| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 101 | Gear testing machine | US600548 | 1948-02-03 | US2582408A | 1952-01-15 | BAUER OLIVER F |
| 102 | Gear-hobbing machine | US72286147 | 1947-01-18 | US2545151A | 1951-03-13 | STANLEY FEARNS |
| 103 | Apparatus for recutting helicoidal gears | US60564132 | 1932-04-16 | US2008740A | 1935-07-23 | ZIMMERMANN WILLIAM F |
| 104 | Anti-back-lash device | US37168229 | 1929-06-17 | US1950419A | 1934-03-13 | SINDERSON JOHN B |
| 105 | Method and machine for finishing gears | US29656228 | 1928-07-31 | US1796484A | 1931-03-17 | SLADE ALTON P |
| 106 | Hobbing machine | US62229723 | 1923-03-02 | US1645596A | 1927-10-18 | HERRMANN KARL L |
| 107 | Gear cutter | US40280620 | 1920-08-11 | US1511077A | 1924-10-07 | FRANCIS HODGKINSON |
| 108 | Apparatus for the production of globoidal worm-wheels. | US1901074141 | 1901-09-03 | US809833A | 1906-01-09 | MOTHES GEORG |
| 109 | Gear-cutting machine | US263298D | US263298A | 1882-08-22 | ||
| 110 | VERFAHREN UND VORRICHTUNG ZUM VERZAHNEN EINES WERKRADES MIT VERMINDERTEM FLANKENLINIENFORMFEHLER | EP16714314.8 | 2016-03-23 | EP3274119A1 | 2018-01-31 | SOBCZYK, Marcel |
| The invention relates to a method for producing a toothed workpiece gear (11), wherein the workpiece gear (11) is clamped or fastened to a workpiece spindle and wherein a cutting tool (1) having cutting teeth (2) is clamped or fastened to a tool spindle. The tool spindle and the workpiece spindle are rotationally driven at a coupling ratio of the angles of rotation (φ2, φ1) thereof having a periodic non-linearity and/or at an axial distance (a) from each other that changes periodically, and the cutting teeth (2) machine left and right tooth flanks (13, 14) of the teeth (12, 12') of the workpiece gear (11) by means of left and right cutting edges (3, 4) in a chip-removing manner. In order to compensate radial run-out errors in particular, according to the invention, before the workpiece is machined, a radial run-out error (7) and/or a pitch error (8, 9) of the cutting tool (1) is determined and the flank line shape errors (18) of the right and/or left tooth flank (13, 14) resulting from the radial run-out error (7) and/or the pitch error (8, 9) are reduced by means of the periodic non-linearity of the coupling ratio and/or by means of the periodic change in the axial distance (a). | ||||||
| 111 | Verfahren zum spanenden Bearbeiten im wesentlichen zylindrischer, innen- oder aussenverzahnter Zahnräder | EP02025260.7 | 2002-11-13 | EP1319457B2 | 2015-03-25 | Fahrer, Siegfried; Peiffer, Klaus, Dr.; Faulstich, Ingo, Dr. |
| 112 | VIBRATION-SUPPRESSING MECHANISM FOR GEAR-SHAPING MACHINE | EP08853372 | 2008-11-18 | EP2186590A4 | 2014-03-12 | TOKAWA TAKAHIDE; MARUYAMA KAZUTAKA |
| Provided is a vibration-reduction mechanism for a gear cutting machine capable of reducing mechanical vibrations in the gear cutting of a helical gear by selecting an optimal balancer weight. For this purpose, provided is a vibration-reduction mechanism for a gear cutting machine that performs gear cutting on a workpiece (W) with a cutter (T) attached to a main shaft (26) made to move reciprocally by a crank. The vibration-reduction mechanism includes balancer shafts (16 and 17) arranged in parallel to a crank shaft (15). The balancer shafts (16 and 17) rotate synchronously with the crank shaft (15) at the same speed as the speed of the crank shaft (15). The balancer shaft (16) rotates in the opposite direction to the rotational direction of the crank shaft (15) while the balancer shaft (17) rotates in the same direction as the rotational direction of the crank shaft (15). The vibration-reduction mechanism also includes: main balancer weights (41 and 42) detachably attached onto the crank shaft (15) so as to reduce vibrations in the axial direction of the main shaft (26); and sub balancer weights (43 to 46) detachably attached onto the balancer shafts (16 and 17) so as to reduce vibrations in directions that are orthogonal to the axial direction of the main shaft (26). The balancer weights (41 to 46) are selected on the basis of a stroke width of the main shaft (26) and on the basis of a lead corresponding to the helical angle to be formed in the workpiece W. | ||||||
| 113 | Verfahren zur Kompensation einer bei der Bearbeitung eines Werkstücks auftretenden Schwingbewegung des Werkstücks bei einer Verzahnmaschine | EP09151385.3 | 2009-01-27 | EP2210693B1 | 2011-07-20 | Glück, Winfried |
| 114 | RUNOUT COMPENSATION ON MACHINE TOOLS | EP09720890.4 | 2009-03-16 | EP2249991A1 | 2010-11-17 | STADTFELD, Hermann, J.; COURTNEY, Joseph, A.; KIMMET, Gary, J. |
| A method of determining axial and/or radial runout due to workholding equipment and compensating for such runout during machining of a gear wherein axial and/or radial runout compensations are executed during the machining of each individual tooth slot. | ||||||
| 115 | VIBRATION-SUPPRESSING MECHANISM FOR GEAR-SHAPING MACHINE | EP08853372.4 | 2008-11-18 | EP2186590A1 | 2010-05-19 | TOKAWA, Takahide; MARUYAMA, Kazutaka |
Provided is a vibration-reduction mechanism for a gear cutting machine capable of reducing mechanical vibrations in the gear cutting of a helical gear by selecting an optimal balancer weight. For this purpose, provided is a vibration-reduction mechanism for a gear cutting machine that performs gear cutting on a workpiece (W) with a cutter (T) attached to a main shaft (26) made to move reciprocally by a crank. The vibration-reduction mechanism includes balancer shafts (16 and 17) arranged in parallel to a crank shaft (15). The balancer shafts (16 and 17) rotate synchronously with the crank shaft (15) at the same speed as the speed of the crank shaft (15). The balancer shaft (16) rotates in the opposite direction to the rotational direction of the crank shaft (15) while the balancer shaft (17) rotates in the same direction as the rotational direction of the crank shaft (15). The vibration-reduction mechanism also includes: main balancer weights (41 and 42) detachably attached onto the crank shaft (15) so as to reduce vibrations in the axial direction of the main shaft (26); and sub balancer weights (43 to 46) detachably attached onto the balancer shafts (16 and 17) so as to reduce vibrations in directions that are orthogonal to the axial direction of the main shaft (26). The balancer weights (41 to 46) are selected on the basis of a stroke width of the main shaft (26) and on the basis of a lead corresponding to the helical angle to be formed in the workpiece W. |
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| 116 | Verfahren zum spanenden Bearbeiten im wesentlichen zylindrischer, innen- oder aussenverzahnter Zahnräder | EP02025260.7 | 2002-11-13 | EP1319457A3 | 2004-02-11 | Fahrer, Siegfried; Peiffer, Klaus, Dr.; Faulstich, Ingo, Dr. |
Zum spanenden Bearbeiten muß das Werkstück so auf der Bearbeitungsmaschine ausgerichtet werden, daß die Radführungsachse (F) und Verzahnungsachse des Werkstückes und die Drehachse (D) der Maschine zusammenfallen. Damit bei geringem Aufwand die Verzahnungsachse eines Zahnrades (2) praktisch mit der Führungsachse (F) des Rades (2) zusammenfällt, wird die Lage der Radführungsachse (F) zur Drehachse (D) der Bearbeitungsmaschine bestimmt und die Verzahnung und die Radführungsachse (F) erzeugt. Mit diesem Verfahren können Zahnräder, Kegelräder, Kronenräder, Schneckenräder und dergleichen hergestellt werden. |
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| 117 | IMPROVED DRIVE TRAIN FOR GEAR HOBBING MACHINE | EP82902557.6 | 1982-07-06 | EP0094392B1 | 1989-02-08 | HUNKELER, Ernst J. |
| 118 | Verzahnungsmaschine zum Schneiden von Spiralkegelrädern und Stirnzahnkupplungen nach dem kontinuierlichen Schneidverfahren | EP85114080.6 | 1985-11-05 | EP0184007B1 | 1988-12-28 | Kotthaus, Erich |
| 119 | Verfahren und Anordnung zum Beseitigen der Zahnflanken-Welligkeit auf Zahnradproduktionsmaschinen | EP84810426.1 | 1984-08-29 | EP0140831B1 | 1988-07-20 | Bloch, Peter, Dr. sc. techn.; Schneider, Otto, dipl. El.-Ing. HTL; Donner, Meinrad |
| 120 | Vorrichtung zum Feinbearbeiten der Verzahnung von Zahnrädern | EP85111532.9 | 1985-09-12 | EP0192817A1 | 1986-09-03 | Loos, Herbert; Erhardt, Manfred |
Zum Feinbearbeiten von insbesondere gehärteten Kegelrädern werden ein Verfahren und eine Vorrichtung vorgeschlagen, bei dem bzw. auf der das Werkstück mit einem kegelradförmigen Werkzeug, das abrasive Flanken aufweist, abwälzt. Werkstück und Werkzeug laufen dabei unter sich im Abstand kreuzenden Achsen und sind mit jeweils einem Führungsrad verbunden, die ebenfalls miteinander abwälzen. Sowohl das Werkstück-Werkzeug-Parr als auch das Führungsradpaar laufen jeweils mit Flankenspiel, aber an entgegengesetzten Flanken, so daß die Gesamtkombination ohne Flankenspiel läuft. |
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