TW201721986A - Crimped-connection connector capable of easily achieving a reliable contact between the contact part and the contact electrode of the other member stable - Google Patents
Crimped-connection connector capable of easily achieving a reliable contact between the contact part and the contact electrode of the other member stable Download PDFInfo
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- TW201721986A TW201721986A TW105132025A TW105132025A TW201721986A TW 201721986 A TW201721986 A TW 201721986A TW 105132025 A TW105132025 A TW 105132025A TW 105132025 A TW105132025 A TW 105132025A TW 201721986 A TW201721986 A TW 201721986A
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Abstract
Description
本發明係關於一種壓接連接器,特別係關於一種具備基部、從基部延伸出之螺旋狀之彈性臂部、及設置於彈性臂部之前端部之接點部的壓接連接器。The present invention relates to a crimp connector, and more particularly to a crimp connector having a base portion, a spiral elastic arm portion extending from the base portion, and a contact portion provided at a front end portion of the elastic arm portion.
按,近年來,作為用於將內置於電子機器之基板的配線電極與其他構件(電子部件、基板等)之接點電極在不直接進行焊接下電性連接的電子部件,有一種具備基部、從基部延伸出之螺旋狀之彈性臂部、及設置於彈性臂部之前端部之接點部的被稱為壓接連接器者已被實用化。 關於先前之壓接連接器在專利文獻1等有揭示。以下,利用圖10說明專利文獻1所揭示之先前的壓接連接器。圖10係顯示專利文獻1所揭示之先前之壓接連接器之竹筍狀接觸件901之構造的說明圖。又,圖10中之方向為便於說明而以彈性臂部912之螺旋之軸向為上下方向、以具有接點部913之側為上側來進行說明。 專利文獻1之竹筍狀接觸件901(壓接連接器)係如圖10所示般將基部911、彈性臂部912、接點部913一體地形成之被稱為竹筍彈簧(錐形彈簧)之彈簧構造的盤簧910,以對具有導電性與彈性之金屬板施以衝壓加工及彎曲加工等而形成。 盤簧910以在上下方向上延伸之未圖示之假想線為螺旋之軸而以板面與螺旋之軸平行之方式構成,且螺旋之內周側(以下簡稱為內周側)較螺旋之外周側(以下簡稱為外周側)朝上方突出。如是,盤簧910之螺旋之最外周之部分(以下簡稱為外周部)成為基部911,較外周部更靠近內側之螺旋之部分成為彈性臂部912,螺旋之內周側之端部即前端部之上側之端面成為接點部913。 又,雖然未圖示,但在專利文獻1中揭示有在以接點部913為上側之狀態下將基部911插入設置於基板之通孔而與基板之配線電極電性連接,且藉由從接點部913之上壓抵其他構件而使接點部913與其他構件之接點電極壓接,從而使基板之配線電極與其他構件之接點電極經由竹筍狀接觸件901電性連接之方法。又,雖然在專利文獻1未揭示,但亦可在以接點部913為上側之狀態下將基部911載置於基板之上並利用焊接等之方法與基板之配線電極電性連接。 [先前技術文獻] [專利文獻] [專利文獻1]日本特開2005-129428號公報In recent years, as an electronic component for electrically connecting a wiring electrode of a substrate built in an electronic device and a contact electrode of another member (electronic component, substrate, or the like) without direct soldering, there is a base portion. A spiral elastic arm portion extending from the base portion and a contact portion provided at the front end portion of the elastic arm portion are referred to as crimp connectors. The prior art crimp connector is disclosed in Patent Document 1 and the like. Hereinafter, a conventional crimp connector disclosed in Patent Document 1 will be described with reference to FIG. Fig. 10 is an explanatory view showing the configuration of a bamboo shoot-shaped contact 901 of the prior crimp connector disclosed in Patent Document 1. In addition, in the direction of FIG. 10, the axial direction of the spiral of the elastic arm part 912 is the up-down direction, and the side with the contact part 913 is the upper side. The bamboo shoot-shaped contact 901 (pressure-bonding connector) of Patent Document 1 is integrally formed with a base portion 911, an elastic arm portion 912, and a contact portion 913 as shown in Fig. 10, and is called a bamboo shoot spring (conical spring). The coil spring 910 having a spring structure is formed by press working, bending, or the like on a metal plate having conductivity and elasticity. The coil spring 910 is configured such that an imaginary line (not shown) extending in the vertical direction is a spiral axis, and the plate surface is parallel to the axis of the spiral, and the inner circumference side of the spiral (hereinafter simply referred to as the inner circumference side) is spiral. The outer peripheral side (hereinafter simply referred to as the outer peripheral side) protrudes upward. In the case where the outermost circumference of the spiral of the coil spring 910 (hereinafter simply referred to as the outer peripheral portion) becomes the base portion 911, the portion of the spiral which is closer to the inner side than the outer peripheral portion becomes the elastic arm portion 912, and the end portion of the inner peripheral side of the spiral is the front end portion. The end surface on the upper side serves as a contact portion 913. Further, although not shown, Patent Document 1 discloses that the base portion 911 is inserted into the through hole provided in the substrate in a state in which the contact portion 913 is on the upper side, and is electrically connected to the wiring electrode of the substrate, and The contact portion 913 is pressed against the other member, and the contact portion 913 is pressed against the contact electrode of the other member, thereby electrically connecting the wiring electrode of the substrate and the contact electrode of the other member via the bamboo shoot contact 901. . Further, although not disclosed in Patent Document 1, the base portion 911 may be placed on the substrate with the contact portion 913 as the upper side, and may be electrically connected to the wiring electrode of the substrate by soldering or the like. [Prior Art Document] [Patent Document] [Patent Document 1] JP-A-2005-129428
[發明所欲解決之問題] 通常,如彈性臂部之螺旋狀之彈簧在以沿螺旋之軸向收縮之方式彈性變形時,由於其端部間之距離會靠近,故螺旋將企圖在徑向上擴展。其結果為,在螺旋捲繞弛緩之方向上使其變形之力施加至彈簧。因此,在先前之壓接連接器中,若施加振動等而彈性臂部在上下方向上彈性變形,則與此相伴彈性臂部亦會在水平方向上彈性變形,而有彈性臂部之前端部在水平方向上移動之可能性。如是,隨著彈性臂部之前端部在水平方向上之移動,由於設置於彈性臂部之前端部的接點部會攀爬至其他構件之接點電極之氧化皮膜上等之理由,而有瞬間性接觸變得不穩定之可能性。另外,可考量為了提高接點壓力,而將2個竹筍彈簧設置為同心狀而將壓力施加至接點部,但在此情形下,上述之在採用1個竹筍彈簧下所言及之水平方向之移動,在採用兩個竹筍彈簧下亦會發生,因而與1個竹筍彈簧之情形相同,有瞬間性接觸變得不穩定之可能性。 本發明係鑒於如此之先前技術之實情而完成者,其目的在於提供一種易於使接點部與其他構件之接點電極之接觸穩定的壓接連接器。 [解決問題之技術手段] 為了解決此課題,技術方案1之壓接連接器之特徵在於具備:基部、從前述基部之不同之位置朝前述基部之上側延伸出之螺旋狀之一對彈性臂部、及設置於前述一對彈性臂部之中之一個彈性臂部之前端部的接點部;且前述彈性臂部包含具有導電性與彈性之板狀之構件,並以在上下方向上延伸之假想線為螺旋之軸而以板面與前述螺旋之軸平行之方式構成,並且前述一對彈性臂部之螺旋之捲繞方向係相互為反方向,前述一對彈性臂部之前端部彼此係相互連結。 在該構成之壓接連接器中,由於係以螺旋之捲繞方向相互為反方向之方式構成一對彈性臂部,故可伴隨著一對彈性臂部在上下方向之彈性變形而使施加在一對彈性臂部之前端部之力的水平方向成分朝向相互不同之方向。 如是,由於一對彈性臂部之前端部彼此係相互連結,故可藉由施加於一對彈性臂部之中之一個彈性臂部之力的水平方向成分來減少或抵消施加於另一個彈性臂部之力的水平方向成分。其結果為,能夠抑制彈性臂部之前端部在水平方向之移動,而使設置於彈性臂部之前端部之接點部與其他構件之接點電極之接觸穩定。 技術方案2之壓接連接器之特徵在於:於前述一個彈性臂部之前端部設置有沿前述彈性臂部之板面朝上方延伸出之延伸部,前述延伸部之上端部為前述接點部。 在該構成之壓接連接器中,藉由在一個彈性臂部之前端部設置沿彈性臂部之板面朝上方延伸之延伸部,並將延伸部之上端部作為接點部,可將彈性臂部與接點部以連續之方式形成,而在接點部之形成上不需要複雜之加工。其結果為,壓接連接器之加工變得容易。 技術方案3之壓接連接器之特徵在於前述一對彈性臂部之前端部彼此係藉由卡合而相互連結。 在該構成之壓接連接器中,藉由使一對彈性臂部之前端部彼此利用卡合而相互連結,前端部之連結構造變得簡單,壓接連接器之加工變得容易。 技術方案4之壓接連接器之特徵在於前述一對彈性臂部之前端部彼此在從上方觀察下相互正交,於前述一對彈性臂部之前端部之至少一者上,沿上下方向設置有可與另一者卡合之槽部。 在該構成之壓接連接器中,由於彈性臂部由板狀之構件構成,且彈性臂部之前端部亦為板狀之部分,故藉由使一對彈性臂部之前端部彼此在從上方觀察下相互正交,且於一對彈性臂部之前端部之至少一者上沿上下方向設置槽部,可無需在彈性臂部之前端部設置複雜的卡合構造即容易地使前端部彼此卡合。 技術方案5之壓接連接器之特徵在於前述一對彈性臂部以相互上下重疊之方式而設置。 在該構成之壓接連接器中,由於一對彈性臂部以相互上下重疊之方式而設置,故與將一對彈性臂部以在水平方向上並排之方式配置之情形相比可將水平方向之大小變小,而可將壓接連接器之安裝面積小型化。 技術方案6之壓接連接器之特徵在於前述一對彈性臂部係從前述基部之相互對向之側部分別延伸而出。 在該構成之壓接連接器中,由於一對彈性臂部從基部之相互對向之側部分別延伸出,故可將一對彈性臂部分開而形成,與從基部10之一個側部使一對彈性臂部以相鄰之方式延伸出之情形相比,易於確保在形成彈性臂部之際之空間,而易於提高針對彈性臂部之形狀的自由度。 [發明之效果] 根據本發明,可提供一種易於使接點部與其他構件之接點電極之接觸穩定的壓接連接器。[Problem to be Solved by the Invention] Generally, when a spiral spring such as a resilient arm is elastically deformed in a manner of contracting in the axial direction of the spiral, since the distance between the ends thereof is close, the spiral will be attempted in the radial direction. Expansion. As a result, a force that deforms in the direction in which the spiral winding is relaxed is applied to the spring. Therefore, in the conventional crimping connector, if the elastic arm portion is elastically deformed in the up-and-down direction by applying vibration or the like, the elastic arm portion is elastically deformed in the horizontal direction, and the front end portion of the elastic arm portion is elastically deformed. The possibility of moving in the horizontal direction. If the front end of the elastic arm portion moves in the horizontal direction, the contact portion provided at the front end portion of the elastic arm portion may climb to the oxide film of the contact electrode of the other member, etc., The possibility that instantaneous contact becomes unstable. In addition, in order to increase the contact pressure, two bamboo shoot springs are arranged concentrically and pressure is applied to the contact portion, but in this case, the above is in the horizontal direction as described under one bamboo shoot spring. The movement occurs under the use of two bamboo shoot springs, so that it is the same as in the case of a bamboo shoot spring, and there is a possibility that the instantaneous contact becomes unstable. The present invention has been made in view of the circumstances of the prior art, and an object thereof is to provide a crimp connector which is easy to stabilize contact between a contact portion and a contact electrode of another member. [Means for Solving the Problems] In order to solve the problem, the crimp connector of the first aspect of the invention is characterized by comprising: a base portion; a pair of spiral arms extending from the different positions of the base portion toward the upper side of the base portion And a contact portion provided at a front end portion of one of the pair of elastic arm portions; and the elastic arm portion includes a plate member having conductivity and elasticity, and extends in the up and down direction The imaginary line is a shaft of the spiral, and the plate surface is parallel to the axis of the spiral, and the winding directions of the spirals of the pair of elastic arm portions are opposite to each other, and the front ends of the pair of elastic arm portions are mutually connected Connected to each other. In the pressure-bonding connector of this configuration, since the pair of elastic arm portions are formed such that the winding directions of the spirals are opposite to each other, the elastic arms can be elastically deformed in the vertical direction. The horizontal direction components of the forces at the front ends of the pair of elastic arms are oriented in mutually different directions. If the front ends of the pair of elastic arm portions are coupled to each other, the horizontal direction component of the force applied to one of the pair of elastic arm portions can be reduced or offset to be applied to the other elastic arm. The horizontal component of the force of the ministry. As a result, it is possible to suppress the movement of the front end portion of the elastic arm portion in the horizontal direction, and to stabilize the contact between the contact portion provided at the end portion of the elastic arm portion and the contact electrode of the other member. The crimp connector of claim 2 is characterized in that an end portion of the elastic arm portion is provided with an extending portion extending upward along a plate surface of the elastic arm portion, and an upper end portion of the extending portion is the contact portion . In the crimp connector of the configuration, the elastic portion can be elasticized by providing an extending portion extending upward along the plate surface of the elastic arm portion at the front end portion of the elastic arm portion, and using the upper end portion of the extending portion as a contact portion. The arm portion and the contact portion are formed in a continuous manner, and complicated processing is not required in the formation of the contact portion. As a result, the processing of the crimp connector becomes easy. The crimp connector of claim 3 is characterized in that the front ends of the pair of elastic arm portions are coupled to each other by engagement. In the crimp connector of this configuration, the front end portions of the pair of elastic arm portions are coupled to each other by engagement, and the connection structure of the distal end portion is simplified, and the processing of the crimp connector is facilitated. The crimp connector of claim 4 is characterized in that the front ends of the pair of elastic arm portions are orthogonal to each other when viewed from above, and are disposed in the up and down direction on at least one of the front ends of the pair of elastic arm portions. There is a groove that can be engaged with the other. In the crimp connector of this configuration, since the elastic arm portion is formed of a plate-like member and the front end portion of the elastic arm portion is also a plate-like portion, the front ends of the pair of elastic arm portions are made to follow each other. The groove portion is disposed in the up-and-down direction on at least one of the front ends of the pair of elastic arm portions as viewed from above, and the front end portion can be easily formed without providing a complicated engagement structure at the front end portion of the elastic arm portion. Engage each other. The crimp connector of claim 5 is characterized in that the pair of elastic arm portions are disposed to overlap each other. In the crimp connector of this configuration, since the pair of elastic arm portions are disposed to overlap each other, the horizontal direction can be set as compared with the case where the pair of elastic arm portions are arranged side by side in the horizontal direction. The size is reduced, and the mounting area of the crimp connector can be miniaturized. The crimp connector of claim 6 is characterized in that the pair of elastic arm portions extend from the opposite sides of the base portion. In the crimp connector of this configuration, since the pair of elastic arm portions respectively extend from the mutually opposing side portions of the base portion, a pair of elastic arms can be partially opened and formed from one side portion of the base portion 10. Compared with the case where a pair of elastic arm portions extend in an adjacent manner, it is easy to secure a space at the time of forming the elastic arm portion, and it is easy to increase the degree of freedom with respect to the shape of the elastic arm portion. [Effects of the Invention] According to the present invention, it is possible to provide a pressure-bonding connector which is easy to stabilize contact between a contact portion and a contact electrode of another member.
以下,一邊參照圖1至圖9一邊說明本發明之實施方式。圖1係顯示本發明之第1實施方式之壓接連接器1之構造的第1說明圖,係壓接連接器1之立體圖。圖2係顯示本發明之第1實施方式之壓接連接器1之構造的第2說明圖,圖2(a)係壓接連接器1之俯視圖,圖2(b)係壓接連接器1之前視圖。圖3係顯示本發明之第1實施方式之壓接連接器1之構造的第3說明圖,圖3(a)係壓接連接器1之右側視圖,圖3(b)係對應於圖2(a)之剖面線A1-A1之壓接連接器1的示意剖視圖。 圖4係顯示本發明之第1實施方式之壓接連接器1之製造方法的說明圖,顯示對應於壓接連接器1之前視圖的加工狀態。圖4(a)顯示形成沖切體M1之後的狀態,圖4(b)顯示形成第1彈性臂部20與第2彈性臂部30之後的狀態,圖4(c)顯示將第1彈性臂部20與第2彈性臂部30移動至特定之位置之後的狀態。圖5係顯示本發明之第1實施方式之壓接連接器1之使用方法的說明圖,顯示對應於壓接連接器1之前視圖的使用狀態。圖5(a)顯示將壓接連接器1安裝於第1基板50之上以後的狀態,圖5(b)顯示將第2基板60配置於壓接連接器1之上以後的狀態。 圖6係顯示本發明之第1實施方式之第1彈性臂部20、第2彈性臂部30之舉動的說明圖,係對應於壓接連接器1之俯視圖的說明圖。圖6(a)係顯示第1彈性臂部20之舉動的說明圖,圖6(a)中粗實線之箭頭表示在第1彈性臂部20之前端部22被朝下方按壓時之、第1彈性臂部20之前端部22在水平方向上企圖移動之方向(從上方觀察時之方向)。又,圖6(b)係顯示第2彈性臂部30之舉動的說明圖,圖6(b)中粗實線之箭頭表示在第2彈性臂部30之前端部32被朝下方按壓時之、第2彈性臂部30之前端部32在水平方向上企圖移動之方向(從上方觀察時之方向)。 圖7係顯示本發明之第1變化例之壓接連接器101之構造的說明圖,係壓接連接器101之立體圖。圖8係顯示本發明之第2變化例之壓接連接器201之構造的說明圖,係壓接連接器201之立體圖。圖9係顯示本發明之第3變化例之壓接連接器301之構造的說明圖,係壓接連接器301之立體圖。 又,各圖中之方向為便於說明而以X1為左、X2為右、Y1為前、Y2為後、Z1為上、Z2為下,而並非限定壓接連接器1之使用時之朝向。另外,為了使發明之特徵易於明確,而將各圖中構件的構造適當簡略化,並將各圖中之構件之尺寸適當變更。 [第1實施方式] 首先,利用圖1至圖3說明本發明之第1實施方式之壓接連接器1的構成。壓接連接器1係用於將內置於電子機器之基板之配線電極與電子部件、基板等之其他構件之接點電極在不直接焊接下電性連接的電子部件,對由具有特定之導電性與彈性之不銹鋼或磷青銅等之材質製成的金屬板施以衝壓加工及彎曲加工等而一體地形成。 壓接連接器1如圖1所示般,具備:安裝於基板之基部10、從基部10朝基部10之上側延伸出的螺旋狀之一對彈性臂部即第1彈性臂部20及第2彈性臂部30、及設置於第1彈性臂部20之前端部22之接點部40。 基部10如圖1至圖3所示般,係沿水平方向擴展之大致正方形之平板狀之部分,具有沿水平方向相互對向之一對側部即右側部11與左側部12。 第1彈性臂部20與第2彈性臂部30係用於將接點部40彈性支持之部分。第1彈性臂部20如圖1至圖3所示般,係從基部10之右側部11朝基部10之上側螺旋狀地延伸出之部分,以在上下方向上延伸之假想線L1作為螺旋之軸而以板面21與螺旋之軸平行之方式構成,並形成螺旋之內周側較螺旋之外周側更朝上方突出之被稱為竹筍彈簧的彈簧構造。而且,第1彈性臂部20之螺旋之捲繞方向(從外周側朝向內周側之捲繞方向),在從上方觀察下為逆時針方向。又,第1彈性臂部20之內周側之端部成為前端部22,前端部22成為可在上下方向上移動之自由端。如是,若前端部22被朝下方按壓,則第1彈性臂部20以朝下方收縮之方式發生彈性變形,伴隨著彈性變形而產生朝上方之彈性力(反彈力)。 第2彈性臂部30如圖1至圖3所示般,係從基部10之左側部12朝基部10之上側螺旋狀地延伸出之部分,以在上下方向上延伸之假想線L1作為螺旋之軸而以板面21與螺旋之軸平行之方式構成,形成螺旋之內周側較螺旋之外周側更朝上方突出之被稱為竹筍彈簧的彈簧構造。而且,第2彈性臂部30之螺旋之捲繞方向(從外周側朝向內周側之捲繞方向),在從上方觀察下為順時針方向,亦即成為與第1彈性臂部20之螺旋之捲繞方向為相反之方向。又,第2彈性臂部30之內周側之端部成為前端部32,前端部32成為可在上下方向上移動之自由端。如是,若前端部32被朝下方按壓,則第2彈性臂部30以朝下方收縮之方式發生彈性變形,伴隨著彈性變形而產生朝上方之彈性力(反彈力)。 又,在本實施方式中,由於第1彈性臂部20、第2彈性臂部30係以假想線L1為螺旋之軸而以板面21、板面31與螺旋之軸平行之方式構成,故第1彈性臂部20、第2彈性臂部30之厚度方向將會沿著螺旋之徑向,而易於將沿螺旋之徑向之尺寸即第1彈性臂部20、第2彈性臂部30之外徑尺寸小型化。 又,由於可將第1彈性臂部20、第2彈性臂部30之上下方向之寬度尺寸相對於厚度尺寸而擴大,故第1彈性臂部20、第2彈性臂部30相對於上下方向易於產生大的彈性力。 又,在本實施方式中,以下述方式設置第1彈性臂部20與第2彈性臂部30,即:以第1彈性臂部20為上側、以第2彈性臂部30為下側而將第1彈性臂部20與第2彈性臂部30相互上下重疊,且,第1彈性臂部20之前端部22與第2彈性臂部30之前端部32在從上方觀察下為相互正交。 又,在本實施方式中,於第2彈性臂部30之前端部32之上端部,沿上下方向設置有可與第1彈性臂部20之前端部22之下端部卡合的槽部33。如是,藉由第1彈性臂部20之前端部22之下端部與第2彈性臂部30之前端部32之槽部33的卡合(以下簡稱為第1彈性臂部20之前端部22與第2彈性臂部30之前端部32的卡合),第1彈性臂部20之前端部22與第2彈性臂部30之前端部32相互連結而連動地移動。 又,在本實施方式中,於第1彈性臂部20之前端部22,設置有沿第1彈性臂部20之板面21朝上方延伸出之延伸部23,延伸部23之上端部成為前述之接點部40。接點部40由第1彈性臂部20彈性支持而可朝下方按壓。如是,在接點部40被朝下方按壓時,接點部40與第1彈性臂部20之前端部22、第2彈性臂部30之前端部32一起朝下方移動,藉由伴隨著第1彈性臂部20、第2彈性臂部30之朝下方彈性變形之反彈力(彈性力),接點部40被朝上方彈推。 其次,利用圖4說明壓接連接器1之製造方法。在製造壓接連接器1之際,首先如圖4(a)所示般,對金屬板施以衝壓加工等而將其沖切為特定之形狀,而形成將相當於基部10之第1區域R1與相當於第1彈性臂部20之第2區域R2以及相當於第2彈性臂部30之第3區域R3一體化之平板狀的構件即沖切體M1。又,第2區域R2係在第1區域R1之右側與第1區域R1之右端部連續地形成,第3區域R3係在第1區域R1之左側與第1區域R1之左端部連續地形成。 其次,如圖4(b)所示般,對沖切體M1之第2區域R2及第3區域R3施以衝壓加工及彎曲加工等而形成第1彈性臂部20與第2彈性臂部30。又,在形成第1彈性臂部20之際,採用在第1彈性臂部20之前端部22設置有延伸部23之構造,在形成第2彈性臂部30之際,採用在第2彈性臂部30之前端部32設置有槽部33之構造。 其次,如圖4(c)所示般,對沖切體M1之第1區域R1與第2區域R2之交界部分、第1區域R1與第3區域R3之交界部分施以彎曲加工,而將第1彈性臂部20與第2彈性臂部30朝基部10側彎折,且使第1彈性臂部20之前端部22與第2彈性臂部30之前端部32卡合。如是,第1區域R1成為基部10,設置於第1彈性臂部20之前端部22之延伸部23的上端部成為接點部40。壓接連接器1係如此般製造而成。 其次,利用圖5說明壓接連接器1之使用方法。圖5顯示將第1基板50之配線電極51與和第1基板50不同之其他構件即第2基板60之接點電極61經由壓接連接器1電性連接之情形的使用方法。在該使用方法中,首先,如圖5(a)所示般,於第1基板50之上安裝壓接連接器1,利用焊接等之方法將壓接連接器1之基部10與第1基板50之配線電極51電性連接。又,在該狀態下,於壓接連接器1之上尚未配置有第2基板60,接點部40成為可朝下方按壓之狀態。 其次,如圖5(b)所示般,於壓接連接器1之上配置第2基板60而將接點部40朝下方按壓。如是,藉由伴隨著接點部40之朝下方之按壓的第1彈性臂部20、第2彈性臂部30之彈性力,接點部40被朝上方彈推,接點部40與第2基板60之接點電極61壓接。如是,藉由接點部40與第2基板60之接點電極61之壓接,第1基板50之配線電極51與第2基板60之接點電極61經由壓接連接器1而被電性連接。 其次,利用圖6說明本實施方式之效果。通常,如第1彈性臂部20、第2彈性臂部30之螺旋狀的彈簧在以沿螺旋之軸向收縮之方式彈性變形時,由於其端部間之距離會靠近,因此將會企圖在螺旋之徑向上擴展。其結果為,在螺旋捲繞弛緩之方向上使其變形之力施加至彈簧。 例如,在本實施方式中,在第1彈性臂部20之前端部22被朝下方按壓,而第1彈性臂部20朝下方彈性變形時,如圖6(a)所示般,第1彈性臂部20之螺旋將朝捲繞弛緩方向撓曲。其結果為,在從上方觀察下可見,由於螺旋之直徑變大,故第1彈性臂部20將企圖以前端部22朝外側移動、且朝與前端側為相反之方向亦即順時針方向移動之方式發生變形。又,在第2彈性臂部30之前端部32被朝下方按壓,而第2彈性臂部30朝下方彈性變形時,如圖6(b)所示般,第2彈性臂部30之螺旋朝捲繞弛緩方向撓曲。其結果為,在從上方觀察下可見,由於螺旋之直徑變大,故第2彈性臂部30將企圖以前端部32朝外側移動、且朝與前端側為相反之方向亦即順時針方向移動之方式發生變形。 如此般,由於第1彈性臂部20之前端部22之變位方向與第2彈性臂部30之前端部32之變位方向相互不為正交,故如前述般僅藉由使前端部22之下端部進入槽部33而可使第1彈性臂部20、第2彈性臂部30之二者不會相對地滑動而一體地連結。而且,在連結之際,前述之接點部40朝反映第1彈性臂部20、第2彈性臂部30之二者之舉動的位置而作變位。此時,相反側之成分被抵消,在相同方向上以較大者之成分移動。又,雖未圖示,在朝第1彈性臂部20、第2彈性臂部30之按壓被解除而從彈性變形回歸時,第1彈性臂部20、第2彈性臂部30以前端部22、前端部32朝與前述方向相反方向移動之方式變形。其結果為,能夠抑制伴隨著第1彈性臂部20、第2彈性臂部30在上下方向上之彈性變形的第1彈性臂部20之前端部22、第2彈性臂部30之前端部32在水平方向上之移動,而可使設置於第1彈性臂部20之前端部22的接點部40與第2基板60之接點電極61之接觸穩定。 又,假定在本實施方式之壓接連接器1中,在第1彈性臂部20與第2彈性臂部30以螺旋之捲繞方向相互為同向之方式構成之情形下,或在第1彈性臂部20之前端部22與第2彈性臂部30之前端部32未相互連結之情形下,會有下述可能性:無法規制第1彈性臂部20、第2彈性臂部30在水平方向上之彈性變形;伴隨著第1彈性臂部20、第2彈性臂部30在上下方向上之彈性變形,第1彈性臂部20、第2彈性臂部30亦會易於在水平方向上發生彈性變形;及伴隨著第1彈性臂部20、第2彈性臂部30在水平方向上之彈性變形,設置於第1彈性臂部20之前端部22的接點部40與第2基板60(其他構件)之接點電極61的接觸變得不穩定。 亦即,由於在接點電極61以表面易於形成氧化被膜等之材質形成之情形下,存在伴隨著第1彈性臂部20之前端部22在水平方向之移動,接點部40從通常之接觸位置偏離而與被接點電極61之氧化被膜所覆蓋之部分接觸之可能性,故在如此之情形下,在氧化皮膜因接點壓力而破裂之期間,易於出現瞬間性接點部40與接點電極61之接觸不穩定。相對於此,在本實施方式之壓接連接器1中,如前述般,以螺旋之捲繞方向相互為反方向之方式構成第1彈性臂部20與第2彈性臂部30,藉由將第1彈性臂部20之前端部22與第2彈性臂部30之前端部32相互連結而消除如此之課題。 又,在本實施方式之壓接連接器1中,於第1彈性臂部20之前端部22設置沿第1彈性臂部20之板面21朝上方延伸之延伸部23,藉由將延伸部23之上端部設為接點部40,可將第1彈性臂部20與接點部40以連續之方式形成,而在接點部40之形成上無需複雜之加工。其結果為,壓接連接器1之加工變得容易。 又,在本實施方式之壓接連接器1中,藉由使第1彈性臂部20之前端部22與第2彈性臂部30之前端部32利用卡合而相互連結,第1彈性臂部20之前端部22與第2彈性臂部30之前端部32之連結構造變得簡單,壓接連接器1之加工變得容易。 又,在本實施方式之壓接連接器1中,由於第1彈性臂部20、第2彈性臂部30係由板狀之構件構成,第1彈性臂部20之前端部22、第2彈性臂部30之前端部32亦為板狀之一部分,故藉由使第1彈性臂部20之前端部22與第2彈性臂部30之前端部32在從上方觀察下相互正交,於第2彈性臂部30之前端部32沿上下方向設置槽部33,可無需在第1彈性臂部20之前端部22、第2彈性臂部30之前端部32設置複雜之卡合構造,即容易地將第1彈性臂部20之前端部22與第2彈性臂部30之前端部32卡合。 又,在本實施方式中,係在第2彈性臂部30之前端部32設置有可與第1彈性臂部20之前端部22卡合之槽部33,但在第1彈性臂部20之前端部22設置有可與第2彈性臂部30之前端部32卡合之槽部亦無妨。在如此之情形下亦然,可獲得與前述之效果相同之效果。另外,藉由在第1彈性臂部20之前端部22與第2彈性臂部30之前端部32之二者設置槽部,可使第1彈性臂部20之前端部22與第2彈性臂部30之前端部32之卡合更難於脫開,而使連結更穩定。 又,在本實施方式之壓接連接器1中,由於第1彈性臂部20與第2彈性臂部30係以相互上下重疊之方式而設置,故與將第1彈性臂部20與第2彈性臂部30在水平方向上並排配置之情形相比,可減小在水平方向之大小,而可使壓接連接器1之安裝面積小型化。 又,在本實施方式之壓接連接器1中,由於第1彈性臂部20與第2彈性臂部30係從沿水平方向相互對向之基部10之側部即右側部11與左側部12分別延伸出,故可將第1彈性臂部20及第2彈性臂部30與基部10之右側及左側分開而形成,與從基部10之一個側部使第1彈性臂部20與第2彈性臂部30以相鄰之方式延伸出之情形相比,易於確保形成第1彈性臂部20、第2彈性臂部30之際之空間,而易於提高對於第1彈性臂部20、第2彈性臂部30之形狀的自由度。 以上對本發明之實施方式進行了說明,但本發明並不限定於上述之實施方式,可在不脫離本發明之主旨下進行適當變更。 例如,在本發明之實施方式中,由於將第1彈性臂部20之前端部22之下端部置入第2彈性臂部30之槽部33,故第1彈性臂部20與第2彈性臂部30係以正交之方式而配置,但亦可將第2彈性臂部30之前端部32以在第1彈性臂部20之前端部22之延長線上呈一條直線之方式以熔接等而形成,在該情形下可更容易地抵消相對於水平方向之任意之方向。又,若可實現特定之機能,可如圖7至圖9所示之變化例般,變更基部10、接點部40之形狀亦無妨。在圖7所示之第1變化例中,基部10成為將第1彈性臂部20、第2彈性臂部30之外周部(螺旋之最外周之部分)一體化之筒狀之部分。在圖8所示之第2變化例中,接點部40成為朝水平方向擴展之平板狀之部分。在圖9所示之第3變化例中,基部10成為將第1彈性臂部20、第2彈性臂部30之外周部一體化之筒狀之部分,且接點部40成為朝水平方向擴展之平板狀之部分。即便基部10、接點部40之形狀為如此之形狀,亦可獲得與前述效果相同之效果。又,將基部10、接點部40之形狀設為除前述之實施方式、變化例以外之形狀亦無妨,於基部10、接點部40之特定之位置設置凸部、彎曲部、缺口部、開口部等亦無妨。 又,雖未圖示,但在本發明之實施方式中,第1彈性臂部20、第2彈性臂部30不為在從上面觀察下呈圓形且以一定之比例朝上方延伸之螺旋構造亦無妨。例如,第1彈性臂部20、第2彈性臂部30在從上面觀察下可呈四角形,又,亦可呈階梯狀朝上方延伸。總之,第1彈性臂部20、第2彈性臂部30只要成為繞假想線L1之周圍且一面朝上方延伸之彈簧構造即可。 又,在本發明之實施方式中,若可使第1彈性臂部20之前端部22與第2彈性臂部30之前端部32穩定地卡合,則第1彈性臂部20之前端部22與第2彈性臂部30之前端部32的卡合構造採用除前述以外之卡合構造亦無妨。又,利用除嵌合、焊接、雷射熔接等之卡合以外的方法將第1彈性臂部20之前端部22與第2彈性臂部30之前端部32連結亦無妨。 又,在本發明之實施形態中,將壓接連接器1安裝後傾斜而使用亦屬無妨。此外,在將壓接連接器1安裝在第1基板50之際,將基部10與第1基板50之配線電極51不進行焊接而是利用導電性接著劑等電性連接亦無妨,使基部10與第1基板50之配線電極51壓接而電性連接亦屬無妨。另外,在壓接連接器1之上配置並非基板而是IC等之電子部件使接點部40與電子部件之端子電極壓接亦無妨。Hereinafter, embodiments of the present invention will be described with reference to Figs. 1 to 9 . 1 is a first explanatory view showing a structure of a crimp connector 1 according to a first embodiment of the present invention, and is a perspective view of a crimp connector 1. 2 is a second explanatory view showing the structure of the crimping connector 1 according to the first embodiment of the present invention, wherein FIG. 2(a) is a plan view of the crimping connector 1, and FIG. 2(b) is a crimping connector 1. Previous view. 3 is a third explanatory view showing a structure of the crimp connector 1 according to the first embodiment of the present invention, wherein FIG. 3(a) is a right side view of the crimp connector 1, and FIG. 3(b) corresponds to FIG. (a) A schematic cross-sectional view of the crimp connector 1 of the section line A1-A1. 4 is an explanatory view showing a method of manufacturing the crimp connector 1 according to the first embodiment of the present invention, and shows a machining state corresponding to a front view of the crimp connector 1. 4(a) shows a state after the punching body M1 is formed, FIG. 4(b) shows a state after the first elastic arm portion 20 and the second elastic arm portion 30 are formed, and FIG. 4(c) shows the first elastic arm. The state in which the portion 20 and the second elastic arm portion 30 are moved to a specific position. Fig. 5 is an explanatory view showing a method of using the crimp connector 1 according to the first embodiment of the present invention, showing a state of use corresponding to the front view of the crimp connector 1. 5(a) shows a state after the crimp connector 1 is mounted on the first substrate 50, and FIG. 5(b) shows a state after the second substrate 60 is placed on the crimp connector 1. FIG. 6 is an explanatory view showing the behavior of the first elastic arm portion 20 and the second elastic arm portion 30 according to the first embodiment of the present invention, and corresponds to a plan view of the crimp connector 1 . Fig. 6(a) is an explanatory view showing the behavior of the first elastic arm portion 20, and the arrow of the thick solid line in Fig. 6(a) indicates when the end portion 22 of the first elastic arm portion 20 is pressed downward. 1 The direction in which the front end portion 22 of the elastic arm portion 20 is attempted to move in the horizontal direction (the direction when viewed from above). 6(b) is an explanatory view showing the behavior of the second elastic arm portion 30, and the arrow of the thick solid line in FIG. 6(b) indicates when the end portion 32 of the second elastic arm portion 30 is pressed downward. The direction in which the front end portion 32 of the second elastic arm portion 30 is attempted to move in the horizontal direction (the direction when viewed from above). Fig. 7 is an explanatory view showing a structure of a crimp connector 101 according to a first modification of the present invention, and is a perspective view of the crimp connector 101. Fig. 8 is an explanatory view showing a structure of a crimp connector 201 according to a second modification of the present invention, and is a perspective view of the crimp connector 201. FIG. 9 is an explanatory view showing a structure of a crimp connector 301 according to a third modification of the present invention, and is a perspective view of the crimp connector 301. Further, the directions in the respective drawings are for convenience of explanation, and X1 is left, X2 is right, Y1 is front, Y2 is rear, Z1 is upper, and Z2 is lower, and the orientation of the crimp connector 1 is not limited. In addition, in order to clarify the features of the invention, the structure of the members in the respective drawings is simplified as appropriate, and the dimensions of the members in the respective drawings are appropriately changed. [First Embodiment] First, a configuration of a crimp connector 1 according to a first embodiment of the present invention will be described with reference to Figs. 1 to 3 . The crimp connector 1 is an electronic component for electrically connecting a wiring electrode of a substrate built in an electronic device to a contact electrode of another member such as an electronic component or a substrate without direct soldering, and has specific conductivity. A metal plate made of a material such as elastic stainless steel or phosphor bronze is integrally formed by press working, bending, or the like. As shown in FIG. 1, the crimping connector 1 includes a base portion 10 attached to the substrate, and a first elastic arm portion 20 and a second elastic arm portion which are spirally extending from the base portion 10 toward the upper side of the base portion 10. The elastic arm portion 30 and the contact portion 40 provided at the front end portion 22 of the first elastic arm portion 20 are provided. As shown in FIGS. 1 to 3, the base portion 10 is a substantially square flat plate portion that expands in the horizontal direction, and has a right side portion 11 and a left side portion 12 which are opposite to each other in the horizontal direction. The first elastic arm portion 20 and the second elastic arm portion 30 are portions for elastically supporting the contact portion 40. As shown in FIGS. 1 to 3, the first elastic arm portion 20 is a portion extending spirally from the right side portion 11 of the base portion 10 toward the upper side of the base portion 10, and the imaginary line L1 extending in the up and down direction is used as a spiral. The shaft is formed such that the plate surface 21 is parallel to the axis of the spiral, and a spring structure called a bamboo shoot spring which protrudes upward from the outer peripheral side of the spiral from the outer peripheral side of the spiral is formed. Further, the winding direction of the spiral of the first elastic arm portion 20 (the winding direction from the outer circumferential side toward the inner circumferential side) is a counterclockwise direction as viewed from above. Further, the end portion on the inner peripheral side of the first elastic arm portion 20 serves as the distal end portion 22, and the distal end portion 22 is a free end that is movable in the vertical direction. When the front end portion 22 is pressed downward, the first elastic arm portion 20 is elastically deformed so as to contract downward, and elastic force (rebounding force) is generated upward with elastic deformation. As shown in FIGS. 1 to 3, the second elastic arm portion 30 is a portion extending spirally from the left side portion 12 of the base portion 10 toward the upper side of the base portion 10, and the imaginary line L1 extending in the up and down direction is used as a spiral. The shaft is formed such that the plate surface 21 is parallel to the axis of the spiral, and a spring structure called a bamboo shoot spring which protrudes upward from the outer peripheral side of the spiral from the outer peripheral side of the spiral is formed. Further, the winding direction of the spiral of the second elastic arm portion 30 (the winding direction from the outer circumferential side toward the inner circumferential side) is a clockwise direction as viewed from above, that is, a spiral with the first elastic arm portion 20 The winding direction is the opposite direction. Further, the end portion on the inner peripheral side of the second elastic arm portion 30 serves as the distal end portion 32, and the distal end portion 32 is a free end that is movable in the vertical direction. When the front end portion 32 is pressed downward, the second elastic arm portion 30 is elastically deformed so as to contract downward, and an elastic force (rebounding force) upward is generated in accordance with the elastic deformation. In the present embodiment, the first elastic arm portion 20 and the second elastic arm portion 30 are configured such that the imaginary line L1 is a spiral axis, and the plate surface 21 and the plate surface 31 are parallel to the axis of the spiral. The thickness direction of the first elastic arm portion 20 and the second elastic arm portion 30 is along the radial direction of the spiral, and the first elastic arm portion 20 and the second elastic arm portion 30 are easily sized in the radial direction of the spiral. The outer diameter is miniaturized. In addition, since the width dimension of the first elastic arm portion 20 and the second elastic arm portion 30 in the vertical direction is increased with respect to the thickness dimension, the first elastic arm portion 20 and the second elastic arm portion 30 are easy to be oriented in the vertical direction. Produces a large elastic force. Further, in the present embodiment, the first elastic arm portion 20 and the second elastic arm portion 30 are provided such that the first elastic arm portion 20 is on the upper side and the second elastic arm portion 30 is on the lower side. The first elastic arm portion 20 and the second elastic arm portion 30 are vertically overlapped each other, and the front end portion 22 of the first elastic arm portion 20 and the front end portion 32 of the second elastic arm portion 30 are orthogonal to each other as viewed from above. Further, in the present embodiment, the groove portion 33 that is engageable with the lower end portion of the front end portion 22 of the first elastic arm portion 20 is provided in the upper end portion of the front end portion 32 of the second elastic arm portion 30 in the vertical direction. In this case, the lower end portion of the front end portion 22 of the first elastic arm portion 20 is engaged with the groove portion 33 of the front end portion 32 of the second elastic arm portion 30 (hereinafter simply referred to as the front end portion 22 of the first elastic arm portion 20 and The front end portion 22 of the second elastic arm portion 20 and the front end portion 32 of the second elastic arm portion 30 are coupled to each other and move in conjunction with each other. Further, in the present embodiment, the front end portion 22 of the first elastic arm portion 20 is provided with an extending portion 23 extending upward along the plate surface 21 of the first elastic arm portion 20, and the upper end portion of the extending portion 23 is the aforementioned The contact portion 40. The contact portion 40 is elastically supported by the first elastic arm portion 20 and can be pressed downward. When the contact portion 40 is pressed downward, the contact portion 40 moves downward together with the front end portion 22 of the first elastic arm portion 20 and the front end portion 32 of the second elastic arm portion 30, with the first The rebounding force (elastic force) of the elastic arm portion 20 and the second elastic arm portion 30 that is elastically deformed downward is pushed upward by the contact portion 40. Next, a method of manufacturing the crimp connector 1 will be described using FIG. When the crimp connector 1 is manufactured, first, as shown in FIG. 4( a ), the metal plate is punched into a specific shape by press working or the like to form a first region corresponding to the base portion 10 . R1 is a punching body M1 which is a flat member which is integrated with the second region R2 of the first elastic arm portion 20 and the third region R3 corresponding to the second elastic arm portion 30. Further, the second region R2 is formed continuously on the right side of the first region R1 and the right end portion of the first region R1, and the third region R3 is formed continuously on the left side of the first region R1 and the left end portion of the first region R1. Then, as shown in FIG. 4(b), the first elastic arm portion 20 and the second elastic arm portion 30 are formed by press working, bending, or the like in the second region R2 and the third region R3 of the punching body M1. Further, when the first elastic arm portion 20 is formed, a structure in which the extending portion 23 is provided at the front end portion 22 of the first elastic arm portion 20 is employed, and when the second elastic arm portion 30 is formed, the second elastic arm is used. The front end portion 32 of the portion 30 is provided with a configuration of the groove portion 33. Next, as shown in FIG. 4(c), the boundary portion between the first region R1 and the second region R2 of the punching body M1 and the boundary portion between the first region R1 and the third region R3 are subjected to bending processing, and The elastic arm portion 20 and the second elastic arm portion 30 are bent toward the base portion 10, and the front end portion 22 of the first elastic arm portion 20 is engaged with the front end portion 32 of the second elastic arm portion 30. In this case, the first region R1 serves as the base portion 10, and the upper end portion of the extending portion 23 provided at the front end portion 22 of the first elastic arm portion 20 serves as the contact portion 40. The crimp connector 1 is manufactured in such a manner. Next, a method of using the crimp connector 1 will be described using FIG. FIG. 5 shows a method of using the wiring electrode 51 of the first substrate 50 and the contact electrode 61 of the second substrate 60 which is another member different from the first substrate 50 to be electrically connected via the crimp connector 1 . In this method of use, first, as shown in FIG. 5(a), the crimp connector 1 is mounted on the first substrate 50, and the base 10 and the first substrate of the crimp connector 1 are crimped by a method such as soldering. The wiring electrode 51 of 50 is electrically connected. Moreover, in this state, the second substrate 60 is not disposed on the crimp connector 1, and the contact portion 40 is pressed downward. Next, as shown in FIG. 5(b), the second substrate 60 is placed on the crimp connector 1, and the contact portion 40 is pressed downward. As a result, the contact portion 40 is pushed upward by the elastic force of the first elastic arm portion 20 and the second elastic arm portion 30 which are pressed downward by the contact portion 40, and the contact portion 40 and the second portion are pushed forward. The contact electrode 61 of the substrate 60 is crimped. In this case, the contact electrode 61 of the first substrate 50 and the contact electrode 61 of the second substrate 60 are electrically connected via the crimp connector 1 by the contact of the contact portion 40 with the contact electrode 61 of the second substrate 60. connection. Next, the effect of the present embodiment will be described using FIG. In general, when the spiral springs of the first elastic arm portion 20 and the second elastic arm portion 30 are elastically deformed so as to contract in the axial direction of the spiral, since the distance between the end portions is close, an attempt is made in The spiral expands in the radial direction. As a result, a force that deforms in the direction in which the spiral winding is relaxed is applied to the spring. For example, in the present embodiment, the front end portion 22 of the first elastic arm portion 20 is pressed downward, and when the first elastic arm portion 20 is elastically deformed downward, as shown in FIG. 6(a), the first elastic force is used. The helix of the arm 20 will deflect in the direction of winding relaxation. As a result, as seen from above, as the diameter of the spiral becomes larger, the first elastic arm portion 20 is intended to move outward at the distal end portion 22 and move clockwise in a direction opposite to the distal end side. The way it is deformed. Further, when the second elastic arm portion 30 is pressed downward toward the front end portion 32 and the second elastic arm portion 30 is elastically deformed downward, as shown in FIG. 6(b), the second elastic arm portion 30 is spirally wound toward the roll. Flexing in the direction of relaxation. As a result, as seen from above, the diameter of the spiral becomes larger, so that the second elastic arm portion 30 is intended to move outward at the distal end portion 32 and move clockwise in a direction opposite to the distal end side. The way it is deformed. In this manner, since the displacement direction of the front end portion 22 of the first elastic arm portion 20 and the displacement direction of the front end portion 32 of the second elastic arm portion 30 are not orthogonal to each other, the front end portion 22 is merely formed as described above. When the lower end portion enters the groove portion 33, both the first elastic arm portion 20 and the second elastic arm portion 30 can be integrally coupled without being relatively slid. Further, when the connection is made, the contact portion 40 is displaced in a position reflecting the behavior of both the first elastic arm portion 20 and the second elastic arm portion 30. At this time, the components on the opposite side are cancelled, and move in the same direction as the larger component. In addition, when the pressing of the first elastic arm portion 20 and the second elastic arm portion 30 is released and the elastic deformation is returned, the first elastic arm portion 20 and the second elastic arm portion 30 are the distal end portions 22. The distal end portion 32 is deformed so as to move in the opposite direction to the aforementioned direction. As a result, the front end portion 22 of the first elastic arm portion 20 and the front end portion 32 of the second elastic arm portion 30 accompanying the elastic deformation of the first elastic arm portion 20 and the second elastic arm portion 30 in the vertical direction can be suppressed. The contact between the contact portion 40 provided at the front end portion 22 of the first elastic arm portion 20 and the contact electrode 61 of the second substrate 60 can be stabilized by the movement in the horizontal direction. Further, in the pressure-bonding connector 1 of the present embodiment, in the case where the first elastic arm portion 20 and the second elastic arm portion 30 are configured to be coaxial with each other in the winding direction of the spiral, or in the first When the front end portion 22 of the elastic arm portion 20 and the front end portion 32 of the second elastic arm portion 30 are not connected to each other, there is a possibility that the first elastic arm portion 20 and the second elastic arm portion 30 are horizontally unregulated. The elastic deformation in the direction; the elastic deformation of the first elastic arm portion 20 and the second elastic arm portion 30 in the vertical direction, the first elastic arm portion 20 and the second elastic arm portion 30 are also likely to occur in the horizontal direction. The elastic deformation; and the elastic deformation of the first elastic arm portion 20 and the second elastic arm portion 30 in the horizontal direction, and the contact portion 40 and the second substrate 60 provided at the front end portion 22 of the first elastic arm portion 20 ( The contact of the contact electrode 61 of the other member becomes unstable. In other words, when the contact electrode 61 is formed of a material such as an oxide film on the surface, the contact portion 40 is normally contacted by the movement of the front end portion 22 of the first elastic arm portion 20 in the horizontal direction. Since the position is deviated and it is in contact with the portion covered by the oxide film of the contact electrode 61, in such a case, the instantaneous contact portion 40 is easily formed during the breakage of the oxide film due to the contact pressure. The contact of the spot electrode 61 is unstable. On the other hand, in the crimp connector 1 of the present embodiment, the first elastic arm portion 20 and the second elastic arm portion 30 are configured such that the spiral winding directions are opposite to each other as described above. The front end portion 22 of the first elastic arm portion 20 and the front end portion 32 of the second elastic arm portion 30 are coupled to each other to eliminate such a problem. Further, in the crimp connector 1 of the present embodiment, the front end portion 22 of the first elastic arm portion 20 is provided with an extending portion 23 extending upward along the plate surface 21 of the first elastic arm portion 20, by extending the portion The upper end portion of the portion 23 is a contact portion 40, and the first elastic arm portion 20 and the contact portion 40 can be formed in a continuous manner, and complicated processing is not required for the formation of the contact portion 40. As a result, the processing of the crimp connector 1 becomes easy. Further, in the crimp connector 1 of the present embodiment, the first elastic arm portion 20 is connected to the front end portion 22 of the second elastic arm portion 30 and the front end portion 32 of the second elastic arm portion 30 by the engagement, and the first elastic arm portion is coupled to each other. The connection structure between the front end portion 22 of the second front end portion 22 and the front end portion 32 of the second elastic arm portion 30 is simplified, and the processing of the crimp connector 1 is facilitated. Further, in the pressure-bonding connector 1 of the present embodiment, the first elastic arm portion 20 and the second elastic arm portion 30 are formed of a plate-shaped member, and the first elastic arm portion 20 has the front end portion 22 and the second elastic portion. The front end portion 32 of the arm portion 30 is also a plate-like portion. Therefore, the front end portion 22 of the first elastic arm portion 20 and the front end portion 32 of the second elastic arm portion 30 are orthogonal to each other as viewed from above. (2) The front end portion 32 of the elastic arm portion 30 is provided with the groove portion 33 in the vertical direction, so that it is not necessary to provide a complicated engagement structure at the front end portion 22 of the first elastic arm portion 20 and the front end portion 32 of the second elastic arm portion 30, that is, it is easy The front end portion 22 of the first elastic arm portion 20 and the front end portion 32 of the second elastic arm portion 30 are engaged with each other. Further, in the present embodiment, the groove portion 33 that can be engaged with the front end portion 22 of the first elastic arm portion 20 is provided at the front end portion 32 of the second elastic arm portion 30, but the first elastic arm portion 20 is provided. The front end portion 22 may be provided with a groove portion engageable with the front end portion 32 of the second elastic arm portion 30. Also in such a case, the same effects as those described above can be obtained. Further, by providing the groove portion at both the front end portion 22 of the first elastic arm portion 20 and the front end portion 32 of the second elastic arm portion 30, the front end portion 22 and the second elastic arm of the first elastic arm portion 20 can be formed. The engagement of the front end portion 32 of the portion 30 is more difficult to disengage, making the connection more stable. Further, in the crimp connector 1 of the present embodiment, since the first elastic arm portion 20 and the second elastic arm portion 30 are disposed to overlap each other, the first elastic arm portion 20 and the second elastic arm portion 20 are provided. Compared with the case where the elastic arm portions 30 are arranged side by side in the horizontal direction, the size in the horizontal direction can be reduced, and the mounting area of the crimp connector 1 can be miniaturized. Further, in the pressure-bonding connector 1 of the present embodiment, the first elastic arm portion 20 and the second elastic arm portion 30 are the right side portion 11 and the left side portion 12 which are side portions of the base portion 10 which face each other in the horizontal direction. Since the first elastic arm portion 20 and the second elastic arm portion 30 are separated from the right side and the left side of the base portion 10, and the first elastic arm portion 20 and the second elastic portion are provided from one side portion of the base portion 10, respectively. When the arm portion 30 is extended adjacently, it is easy to secure a space for forming the first elastic arm portion 20 and the second elastic arm portion 30, and it is easy to improve the first elastic arm portion 20 and the second elastic portion. The degree of freedom of the shape of the arm portion 30. The embodiments of the present invention have been described above, but the present invention is not limited to the above-described embodiments, and can be appropriately modified without departing from the spirit of the invention. For example, in the embodiment of the present invention, since the lower end portion of the front end portion 22 of the first elastic arm portion 20 is placed in the groove portion 33 of the second elastic arm portion 30, the first elastic arm portion 20 and the second elastic arm are provided. The portion 30 is disposed so as to be orthogonal to each other. However, the front end portion 32 of the second elastic arm portion 30 may be formed by welding or the like in a straight line on the extension line of the front end portion 22 of the first elastic arm portion 20 . In this case, any direction with respect to the horizontal direction can be more easily offset. Further, if a specific function can be realized, the shape of the base portion 10 and the contact portion 40 may be changed as in the case of the modification shown in FIGS. 7 to 9. In the first modification shown in FIG. 7, the base portion 10 is a tubular portion in which the outer peripheral portion of the first elastic arm portion 20 and the second elastic arm portion 30 (the portion of the outermost circumference of the spiral) is integrated. In the second modification shown in FIG. 8, the contact portion 40 is a flat portion that expands in the horizontal direction. In the third modification shown in FIG. 9, the base portion 10 is a tubular portion in which the outer peripheral portions of the first elastic arm portion 20 and the second elastic arm portion 30 are integrated, and the contact portion 40 is expanded in the horizontal direction. The flat part. Even if the shape of the base portion 10 and the contact portion 40 is such a shape, the same effects as those described above can be obtained. Further, the shape of the base portion 10 and the contact portion 40 may be a shape other than the above-described embodiments and modifications, and a convex portion, a curved portion, a notch portion, and a predetermined portion may be provided at a specific position of the base portion 10 and the contact portion 40. It is also possible to open the opening. Further, although not shown, in the embodiment of the present invention, the first elastic arm portion 20 and the second elastic arm portion 30 are not spiral structures that are circular in shape as viewed from above and extend upward at a constant ratio. It doesn't matter. For example, the first elastic arm portion 20 and the second elastic arm portion 30 may have a quadrangular shape when viewed from above, or may extend upward in a stepped manner. In short, the first elastic arm portion 20 and the second elastic arm portion 30 may have a spring structure that extends around the imaginary line L1 and extends upward. Further, in the embodiment of the present invention, the front end portion 22 of the first elastic arm portion 20 and the front end portion 32 of the second elastic arm portion 30 can be stably engaged, and the front end portion 22 of the first elastic arm portion 20 is provided. The engagement structure with the front end portion 32 of the second elastic arm portion 30 may be an engagement structure other than the above. Further, the front end portion 22 of the first elastic arm portion 20 and the front end portion 32 of the second elastic arm portion 30 may be connected by a method other than engagement by fitting, welding, laser welding or the like. Further, in the embodiment of the present invention, it is also possible to use the crimp connector 1 after installation and tilting. In addition, when the crimping connector 1 is mounted on the first substrate 50, the base portion 10 and the wiring electrode 51 of the first substrate 50 are electrically connected without being welded, and the base portion 10 may be electrically connected by a conductive adhesive or the like. It is also possible to press-contact and electrically connect the wiring electrode 51 of the first substrate 50. Further, an electronic component such as an IC that is not a substrate but an IC or the like is disposed on the crimp connector 1, and the contact portion 40 may be pressed against the terminal electrode of the electronic component.
1‧‧‧壓接連接器
10‧‧‧基部
11‧‧‧右側部
12‧‧‧左側部
20‧‧‧第1彈性臂部
21‧‧‧板面
22‧‧‧前端部
23‧‧‧延伸部
30‧‧‧第2彈性臂部
31‧‧‧板面
32‧‧‧前端部
33‧‧‧槽部
40‧‧‧接點部
50‧‧‧第1基板
51‧‧‧配線電極
60‧‧‧第2基板
61‧‧‧接點電極
101‧‧‧壓接連接器
201‧‧‧壓接連接器
301‧‧‧壓接連接器
901‧‧‧竹筍狀接觸件
910‧‧‧盤簧
911‧‧‧基部
912‧‧‧彈性臂部
913‧‧‧接點部
A1-A1‧‧‧剖面線
L1‧‧‧假想線
M1‧‧‧沖切體
R1‧‧‧第1區域
R2‧‧‧第2區域
R3‧‧‧第3區域
X1‧‧‧左
X2‧‧‧右
Y1‧‧‧前
Y2‧‧‧後
Z1‧‧‧上
Z2‧‧‧下
1‧‧‧Crimp connector
10‧‧‧ base
11‧‧‧ right side
12‧‧‧ left side
20‧‧‧1st elastic arm
21‧‧‧ board
22‧‧‧ front end
23‧‧‧Extension
30‧‧‧2nd elastic arm
31‧‧‧ board
32‧‧‧ front end
33‧‧‧Slots
40‧‧‧Contact Department
50‧‧‧1st substrate
51‧‧‧Wiring electrodes
60‧‧‧2nd substrate
61‧‧‧Contact electrode
101‧‧‧Crimp connector
201‧‧‧Crimp connector
301‧‧‧Crimp connector
901‧‧‧Bamboo shoots
910‧‧‧ coil spring
911‧‧‧ base
912‧‧‧Flexible arm
913‧‧‧Contact Department
A1-A1‧‧‧ hatching
L1‧‧‧ imaginary line
M1‧‧‧ punching body
R1‧‧‧1st area
R2‧‧‧2nd area
R3‧‧‧3rd area
X1‧‧‧ left
X2‧‧‧right
Before Y1‧‧‧
After Y2‧‧‧
On Z1‧‧‧
Under Z2‧‧‧
圖1係本發明之第1實施方式之壓接連接器之立體圖。 圖2(a)、圖2(b)係本發明之第1實施方式之壓接連接器之俯視圖及前視圖。 圖3(a)、圖3(b)係本發明之第1實施方式之壓接連接器之右側視圖及示意剖視圖。 圖4(a)~圖4(c)係顯示本發明之第1實施方式之壓接連接器之製造方法的說明圖。 圖5(a)、圖5(b)係顯示本發明之第1實施方式之壓接連接器之使用方法的說明圖。 圖6(a)、圖6(b)係顯示本發明之第1實施方式之彈性臂部之舉動的說明圖。 圖7係本發明之第1變化例之壓接連接器的立體圖。 圖8係本發明之第2變化例之壓接連接器的立體圖。 圖9係本發明之第3變化例之壓接連接器的立體圖。 圖10係顯示先前之壓接連接器之構造的說明圖。Fig. 1 is a perspective view of a crimp connector according to a first embodiment of the present invention. 2(a) and 2(b) are a plan view and a front view of a crimp connector according to a first embodiment of the present invention. 3(a) and 3(b) are a right side view and a schematic cross-sectional view of a crimp connector according to a first embodiment of the present invention. 4(a) to 4(c) are explanatory views showing a method of manufacturing the pressure-bonding connector according to the first embodiment of the present invention. 5(a) and 5(b) are explanatory views showing a method of using the crimp connector of the first embodiment of the present invention. 6(a) and 6(b) are explanatory views showing the behavior of the elastic arm portion according to the first embodiment of the present invention. Fig. 7 is a perspective view of a crimp connector according to a first modification of the present invention. Fig. 8 is a perspective view of a crimp connector according to a second modification of the present invention. Fig. 9 is a perspective view showing a crimp connector of a third modification of the present invention. Fig. 10 is an explanatory view showing the configuration of a prior crimp connector.
1‧‧‧壓接連接器 1‧‧‧Crimp connector
10‧‧‧基部 10‧‧‧ base
11‧‧‧右側部 11‧‧‧ right side
12‧‧‧左側部 12‧‧‧ left side
20‧‧‧第1彈性臂部 20‧‧‧1st elastic arm
21‧‧‧板面 21‧‧‧ board
22‧‧‧前端部 22‧‧‧ front end
23‧‧‧延伸部 23‧‧‧Extension
30‧‧‧第2彈性臂部 30‧‧‧2nd elastic arm
31‧‧‧板面 31‧‧‧ board
32‧‧‧前端部 32‧‧‧ front end
40‧‧‧接點部 40‧‧‧Contact Department
L1‧‧‧假想線 L1‧‧‧ imaginary line
X1‧‧‧左 X1‧‧‧ left
X2‧‧‧右 X2‧‧‧right
Y1‧‧‧前 Before Y1‧‧‧
Y2‧‧‧後 After Y2‧‧‧
Z1‧‧‧上 On Z1‧‧‧
Z2‧‧‧下 Under Z2‧‧‧
Claims (6)
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2015240887A JP6406645B2 (en) | 2015-12-10 | 2015-12-10 | IDC connector |
Publications (2)
Publication Number | Publication Date |
---|---|
TW201721986A true TW201721986A (en) | 2017-06-16 |
TWI616032B TWI616032B (en) | 2018-02-21 |
Family
ID=59060061
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
TW105132025A TWI616032B (en) | 2015-12-10 | 2016-10-04 | Crimp connector |
Country Status (2)
Country | Link |
---|---|
JP (1) | JP6406645B2 (en) |
TW (1) | TWI616032B (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
TWI788502B (en) * | 2018-01-19 | 2023-01-01 | 英屬開曼群島商鴻騰精密科技股份有限公司 | Crimp connector and method of manufacturing same |
TWI791734B (en) * | 2018-01-19 | 2023-02-11 | 英屬開曼群島商鴻騰精密科技股份有限公司 | Crimp connector and method of manufacturing same |
Family Cites Families (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3773996A (en) * | 1971-05-20 | 1973-11-20 | Controls Res Corp | Pushbutton switch with coil spring contacts |
US5297967A (en) * | 1992-10-13 | 1994-03-29 | International Business Machines Corporation | Electrical interconnector with helical contacting portion and assembly using same |
JP2005129428A (en) * | 2003-10-27 | 2005-05-19 | Sumitomo Electric Ind Ltd | Manufacturing method for telescopic contact, contact manufactured by the method and inspection device or electronic instrument provided with the contact |
JP2006184285A (en) * | 2005-12-28 | 2006-07-13 | Adorinkusu:Kk | Volute spring |
US8410610B2 (en) * | 2007-10-19 | 2013-04-02 | Nhk Spring Co., Ltd. | Connecting terminals with conductive terminal-forming members having terminal portions extending in different directions |
DE102010026027A1 (en) * | 2010-07-03 | 2012-01-05 | Amphenol-Tuchel Electronics Gmbh | spring contact |
JP6224551B2 (en) * | 2014-05-23 | 2017-11-01 | アルプス電気株式会社 | Pressure contact connector and manufacturing method thereof |
-
2015
- 2015-12-10 JP JP2015240887A patent/JP6406645B2/en active Active
-
2016
- 2016-10-04 TW TW105132025A patent/TWI616032B/en active
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
TWI788502B (en) * | 2018-01-19 | 2023-01-01 | 英屬開曼群島商鴻騰精密科技股份有限公司 | Crimp connector and method of manufacturing same |
TWI791734B (en) * | 2018-01-19 | 2023-02-11 | 英屬開曼群島商鴻騰精密科技股份有限公司 | Crimp connector and method of manufacturing same |
Also Published As
Publication number | Publication date |
---|---|
JP2017107754A (en) | 2017-06-15 |
TWI616032B (en) | 2018-02-21 |
JP6406645B2 (en) | 2018-10-17 |
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