shaped holding member 3 extending horizontally between the first storage means 15 and the second storage means 17 is provided an adhesive coating means 1 for applying an adhesive to the belt-shaped holding member 3. 9. This adhesive coating means 19 is based on the amount of movement of the band-shaped holding member 3 detected by the movement amount detecting means (not shown), and the adhesive 9 is intermittently discharged. Thereby, the adhesive 9 is applied to the tape-shaped holding member 3 in a direction in which it is extended at intervals. An upper portion of the band-shaped holding member 3 extending in a horizontal direction between the first storage means 15 and the second storage means 17 is provided between the adhesive coating means 19 and the second storage means 17. RFID element storage means 1 3 for storing RFID elements 5. A supply port 13A for disposing the RFID element 5 stored in the RFID element storage means 13 on the band-shaped holding member 3 is provided below the RFID element storage means 13. Between the RFID element storage means 13 and the supply port 13A, a supply means 21 capable of intermittently supplying each RFID element 5 is provided. The supply means 21 is a flat shutter 2 1 A, 2 provided with a path 2 3 extending between the RFID element storage means 13 and the supply port (6) (6) 200423154 1 3 A in a horizontal direction and freely movable in the horizontal direction. 1 B. Each of the shutters 2 1 A and 2 1 B is movable by an actuator (not shown) provided in the shutter driving section 21C. A shutter 2 1 B is provided on the upper part of the shutter 2 1 A, and only one RFID element 5 can be accommodated in the space of the passage 23 surrounded by the shutter 2; [a and the shutter 2 1B. In the state shown in FIG. 2, there is one RFID element 5A between the shutters 2 1 A and 2 1 B, and a plurality of RFID elements 5 exist at the upper part of the shutter 21B. 21B blocked the passage 23. From this state, when the passageway 23 is still closed by the shutter 21B and the passageway 23 'is released by the shutter 21A, the RFID element 5A is supplied to the band-shaped holding member 3 through the supply port 1 3A. Then, when the path 2 3 is blocked by the shutter 2 1 A and the path 2 3 is dismantled by the shutter 2 1 B, the RFID element 5B falls between the shutter 21A and the shutter 21B. Then, by blocking the passage 23 with the shutter 21B, the state is the same as that shown in FIG. 2. By repeating the operations described above for each of the shutters 21A and 21B, it becomes possible to supply the RFID elements 5 to the band-shaped holding member 3 one by one. The supply means 21 is to supply the RFID elements 5 intermittently in accordance with the movement amount of the strip-shaped holding member 3 detected by the above-mentioned movement amount detection means (not shown), so that the RFID elements 5 can be supplied one by one to The position where the adhesive 9 of the band-shaped holding member 3 is applied. Thereby, the RFID elements 5 are adhered one by one in the longitudinal direction of the strip-shaped holding member 3 at intervals. Hereinafter, various types of cables provided with the continuous body 1 will be described. Fig. 3 is a cross-sectional view showing a first embodiment of the cable provided with the elongated body 1 taken along a plane perpendicular to the longitudinal direction of the cable at -10- (7) (7) 200423154. The cable 25 is provided with a cable core 27 and a sheath 29 covering the outer side of the cable core 27. The cable core 27 is provided with a tensile body 28 provided at the center along the length direction of the cable 25 and capable of surrounding the tensile body A groove 31 having a substantially circular cross-section is provided around the periphery of the cable 28 along the length direction of the cable 25. A plurality of grooves 33A to 33E along the length of the cable 25 are provided on the outer periphery of the groove 31 at approximately equal angular intervals. Each of the structures 33 A to 33E is provided with a plurality of 4-core fiber ribbons 35, for example. Except for the portions where the grooves 33A to 33E are provided, the continuous body 1 is provided so as to contact the outer periphery of the groove 31. The continuous body 1 is installed longitudinally or wound laterally (spirally wound) around the outer periphery of the groove 31. The grooves 33A to 33E prevent the optical fiber ribbons 35 located on the outside from being extended when the cable 25 is wound around the drum. In order to allow each optical fiber ribbon 35 to extend approximately evenly, the central axis CL extending in the length direction of the cable 25 , Slightly twisted (spirally) and extended in the length direction. That is, the paper surface of FIG. 3 extends slightly obliquely. On the outer periphery of the groove 31 provided with the optical fiber ribbon 35, a press-fit wound body 37 for pressing the continuous body 1 and the optical fiber ribbon 35 into the groove 31 is wound horizontally. The outer side of the cable core 27 around which the press-in winding body 37 is wound is covered with a sheath 29. The sheath 29 is made of, for example, polyethylene (PE), polyvinyl chloride (PVC), a non-halogen flame retardant material, a practical material that does not generate toxic gases during combustion, or a material that is easily separated from vinyl resin. Fig. 4 is a cross-sectional view showing a second embodiment of the cable provided with the elongated body 1 and cut at a plane perpendicular to the longitudinal direction of the cable. -11-(8) (8) 200423154 The cable 3 9 is provided with a cable core 41, and a sheath covering the outside of the cable core 41 1 43 ° The electric core 41 is provided. It is installed along the length of the electric core 39. The tensile member 45 having a circular cross section of the tensile member 44 in the center portion, and a plurality of optical fiber cords 47 having a circular cross section surrounding the tensile member 45. The optical fiber cord 47 is arranged along the longitudinal direction of the cable 39. As shown in Fig. 4, the respective optical fiber cords 47 are in contact with the outer periphery of the tension member 45, and the adjacent optical fiber cords 47 are in contact with each other. In order to fix the optical fiber cord 47 to the tension member 45, a press-fit winding body 49 is wound horizontally so as to cover the optical fiber cord 47. On the outside of the cable core 41 on which the press-fit winding body 49 is wound, the long body 1 is longitudinally or laterally wound. The continuous body 1 and the cable core 41 on which the press-fit roll 49 is wound are covered, and the press-fit roll 51 is wound laterally. The outer side of the cable core 4 1 around which the press-fit winding body 51 is wound is covered with a sheath 4 3. The sheath 43 is made of, for example, polyethylene, polyvinyl chloride, a non-halogen flame-resistant material, or a practical material, similarly to the sheath 29 (Fig. 3). The optical fiber cord 47 or the extended body 1 is extended slightly twisted (spirally) in the length direction of the cable 39 as in the case of the cable 25 (FIG. 3). FIG. 5 shows that the extended body 1 is provided. A cross-sectional view of a third embodiment of a cable cut at a plane perpendicular to the longitudinal direction of the cable. The cable 53 is a groove in which the continuous body 1 is arranged in the groove of the groove. The cable 53 is different from the cable 25 (Fig. 3), and is otherwise constructed similarly to the cable 25. -12- 200423154 〇) The cable 5 3 is provided with a cable core 5 5 and a sheath 57 covering the outside of the cable core 5 5 〇 The cable core 5 5 is provided with a resistance provided at the center along the length of the cable 5 3 The tension body 59, and a groove 6i of a substantially circular cross-section around the tension body 59, which is provided along the length direction of the cable 53. A plurality of grooves 63A to 63F are provided on the outer periphery of the groove 61 at approximately equal angular intervals along the longitudinal direction of the cable 53. One of the grooves 63A to 63F is provided with a continuous body 1. In each of the other grooves 6 3 A to 6 3 E, a plurality of optical fiber ribbons such as 4 cores are provided. On the outer periphery of the groove 61 where the elongated body 1 and the optical fiber ribbon 65 are arranged, the elongated body 1 and the optical fiber are wound laterally. The press-wound body 67 for pressing the tape 65 into the groove 61. The optical fiber cord 65 or the extended body 1 is twisted slightly (helically) in the length direction of the cable 53 as in the case of the cable 25 (Fig. 3). It extends in the shape of 0. On the outside of the cable core 55 around which the press-wound body 67 is wound, it is covered with a sheath 5 7. The sheath 5 7 is made of, for example, polyethylene (PE), polyvinyl chloride (PVC), a non-halogen flame retardant material, and does not generate toxic gases during combustion, as with the cable 2 5 (Figure 3). Resins are easily constructed from practical materials and the like. Fig. 6 is a cross-sectional view showing a fourth embodiment of the cable provided with the elongated body 1 and cut at a plane perpendicular to the longitudinal direction of the cable. The cable 69 uses a long body and a plurality of optical fiber cords to surround the surroundings of the tension member, which is different from the cable 39 (Figure 4), and other points -13- (10) (10) 200423154 is about the same as the cable 39 It is the same structure. The cable 69 is a circular cross section including a cable core 71 and a sheath 73 covering the outside of the cable core 71. The cable core 71 is provided with a tensile body 75 provided at the center along the length direction of the cable 69. The tension member 75 and the plurality of optical fiber cords 79 and the cross-section body 1 and a circular cross section provided around the tension member 77 and along the length direction of the cable 69 are provided. As shown in FIG. 6, each optical fiber cord 79 and the connected body 1 (RFID 5) are in contact with the outer periphery of the tension member 7 7, and each adjacent optical fiber cord 79 is in contact with each other and in contact with each other. There are a long body 1 (RFID 5) and an optical fiber cord 79 adjacent to the long body 1 (RFID 5). In FIG. 6, along the envelope line connecting the portion furthest from the tension member 77 on the outer periphery of the continuous body 1 and the portion furthest from the tension member 77 on the outer periphery of each optical fiber cord 79, the coil is wound laterally. The body 1 and the optical fiber cord 9 are press-fitted into a press-wound body 81 used for the tension member 77. Each of the optical fiber cords 79 or the extended bodies 1 is twisted slightly in the longitudinal direction of the cable 69 and extends as in the case of the cable 25 (FIG. 3). The outer side of the cable core 71 where the press-fit wound body 81 is wound is covered with a sheath 73. The sheath 73 is made of, for example, polyethylene, polyvinyl chloride, a non-halogen flame-resistant material, or a practical material in the same manner as the cable 29 (Fig. 3). The cable 25 (picture 3) or cable 39 (picture 4) is an ideal embodiment in which the shape of the long body 1 is sufficiently small for the shape of the cable core. 'Cable 53 (picture 5) or cable 69 (picture 6) ) Is an ideal embodiment in which the shape of the continuous body 1 is not sufficiently small for the shape of the cable core. -14- (11) (11) 200423154 From the above description, it can be seen that according to the invention of the present invention, the embodiment of the use of the cable, the device for manufacturing the connector, and the method of manufacturing the method for the connector has The following features. (1) A continuous body 1 comprising: a band-shaped holding member 3; and a plurality of band-shaped holding members 3 arranged at intervals in the extending direction thereof and held by the band-shaped holding members 3. Radio frequency identification (RFID) element 5. (2) The band-shaped holding member 3 is formed of a tear tape of a cable, and each RFID element 5 is fixed to a continuous band-shaped holding member 3 using an adhesive. (3) The above-mentioned radio frequency identification element 5 includes a 1C chip storing identification information, and a transmitting means connected to the 1C chip and using radio frequency transmission to be stored in the chip. (4) A cable 25, 39, 53, 69, characterized by having: a cable core 2 7, 4 1, 5 5, 7 1 and approximately along the cable core 2 7, 4 1, 5 5, 7 1 The connected elongated body 1 is provided with a band-shaped holding member 3 which is arranged at a distance from the extending direction of the band-shaped holding member 3 and is held by the plurality of radio-frequency identification elements 5 of the band-shaped holding member 3. Body 1 ′ and sheaths 29, 43, 57 and 73 covering the cable cores 27, 41, 55, 71 and the extended body 1 (5) The connected body 1 is spirally wound around the cable core 2 Around 7, 41, 55, 71. -15- (12) (12) 200423154 (6) The above-mentioned band-shaped holding member 3 is a tear tape for tearing the sheath, which is disposed on the inner side of the sheaths 2 9, 4, 3, 5, 7, 7 3. (7) The cables 25, 39, 53, 69 are also wound on the outer side of the cable core 2 7, 4 1, 5 5, 71, and the connecting body 1, and bundle the cable cores 27, 41, 55, 71 and the press-wound body 37, 51, 67, 81 of the continuous body 1 (8) The cable 39 further has: a first press-wound body wound around the outer side of the cable core 41 49, and a second press-in wound body 51 wound around the cable core 41 and the extended body 1 and bundling the cable core 41 and the extended body 丨. (9) The cable core 55 is a groove 6 1 including a plurality of grooves 6 3 A to 6 3 E formed along the extending direction of the cable 53; the continuous body 1 is disposed between the grooves 63A to 63E. A ditch. (10) A continuous elongated body manufacturing device for manufacturing a holding member 3 having a band shape, and the holding member 3 is arranged on the band holding member 3 ′ at intervals in the extending direction thereof and is held by the band holding member 3. A long body manufacturing device 7 for a long body 1 of a plurality of radio frequency identification elements 5, comprising: a first drum 15 storing a portion of the band-shaped holding member 3 before the radio frequency identification elements are arranged; and The first roller 15 is provided in isolation, and a second roller 17 is wound up and stored in a portion where the radio frequency identification element 5 of the band-shaped holding member 3 is arranged; and the above-mentioned generated by the winding of the second roller 17 is detected. Movement amount detection means for the movement amount of the belt-shaped holding member 3; -16- (13) (13) 200423154 is arranged between the first drum 15 and the second drum 17 according to the position detected by the movement amount detection means. The amount of movement of the belt-shaped holding member 3 detected is an adhesive coating means 19 for applying an adhesive to the belt-shaped holding member 3 at intervals in the direction in which it is extended; and it is disposed on the adhesive coating means 1 9 with the second roller 1 Between 7 and 7 according to the movement amount of the band-shaped holding member 3 detected by the movement amount detecting means, the RFID identification elements 5 are supplied one by one to the adhesion where the band-shaped holding member 3 is coated. Radio frequency identification element supply means 21 for the position of the agent. (11) A method for manufacturing a continuous body, which belongs to a method of manufacturing a holding member 3 having a band shape, and arranged to be spaced apart from the holding member 3 with a gap in the extending direction thereof, and held by the holding member 3 with a band. The method for manufacturing a long body of the long body 1 of the plurality of radio frequency identification elements 5 is characterized in that: a process of storing the portion of the band-shaped holding member 3 before the radio frequency identification element 5 is arranged in the first drum 15; The portion of the band-shaped holding member 3 where the radio frequency identification element 5 is arranged is taken up and stored in a second drum 17 provided separately from the above-mentioned first drum 15; it is detected that the second drum 17 is wound up A process of moving the belt-shaped holding member 3 according to the movement amount of the belt-shaped holding member 3 according to the amount of movement of the belt-shaped holding member 3 in the direction in which the adhesive is applied to the belt-shaped holding member 3 at intervals, extending to the first roller. 15 and the second roller 17; and supplying the RFID devices 5-1 to 17- (14) (14) 200423154 one by one according to the moving amount of the belt-shaped holding member 3 described above. Construction of the position of the adhesive of the shape-retaining member 3. As can be understood from the description of the embodiment of the invention as described above, according to the elongated body 1, the plurality of RFID elements 5 are fixedly arranged on the strip-shaped retaining member 3 at intervals in the length direction of the strip-shaped retaining member 3. The body 1 is arranged in the cable so that the longitudinal direction of the continuous body 1 (belt-shaped holding member 3) coincides with the longitudinal direction of the cable, and the operation of arranging the RFID elements 5 at intervals in the longitudinal direction of the cable can be easily performed. In addition, according to the continuous body 1, a tear tape generally used for a cable can be used as a holding member, so that a holding member for manufacturing the continuous body 1 is not necessary. The RFID element 5 is fixed to the tear tape with an adhesive. Therefore, the continuous body 1 can be easily manufactured. According to the cable 25 provided with the connected body 1, an RFID element is used as a memory medium for storing information about the cable 25, and a larger amount of information can be stored than by storing (displaying) the information by printing or labeling. Furthermore, by simply placing the RFID reader on the cable 25, the information about the cable 25 stored in the RFID element 5 can be easily read and displayed without exposing the outer cover of the cable 25. In addition, according to the cable 25 provided with the connected body 1, an RFID element is used as a storage medium for storing information about the cable 25, so that a larger amount of information can be stored than by storing (displaying) the information by printing or labeling. Furthermore, the RFID reader is only brought close to the cable 25, and the information about the cable 25 stored in the RFID element 5 can be easily read and displayed without exposing the sheath of the cable 25. -18- (15) (15) 200423154 In addition, according to the cable 25 provided with the long body 1, the sheath 29 is used to cover the RFID element 5 that stores the information about the cable 25. Therefore, the cable 2 is laid. After the elapsed time or the rubbing when the cable 25 is installed, the information about the cable 25 will be lost, and the situation that cannot be read can be avoided. In addition, since the RFID element 5 is covered with the sheath 29, for example, even if an external force is applied to the cable 25 when the cable 25 is installed, the sheath 29 is used to relax the external force, so that the RFID element 5 is not easily damaged. In addition, according to the cable 25 provided with the continuous body 1, the RFID element 5 is not buried in the tubular sheath 29, and the sheath 29 has approximately the same shape. Therefore, even if the cable 25 is bent for installation or maintenance, Stress concentration is unlikely to occur in the sheath 29. Therefore, through the bending caused by installation or maintenance, it becomes a sheath 29 that does not easily damage the cable 25. If the RFID element 5 is to be placed in the sheath 29, the RFID element 5 must be inserted at a high temperature during manufacture. Among the constituent members of the sheath 29 in the molten state, the function of the RFID element 5 may be hindered by high temperature. However, "when the cable 25 and the cable core 27 are covered with the sheath 29," the wound body 37 is interposed between the long body 1 and the sheath 29, so the RFID element 5 of the long body 1 does not The constituent members of the sheath 29 directly exposed to a high temperature state. Therefore, when the sheath 29 is covered, there is less possibility that the function of the RFID element 5 will be hindered. Further, when the sheath 29 is to be coated on the cable core 27 ', it is possible to coat the sheathed sheath 29 with a circular cross-section on the cable core 27 having a substantially circular cross-section, and the sheath can be easily coated. In addition, according to the electrical continuation 25, each RFID element 5 is provided at a predetermined interval in the longitudinal direction of the continuous body 1. Therefore, it can be obtained at any desired position in the longitudinal direction of the cable 25 (16) (16) 200423154. Information for cable 2 5 (for example, information used to identify cable 2 5). Even if the cable 25 is laid in a groove and covered with the groove, and the groove is buried in the earth and sand, it is not necessary to remove the earth and sand for a long period of time. , And the number of jobs to remove soil and sand can be deleted. The setting interval of the RFID element 5 may be determined in accordance with the distance at which the RFID reader can read the information stored in the R F I D element 5. For example, if the readable distance is 1 m, if the setting interval of the RFID element 5 is set to 1 m ', the RFID reader will be closer to the cable 25 from the distance of 87 m (1 m + 2 W + 0.87 m). Within a distance, the information stored in the RFID element 5 can be read. The information on the cable 25 may be stored in the RFID element 5 before the connected body 1 is manufactured. It is provided between the RFID element storage means 13 and the second storage means 17 of the connected body manufacturing device 7 as shown in FIG. 2 or near the passage 23 of the connected body manufacturing device 7 to write information. The RFID writer incorporated in the RFID element 5 may write the information about the cable 25 into each RFID element 5 when the connected body 1 is manufactured. After laying the cable 25, the RFID writer may be used to rewrite the information of each RFID element 5. According to the cables 39, 53, 69 of the connected body 1, a large amount of information about the cables 3 9, 5, 3, and 6 can be stored, and the information about the cables 39, 53, 69 can be easily read and displayed. The effects provided by the cable 25 are approximately the same as those provided by the cable 25. Also, among the cables 39, 53, and 69, the same as the cable 25, the plurality of RFID elements 5 are provided at predetermined intervals in the length direction of the company -20- (17) (17) 200423154. 39, 53, 69 at any position in the length direction can obtain information about the cables 39, 53, 69. The installation interval of the RFID elements 5 of the cables 39, 53, and 69 may be determined in the same manner as the cable 25. Information about the cables 39, 53, and 69 stored in the RFID element 5 can be written in the same manner as in the case of the cable 25. As described above, according to the present invention, a larger amount of information about the cable can be stored than before. Although the stored information will not be distinguishable after a long period of time after installation, for setting or maintenance, even bending It is also possible to provide a cable that is not easily broken and a connected body that can be easily installed on the cable. The present invention is not limited to the above-mentioned embodiments, and can be implemented in other forms by making appropriate changes. For example, the cables 25, 39, 53, 69 can be made into metal cables instead of optical fiber cables, and cables with mixed optical fibers and metal wires can also be used. [Simplified illustration of the drawings] Fig. 1 shows a connected body of the present invention. A perspective view of an embodiment. Fig. 2 is a schematic diagram showing a long body manufacturing apparatus for manufacturing the long body of Fig. 1; Fig. 3 is a cross-sectional view showing a first embodiment of the cable provided with the extended body shown in Fig. 1; Fig. 4 is a cross-sectional view showing a second embodiment of the cable provided with the continuous body shown in Fig. -21-(18) (18) 200423154. Fig. 5 is a cross-sectional view showing a third embodiment of the cable provided with the continuous body of Fig. 1; Fig. 6 is a cross-sectional view showing a fourth embodiment of the cable provided with the extended body shown in Fig. 1; [Comparison table of main components] 1 Long body 3 Band-shaped holding member 5 Radio frequency m RFID (RFID) device 7 Long body manufacturing device 9 Adhesive 11 Abutment 13 RFID component storage means 15 First storage means 17 Second storage Means 19 Adhesive coating means 2 1 Supply means 23 Paths 25 ^ 39, 53 ^ 69 Cables 27, 41, 55 > 71 Cable core 28 '59, 75 Tensile body 29, 43, 5 7, 73 Sheath 3 1, 6, 1 Slot -22- (19) (19) 200423154 33A to 33E, 63A to 63F Groove 35 Fiber ribbon 37, 51, 67, 81 Press into the winding body 4 5, 7 7 Tension member 47, 65, 79 optical fiber cord
-23·-twenty three·