| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 盘簧的制造方法 | CN201380061198.8 | 2013-11-20 | CN104822473A | 2015-08-05 | 岸原龙二; 和田直也; 寺床圭一郎 |
| 包含螺旋形成工序,通过由一对输送辊将大致直线状的长尺寸部件向沿着长边方向的第1方向的一方侧输送、同时使所述长尺寸部件的第2方向的一方侧触压于能够在所述第2方向上移动的按压部件,从而利用直线状的所述长尺寸部件形成包括固定卷绕部、第1可动卷绕部以及第2可动卷绕部的螺旋体。所述螺旋形成工序,在基于来自检测所述输送辊的转速的转速传感器的信号而识别出触压于所述按压部件的长尺寸部件的长边方向位置与形成为螺旋体后的周向位置的关系的状态下,控制所述按压部件的第2方向位置。 | ||||||
| 2 | 盘簧的制造方法 | CN201380061198.8 | 2013-11-20 | CN104822473B | 2016-08-24 | 岸原龙二; 和田直也; 寺床圭一郎 |
| 包含螺旋形成工序,通过由一对输送辊将大致直线状的长尺寸部件向沿着长边方向的第1方向的一方侧输送、同时使所述长尺寸部件的第2方向的一方侧触压于能够在所述第2方向上移动的按压部件,从而利用直线状的所述长尺寸部件形成包括固定卷绕部、第1可动卷绕部以及第2可动卷绕部的螺旋体。所述螺旋形成工序,在基于来自检测所述输送辊的转速的转速传感器的信号而识别出触压于所述按压部件的长尺寸部件的长边方向位置与形成为螺旋体后的周向位置的关系的状态下,控制所述按压部件的第2方向位置。 | ||||||
| 3 | 压平夹紧模具及其装置 | CN201610971195.3 | 2016-11-01 | CN106623687A | 2017-05-10 | 钱承林; 陈八一; 李艳杰; 冯鹏森 |
| 本发明属于模具技术领域,尤其涉及一种压平夹紧模具及其装置。它解决了现有技术设计不合理等问题。本压平夹紧模具包括下模板和位于下模板上方且能够靠近或远离下模板的上模板,在下模板和上模板之间设有能对空心线圈的内线头进行压平夹紧的内线头压平夹紧机构,在下模板和上模板之间设有能对空心线圈的外线头进行压平夹紧的外线头压平夹紧机构,所述的内线头压平夹紧机构和外线头压平夹紧机构同步动作或者异步动作,在上模板上设有当内线头和/或外线头被压平夹紧时能对所述内线头和/或外线头进行加热的加热机构。本发明的优点在于:能提高效率和提高质量。 | ||||||
| 4 | Method of manufacturing a coil component for Mri equipment | JP13778189 | 1989-05-30 | JP2752156B2 | 1998-05-18 | TAKAHASHI RYOICHI; YOSHIDA JUZO; TSURUNO DAIHACHIRO |
| Saddle coils are manufactured by placing wires in grooves formed in a first mold, so that the spatial arrangement of the saddle coils are determined by the positions of the grooves. This enables the wires to be precisely located in predetermined positions and assures a precise spatial arrangement of the saddle coils. Further, the wire is held by guides to form a solenoid coil. With this arrangement, high positional accuracies of the saddle coils and the solenoid coil are obtained, improving the detecting accuracy of the slice position of an object to be examined. | ||||||
| 5 | Support of candle core and its production | JP3654286 | 1986-02-22 | JPS61241398A | 1986-10-27 | JIYATSUKU KAZAMAYOU |
| 6 | 計時器用メインばねをプレスロールによって製造する方法 | JP2017104208 | 2017-05-26 | JP2017217697A | 2017-12-14 | ジョナ・ヴァノ; クリスチャン・シャルボン |
| 【課題】動作が確実なばねをプレスロールによって製造する。 【解決手段】あらかじめ形成された眼部を有するワイヤー1から、プレスロールによってメインばねを製造する方法である。第2の支持ガイド手段12に設けられた第2の接触領域Bと第3の支持ガイド手段13に設けられた第3の接触領域Cの間に位置する第1の接触領域Aにおいてワイヤーに力Fを与える第1の支持ガイド手段10を有するローラープレス20を用い、これによって、ワイヤーを前進させるにしたがって、眼部を越えた領域において、眼部の曲がりとは反対に曲がっている蓄積領域を巻き、第1の接触領域の位置は、第2の接触領域と第3の接触領域から離れるにしたがって、漸次的に変わり、これによって、蓄積領域と眼部の間の首部の接合におけるプレスロール半径が、最小の第1の値R1から最大の第2の値R2へと変わる。 【選択図】図4 |
||||||
| 7 | Method and apparatus for producing member comprising flat winding made of metal wire | JP17395386 | 1986-07-25 | JPS6277136A | 1987-04-09 | JIYATSUKU KASAMAYU |
| 8 | SPIRAL SPRING MANUFACTURING METHOD | EP13863522.2 | 2013-11-20 | EP2933036A1 | 2015-10-21 | KISHIHARA, Ryuji; WADA, Naoya; TERATOKO, Keiichiro |
The present invention includes a spiral forming step causing a substantially liner elongated member, which is conveyed toward one side in a longitudinal direction of the elongated member by a pair of conveying rollers, to be engaged at one side in a second direction with a pressing member movable in the second direction so that a spiral body including the fixed coil part, the first movable coil part and the second movable coil part is formed from the linear elongated member. The spiral forming step is configured to control the position of the pressing member with respect to the second direction, while recognizing, based on a signal from a rotational speed sensor for detecting the rotational speed of the conveying roller, a relationship between a position in the longitudinal direction of the elongated member that is engaged with the pressing member and the position in the circumferential direction after the spiral body is formed. |
||||||
| 9 | Method of making a spiral drive spring | EP84111855 | 1984-10-04 | EP0140202A3 | 1985-06-12 | Siebers, Gunter |
| 10 | Verfahren zur Herstellung einer spiralförmigen Triebfeder | EP84111855.7 | 1984-10-04 | EP0140202A2 | 1985-05-08 | Siebers, Gunter |
Aus einem Federband (6) wird ein erster Wickel (18) gewunden, der satt aneinanderliegende Windungen aufweist. Eine noch ungewundene, geradlinige Endpartie (6A) des Federbandes wird entgegen dem Biegesinn der Windungen des Wickels (18) kreisbogenförmig zu einem Endbogen (6B) geformt, der unmittelbar und mit stetigem, kontinuierlichem Uebergang an die äusserste Windung des Wickels (18) anschliesst. Der Krümmungsradius des Endbogens (6B) stimmt mit dem Radius eines Wickeldornes (19) überein, auf den das Federband (6) nach einer Wärmebehandlung aufgewickelt wird, und zwar entgegen dem Biegesinn der Windungen des ersten Wickels (18). Der so gebildete zweite Wickel (20) ist dazu bestimmt, als Triebfeder in ein Federhaus eingebracht zu werden, wobei das am zweiten Wickel (20) Bussen liegende Ende (7) des Federbandes (6) mit der Umfangswand des Federhauses verbunden und der jetzt innen liegende Endbogen (6B) mit einem im Federhaus drehbaren Federkern verbunden wird, dessen Radius ebenfalls mit dem Krümmungsradius des Endbogens (6B) übereinstimmt. Der Federkern kann mit einer Aufrolltrommel, z.B. für einen Sicherheitsgurt, gekuppelt sein. Die so erhaltene Triebfeder zeichnet sich durch ein verhälitnismässighohes Anfangsdrehmoment schon bei wenigen Umdrehungen des Federkernes aus. |
||||||
| 11 | METHOD FOR PRESS-ROLLING A TIMEPIECE MAINSPRING | US15615263 | 2017-06-06 | US20170355012A1 | 2017-12-14 | Jonas VANNOD; Christian CHARBON |
| Method for press-rolling a mainspring, from a wire comprising a pre-formed eye, utilising a roller press comprising a first support and guide means exerting a force on the wire in a first contact area located between a second and a third contact area comprised in a second and a third support and guide means, in order to wind, beyond the eye, an accumulation area with an opposite curvature to that of the eye, and wherein, as the wire advances, the position of the first contact area is gradually moved away from the second and third contact areas, to vary the press-rolling radius from a first minimum value to a second maximum value at a neck junction between the accumulation area and the eye. | ||||||
| 12 | Spiral spring manufacturing method | US14436794 | 2013-11-20 | US09782819B2 | 2017-10-10 | Ryuji Kishihara; Naoya Wada; Keiichiro Teratoko |
| A method includes a spiral forming step causing a substantially linear elongated member, conveyed toward one side in a longitudinal direction of the elongated member by a pair of conveying rollers, to be engaged at one side in a second direction with a pressing member movable in the second direction so that a spiral body including the fixed coil part, the first movable coil part and the second movable coil part is formed from the linear elongated member. The spiral forming step is configured to control the position of the pressing member with respect to the second direction, based on a signal from a rotational speed sensor detecting the rotational speed of the conveying roller, a relationship between a position in the longitudinal direction of the elongated member that is engaged with the pressing member and the position in the circumferential direction after the spiral body is formed. | ||||||
| 13 | Wire feeder driving mechanism for spring manufacturing machine | US10938622 | 2004-09-13 | US07134305B2 | 2006-11-14 | David Wu |
| A wire feeder driving mechanism capable of driving a wire feeder of a spring manufacturing machine to perform a three-dimensional movement. The spring manufacturing machine includes a machine base and a work table. The work table has an opening and a plurality of tool seats. The opening provides the feeding chuck of the wire feeder a moving space. The tool seat is provided to install a tool set to move back and forth on the work table. The wire feeder is assembled with a plurality of axial driving devices. The axial driving device is able to receive power and to move perpendicular to each other. The metal wire led through the wire feeder is thereby able to approach the tool seat in a three-dimensional manner. The spring manufacturing machine is therefore able to produce various complicated springs. | ||||||
| 14 | Driven mandrel and method | US950656 | 1978-10-12 | US4212179A | 1980-07-15 | Tristan D. Juergens |
| A mandrel useful in the spiral winding of flexible strip members is described including a pair of juxtaposed curvilinear perimetric driving portions which are offset laterally relative to one another and which have a slot or slots for receiving the elements to be wound. A process and winder are also described for the spiral winding of the strip members into a coiled element, e.g., a coiled capacitor or spirally wound battery cell pack. | ||||||
| 15 | Method and apparatus for making elongated flat wire coils | US690793 | 1976-05-27 | US4044583A | 1977-08-30 | C. Mills Kinney, Jr. |
| A wire winding blade extends through spiral outfeed guide members and receives spring-like unannealed wire from a source drawn by rotation of the winding blade; the wire from the source first passes through tensioning means then over an infeed guide pulley which guides it into a linear guide member having a bore slightly in excess of the wire diameter from which the wire passes over a small diameter idler roller sheave which imparts a back bend to the wire which is then fed into the slot of the spiral wire guide means where it is bent in a reverse manner about the winding blade. | ||||||
| 16 | Machine for winding spiral springs | US58022856 | 1956-04-24 | US2871910A | 1959-02-03 | BERNARD JANSEN WILLEM JOHAN |
| 17 | Art of springmaking | US5224848 | 1948-10-01 | US2548735A | 1951-04-10 | ADOLPH MELETTI |
| 18 | Machine for making springs | US40440420 | 1920-08-18 | US1421566A | 1922-07-04 | REESE REESE D |
| 19 | 計時器用メインばねをプレスロールによって製造する方法 | JP2017104208 | 2017-05-26 | JP6345845B2 | 2018-06-20 | ジョナ・ヴァノ; クリスチャン・シャルボン |
| 20 | ぜんまいばねの製造方法 | JP2012272912 | 2012-12-14 | JP5839714B2 | 2016-01-06 | 岸原 竜二; 和田 直也; 寺床 圭一郎 |
