1221686 (1) 玖、發明說明 【發明所屬之技術領域】 本發明有關於,使用於資訊終端機器或有關電腦機器 等的電子機器的同軸套用之扳彎加工時所使用之軸套加工 工模。 【先前技術】 以往將同軸電纜的端部做成連接器時,係將同軸電纜 與連接器予以結線由而可製成附同軸電纜的連接器。又也 準備收容連接器之套殼(housing)及收容套殻之軸套( shell)。並且以操作者的一方的手握持軸套,而軸套蓋的 成爲呈顯垂直的豎立於上方的姿勢地,且,以軸套主體的 底面全體抵接狀態地載置置於載置台上。而後由操作者一 面保持軸套之姿勢,一面以其他的手握持軸套插入於軸套 主體內,接著在於套殼內插入附同軸電纜的連接器被收容 之後,扳彎(傾倒)軸套蓋而以軸套蓋來封閉軸套主體之 頂面。而後將軸套移換於假鉚接(暫時鉚接)用之工模( Jig)而施予假鉚接,或由操作者提起軸套實施假鉚接,並 且由操作者實施這些一連串的加工處理後,實施正式的鉚接 製成連接器。 惟如上述的先前的方法,由操作者的一方的手將軸套 保持於預定的姿勢一面又以另一方之手實施連接器及套殻 之插入作業,同時實施軸套之傾倒(扳彎)作業的方法時, 由於操作者係需要同時實施種類不同之手作業,因此對於操 -5- (2) (2)1221686 作者係成爲很大的負擔,同時爲了實施假鉚接起見提起軸套 或移換到其他位置時,有時很容易發生軸套的脫落等所致的 不合宜的情形,由而先前的方法係成爲生產性及良品率不高 之方法。特別是這個情形乃在於使用攝子等工模來握持軸套 等各零件時特別顯著。 於是本發明乃提供一種,可以減輕軸套之加工處理時 之操作者的作業負擔,同時防止在於假鉚接時所發生之不合 宜之情形,由而可以提高生產性及良品率之軸套的加工工模 者。 【發明內容】 本發明的軸套加工工模乃,在於具備有,用於安裝收 容了附同軸電纜的連結器的套殼的軸套主體,及垂立於該 軸套主體的一方側,藉板彎至另一方側而可以封閉該軸套 主體的上面的軸套蓋而構成的,使用於加工軸套的軸套加 工工模,具有:備有平板狀的加工面,及使上述軸套蓋直 交於該加工面,將上述軸套成爲從上述軸套主體的一方側 而使另一方側成爲與推壓方向相一致的加工姿勢地予以保 持的軸套保持部的基板,以及,將上述保持於上述軸套保 持部的軸套的軸套蓋朝推壓方向推壓而予以披彎的扳彎機 構。 依上述構成時,如將軸套調定於基板之軸套保持部, 即雖然調定軸套時之定位精度低的情形下,仍然可以使軸 套蓋對於基板之加工面成直交,而從軸套主體的一方側將 另一方側地使之與推壓方向成一致的加工姿勢狀地可以調 -6 - (3) (3)1221686 定軸套。並且一面維持該加工姿勢一面藉扳彎機構將軸套 蓋推壓於推壓方向使之扳彎(傾倒)。由而使軸套蓋的對 於加工姿勢的調定作業以及軸套蓋的扳彎作業成爲很簡單 又操作者在實施軸套的調定於軸套保持部的調定作業 時,至少到軸套蓋的扳彎爲止的連接器之組合作業中,操作 員並不需要使用攝子而將軸套保持於加工姿勢,所以可以使 操作員的注意力集中,一方面可以防止各零件的位置關係的 偏差移位,同時可減輕操作員之精神負擔,結果可以提高生 產性以及良品率,特別是在於處理極小型的軸套時,更可以 顯著的提高效率及良品率。 又本發明之軸套加工工模乃上述扳彎機構係具備,其 移動方向係被限定於沿著上述基板之加工面的上述推壓方向 的軸套蓋推壓構件,及由上述軸套蓋推壓構件的推壓,使軸 套蓋扳彎地,使上述軸套蓋推壓構件進退移動於上述推壓方 向的推壓機構。 依上述構成時,藉推壓機構移動軸套蓋推壓構件就可 以沿著基板的加工面將軸套蓋推壓構件移動於推壓方向,由 而以軸套蓋推壓構件來推壓軸套蓋使之傾倒(扳彎),由而 很簡單的可以實施軸套蓋的扳彎(傾倒)作業。 又本發明的上述軸套蓋推壓構件,係備有抵接於上述 軸套蓋的外壁面的外壁面抵接部,該外壁面抵接部係使上面 側比下面側更接近於上述軸套蓋狀地傾斜。 依上述構成時,由於外壁面抵接部的上面側係比下面 (4) (4)1221686 側地接近於軸套蓋狀地傾斜形成,所以使外壁面抵接部抵接 於軸套蓋的外壁面地推壓時,在於抵接初期對於軸套蓋之上 側部份施加推壓力,結果,由於軸套蓋與軸套主體所連接部 (固定端部)與上側部份的大的距離,而會發生很大的轉矩 ,所以得以軸套蓋的固定端部做爲曲折點而很容易的扳彎軸 套蓋。並且軸套蓋開始傾倒時,軸套蓋推壓構件的外壁面抵 接部係一面面狀地抵接於軸套蓋一面推壓,所以充分的可以 防止軸套蓋的扳彎過程中的不合宜之折彎等情形。 又在於本發明的軸套加工工模係在於基板之加工面上 ,從上述軸套保持部到上述基板的端面且朝向上述推壓方向 地,形成有,收容上述同軸電纜的電纜收容部爲其特徵。 依上述構成時,只要將同軸電纜收容於同電纜收容部 ,就在於軸套蓋的扳彎作業中可以防止鈎掛電攬而使軸套的 加工姿勢弄亂之情形。 又本發明係具備有軸套固定機構,該軸套固定機構係 可從被保持於上述軸套保持部的上述軸套主體的上面抵接上 述軸套蓋的固定端。 依上述構成時,將軸套主體的上面與軸套固定機構抵 接就可以使軸套更確實的安裝於軸套固定部。又藉由從軸套 主體之上面抵接軸套蓋的固定端,而可使軸套的扳彎更爲確 實。 又本發明的軸套固定機構係具備有,自前端部到後端 地將其厚度增大的軸套固定構件,及使上述軸套固定構件的 前端部可以抵接於軸套蓋的內壁面地,沿著上述基板的加工 -8- (5) (5)1221686 面而可以使上述軸套固定構件移動的滑移機構。 依上述構成時,該軸套固定構件的厚度係在於軸套蓋 的固定端側成爲最薄,所以使軸套蓋呈顯充分大的傾倒角度 爲止,得以軸套固定構件一面支承一面予以扳彎(傾倒)。 由而可以確實的扳彎軸套蓋。 又,本發明係具備將藉由扳彎機構所披彎的軸套蓋假 鉚接於軸套主體的假鉚機構。 依上述構成時,可以免去將軸套移換到假鉚用的工模 以資實施假鉚接或在於扳彎軸套蓋後,操作者提起軸套實 施假鉚等以往的作業,而將軸套保持於軸套保持部的狀態下 簡單的可以實施,從扳彎軸套到實施假鉚接爲止的一連串的 作業,結果而言,可以免除軸套的提起的作業或移換到其他 的作業,由而可以防止在這些作業中的起因於軸套的脫落所 引起的不合宜的情形。 又本發明係具有,從下方頂出而排出該保持於上述軸 套保持部的上述軸套的軸套排出機構。 依此構成時,不藉操作者的手,很容易從軸套保持部 取出加工後之軸套。 【實施方式】 下面依據第1圖乃至第7圖說明本發明的實施形態的軸 套加工工模。 本實施形態之軸套加工工模係如第1圖所示,具備有 平面視長方形狀之基板1。基板1係具有備有平面狀的支承 -9 - (6) (6)1221686 面2a的支承台部2,及備有平面狀之加工面3 a的加工台部3 〇 加工台部3的加工面3a係,如第2圖所示據於比支承台 部2之支承面2a更上方之位置,同時對於支承面2a設定爲 平行。又’如第1圖所示,在於加工台部3的加工面3a的略 中央部配置有軸套保持部4。 ’ 上述的軸套保持部4係被形成得於保持第7圖的軸套 151 狀。 _ 本例中,軸套1 5 1係如第7圖所示,具有:收容套殼( housing) 130的軸套主體152,及成一體地設於軸套主體152 的軸套蓋153。 軸套主體152係具有套殼主收容部154及套殻副收容部 155。套殼主收容部154係可收容套殼主體131之上側套殼部 140及下側套殼部141狀地被形成爲上面及下面開口的圓筒形 狀。又套殻副收容部155係可收容套殻主體131的電纜收容部 142狀地被形成上面開口的箱型形狀。 · 另一方面,軸套蓋153係設於套殼主收容部153的上緣部 。軸套蓋153係面向於套殻副收容部155狀地被配置。在於連 接部153a而形成可以扳彎。 · 軸套蓋153係具備有:覆罩套殼主收容部154的上面的第 _ 1蓋部153b,及覆罩套殻副收容部155的上面的第2蓋部153 ’ 及壓接於同軸電纜120的遮蔽導體123之導體壓接部153d’以 及壓接於同軸電纜120的外皮122的外皮壓著部153e。並且扳 彎前的軸套蓋153係被做成對於套殻主收容部153呈顯呈垂直 -10- (7) (7)1221686 樹立的狀態,開放套殼主收容部154的上面而可以收容套殻 130。再者,當將軸套蓋構件153在於連接部153a予以扳彎而 扳彎(傾倒)於軸套主體152時,分別以第1蓋部153b及第2 蓋部153c罩覆收容於軸套主體152的套殼主體131的上側套殼 部140以及電纜收容部142的上面,同時,可以將導體壓接部 15 3d壓接於同軸電纜120的遮蔽導體123。 用於保持如上述地構成的軸套151的軸套保持部4係,如 第1圖所示具有:軸套收容孔4a及第1軸套蓋收容部4b,4b及 第2軸套蓋收容部4c。 軸套收容孔4a係如第4圖所示,從加工面3a朝下面貫穿 於垂直方向。軸套收容孔4a係可以嵌入第7圖之軸套主體152 之套殼主收容部154狀地被設定爲比套殼主收容部154稍大的 直徑。 另一方面,第1軸套蓋收容部4b,4b係以軸套主體收 # 容孔4a爲中心,左右方向對稱的配置於基板1的寬度方向。 這些第1軸套蓋收容部4b,4b係被形成爲當第7圖的軸套蓋 153之被扳彎時,可以收容第1蓋部153b狀。 又第2軸套蓋收容部4c係,在於軸套主體收容孔4a的 支承台部2側的相反側的領域而配置於基板1的長軸方向。第 2軸套蓋收容部4c係被形成爲,一方面收容部第7圖的套殼 副收容部155,同時扳彎軸套蓋153時可以收容軸套蓋153的 前端狀。 在於上述的軸套保持部4的支承台部2側配置有扳彎機 構5。扳彎機構5係具有,保持於軸套保持部4的軸套151的軸 -11 - (8) (8)1221686 套蓋153推壓於推壓方向而予以扳彎的功能。又本例的推壓 方向係指基板1的長軸方向的從支承面2a側朝向加工面3a側 的方向而言。 上述的扳彎機構係具有:使該前端部可以抵接於軸套 蓋153的外壁地形成的軸套蓋抵接機構6,及使軸套蓋抵接機 構6的前端部進退移動於推壓方向的推壓機構7。 軸套蓋抵接機構6係具有軸套蓋推壓構件8,及導框體9 ,導框體9係具有插通部9a,及配置於插通部9a的寬度方向 的兩側部的安裝部9b,9b。兩安裝部9b,9b係可固定導框體 9狀地繫結於加工台部3。插通部9a係與加工面,在於推壓方 向形成插通孔。以導框體9所形成的插通孔中,移動自如地 插通有軸套蓋推壓構件8。由而導框體9係,使軸套蓋推壓構 件8的前端部朝向軸套保持部4移動地將軸蓋推壓構件8引導 於推壓方向。 由上述導框體9所導引的軸套蓋推壓構件乃,如第5圖 也所示形成爲略長方體形狀。長方體形狀之軸套推壓構件8 乃被配置成爲其長軸方向係推壓方向相一致狀。軸套蓋推壓 構件8係具有,形成於軸套保持部4側的外壁面抵接部8a,及 形成於推壓機構7側的連結部8b,及形成於軸套蓋推壓構件8 的底部,並且滑動自如地抵接於加工台部3的加工面3a的底 面部8c。 外壁面抵接部3a係構成軸套蓋抵接機構6的前端部。外 壁面抵接部8a係配置在比底面部8c更上方位置。外壁面抵接 部8a的下面與底面部8c的級層(高度)差乃被設定爲,扳彎 -12 - 1221686 Ο) 後之軸套蓋15 3確實的接觸於軸套主體152,又可形成接觸狀 態地罩蓋該抵接於軸套主體152的軸套蓋153程度的間隙。 再者,如第6圖(a) ~ ( d)所示,外壁面抵接部8a係其 上面側比下面側更接近於軸套蓋1 53狀地被傾斜形成。具體 的說,外壁抵接部8a乃,其下側的傾斜面係以小的上昇角度 地被傾斜,上側的傾斜面即以很大的上昇角度予以傾斜。於 是外壁面抵接部8a乃,在對於軸套蓋153的抵接的初期,係 以上側的傾斜面來對於軸套蓋153的上側部份施予推壓力, 在於軸套蓋1 53之扳彎中期至扳彎後期乃,以下側的傾斜面 ,面狀的一面抵接於軸套蓋153—面施予推壓。 另一方面,如第1圖及第5圖所示,連結部8b係具有形成 於上下方向之鍵溝8d,鍵溝8d係被設定爲連結部8b的端面側 的溝寬,小於內部側的溝寬。在於連結部8b的鍵溝8d卡合了 連結螺絲10的頭部10a。連結螺絲10係連結於推壓機構7。 推壓機構7係具有:繫結於支承台部2的支承面2a的推壓 基體11,及,迴旋自如地軸支於推壓基體11,供操作員所握 持的握持部件12,以及由握持構件12的迴旋而進退移動於推 壓方向的推壓移動構件13。在於推壓移動構件13螺合上述的 連結螺絲10,並且推壓機構7乃當操作員所握持的握持構件 12,迴旋於上方向時,從推壓基體11中,推出推壓移動構件 13,由而將軸套推壓構件8的外壁面抵接部8a進出到軸套保 持部4的上方位置,另一方面當握持構件12迴旋於下方向時 將推壓移動構件13拉入於推壓基體11內,由而將軸套蓋推壓 構件8的外壁面抵接部8a後退到從軸套保持部4退避的位置。 •13- (10) (10)1221686 又,在於基板1的加工台部的加工面3a,形成有收容同 軸電纜120的電纜收容部14。電纜收容部14係被形成爲剖面 凹形狀,同時在於推壓方向,自軸套保持部4到基板1 (加工 台部3)的端面的被形成。在於加工台部3的端面側,設有防 止同軸電纜120的從電纜收容部14的脫落用的電纜壓接機構 15 ° 電纜壓接機構15係具有:薄板狀的電纜壓接板16,及 將電纜壓接板16固設於加工台部3的固定螺絲17。電纜壓接 板16係設置於加工台部3的寬方向,而由抵接於加工面3a的 上面部6a,及抵接於側面的側面部16b而形成爲L字形狀。電 纜壓接板16的上面部16a的長度乃被設定爲可以罩覆電纜收 容部14的長度。上面部16a的前端部係傾斜於上面。上面部 16a的前端與加工面的間隙乃,爲了使同軸電纜120容易進入 於電纜壓接板16與加工面3a間起見設定爲比同軸電纜120之 直徑更大的寬度。 在於上述電纜壓接機構15的支承台部2側,設置有軸套 固定機構18。軸套固定機構18係可以抵接於,從保持於軸套 保持部4的第7圖的軸套主體152的上面一直到做爲軸套蓋153 的固定端部的連接部153a,具體的說,軸套固定機構18係具 有:軸套固定構件19,及使軸套固定構件19的前端部19a可 以抵接於第7圖的軸套蓋153的內避面地可以將軸套固定構件 19沿著基板1的加工面3a移動的滑移機構20。 軸套固定構件19係被形成爲,自前端部到後部地厚度 的漸漸增大的角柱形狀。軸套固定構件19係當前端部19a抵 -14- (11) (11)1221686 接於軸套主體152的連接部15 3a時,得以該下面來壓接軸套 主體152的上面的被形成。 上述軸套固定構件19係設於滑移機構20上。 滑移機構20係具有:一端係迴旋自如地被軸支,在另 一端部移動自如地穿設有,軸套固定構件19的固定機構主體 21,及設於固定機構主體21的另一端部側的彈撥機構22。 上述的彈撥機構22係具有:形成於固定機構主體21的 軸套固定構件19的插通位置的長孔部22a,及介著長孔部22a 連接於軸套固定構件19的移動用螺絲23,設於長孔部22a的 長徑方向的固定螺絲24,以及張架於移動用螺絲23與固定螺 絲24間的第1彈簧構件25。 第1彈簧構件25係將軸套固定構件19彈撥於,將軸套固 定構件19的前端部19a拉入於固定機構主體21內之方向。並 且彈撥機構22乃構成爲,當作業者使軸套固定構件19從固定 機構主體2 1進出之後藉減弱該使之進出的推壓力而可能做到 隨著軸套蓋153的被傾倒(扳彎)而使軸套固定構件19一面 抵接於軸套蓋一面使之慢慢地後退。由而彈撥機構22係可以 發揮雖然軸套固定構件19的前端部19a並沒有垂直地抵接於 軸套蓋153的連接部153a的情形下,仍然可以容且確實軸套 蓋153的扳彎的功能。 · 上述滑移機構20係藉止轉機構3 8來限制其迴旋角度。 止轉機構38係具有第1止轉構件26及第2止轉構件27。 第1止轉構件26係設於支承台部2的寬度方向的一方側, (滑移機構20側),第1止轉構件26係當固定機構主體21被 -15- (12) (12)1221686 迴旋成爲將軸套固定構件19離開軸套保持部4,由而固定機 構21移動於完全脫離電纜收容部的位置時,得禁止固定機構 21的迴旋者。 另一方面,第2止轉構件27係設於支承台部2的寬度方向 的另一方側(與滑移機構20側的相反側)。第2止轉構件27 係迴旋於固定機構主體21係迴旋於軸套保持部4方向。而當 軸套固定構件19的前端部19a抵接於軸套主體152的連接部 153a時,將固定機構主體21的端面21a抵接於前端面27a由而 禁止迴旋者。又除了第2止轉構件27之外,再在於固定機構 主體21的迴旋方向側,設置,與第1止轉構件26同樣的止轉 構件也可以。此時就可以確實的停止固定機構主體21的迴旋 〇 又,以軸套保持部4爲中心的加工台部3的寬度方向的 兩側,左右對稱地設置有,將藉扳彎機構5所扳彎的軸套 蓋153假鉚接於軸套主體152的假鉚機構28· 28。各假鉚機 構28係如第3圖所示具有:從軸套保持部4的第2軸套蓋 收容部4c的側面到加工台部3的側面的形成的假鉚棒插通 孔3b,及移動自如地插通於假鉚棒插通孔3b的假鉚棒29, 以及假鉚棒移動構件3 0。 上述假鉚棒29係被形成該前端部29b可以進入於第2軸 套蓋收容部4c,同時後端部即從假鉚棒插通孔3b而突出於 外部。在於假鉚(接)棒29的突出方向配設有假鉚棒移動 構件30。 假鉚棒移動構件3 0係被形成爲棒狀。假鉚棒移動構件 -16 - (13) (13)1221686 3〇的固定端部乃如第1圖所示,迴轉自如地軸支於加工台 部3的側面。並且假鉚棒移動構件3 0係由操作員所握持’ 沿著加工台部3方向地被迴旋時,藉該胴部抵接於假鉚棒 29的後端部,由而使假鉚棒29移動於第2軸套蓋收容部4c 方向(假鉚接方向),而可以使前端部29b進入於第2軸 套蓋收容部4c內。 又,假鉚機構28係如第3圖所示,具有第2彈簧構件31 及假鉚棒擋止器3 2,第2彈簧構件3 1係設在假鉚棒29的前 端部29b側。另一方端係抵接於假鉚棒29的胴部,另一方 端係抵接於假鉚棒插通孔3b。並且第2彈簧構件3 1係,當 假鉚棒29前進於假鉚方向時,使假鉚棒29彈撥於後退方向 。又在於假鉚棒29的下面,形成有卡合凹部2 9a.在於卡合 凹部29a滑動自如地卡合有,固設於加工台部3的假鉚棒擋 止器32。並且假鉚棒擋止器32及卡合凹部29a係決定假鉚 棒29的進退移動於假鉚方向時的前進端及後退端。又前進 端係設定於以假鉚棒29來實施假鉚接時的最適宜的位置。 再者,在於軸套保持部4的下方,設有藉從下方頂舉 軸套151由而排出軸套的軸套排出機構33。軸套排出機構 33係如第4圖所示,具有軸套排出棒34,軸套排出棒34係 移動自如地插通於形成於推壓方向的軸套排出孔3c。軸套 排出孔3 c係配置於電纜收容部1 4的下方。而從加工台部3 的端面而能通過軸套保持部4的軸套收容孔4a狀地形成於 水平。 插通於上述軸套排出孔3c的軸套排出棒34係該前端部 •17· (14) (14)1221686 的水平支承面34a係據於軸套保持部4的下方位置。水平支 承面34a係形成於比橫設狀態的軸套排出棒34的胴部上面 低的位置。 並且水平支承面34a與胴部上面係由傾斜於預定角度 的傾斜支承面34b所連絡。另一方面軸套排出棒34的後端 部係從軸套排出孔3c突出,在於軸套排出棒34的後端部, 設有由操作者可能握持的推壓把手35。推壓把手35上抵接 有第3彈簧構件3 6的一端。第3彈簧構件3 6係外插於軸套排 出棒34,軸套排出棒34的另一端係抵接於軸套排出孔3c內 之預定位置。並且第3彈簧構件36係當軸套排出棒34介著 推壓把手35推入於軸套排出孔3c內時,將軸套排出棒34彈 撥於相反方向而使之推回。 又,軸套排出棒34的下面形成有卡合凹部34c。在於 卡合凹部34c滑動自如地卡合有,固設於加工台部3的軸套 排出棒擋止器37,並且軸套排出棒擋止器37及卡合凹部 34c係決定軸套排出棒34進退移動軸套排出孔3c內時的前 進端及後退端。又前進端係被設定爲軸套排出棒3 4的胴部 上面據於軸套保持部4的位置。另一方面,後退端係被設 定爲,軸套排出棒34的水平支承面34a與軸套保持部4相一 致狀。 再者,軸套排出機構33係在於軸套保持部4而具有軸 套排出構件40及第4彈簧構件41。軸套排出構件40係昇降 自如地嵌插於軸套收容孔4a,下端係以軸套排出棒34的水 平支承面34a所支承。又第4彈簧構件41係將軸套排出構件 •18- (15) (15)1221686 40彈撥於下方。並且如此地構成的軸套排出機構33係當推 壓推壓把手3,而軸套排出棒34被推壓於軸套排出孔3c內 時,可以使軸套排出構件40由水平支承面34a沿著傾斜支 承面3 4b上昇由而將保持於軸套保持部4的軸套151推出由 而予以排出。 在於上述的構成說明軸套加工工模動作。 · (準備過程) β 首先如第7圖所示,準備,附同軸電纜120的連接器 101,及套殼130以及軸套151。具體的說,將與載體一齊 捲成卷狀的連接器101調定於送出裝置。據於前端側的連 接器101係裝置於爲實施熔接作業用的固定具上。並且施予 剝皮加工的同軸電纜120係移動至固定具的連接器101的上方 。而使其中心軸體121抵接於連接器101的結線部102狀的, 將同軸電纜120調定於連接器101。而後藉錫焊將中心導體 1 2 1結線於結線部1 〇2。而從不圖示的載體切離就可以製成附 φ 同軸電纜的連接器101。 再者,準備對應於套殻130的外形的模穴的射鑄模。將 射鑄模設定於射出成形機,將備有絕緣性的粒狀的合成樹脂 材料供給於射出成形機,而製成套殼1 30,又以壓製加工裝 置等對於帶狀薄板實施沖壓及扳彎加工而製成軸套151。 如上所述地製成的同軸連接器用連接器101,套殼主體 131及軸套151係多數個分別收容於各零件箱。並且這些零 件箱係運送至載置了第1圖的軸套加工工模的作業台。 -19- (16) (16)1221686 (零件調定過程) 同軸連接器用連接器101等的零件的準備完了後,首 先操作員係使用攝子等握持具來握持第7圖的軸套151,而 如第1圖所示調定於基板1的軸套保持部4。此時設如調定 軸套151時的定位精度不高時,仍然只要將套殻主收容部 154嵌入於軸套收容孔4a,且將套殼副收容部155嵌入於第 2軸套蓋收容部4c,就可以調定成爲,軸套蓋153對於基 板1的加工面成直交,從軸套主體1 5 2的一方側到另一方側 朝向於與推壓方向相一致之加工姿勢。 接著,以握持具握持套殼130,插入於軸套151的套殻 主收容部154。接著將附同軸電纜120的同軸連接器用連接 器101插入於套殻主體131,接著如第7圖所示扳彎套殼蓋 1 3 2的固定端,由而套殻蓋1 3 2係扳彎(傾倒)至套殼主體 131側,由而閉合套殼蓋132,於是同軸連接器用連接器1 的上方係由套殼蓋13 2所覆罩。此後,如第1圖所示,將同 軸電纜120插入於電纜壓接板16的上面部16a與加工台部3 的加工面3a之間,於是加工面3a上的全同軸電纜120係被 收容於電纜收容14。 由上述操作,同軸電纜120係被收容於電纜收容部14 內,所以在於以後的作業中,可以使同軸電纜120不容易 鈎掛於操作員的手等。同時,萬一發生鈎掛於操作員的手 時,由於覆罩電纜收容部14狀地配置了電纜壓接板16,所 以可以防止同軸於作業中同軸電纜120的從電纜部14脫落 •20- (17) (17)1221686 的情形。結果而言,可防防止由於作業中同軸電纜的被移 動所致的同軸電纜連接器用連接器101,或套殻130,軸套 151的加工姿勢發生偏差等等不合宜情形的發生。 (軸套蓋扳彎(傾倒)過程) 如上所述地完成零件的調定過程之後,軸套固定機構 18的固定機構主體21係被迴旋至軸套保持部4的方向。並 且如第6圖(a)所示,由於操作員將移動螺絲23推壓至軸 套殼保持部4方向,由而設於固定機構主體21的另一端的 軸套殼固定構件19的先端部19a,係抵接於調定於軸套保 持部4的軸套蓋153的連接部153a (固定端部)的內壁面。 又,軸套固定構件19的前端部抵接(碰接)於連接部 153a時,軸套固定構件19的前端部19a會抵接於軸套主體 152的上面,由而以軸套固定構件19壓接軸套主體152,而 軸套151的加工姿勢的調定將更爲確實。 接著,如第2圖所示,握持構件1 2係自圖示的實線位 置迴旋於上方向,軸套蓋推壓構件8係進出於固定機構主 體21方向。並且如第6圖(a)所示,軸套蓋推壓構件8的 外壁面抵接部8a係抵接於軸套藍153的外壁面。此時由於 軸套蓋推壓構件8係其外壁面抵接部8a的上面側,能比下 面側更可以近接於軸套蓋狀被傾斜,所以當外壁面抵接部 8a抵接於軸套蓋153的外壁面,開始推壓時,在抵接初期 即對於軸套蓋153的上側部份(從連接部153 a隔開的部位 )施加推壓力。此結果,由於連接部153a與軸套蓋153的 -21 - (18) (18)1221686 上側部份的很大距離而發生很大的扭矩,同時由於連接部 153 a的內壁面係由軸套固定構件19所支承,所以以連接部 153a爲折曲點地容易扳彎軸套蓋153。 接著,如第6圖(a ) , ( b )所示,將軸套蓋1 5 3以大 角度地扳彎,即軸套蓋推壓構件8的外壁面抵接部8a的下 側部份係一方面面狀地抵接軸套蓋1 53 —面繼續推壓’結 果充分的可以防止軸套蓋153的扳彎過程中的不合宜的折 曲等。再者,在於軸套蓋153的扳彎過程中,由於配置於 軸套蓋153的扳彎側的軸套固定構件19係其厚度被形成爲 在於軸套蓋153的連接部153 a側成爲最薄的狀態。由而軸 套蓋1 53係由軸套固定構件1 9支承到可以達到充分大的扳 彎角度爲止,所以軸套蓋153可以確實的實施扳彎。 又從內壁面側支承軸套蓋1 53的軸套固定構件1 9係由於 操作員採用比第1彈簧構件25的彈撥力大的推壓力而推壓於 進出方向所支承,所以隨著軸套蓋153的傾倒而操作員放鬆 推壓力時,軸套固定構件19係藉第1彈簧構件25的彈撥力而 一面抵接於軸套蓋153—面慢慢的後退。此結果,設使軸套 固定構件19的前端部並沒有垂直的抵接於軸套蓋153的連接 部153a的情形之下,仍然可以確實的實施軸套蓋153的扳彎 〇 當軸套蓋1 53被扳彎到預定大的傾倒角度(例如從垂直 方向60度)時,第2圖的握持構件12的上昇會停止,於是暫 時地停止軸套蓋推壓構件8的進出。並且由操作員的釋放推 壓由而如第6圖(d)所示,而軸套固定構件19係由於第1彈 •22- (19) (19)1221686 簧構件25的彈撥力而從軸套蓋153的連接部153a。此後第2圖 的握持構件1 2係上昇到圖示二點鏈鎖線之位置,而再開始軸 套蓋推壓構件8的再開,於是軸套蓋153係被扳彎到抵接於軸 套蓋主體152,同時由於軸套蓋153係在於外壁面抵接部8a的 下面,由軸套主體152所推壓,因而成爲不容易回到原來的 垂立狀態。此後如第1圖所示,固定機構主體21被迴旋於相 反方向而回復至圖示實線的候命位置。 又本實施形態中,該軸套固定構件1 9的退避,動作係 採取,暫時停止軸套蓋推壓構件8的進出地實施,惟連續 的實施亦可以。 (假鉚接過程) 接著,如第1圖所示,維持以軸套蓋推壓構件8壓接軸 套蓋153的狀態下,啓動假鉚機構28 · 28。詳述之,以操 作員握持假鉚機構2 8 · 2 8的兩假鉚棒移動構件3 0 · 3 0,迴 旋於基板1方向。由而如第3圖所示,而假鉚棒移動構件30 • 30係將假鉚棒29· 29移動於屬於軸套保持部4方向的假 鉚接方向,於是假鉚棒29· 29的前端部29· 29係進出於第 2軸套蓋收容部4c內。此時,在第2軸套蓋收容部4c的假 鉚棒29· 29的進出前方係由於上述第2軸套蓋153的扳倒 動作而存在有第7圖所示的第2蓋部153c的兩端部。該結果 ,第2蓋部153c的兩端部係由假鉚棒29 · 2 9而由外側而挾 入地被推壓而施予第2蓋部153c的兩端部的繞入於套殻副 收容部1 5 5的假鉚接作業。又實施假鉚接的結果,暫且可以 -23- (20) (20)1221686 固定在於軸套151內的套殼130,連接器101以及同軸電纜120 的位置關係,所以被施予相當的外力之狀態下仍然不會發生 各位置的偏移。 (排出過程) 完成假鉚接後,假鉚棒移動構件30 · 30即被處於自由狀 態。 於是藉第2彈簧構件31 · 31的彈撥力而假鉚棒移動構件 30· 30後退,假鉚棒移動構件30· 30的前端部係由第2軸套 蓋收容部4c而被退避。又,如第1圖所示,握持構件12係從 第2圖的二點鏈鎖線位置而下降至實線位置,由於軸套蓋推 壓構件8離開軸套保持部4,於是開放該軸套保持部4的上方 〇 接著,如第4圖所示,操作員握持推壓把手35推壓於基 板1方向,由而將軸套棒出棒34插入於軸套排出孔3c內,結 果被支承於軸套排出棒34的水平支承面34a的軸套排出構件 40係沿著傾斜支承面34b上昇,由而頂舉調定於該軸套排出 構件40的上方的軸套151,而可以從軸套保持部4排出。 此後由操作員握持被施予假鉚接的軸套151,移送至下 一過程的正式鉚接過程,並且在於此正式鉚接過程中,如第 7圖所示對於,覆罩了絕緣體124的第2蓋部153c的兩端部充 分的施加折彎,實施壓接,同時將遮蔽導體123及外皮122分 別壓著於導體壓接部153及外皮壓接部153e,由而製成同軸 連接器61。 -24· (21) (21)1221686 如上所述本實施形態的軸套加工工模乃,具有在於具 備有,用於安裝收容了附同軸電纜120的連結器101的套殼 130的軸套主體152,及垂立於該軸套主體152的一方側, 藉板彎至另一方側而可以封閉該軸套主體152的上面的軸 套蓋1 5 3而構成的’使用於加工軸套1 5 1的軸套加工工模’ 具有:備有平板狀的加工面3a,及使上述軸套蓋153直交 於該加工面3a,將上述軸套151成爲從上述軸套主體152的 一方側而使另一方側成爲與推壓方向相一致的加工姿勢地 予以保持的軸套保持部4之基板1,以及,將上述保持於上 述軸套保持部4的軸套151的軸套蓋153推壓於推壓方向而 予以披彎的扳彎機構5而構成。 依上述構成時,如將軸套151調定於基板1之軸套保持 部4,即雖然調定軸套1 5 1時之定位精度低的情形下,仍然 可以使軸套蓋153對於基板1之加工面3 a成直交,而從軸套 主體1 52的一方側將另一方側地使之與推壓方向成一致的 加工姿勢狀地可以調定軸套151。並且一面維持該加工姿 勢一面藉扳彎機構5將軸套蓋153推壓於推壓方向使之扳彎 (傾倒)。由而使軸套蓋1 53的對於加工姿勢的調定作業 以及軸套蓋153的扳彎作業成爲很簡單化。 又操作者在實施軸套151的調定於軸套保持部4的調定 作業時,至少到軸套蓋153的扳彎爲止的連接器之組合作業 中,操作員並不需要使用例如攝子而將軸套151保持於加工 姿勢,所以可以使操作員的注意力集中,一方面可以防止各 零件的位置關係的偏差移位,同時可減輕操作員之精神負擔 -25· (22) (22)1221686 ,結果可以提高生產性以及良品率,特別是在於處理極小型 的軸套時,更可以顯著的提高效率及良品率。 又本實施形態中上述扳彎機構5係具備,其移動方向係 被限定於沿著上述基板1之加工面3a的上述推壓方向的軸套 蓋推壓構件8,及由上述軸套蓋推壓構件8的推壓,使軸套蓋 153扳彎地,使上述軸套蓋推壓構件8進退移動於上述推壓方 向的推壓機構7而構成。 依上述構成時,藉推壓機構7移動軸套蓋推壓構件8就 可以沿著基板1的加工面3a將軸套蓋推壓構件8移動於推壓方 向,由而以軸套蓋推壓構件8來推壓軸套蓋153使之傾倒(扳 彎),由而很簡單的可以實施軸套蓋153之扳彎(傾倒)作 業。 又本實施形態的上述軸套蓋推壓構件8,係備有抵接於 上述軸套蓋153的外壁面的外壁面抵接部8a,該外壁面抵接 部8a係上面側係比下面側更接近於上述軸套蓋153狀的被傾 斜而構成。 依上述構成時,由於外壁面抵接部8a的上面側係比下面 側地接近於軸套蓋1 53狀地被傾斜地形成,所以使外壁面抵 接部8a抵接於軸套蓋153的外壁面地推壓時,在於抵接初期 對於軸套蓋1 5 3之上側部份施加推壓力,結果,由於軸套蓋 153與軸套主體152所連接部153a (固定端部)與上側部份的 大的距離,而會發生很大的轉矩,所以得以軸套蓋153的固 定端部做爲曲折點而很容易的扳彎軸套蓋丨53。並且軸套蓋 153開始傾倒時,軸套蓋推壓構件8的外壁面抵接部8a係一面 •26- (23) (23)1221686 面狀地抵接於軸套蓋153—面推壓,所以充分的可以防止軸 套蓋153的扳彎過程中的不合宜之折彎等情形。 又在於本實施形態的軸套加工工模係,在於基板1之加 工面3a上,從上述軸套保持部4到上述基板1的端面且朝向上 述推壓方向地,形成有,收容上述同軸電纜120的電纜收容 部14而構成。 依上述構成時,只要將同軸電纜120收容於同電纜收容 部14,就在於軸套蓋153的扳彎作業中可以防止鈎掛電纜120 而使軸套1 5 1的加工姿勢弄亂之情形。 又本實施形態的軸套加工工模係具備有軸套固定機構 18,該軸套固定機構18係被構成可能抵接於保持於上述軸套 保持部的上述軸套主體152的上面,一直到上述軸套蓋153的 固定端而構成。 依上述構成時,將軸套主體152的上面抵接於軸套固定 機構18就可以使軸套151更確實的調定於軸套固定部18。又 從軸套主體152之上面一直到軸套蓋153的連接部15 3a地予以 抵接,由而使軸套153的扳彎更成爲確實。 又本實施形態的軸套固定機構18係具備有,自前端部 19a到後端地將其厚度增大的軸套固定構件19,及使上述軸 套固定構件19的前端部19a可以抵接於軸套蓋153的內壁面地 ,沿著上述基板1的加工面3a而可以使上述軸套固定構件19 移動的滑移機構20而構成。 依上述構成時,該軸套固定構件19的厚度係在於軸套 蓋153的連接部153a側成爲最薄,所以使軸套蓋153呈顯充分 -27- (24) (24)1221686 大的傾倒角度爲止,得以軸套固定構件19 一面支承一面予以 扳彎(傾倒)。由而可以確實的扳彎軸套蓋153。 又,本實施形態係具備將藉由扳彎機構5所披彎的軸 套蓋153假鉚接於軸套主體152的假鉚機構28 · 28而構成。 依上述構成時,可以免去將軸套151移換到假鉚用的 工模以資實施假鉚接,或在於扳彎軸套蓋153後,操作者提 起軸套151實施假鉚等以往的作業,而將軸套151保持於軸套 保持部4的狀態下簡單的可以實施,從扳彎軸套151到實施假 鉚接爲止的一連串的作業,結果而言,可以免除軸套151的 提起的作業或移換到其他的作業,由而可以防止在這些作業 中的起因於軸套151的脫落所引起的不合宜的情形。 又本實施形態的軸套加工工模係具有,從下方頂出, 該保持於上述軸套保持部4的上述軸套151,由而排出的軸套 排出機構33而構成。 依此構成時,不藉操作者的手,很容易從軸套保持部4 取出加工後之軸套151也。 上面依照合宜的實施形態說明了本發明,惟本發明係 在不超越其技術精神的範圍內可以做種種變更。 例如本實施形態中,第1彈簧構件25係採用將軸套固定 構件19的前端部19a拉入於固定機構主體21內地彈撥軸套固 定構件19爲例,惟不侷限於此方式,將軸套固定構件19的前 端部19a彈撥於從固定機構主體21進出的方向亦可以。 依上述構成時,彈撥機構22乃可以發揮’吸收當藉滑 移機構20而軸套固定構件19抵接於連接部153a時的衝擊的功 -28- (25) (25)1221686 能,及發揮將軸套固定構件19以對於軸套151的位置關係中 予以微調整且定位的功能。以及發揮隨著軸套蓋153的被扳 彎(傾倒)而使軸套固定構件19一面抵接於軸套蓋153—面 慢慢地後退,由而如果軸套固定構件19的前端部19a雖然沒 有垂直地抵接於軸套蓋153的連接部153a的情形下仍然很容 易且確實的實施軸套蓋153的扳彎的功能。 由而在於軸套蓋扳彎過種中當固定機構主體21被迴旋 於軸套保持部4方向。而如第6圖(a)所示設於固定機構主 體21的另一端部的軸套固定構件19的前端部19a抵接於軸套 蓋153的連接部153a時可達成下述之效果。 詳述之,如第1圖所示,軸套固定構件19係一面被施予 彈撥機構22的第1彈撥機構22的第1彈簧構件25的彈撥力一面 進退自如於推壓方向地被支承。所以例如由經年的使用而第 2止轉構件27鬆緩,固定機構主體21過度的迴旋於軸套保持 部4側時,仍然可以將軸套固定構件19定位於最適宜的位置 ,同時可以吸收軸套固定構件19抵接於軸套151的連接部 15 3a時的衝擊,而可以防止軸套151的破損。 再者,在於軸套蓋153的扳彎過程中,操作者將移動用 螺絲23推壓於進出方向的情形下,由於隨著軸套蓋153的傾 倒而軸套固定構件19係一面抵接於軸套蓋153—面慢慢的自 動地後退,所以可以達成減少作業過程的效果。 (產業上的利用可能性) 上面所說明的軸套加工工模係可以適用於同軸連接器 -29 - (26) (26)1221686 用的軸套的扳彎(傾倒)加工的用途。 【圖式簡單說明】 第1圖表示軸套加工工模之平面圖。 第2圖表示軸套加工工模之平面圖。 第3圖表示第1圖之A-A線剖面圖。 - 第4圖表示軸套排出機構之槪略說明圖。 第5圖表示軸套加工工模之分解斜視圖。 鲁 第6圖表示使軸套蓋扳彎之過程之說明圖,第6圖(a )表示軸套蓋之扳彎初期之狀態,第6圖(b)表示軸套蓋 之扳彎中期之狀態,第6圖(c)表示軸套蓋之扳彎後期之 狀態,第6圖(d )表示軸套蓋之扳彎末期之狀態。 第7圖表示同軸套之被組合狀態之說明圖。 [主要元件對照表] 1 基板 2 支承台部 2 a 支承面 3 力口工台部 3 a 加工面 3b 假鉚棒插通孔 3 c 軸套排出孔 4 軸套保持部 4 a 軸套收容孔 -30- (27)1221686 4b 軸 套 蓋 收 容 部 4 c 軸 套 蓋 收 容部 5 扳 彎 機 構 6 軸 套 蓋 抵 接 機 構 7 推 壓 機 構 8 軸 套 蓋 推 壓 構 件 8 a 外 壁 面 抵 接 部 8b 連 結 部 8 c 底 面 部 8d 鍵 溝 9 導 框 體 9 a 安 裝 部 ( 插 通 部) 9b 安 裝 部 ( 插 通 部) 10 連 結 螺 絲 10a 頭 部 11 推 壓 基 am 體 12 握 持 構 件 13 推 壓 移 動 構 件 14 電 纜 收 容 部 15 電 纜 壓 接 機 構 16 電 纜 壓 接 板 16a 上 面 部 16b 側 面 部 17 固 定 螺 絲1221686 (1) 发明. Description of the invention [Technical field to which the invention belongs] The present invention relates to a bushing processing tool used for the bending process of a coaxial sleeve used in an electronic device such as an information terminal device or a computer device. [Prior Art] Conventionally, when the end of a coaxial cable is made into a connector, the coaxial cable and the connector are connected to form a connector with a coaxial cable. A housing for housing the connector and a shell for housing the housing are also prepared. The shaft sleeve is held by one hand of the operator, and the cover of the sleeve cover is vertically erected upward, and is placed on the mounting table with the entire bottom surface of the sleeve body abutting. Then the operator holds the sleeve while holding the sleeve with other hands and inserts it into the sleeve body. Then, after the connector with the coaxial cable is inserted into the sleeve and is accommodated, the sleeve is bent (dumped). The cover covers the top surface of the sleeve body with a sleeve cover. Then, the sleeve is replaced with a jig for false riveting (temporary riveting), and the dummy riveting is performed, or the operator lifts the sleeve to perform the false riveting, and the operator performs these series of processing and then implements Formal riveting makes the connector. Only in the previous method described above, one side of the operator holds the sleeve in a predetermined posture, and the other hand performs the insertion of the connector and the casing, and at the same time, the sleeve is tilted (turned) In the method of operation, since the operator needs to perform different types of hand work at the same time, the author becomes a heavy burden for operating -5- (2) (2) 1221686, and at the same time, lift the sleeve or When transferring to another position, it is easy to cause unsuitable situations such as the falling of the sleeve, and the previous method has become a method with low productivity and poor yield. This is particularly the case when using tools such as a camera to hold parts such as the hub. Therefore, the present invention provides a bushing processing that can reduce the operator's workload during the processing of the bushing and prevent the unfavorable situations that occur during false riveting, thereby improving the productivity and yield of the bushing. Workers. [Summary of the Invention] The bushing processing mold of the present invention is provided with a bushing body for mounting a housing housing a connector with a coaxial cable, and a shaft body standing on one side of the bushing body. A bushing processing mold used for processing a bushing, which is formed by bending a plate to the other side so as to close the upper surface of the bushing main body, has a flat-shaped processing surface, and the bushing is provided. The cover is orthogonal to the processing surface, and the sleeve is a substrate of a sleeve holding portion which is held from one side of the sleeve main body and the other side is held in a processing posture consistent with the pressing direction; and A bending mechanism that pushes a bushing cover of a bushing held by the bushing holding portion in a pushing direction to bend. According to the above configuration, if the sleeve is adjusted to the sleeve holding portion of the substrate, that is, although the positioning accuracy is low when the sleeve is adjusted, the sleeve cover can still be orthogonal to the processing surface of the substrate, and One side of the sleeve main body can be adjusted to -6-(3) (3) 1221686 by adjusting the processing posture of the other side to match the pressing direction. And while maintaining the processing posture, the shaft cover is pushed (thrown over) by pushing the shaft cover in the pushing direction by the turning mechanism. As a result, the adjustment operation of the bushing cover for the processing posture and the bending operation of the bushing cover are very simple. When the operator performs the adjustment operation of the bushing to the bushing holding portion, the operator must at least reach the bushing. In the combined operation of the connector until the cover is turned, the operator does not need to use the camera to maintain the sleeve in the processing posture, so that the operator's attention can be focused, and on the one hand, the positional relationship between the parts can be prevented from deviating. Displacement can reduce the operator's mental burden at the same time. As a result, productivity and yield can be improved. Especially when handling very small shaft sleeves, the efficiency and yield can be significantly improved. In addition, the bushing processing die of the present invention is provided with the above-mentioned bending mechanism, and its moving direction is limited to the bushing cover pressing member along the pushing direction along the processing surface of the substrate, and the bushing cover The pressing mechanism of the pressing member pushes the sleeve cover to bend, and moves the bearing cover pressing member forward and backward in the pressing direction. According to the above structure, by moving the sleeve cover pressing member by the pressing mechanism, the sleeve cover pressing member can be moved in the pressing direction along the processing surface of the substrate, and the sleeve cover pressing member is used to push the sleeve. The cover can be tilted (tipped), so that it is easy to perform the turning (tilt) operation of the sleeve cover. In addition, the sleeve cover pressing member of the present invention is provided with an outer wall surface abutting portion that abuts on an outer wall surface of the sleeve cover, and the outer wall surface abutting portion makes the upper surface side closer to the shaft than the lower surface side. The cover is inclined like a cover. According to the above configuration, since the upper side of the outer wall surface abutting portion is inclined closer to the sleeve cover side than the lower surface (4) (4) 1221686, the outer wall surface abutting portion is abutted against the shaft cover. When the outer wall surface is pushed, the upper part of the sleeve cover is pushed at the initial contact time. As a result, due to the large distance between the connecting portion (fixed end) of the sleeve cover and the sleeve body and the upper portion, A large torque will occur, so the fixed end of the sleeve cover can be used as a turning point to easily bend the sleeve cover. In addition, when the sleeve cover starts to fall, the outer wall surface abutment portion of the sleeve cover pressing member abuts on the surface of the sleeve cover in a plane shape, so it can sufficiently prevent the shaft cover from being bent during the bending process. Appropriate bending, etc. Also, the bushing processing mold of the present invention is formed on the processing surface of the substrate, and is formed from the bushing holding portion to the end surface of the substrate and facing the pressing direction, and a cable receiving portion for housing the coaxial cable is formed thereon. feature. According to the above configuration, as long as the coaxial cable is accommodated in the same cable receiving portion, it is possible to prevent the processing posture of the sleeve from being disturbed by hooking the electric bracket during the bending operation of the sleeve cover. The present invention is also provided with a bushing fixing mechanism which abuts a fixed end of the bushing cover from an upper surface of the bushing body held by the bushing holding portion. With the above configuration, the upper surface of the sleeve main body is brought into contact with the sleeve fixing mechanism, so that the sleeve can be more surely mounted on the sleeve fixing portion. By abutting the fixed end of the sleeve cover from the top of the sleeve body, the bending of the sleeve can be made more reliable. Further, the sleeve fixing mechanism of the present invention includes a sleeve fixing member that increases its thickness from the front end portion to the rear end, and the front end portion of the sleeve fixing member can abut against the inner wall surface of the sleeve cover. Ground, a sliding mechanism capable of moving the above-mentioned bushing fixing member along the processing -8- (5) (5) 1221686 plane of the above-mentioned substrate. According to the above configuration, the thickness of the bushing fixing member is that the fixed end side of the bushing cover becomes the thinnest, so that the bushing fixing member can be bent while supporting and supporting the bushing cover at a sufficiently large tilting angle. (Dumping). Therefore, the shaft cover can be reliably bent. The present invention is also provided with a false riveting mechanism for falsely riveting a sleeve cover bent by a bending mechanism to a sleeve main body. According to the above structure, it is possible to eliminate the need to transfer the sleeve to a false riveting tool to perform false riveting or to bend the sleeve cover, and then the operator lifts the sleeve to perform the conventional operations such as false riveting, and replaces the shaft. The sleeve can be easily carried out while the sleeve is held by the sleeve holding portion. A series of operations from the bending of the sleeve to the false riveting can be performed. As a result, the lifting operation of the sleeve or the replacement of the sleeve can be eliminated. Thus, it is possible to prevent unfavorable situations caused by the falling of the sleeve in these operations. The present invention further includes a bushing ejection mechanism for ejecting the bushing held by the bushing holding portion from below. With this configuration, it is easy to take out the processed bushing from the bushing holding portion without the operator's hand. [Embodiment] A bushing working mold according to an embodiment of the present invention will be described below with reference to Figs. 1 to 7. As shown in Fig. 1, the sleeve processing tool of this embodiment is provided with a substrate 1 having a rectangular shape in plan view. The substrate 1 has a support table portion 2 provided with a planar support -9-(6) (6) 1221686 surface 2a, and a processing table portion 3 provided with a planar processing surface 3a. Processing of the processing table portion 3 The surface 3a is located at a position higher than the support surface 2a of the support base portion 2 as shown in FIG. 2 and is set to be parallel to the support surface 2a. As shown in Fig. 1, a sleeve holding portion 4 is arranged at a substantially central portion of the processing surface 3a of the processing table portion 3. The above-mentioned sleeve holding portion 4 is formed to hold the sleeve 151 in the shape shown in FIG. 7. _ In this example, as shown in FIG. 7, the bushing 1 5 1 includes a bushing body 152 for housing a housing 130 and a bushing cover 153 integrally provided on the bushing body 152. The sleeve body 152 includes a sleeve main receiving portion 154 and a sleeve sub receiving portion 155. The main casing accommodating portion 154 is a cylindrical shape that can accommodate the upper casing portion 140 and the lower casing portion 141 of the casing body 131 and has an upper surface and a lower surface. The casing sub-receiving portion 155 is a box-like shape having an upper surface opened in a cable receiving portion 142 that can accommodate the casing main body 131. · On the other hand, the sleeve cover 153 is provided on the upper edge portion of the main housing accommodating portion 153. The sleeve cover 153 is arranged in a shape facing the sleeve sub accommodating portion 155. The connection portion 153a is formed so as to be bendable. The bushing cover 153 is provided with a first cover portion 153b covering the upper surface of the main housing receiving portion 154, a second cover portion 153 'covering the upper surface of the sub housing receiving portion 155, and a crimped coaxially The conductor crimping portion 153 d ′ of the shield conductor 123 of the cable 120 and the sheath crimping portion 153 e crimped to the sheath 122 of the coaxial cable 120. In addition, the sleeve cover 153 before the bending is made to be vertical to the main housing receiving portion 153 -10- (7) (7) 1221686, and it can be accommodated by opening the upper part of the main housing receiving portion 154. Case 130. In addition, when the sleeve cover member 153 is bent at the connection portion 153a and is bent (fall over) to the sleeve body 152, the first cover portion 153b and the second cover portion 153c are covered and accommodated in the sleeve body, respectively. At the same time, the upper casing portion 140 of the casing body 131 and the upper surface of the cable accommodation portion 142 of the casing body 131 can be crimped with the conductor crimping portion 15 3d to the shield conductor 123 of the coaxial cable 120. The bushing holding portion 4 for holding the bushing 151 configured as described above includes a bushing receiving hole 4a and first bushing cover receiving portions 4b, 4b and a second bushing cover, as shown in FIG. 1. Department 4c. As shown in Fig. 4, the sleeve housing hole 4a penetrates the vertical direction from the working surface 3a downward. The sleeve receiving hole 4a is set to a slightly larger diameter than the sleeve main receiving portion 154 so that the sleeve main receiving portion 154 of the sleeve main body 152 shown in Fig. 7 can be fitted. On the other hand, the first sleeve cover accommodating portions 4b, 4b are arranged symmetrically in the width direction of the substrate 1 with the center of the sleeve body receiving hole 4a as the center. These first sleeve cover accommodating portions 4b, 4b are formed so that the first cover portion 153b can be accommodated when the sleeve cover 153 of Fig. 7 is turned. Further, the second sleeve cover accommodating portion 4c is arranged in the long axis direction of the substrate 1 in a region on the side opposite to the support table portion 2 side of the sleeve main body accommodating hole 4a. The second sleeve cover accommodating portion 4c is formed so that the sleeve housing sub-receiving portion 155 of the accommodating portion shown in FIG. 7 can receive the front end of the sleeve cover 153 when the sleeve cover 153 is bent. A bending mechanism 5 is arranged on the support base portion 2 side of the sleeve holding portion 4 described above. The bending mechanism 5 has a function of pressing the sleeve cover 153 of the shaft 151 of the sleeve 151 held by the sleeve holding portion 4 in a pressing direction to perform a bending. The pressing direction in this example refers to a direction from the support surface 2a side to the processing surface 3a side in the long axis direction of the substrate 1. The above-mentioned turning mechanism includes a sleeve cover abutment mechanism 6 formed so that the front end portion can abut against the outer wall of the sleeve cover 153, and the front end portion of the sleeve cover abutment mechanism 6 is moved forward and backward to press. Directional pushing mechanism 7. The bushing cover abutment mechanism 6 includes a bushing cover pressing member 8 and a guide frame 9. The guide frame 9 has an insertion portion 9a and is mounted on both sides of the insertion portion 9a in the width direction. Section 9b, 9b. The two mounting portions 9b and 9b are fixed to the processing table portion 3 in such a manner that the guide frame body 9 can be fixed. The insertion portion 9a is formed on the processing surface, and the insertion hole is formed in the pressing direction. A bushing cover pressing member 8 is inserted through the insertion hole formed by the guide frame body 9 freely. Accordingly, the guide frame 9 is configured to guide the shaft cover pressing member 8 in the pressing direction by moving the front end portion of the shaft cover pressing member 8 toward the shaft holding portion 4. The sleeve cover pressing member guided by the guide frame 9 is formed in a slightly rectangular parallelepiped shape as shown in FIG. 5. The rectangular parallelepiped-shaped bushing pushing member 8 is arranged so that its long axis direction is consistent with the pushing direction. The sleeve cover pressing member 8 includes an outer wall surface contact portion 8a formed on the sleeve holding portion 4 side, a connecting portion 8b formed on the pressing mechanism 7 side, and a sleeve cover pressing member 8 formed thereon. The bottom is slidably abutted against the bottom surface portion 8c of the processing surface 3a of the processing table portion 3. The outer wall surface contact portion 3 a constitutes a front end portion of the sleeve cover contact mechanism 6. The outer wall surface contact portion 8a is disposed above the bottom surface portion 8c. The difference in level (height) between the lower surface of the outer wall surface abutting portion 8a and the bottom surface portion 8c is set so that the sleeve cover 15 3 after the bending is -12-1221686 0) is surely in contact with the sleeve body 152. A gap is formed so as to cover the sleeve cover 153 that is in contact with the sleeve body 152 in a contact state. Further, as shown in Figs. 6 (a) to (d), the outer wall surface abutting portion 8a is formed obliquely closer to the sleeve cover 153 than the lower surface side. Specifically, the outer wall abutment portion 8a is inclined at a lower rising angle at a lower rising angle, and the inclined surface at an upper side is inclined at a larger rising angle. Therefore, the outer wall surface abutment portion 8a is an inclined surface on the upper side to apply a pressing force to the upper portion of the sleeve cover 153 at the initial stage of contact with the sleeve cover 153. During the middle to late bending period, the inclined surface on the lower side and the planar side abut against the sleeve cover 153—the surface is pressed. On the other hand, as shown in FIGS. 1 and 5, the connecting portion 8 b has a key groove 8 d formed in the up-down direction, and the key groove 8 d is set to have a groove width on the end face side of the connecting portion 8 b, which is smaller than that on the inner side. The ditch is wide. The key groove 8d of the connection portion 8b engages the head portion 10a of the connection screw 10. The connection screw 10 is connected to the pressing mechanism 7. The pressing mechanism 7 includes a pressing base 11 bound to the support surface 2 a of the support base portion 2, a pivoting member 11 rotatably supported by the pressing base 11, a holding member 12 held by the operator, and The pressing moving member 13 that moves forward and backward in the pressing direction by rotating the gripping member 12. The pressing moving member 13 is screwed with the above-mentioned connection screw 10, and the pressing mechanism 7 is pushed out from the pressing base 11 when the holding member 12 held by the operator rotates in the upward direction. 13. The outer wall surface abutment portion 8a of the sleeve pressing member 8 is thereby brought in and out of the upper position of the sleeve holding portion 4. On the other hand, when the holding member 12 is rotated in the downward direction, the pressing moving member 13 is pulled in In the pressing base 11, the outer wall surface contact portion 8 a of the sleeve cover pressing member 8 is retracted to a position retracted from the sleeve holding portion 4. • 13- (10) (10) 1221686 A cable receiving portion 14 is formed on the processing surface 3a of the processing table portion of the substrate 1 to receive the coaxial cable 120. The cable accommodating portion 14 is formed in a concave shape in the cross section, and at the same time, it is formed in the pressing direction from the sleeve holding portion 4 to the end surface of the substrate 1 (processing table portion 3). On the end surface side of the processing table portion 3, a cable crimping mechanism 15 for preventing the coaxial cable 120 from falling off from the cable accommodating portion 14 is provided. The cable crimping mechanism 15 includes: a thin plate-shaped cable crimping plate 16; The cable crimping plate 16 is fixed to a fixing screw 17 of the processing table portion 3. The cable crimping plate 16 is provided in the width direction of the processing table portion 3, and is formed in an L shape by an upper surface portion 6a abutting on the processing surface 3a and a side surface portion 16b abutting on the side surface. The length of the upper surface portion 16a of the cable crimping plate 16 is set to a length that can cover the cable accommodation portion 14. The front end portion of the upper surface portion 16a is inclined upward. The clearance between the front end of the upper surface portion 16a and the processing surface is set to be larger than the diameter of the coaxial cable 120 so that the coaxial cable 120 can easily enter between the cable crimping plate 16 and the processing surface 3a. A sleeve fixing mechanism 18 is provided on the support base portion 2 side of the cable crimping mechanism 15 described above. The bushing fixing mechanism 18 is capable of abutting from the upper surface of the bushing body 152 held in the bushing holding portion 4 in FIG. 7 to the connecting portion 153a serving as a fixed end portion of the bushing cover 153, specifically, The bushing fixing mechanism 18 includes a bushing fixing member 19 and a front end portion 19a of the bushing fixing member 19 can abut the inner avoiding surface of the bushing cover 153 in FIG. A sliding mechanism 20 that moves along the processing surface 3 a of the substrate 1. The bushing fixing member 19 is formed in a shape of an angle pillar which gradually increases in thickness from the front end portion to the rear portion. The bushing fixing member 19 is formed when the front end portion 19a abuts the connection portion 15 3a of the bushing body 152 with the front end 19a. The upper surface of the bushing body 152 is crimped to the lower surface. The sleeve fixing member 19 is provided on the sliding mechanism 20. The sliding mechanism 20 includes: one end is rotatably supported by a shaft, and the other end is movably inserted; a fixing mechanism main body 21 of a sleeve fixing member 19; and the other end side of the fixing mechanism main body 21的 弹弹 机构 22. The above-mentioned plucking mechanism 22 includes an elongated hole portion 22a formed at the insertion position of the sleeve fixing member 19 of the fixing mechanism body 21, and a moving screw 23 connected to the sleeve fixing member 19 via the long hole portion 22a. The fixing screw 24 provided in the longitudinal direction of the long hole portion 22 a and the first spring member 25 stretched between the moving screw 23 and the fixing screw 24. The first spring member 25 is a direction in which the bushing fixing member 19 is spring-pushed, and the front end portion 19a of the bushing fixing member 19 is drawn into the fixing mechanism body 21. In addition, the plunger mechanism 22 is structured so that when the operator causes the sleeve fixing member 19 to come in and out from the fixing mechanism body 21, it is possible to reduce the pushing force of the sleeve fixing member 19 as the sleeve cover 153 is tilted (turned ) While making the sleeve fixing member 19 abut against the sleeve cover, it is slowly retracted. As a result, the plucking mechanism 22 can play a role in which, although the front end portion 19a of the sleeve fixing member 19 does not abut the connection portion 153a of the sleeve cover 153 vertically, the sleeve cover 153 can still be tolerated. Features. · The above-mentioned sliding mechanism 20 is limited by the rotation preventing mechanism 38 to its turning angle. The rotation prevention mechanism 38 includes a first rotation prevention member 26 and a second rotation prevention member 27. The first rotation preventing member 26 is provided on one side in the width direction of the support base portion 2 (the sliding mechanism 20 side), and the first rotation preventing member 26 is used as the fixing mechanism body 21 by -15- (12) (12) 1221686 The swivel becomes the rotator of the fixing mechanism 21 when the sleeve fixing member 19 is separated from the sleeve holding portion 4 and the fixing mechanism 21 is moved away from the cable accommodation portion completely. On the other hand, the second rotation preventing member 27 is provided on the other side in the width direction of the support base portion 2 (the side opposite to the side of the sliding mechanism 20). The second rotation preventing member 27 is rotated around the fixing mechanism main body 21 and is rotated around the sleeve holding portion 4. On the other hand, when the front end portion 19a of the sleeve fixing member 19 is in contact with the connecting portion 153a of the sleeve main body 152, the end surface 21a of the fixing mechanism body 21 is brought into contact with the front end surface 27a to prevent the gyrator. In addition to the second rotation preventing member 27, a rotation preventing member similar to the first rotation preventing member 26 may be provided on the rotation direction side of the fixing mechanism body 21. At this time, the rotation of the fixing mechanism main body 21 can be reliably stopped. The widthwise sides of the processing table portion 3 centered on the sleeve holder portion 4 are provided symmetrically on the left and right sides. The bent bushing cover 153 is falsely riveted to the false riveting mechanism 28 · 28 of the bushing body 152. Each dummy riveting mechanism 28 includes a dummy riveting rod insertion hole 3b formed from the side of the second sleeve cover accommodating portion 4c of the sleeve holding portion 4 to the side of the processing table portion 3 as shown in FIG. 3, and The dummy rivet rod 29 and the dummy rivet rod moving member 30 are freely inserted into the dummy rivet rod insertion hole 3b. The dummy rivet rod 29 is formed so that the front end portion 29b can enter the second sleeve cover accommodating portion 4c, and the rear end portion projects from the dummy rivet rod insertion hole 3b to the outside. A dummy riveting rod moving member 30 is arranged in a protruding direction of the dummy riveting (joining) rod 29. The pseudo-rivet rod moving member 30 is formed in a rod shape. The dummy riveting rod moving member -16-(13) (13) 1221686 30 has a fixed end portion pivotably supported on the side of the processing table portion 3 as shown in Fig. 1. In addition, when the false rivet rod moving member 30 is held by the operator 'while being turned in the direction of the processing table portion 3, the dummy rivet rod 29 is brought into contact with the rear end portion of the dummy rivet rod 29, thereby causing the dummy rivet rod 29 to be rotated. The front end portion 29b can be moved into the second sleeve cover accommodating portion 4c by moving in the direction (false swaging direction) of the second sleeve cover accommodating portion 4c. As shown in Fig. 3, the dummy riveting mechanism 28 includes a second spring member 31 and a dummy riveting rod stopper 32, and the second spring member 31 is provided on the front end portion 29b side of the dummy riveting rod 29. The other end is in contact with the crotch portion of the dummy rivet rod 29, and the other end is in contact with the dummy rivet insertion hole 3b. In addition, the second spring member 31 is configured to cause the dummy rivet rod 29 to spring in the backward direction when the dummy rivet rod 29 is advanced in the false rivet direction. On the lower surface of the dummy rivet rod 29, an engaging recessed portion 29a is formed. The engaging recessed portion 29a is slidably engaged with the dummy rivet rod stopper 32 fixed to the processing table portion 3. In addition, the pseudo-rivet bar stopper 32 and the engaging recess 29a determine the forward end and the backward end when the forward and backward movement of the pseudo-rivet bar 29 moves in the pseudo-rivet direction. The forward end is set at the most suitable position when the false riveting is performed with the dummy riveting rod 29. Further, a sleeve discharge mechanism 33 is provided below the sleeve holding portion 4 by lifting the sleeve 151 from below to discharge the sleeve. As shown in FIG. 4, the sleeve discharge mechanism 33 has a sleeve discharge rod 34, and the sleeve discharge rod 34 is movably inserted into a sleeve discharge hole 3c formed in the pressing direction. The bushing discharge hole 3 c is arranged below the cable accommodation portion 14. On the other hand, a sleeve receiving hole 4a that can pass through the sleeve holding portion 4 from the end surface of the processing table portion 3 is formed horizontally. The bushing discharge rod 34 inserted into the bushing discharge hole 3c is the front end portion. The horizontal support surface 34a of the front end portion • 17 (14) (14) 1221686 is located below the bushing holding portion 4. The horizontal support surface 34a is formed at a position lower than the upper surface of the crotch portion of the sleeve discharge rod 34 in the horizontally-arranged state. The horizontal support surface 34a and the upper surface of the crotch are connected by an inclined support surface 34b inclined at a predetermined angle. On the other hand, the rear end portion of the sleeve discharge rod 34 protrudes from the sleeve discharge hole 3c, and the rear end portion of the sleeve discharge rod 34 is provided with a push handle 35 which may be held by an operator. One end of the pressing handle 35 is in contact with the third spring member 36. The third spring member 36 is externally inserted into the bushing discharge rod 34, and the other end of the bushing discharge rod 34 is abutted to a predetermined position in the bushing discharge hole 3c. In addition, the third spring member 36 pushes the sleeve discharge rod 34 in the opposite direction when the sleeve discharge rod 34 is pushed into the sleeve discharge hole 3c via the pushing handle 35, and pushes it back. An engagement recess 34c is formed on the lower surface of the sleeve discharge rod 34. The engagement recessed portion 34c is slidably engaged with the sleeve discharge rod stopper 37 fixed to the processing table 3, and the sleeve discharge rod stopper 37 and the engagement recessed portion 34c determine the sleeve discharge rod 34. The forward end and the backward end when the bushing discharge hole 3c is moved forward and backward. Further, the forward end is set as the upper surface of the crotch portion of the sleeve discharge rod 3 4 according to the position of the sleeve holding portion 4. On the other hand, the receding end is set so that the horizontal support surface 34a of the sleeve discharge rod 34 matches the sleeve holding portion 4. The sleeve discharge mechanism 33 includes a sleeve discharge member 40 and a fourth spring member 41 in the sleeve holding portion 4. The bushing discharge member 40 is inserted into the bushing accommodation hole 4a so as to be lifted and lowered, and the lower end is supported by the horizontal bearing surface 34a of the bushing discharge rod 34. And the fourth spring member 41 is a spring ejection member • 18- (15) (15) 1221686 40 plucked below. The bushing ejection mechanism 33 configured as described above can push the bushing ejection member 40 along the horizontal support surface 34a when the bushing ejection rod 34 is pushed into the bushing ejection hole 3c. The inclined bearing surface 3 4b is raised to push out the sleeve 151 held by the sleeve holding portion 4 to be discharged. The above-mentioned configuration will explain the operation of the bushing processing mold. · (Preparation process) β First, as shown in Fig. 7, prepare the connector 101 with the coaxial cable 120, the housing 130, and the shaft sleeve 151. Specifically, the connector 101 rolled into a roll shape with the carrier is set in the delivery device. The connector 101 on the front end side is mounted on a fixture for performing a welding operation. The coaxial cable 120 subjected to the peeling process is moved above the connector 101 of the fixture. And the coaxial cable 120 is adjusted to the connector 101 by making the central axis body 121 contact the junction part 102 of the connector 101. Then, the center conductor 1 2 1 is connected to the junction portion 102 by soldering. On the other hand, a carrier (not shown) can be cut to form a connector 101 with a φ coaxial cable. Furthermore, an injection mold corresponding to the cavity of the outer shape of the case 130 is prepared. The injection mold is set in an injection molding machine, and an insulating granular synthetic resin material is supplied to the injection molding machine to form a casing 1 30, and a strip-shaped sheet is subjected to pressing and bending processing by a press processing device, etc. And made into a sleeve 151. The coaxial connector 101 manufactured as described above has a plurality of housing bodies 131 and a shaft sleeve 151 respectively housed in each component box. And these parts are transported to the worktable on which the bushing processing tool of Fig. 1 is placed. -19- (16) (16) 1221686 (part adjustment process) After the preparation of parts such as the connector 101 for the coaxial connector is completed, the operator first uses a gripper such as a camera to hold the sleeve 151 in FIG. 7 As shown in FIG. 1, it is set on the sleeve holding portion 4 of the substrate 1. At this time, if the positioning accuracy when setting the sleeve 151 is not high, it is still only necessary to embed the sleeve main receiving portion 154 into the sleeve receiving hole 4a, and insert the sleeve auxiliary receiving portion 155 into the second sleeve cover. The portion 4c can be set such that the sleeve cover 153 intersects the processing surface of the substrate 1 at right angles, and faces from one side to the other side of the sleeve body 152 toward a processing posture consistent with the pressing direction. Next, the cover case 130 is held by a holder, and is inserted into the cover main receiving portion 154 of the sleeve 151. Next, insert the connector 101 for the coaxial connector with the coaxial cable 120 into the casing body 131, and then, as shown in FIG. 7, the fixed end of the casing cover 1 3 2 is bent, and the casing cover 1 3 2 is bent. (Pour down) to the casing main body 131 side, thereby closing the casing cover 132, so that the upper part of the coaxial connector connector 1 is covered by the casing cover 132. Thereafter, as shown in FIG. 1, the coaxial cable 120 is inserted between the upper surface portion 16a of the cable crimping plate 16 and the processing surface 3a of the processing table portion 3. Thus, the all-coaxial cable 120 on the processing surface 3a is housed in Cable accommodation 14. With the above-mentioned operation, the coaxial cable 120 is housed in the cable accommodating portion 14, so that the coaxial cable 120 can be prevented from being easily caught by the operator's hand or the like in subsequent operations. At the same time, in the event of hooking in the operator's hand, the cable crimping plate 16 is arranged in a shape covering the cable receiving portion 14 so that the coaxial cable 120 can be prevented from falling off the cable portion 14 coaxially during work. 20- (17) (17) 1221686. As a result, it is possible to prevent the occurrence of unfavorable situations such as the deviation of the processing posture of the coaxial cable connector 101, the casing 130, and the sleeve 151 caused by the coaxial cable being moved during operation. (Sleeve Cover Turning (Tilting) Process) After the component setting process is completed as described above, the fixing mechanism main body 21 of the sleeve fixing mechanism 18 is turned to the direction of the sleeve holding portion 4. As shown in FIG. 6 (a), the operator pushes the moving screw 23 in the direction of the sleeve housing holding portion 4, so that the front end portion of the sleeve housing fixing member 19 provided at the other end of the fixing mechanism body 21 is provided. 19a is an inner wall surface which abuts on the connection portion 153a (fixed end portion) of the sleeve cover 153 set to the sleeve holding portion 4. When the front end portion of the bushing fixing member 19 abuts (abuts) on the connection portion 153a, the front end portion 19a of the bushing fixing member 19 abuts on the upper surface of the bushing body 152, thereby fixing the member 19 with the bushing. The sleeve body 152 is crimped, and the processing posture of the sleeve 151 can be adjusted more accurately. Next, as shown in FIG. 2, the holding member 12 is rotated in the upward direction from the solid line position shown in the figure, and the sleeve cover pressing member 8 is inserted into the direction of the main body 21 of the fixing mechanism. Further, as shown in FIG. 6 (a), the outer wall surface contact portion 8a of the bushing cover pressing member 8 is in contact with the outer wall surface of the bushing blue 153. At this time, since the sleeve cover pressing member 8 is the upper side of the outer wall surface abutment portion 8a, it can be inclined closer to the sleeve cover than the lower side, so when the outer wall surface abutment portion 8a abuts on the sleeve When the outer wall surface of the cover 153 starts to be pressed, a pressing force is applied to the upper portion of the sleeve cover 153 (the portion separated from the connection portion 153 a) in the initial contact period. As a result, a large torque occurs due to the large distance between the connecting portion 153a and the upper portion of the bushing cover 153-(18) (18) 1221686, and at the same time, the inner wall surface of the connecting portion 153a is covered by the bushing. Since the fixing member 19 is supported, the sleeve cover 153 can be easily bent with the connection portion 153a as a bending point. Next, as shown in Figs. 6 (a) and (b), the bushing cover 1 5 3 is bent at a large angle, that is, the lower part of the outer wall surface abutment portion 8a of the bushing cover pressing member 8 On the one hand, the abutment of the sleeve cover 1 53 in a planar shape is continued, and the result is that the surface can continue to be pressed, which can sufficiently prevent undesired bending and the like during the bending process of the sleeve cover 153. Furthermore, during the turning of the bushing cover 153, the thickness of the bushing fixing member 19 arranged on the turning side of the bushing cover 153 is formed so that the connecting portion 153a of the bushing cover 153 becomes the most thick. Thin state. As a result, the bushing cover 153 is supported by the bushing fixing member 19 until a sufficiently large turning angle can be reached, so the bushing cover 153 can surely perform the turning. The bushing fixing member 19 supporting the bushing cover 153 from the inner wall surface side is supported by the operator in the direction of entry and exit by using a pushing force larger than the plucking force of the first spring member 25. When the cover 153 is toppled and the operator relaxes the pushing pressure, the sleeve fixing member 19 is abutted against the sleeve cover 153 by the spring force of the first spring member 25, and the surface is slowly retracted. As a result, if the front end portion of the bushing fixing member 19 does not abut the connection portion 153a of the bushing cover 153 vertically, the turning of the bushing cover 153 can still be performed reliably. When 1 53 is pulled to a predetermined large tilting angle (for example, 60 degrees from the vertical direction), the lifting of the gripping member 12 in FIG. 2 is stopped, and the entrance and exit of the sleeve cover pressing member 8 is temporarily stopped. In addition, as shown in FIG. 6 (d) by the operator's release and pushing, the sleeve fixing member 19 is driven from the shaft due to the plucking force of the first bullet 22- (19) (19) 1221686 spring member 25. The connecting portion 153a of the cover 153. Thereafter, the holding member 12 in FIG. 2 is raised to the position of the two-point chain lock line shown in the figure, and the re-opening of the sleeve cover pressing member 8 is started, so the sleeve cover 153 is bent to abut the shaft sleeve. At the same time, the cover body 152 is located under the outer wall surface abutting portion 8a and is pushed by the sleeve body 152, so that it is not easy to return to the original standing state. Thereafter, as shown in Fig. 1, the fixing mechanism body 21 is turned in the opposite direction and returned to the standby position shown by the solid line in the figure. In this embodiment, the retraction and action of the bushing fixing member 19 is taken to temporarily stop the entry and exit of the bushing cover pressing member 8, but continuous execution is also possible. (False riveting process) Next, as shown in FIG. 1, the dummy riveting mechanism 28 · 28 is activated while the sleeve cover 153 is crimped with the sleeve cover pressing member 8. In detail, the operator holds two dummy rivet rod moving members 3 0 · 30 of the dummy riveting mechanism 2 8 · 2 8 and rotates in the direction of the substrate 1. Therefore, as shown in FIG. 3, the dummy riveting rod moving member 30 • 30 moves the dummy riveting rod 29 · 29 in the direction of the dummy riveting which belongs to the 4 direction of the sleeve holding portion, so the front end portion of the dummy riveting rod 29 · 29 29 · 29 is inserted into the second sleeve cover accommodating portion 4c. At this time, the entrance and exit of the dummy rivets 29 · 29 in the second sleeve cover accommodating portion 4c is caused by the second cover portion 153c shown in FIG. Both ends. As a result, both end portions of the second cover portion 153c are pushed in from the outside by the dummy rivets 29 · 29, and the end portions of the second cover portion 153c are wound around the casing pair. The false riveting operation of the receiving section 1 5 5. As a result of the implementation of false riveting, for the time being -23- (20) (20) 1221686 can be fixed in the position relationship between the sleeve 130, the connector 101 and the coaxial cable 120 in the shaft sleeve 151, so a state of considerable external force is applied The position will still not shift. (Discharge process) After the false riveting is completed, the dummy riveting rod moving member 30 · 30 is placed in a free state. Then, the pseudo-rivet rod moving members 30 · 30 are retracted by the plucking force of the second spring members 31 · 31, and the front end portion of the pseudo-rivet rod moving members 30 · 30 is retracted by the second sleeve cover housing portion 4c. As shown in FIG. 1, the holding member 12 is lowered from the two-point chain-locking position in FIG. 2 to the solid line position. Since the sleeve cover pressing member 8 leaves the sleeve holding portion 4, the shaft is opened. Above the sleeve holding portion 4 As shown in FIG. 4, the operator holds the pushing handle 35 and pushes it in the direction of the substrate 1 to insert the sleeve rod out rod 34 into the sleeve discharge hole 3 c. The bushing discharge member 40 supported by the horizontal support surface 34 a of the bushing discharge rod 34 rises along the inclined support surface 34 b, and lifts up the bushing 151 set above the bushing discharge member 40, so that It is discharged from the sleeve holding portion 4. The operator then holds the shaft sleeve 151 to which the false riveting has been applied, and transfers it to the formal riveting process of the next process, and during this formal riveting process, as shown in FIG. 7, the second part covered with the insulator 124 Both ends of the cover portion 153c are sufficiently bent and crimped, and at the same time, the shield conductor 123 and the sheath 122 are pressed against the conductor crimping portion 153 and the sheath crimping portion 153e, respectively, thereby forming the coaxial connector 61. -24 · (21) (21) 1221686 As described above, the sleeve processing mold of the present embodiment is provided with the sleeve body provided with the sleeve 130 for mounting the connector 101 with the coaxial cable 120 attached therein. 152, and a sleeve cover 1 5 3 which is erected on one side of the sleeve body 152 and can be closed by bending the plate to the other side, which is used for processing the sleeve 1 5 The sleeve machining tool 1 includes a flat plate-shaped working surface 3a, the sleeve cover 153 is orthogonally intersected to the processing surface 3a, and the sleeve 151 is formed from one side of the sleeve body 152. The other side becomes the base plate 1 of the sleeve holding portion 4 held in a processing posture corresponding to the pressing direction, and the sleeve cover 153 of the sleeve 151 held by the sleeve holding portion 4 is pressed against The bending mechanism 5 is formed by pressing in a direction and bending. According to the above configuration, if the sleeve 151 is adjusted to the sleeve holding portion 4 of the substrate 1, that is, although the positioning accuracy when the sleeve 1 51 is adjusted is low, the sleeve cover 153 can still be made to the substrate 1 The machining surface 3 a is orthogonal, and the machining process can be performed by setting the bushing 151 from one side of the bushing body 152 to the other side so that the machining posture is aligned with the pressing direction. And while maintaining the processing posture, the sleeve cover 153 is pushed by the bending mechanism 5 in the pressing direction to bend (tilt). As a result, the setting operation of the bushing cover 153 for the processing posture and the bending operation of the bushing cover 153 are simplified. In addition, when the operator performs the adjustment operation of the sleeve 151 to the sleeve holding portion 4, the operator does not need to use, for example, a camera to perform a combination operation of at least the connector until the sleeve cover 153 is turned. Keeping the sleeve 151 in the processing posture can focus the operator's attention. On the one hand, it can prevent the deviation of the positional relationship of each part from shifting, and it can reduce the operator's mental burden. -25 · (22) (22) 1221686, the result can improve productivity and yield, especially when processing very small shaft sleeves, it can significantly improve efficiency and yield. Further, in the present embodiment, the bending mechanism 5 is provided, and its moving direction is limited to a sleeve cover pressing member 8 along the pressing direction along the processing surface 3a of the substrate 1, and the sleeve cover is pushed by the sleeve cover. The pressing of the pressing member 8 causes the sleeve cover 153 to be bent, and the pressing mechanism 7 is configured to move the sleeve cover pressing member 8 forward and backward in the pressing direction. With the above configuration, by moving the sleeve cover pressing member 8 by the pressing mechanism 7, the sleeve cover pressing member 8 can be moved in the pressing direction along the processing surface 3a of the substrate 1, so that the sleeve cover is pressed by the sleeve cover. The component 8 pushes the sleeve cover 153 to fall (toggle), so that the bending (falling) of the sleeve cover 153 can be easily performed. In addition, the sleeve cover pressing member 8 of this embodiment is provided with an outer wall surface abutment portion 8a that abuts against an outer wall surface of the sleeve cover 153, and the outer wall surface abutment portion 8a is on the upper side and on the lower side. It is configured to be inclined closer to the above-mentioned sleeve cover 153. In the above configuration, since the upper surface side of the outer wall surface contact portion 8a is formed obliquely closer to the sleeve cover 153 than the lower surface side, the outer wall surface contact portion 8a is brought into contact with the outside of the sleeve cover 153. When the wall surface is pushed, the upper part of the bushing cover 1 5 3 is pushed at the initial contact time. As a result, the connecting part 153a (fixed end) and the upper part of the bushing cover 153 and the bushing body 152 The large distance will cause a large torque, so the fixed end of the sleeve cover 153 can be used as a turning point to easily bend the sleeve cover 53. And when the bushing cover 153 starts to fall, the outer wall surface abutting portion 8a of the bushing cover pressing member 8 is one side. 26- (23) (23) 1221686 is abutted flatly against the bushing cover 153, Therefore, it is possible to sufficiently prevent unsuitable bending and the like during the bending process of the sleeve cover 153. In the bushing processing mold system of the present embodiment, the processing surface 3a of the substrate 1 is formed to receive the coaxial cable from the bushing holding portion 4 to the end surface of the substrate 1 and facing the pressing direction. It is comprised by the cable accommodation part 14 of 120. With the above configuration, as long as the coaxial cable 120 is accommodated in the same cable accommodation portion 14, it is possible to prevent the cable 120 from being caught and the processing posture of the sleeve 151 being disturbed during the bending operation of the sleeve cover 153. In addition, the sleeve processing mold of the present embodiment is provided with a sleeve fixing mechanism 18 which is configured to be in contact with the upper surface of the sleeve main body 152 held by the sleeve holding portion until it reaches The fixed end of the sleeve cover 153 is configured. With the above configuration, the upper surface of the sleeve main body 152 is brought into contact with the sleeve fixing mechanism 18, so that the sleeve 151 can be more accurately adjusted to the sleeve fixing portion 18. The contact of the shaft cover 153 from the upper surface of the shaft cover body 152 to the connection portion 15 3a of the shaft cover 153 is made, so that the turning of the shaft cover 153 can be made more reliable. Further, the sleeve fixing mechanism 18 of the present embodiment is provided with a sleeve fixing member 19 that increases its thickness from the front end portion 19a to the rear end, and the front end portion 19a of the sleeve fixing member 19 can abut against The inner wall surface of the sleeve cover 153 is constituted by a slide mechanism 20 that can move the sleeve fixing member 19 along the processing surface 3 a of the substrate 1. According to the above configuration, the thickness of the sleeve fixing member 19 is the thinnest on the side of the connecting portion 153a of the sleeve cover 153, so that the sleeve cover 153 is sufficiently full. -27- (24) (24) 1221686 At this angle, the bushing fixing member 19 can be bent (tilted) while supporting. Thereby, the shaft cover 153 can be reliably bent. In addition, the present embodiment is provided with a dummy riveting mechanism 28 · 28 for falsely riveting the sleeve cover 153 bent by the bending mechanism 5 to the sleeve main body 152. According to the above structure, the conventional operations such as replacing the sleeve 151 to a false riveting tool to perform false riveting can be eliminated, or after the sleeve cover 153 is bent, the operator lifts the sleeve 151 and performs false riveting. In the state where the sleeve 151 is held in the sleeve holding portion 4, it can be easily implemented. A series of operations from bending the sleeve 151 to performing false riveting can be eliminated. As a result, the lifting operation of the sleeve 151 can be eliminated. Or it can be shifted to other work, thereby preventing the unfavorable situation caused by the fall of the shaft sleeve 151 in these work. Further, the bushing processing mold of the present embodiment includes a bushing ejection mechanism 33 which is pushed out from below, and the bushing 151 held by the bushing holding portion 4 is discharged. With this configuration, it is easy to take out the processed sleeve 151 from the sleeve holding portion 4 without using the operator's hand. The present invention has been described above with reference to a suitable embodiment, but the present invention can be modified in various ways without departing from the technical spirit thereof. For example, in this embodiment, the first spring member 25 is an example in which the front end portion 19a of the sleeve fixing member 19 is pulled into the fixing mechanism main body 21 and the sleeve fixing member 19 is plucked. However, the method is not limited to this. The front end portion 19 a of the fixing member 19 may be snapped in a direction in which the fixing mechanism body 21 is moved in and out. With the above structure, the plucking mechanism 22 can perform the function of absorbing the impact when the sleeve fixing member 19 abuts against the connecting portion 153a by the sliding mechanism 20-28-(25) (25) 1221686 A function of finely adjusting and positioning the sleeve fixing member 19 with respect to the positional relationship of the sleeve 151. In addition, when the bushing cover 153 is pulled (tilted), the bushing fixing member 19 abuts against the bushing cover 153 while slowly retreating, so that if the front end portion 19a of the bushing fixing member 19 is In the case where the connecting portion 153 a of the sleeve cover 153 is not vertically abutted, the function of turning the sleeve cover 153 is easily and reliably performed. Therefore, when the sleeve cover is bent, the fixing mechanism main body 21 is rotated in the direction of the sleeve holding portion 4. When the front end portion 19a of the sleeve fixing member 19 provided on the other end portion of the fixing mechanism main body 21 as shown in FIG. 6 (a) abuts against the connection portion 153a of the sleeve cover 153, the following effects can be achieved. In detail, as shown in FIG. 1, the bushing fixing member 19 is supported while being able to move forward and backward in a pushing direction while being biased by a first spring member 25 of the first spring mechanism 22 of the spring mechanism 22. Therefore, for example, when the second rotation preventing member 27 is loosened due to years of use, and the fixing mechanism main body 21 is excessively swiveled to the sleeve holder 4 side, the sleeve fixing member 19 can still be positioned at the most suitable position, and at the same time, It is possible to absorb the impact when the sleeve fixing member 19 is in contact with the connecting portion 15 3 a of the sleeve 151, and to prevent the sleeve 151 from being damaged. In addition, during the turning of the sleeve cover 153, when the operator pushes the moving screw 23 in the in-out direction, the sleeve fixing member 19 abuts on one side as the sleeve cover 153 is tilted. The sleeve cover 153-face slowly and automatically retreats, so the effect of reducing the working process can be achieved. (Industrial Applicability) The above-mentioned bushing processing mold system can be applied to the application of the bending (dumping) of the bushing for coaxial connectors -29-(26) (26) 1221686. [Brief Description of the Drawings] Figure 1 shows the plan view of the sleeve machining tool. Fig. 2 is a plan view of a bushing processing mold. Fig. 3 is a sectional view taken along the line A-A in Fig. 1. -Figure 4 shows a schematic illustration of the sleeve ejection mechanism. Fig. 5 shows an exploded perspective view of the sleeve machining tool. Figure 6 shows the process of turning the sleeve cover. Figure 6 (a) shows the initial state of the sleeve cover, and Figure 6 (b) shows the middle state of the sleeve cover. Figure 6 (c) shows the state of the late stage of the sleeve cover, and Figure 6 (d) shows the state of the late stage of the sleeve cover. Fig. 7 is an explanatory diagram showing a state where the coaxial sleeve is assembled. [Comparison table of main components] 1 Base plate 2 Support table portion 2 a Support surface 3 Orifice table portion 3 a Working surface 3b False rivet insertion hole 3 c Bushing outlet hole 4 Bushing holding portion 4 a Bushing receiving hole -30- (27) 1221686 4b Sleeve cover receiving section 4 c Sleeve cover receiving section 5 Bending mechanism 6 Sleeve cover contacting mechanism 7 Pushing mechanism 8 Sleeve cover pressing member 8 a Outer wall surface abutting section 8b Coupling part 8 c Bottom part 8d Key groove 9 Guide frame 9 a Mounting part (penetrating part) 9b Mounting part (penetrating part) 10 Connecting screw 10a Head 11 Pressing base body 12 Holding member 13 Pressing movement Member 14 Cable receiving portion 15 Cable crimping mechanism 16 Cable crimping plate 16a Upper surface portion 16b Side surface portion 17 Fixing screw
•31 · (28) 軸套固定機構 軸套固定構件 軸套固定構件前端部 滑移機構 固定機構主體 彈撥機構 長孔部 移動用螺絲 固定螺絲 第1彈簧構件 第1止轉構件 第2止轉構件 前端面 假鉚機構 假鉚棒 卡合凹部 前端部 假鉚棒移動構件 第2彈簧構件 假鉚棒擋止器 軸套排出機構 軸套排出棒 水平支承面 傾斜支承面 -32- (29)1221686 34c 卡 35 推 36 第 37 軸 38 止 40 軸 4 1 第 101 接 102 結 120 同 121 中 123 遮 122 外 130 套 13 1 套 132 套 15 1 軸 152 軸 153 軸 153a 連 153b 第 153c 第 153d 導 154 套 合凹部 壓把手 3彈簧構件 套排出棒擋止器 轉機構 套排出構件 4彈簧構件 點 線部 軸電纜 心導體 蔽導體 皮 殼 殻主體 殼主體 套 套主體 套蓋 接部 1蓋部 2蓋部 體壓接部 殼主收容部• 31 · (28) Sleeve fixing mechanism Sleeve fixing member Sleeve fixing member Front end slide mechanism fixing mechanism Main body plucking mechanism Long hole part movement Screw fixing screw 1st spring member 1st rotation preventing member 2nd rotation preventing member Front end false riveting mechanism false riveting rod engaging recessed portion front end false riveting rod moving member second spring member false riveting rod stopper sleeve ejection mechanism sleeve ejecting rod horizontal support surface inclined support surface -32- (29) 1221686 34c Card 35 Push 36 37th shaft 38 Only 40 shaft 4 1st 101 connection 102 knot 120 same 121 middle 123 cover 122 outer 130 set 13 1 set 132 set 15 1 shaft 152 shaft 153 shaft 153a with 153b 153c 153d guide 154 set Closing recessed handle 3 Spring member cover Exhaust rod stopper Turn mechanism cover Discharge member 4 Spring member Dotted line shaft Cable core conductor Sheathing conductor Leather case Main body case Main body sleeve Main body cover cover 1 Cover 2 Cover Main housing
•33- (30)1221686 155 套殻副收容部 140 上側套殻 142 電纜收容部• 33- (30) 1221686 155 Casing sub-receiving section 140 Upper casing 142 Cable receiving section
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