AU2017100751A4 - Tooling for linearly cutting internal splines of input planet carriers which can ensure the precision of axial processing - Google Patents

Tooling for linearly cutting internal splines of input planet carriers which can ensure the precision of axial processing Download PDF

Info

Publication number
AU2017100751A4
AU2017100751A4 AU2017100751A AU2017100751A AU2017100751A4 AU 2017100751 A4 AU2017100751 A4 AU 2017100751A4 AU 2017100751 A AU2017100751 A AU 2017100751A AU 2017100751 A AU2017100751 A AU 2017100751A AU 2017100751 A4 AU2017100751 A4 AU 2017100751A4
Authority
AU
Australia
Prior art keywords
face
positioning sleeve
chassis
input planet
gland
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Ceased
Application number
AU2017100751A
Inventor
Junwei JIN
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Hengdian Group Innuovo Electric Co Ltd
Original Assignee
Hengdian Group Innuovo Electric Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Hengdian Group Innuovo Electric Co Ltd filed Critical Hengdian Group Innuovo Electric Co Ltd
Priority to AU2017100751A priority Critical patent/AU2017100751A4/en
Application granted granted Critical
Publication of AU2017100751A4 publication Critical patent/AU2017100751A4/en
Ceased legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Landscapes

  • Retarders (AREA)

Abstract

TITLE: TOOLING FOR LINEARLY CUTTING INTERNAL SPLINES OF INPUT PLANET CARRIERS WHICH CAN ENSURE THE PRECISION OF AXIAL PROCESSING Abstract A tooling for linearly cutting internal splines of input planet carriers which can ensure the precision of axial processing, comprising a chassis, a positioning sleeve and a gland, characterized in that the chassis, the positioning sleeve and the gland being three independent components; a central positioning hole running through the chassis from top to bottom is formed on the chassis; an inner cavity for accommodating several input planet carriers to be cut is formed within the positioning sleeve; an inner edge of a radial cross-section of the positioning sleeve is circular; the inner cavity of the positioning sleeve and the central positioning hole of the chassis are arranged coaxially; a through hole running through the gland from top to bottom is formed on the gland; several input planet carriers to be cut are stacked within the inner cavity, with the position of an upper end face of the topmost input planet carrier to be cut being higher than the position of an upper end face of the positioning sleeve and the position of a lower end face of the topmost input planet carrier to be cut being lower than the position of the upper end face of the positioning sleeve; a lower end face of the gland extends upward to form a circular groove communicated with the through hole; and, when the gland and the positioning sleeve are fixed, the upper end face of the topmost input planet carrier to be cut is located within the circular groove; all the upper end face of the positioning sleeve, the lower end face of the positioning sleeve, the upper end face of the chassis and the lower end face of the chassis are flat, and both the upper end face and the lower end face of the positioning sleeve are arranged perpendicularly to the axis of the positioning sleeve.

Description

2017100751 15 Jun2017
DESCRIPTION
TOOLING FOR LINEARLY CUTTING INTERNAL SPLINES OF INPUT PLANET CARRIERS WHICH CAN ENSURE THE PRECISION OF AXIAL
PROCESSING
Technical Field of the Invention
The present invention relates to a tooling for linearly cutting internal splines of input planet carriers which can ensure the precision of axial processing.
Background of the Invention
In the prior art, in order to linearly cut internal splines of input planet carriers, each input planet carrier needs to be fixed. The input planet carriers are machined successively by linear cutting, and it is unable to machine internal splines of a plurality of input planet carriers in one time. Therefore, the machining efficiency is low.
Summary of the Invention
An objective of the present invention is to provide a tooling for linearly cutting internal splines of input planet carriers which can ensure the precision of axial processing.
For this purpose, the present invention employs the following technical solutions: a tooling for linearly cutting internal splines of input planet carriers which can ensure the precision of axial processing is provided, including a chassis, a positioning sleeve and a gland, the chassis, the positioning sleeve and the gland being three independent components; a central positioning hole running through the chassis from top to bottom is formed on the chassis; an inner cavity for accommodating several input planet carriers to be cut is formed within the positioning sleeve; an inner edge of a radial cross-section of the 1 2017100751 15 Jun2017 positioning sleeve is circular; the inner cavity of the positioning sleeve and the central positioning hole of the chassis are arranged coaxially; a through hole running through the gland from top to bottom is formed on the gland; several input planet carriers to be cut are stacked within the inner cavity, with the position of an upper end face of the topmost input planet carrier to be cut being higher than the position of an upper end face of the positioning sleeve and the position of a lower end face of the topmost input planet carrier to be cut being lower than the position of the upper end face of the positioning sleeve; a lower end face of the gland extends upward to form a circular groove communicated with the through hole; and, when the gland and the positioning sleeve are fixed, the upper end face of the topmost input planet carrier to be cut is located within the circular groove; all the upper end face of the positioning sleeve, the lower end face of the positioning sleeve, the upper end face of the chassis and the lower end face of the chassis are flat, and both the upper end face and the lower end face of the positioning sleeve are arranged perpendicularly to the axis of the positioning sleeve. Through the flat fitting of the positioning sleeve and the chassis, the perpendicularity of the positioning sleeve is ensured, and the axial precision of machining is thus ensured.
In the present invention, a plurality of pieces to be cut (input planet carriers to be cut) can be linearly cut and machined in one time, so that the machining efficiency is high; moreover, the axial precision of the pieces to be cut may be ensured, and the machining precision is thus high.
Brief Description of the Drawings
Fig. 1 is a structural diagram of the present invention; and
Fig. 2 is a structural diagram of the present invention, when fitted with pieces to be cut.
Detailed Description of the Invention
The present invention will be further described below by specific 2017100751 15 Jun2017 embodiments with reference to the accompanying drawings.
As shown in Figs. 1 and 2, the present invention provides a tooling for linearly cutting internal splines of input planet carriers which can ensure the precision of axial processing, including a chassis 1, a positioning sleeve 2 and a gland 3, wherein the chassis 1, the positioning sleeve 2 and the press cover 3 are three independent components; a central positioning hole 11 running through the chassis from top to bottom is formed on the chassis 1; an inner cavity for accommodating several input planet carriers 4 to be cut is formed within the positioning sleeve 2; an inner edge of a radial cross-section of the positioning sleeve 2 is circular; the inner cavity of the positioning sleeve 2 and the central positioning hole 11 of the chassis 1 are arranged coaxially; and, a through hole 31 running through the gland from top to bottom is formed on the gland 3.
In the present invention, the inner cavity of the positioning sleeve 2 is used for accommodating four input planet carriers 4 to be cut which are stacked from top to bottom. When the four input planet carriers 4 to be cut, which are stacked from top to bottom, are placed into the inner cavity, the position of an upper end face of the topmost input planet carrier 4 to be cut is higher than the position of an upper end face of the positioning sleeve 2, and the position of a lower end face of the topmost input planet carrier 4 is lower than the position of the upper end face of the positioning sleeve 2. A lower end face of the gland 3 extends upward to form a circular groove communicated with the through hole31. When the gland 3 and the positioning sleeve 2 are fixed, the upper end face of the topmost input planet carrier 4 to be cut is located within the circular groove 32. The value of the height from the upper end face of the topmost input planet carrier 4 to be cut to a lower end face of the bottommost input planet carrier 4 to be cut is denoted by Li, the value of the height of the inner cavity of the positioning sleeve 2 is denoted by L2, the value of the depth of the circular groove 32 is denoted byL3, and U is greater than the sum of L2 and L3. A boss 41 is formed on an end face of each of the input planet carriers 4 to be 3 2017100751 15 Jun2017 cut, and the inner diameter of the through hole 31 of the gland 3 is greater than the outer diameter of the boss 41.
The gland 3 is fixed with the positioning sleeve 2 through three first screws 5, three fitting holes 51 for fitting the first screws 5 are formed on both the gland 3 and the positioning sleeve 2, and an internal thread structure is formed within each of the fitting holes 51 of the positioning sleeve 2. The three fitting holes of the positioning sleeve 2 and the three fitting holes of the gland are annularly and uniformly arranged at intervals around an axis of the central positioning hole 11 of the chassis.
All the upper end face of the positioning sleeve 2, the lower end face of the positioning sleeve 2, the upper end face of the chassis 1 and the lower end face of the chassis 1 are flat, and both the upper end face and the lower end face of the positioning sleeve 2 are arranged perpendicularly to the axis of the positioning sleeve 2. The positioning sleeve 2 and the chassis 1 are fixed by three second screws 6, a fitting hole for fitting a positioning pin 7 is formed on both the positioning sleeve 2 and the chassis 1, and the fitting hole of the positioning sleeve 2 corresponds to the fitting hole of the chassis 1. 4

Claims (2)

  1. Claims
  2. 1. A tooling for linearly cutting internal splines of input planet carriers which can ensure the precision of axial processing, comprising a chassis, a positioning sleeve and a gland, characterized in that the chassis, the positioning sleeve and the gland being three independent components; a central positioning hole running through the chassis from top to bottom is formed on the chassis; an inner cavity for accommodating several input planet carriers to be cut is formed within the positioning sleeve; an inner edge of a radial cross-section of the positioning sleeve is circular; the inner cavity of the positioning sleeve and the central positioning hole of the chassis are arranged coaxially; a through hole running through the gland from top to bottom is formed on the gland; several input planet carriers to be cut are stacked within the inner cavity, with the position of an upper end face of the topmost input planet carrier to be cut being higher than the position of an upper end face of the positioning sleeve and the position of a lower end face of the topmost input planet carrier to be cut being lower than the position of the upper end face of the positioning sleeve; a lower end face of the gland extends upward to form a circular groove communicated with the through hole; and, when the gland and the positioning sleeve are fixed, the upper end face of the topmost input planet carrier to be cut is located within the circular groove; all the upper end face of the positioning sleeve, the lower end face of the positioning sleeve, the upper end face of the chassis and the lower end face of the chassis are flat, and both the upper end face and the lower end face of the positioning sleeve are arranged perpendicularly to the axis of the positioning sleeve.
AU2017100751A 2017-06-15 2017-06-15 Tooling for linearly cutting internal splines of input planet carriers which can ensure the precision of axial processing Ceased AU2017100751A4 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
AU2017100751A AU2017100751A4 (en) 2017-06-15 2017-06-15 Tooling for linearly cutting internal splines of input planet carriers which can ensure the precision of axial processing

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
AU2017100751A AU2017100751A4 (en) 2017-06-15 2017-06-15 Tooling for linearly cutting internal splines of input planet carriers which can ensure the precision of axial processing

Publications (1)

Publication Number Publication Date
AU2017100751A4 true AU2017100751A4 (en) 2017-07-20

Family

ID=59335316

Family Applications (1)

Application Number Title Priority Date Filing Date
AU2017100751A Ceased AU2017100751A4 (en) 2017-06-15 2017-06-15 Tooling for linearly cutting internal splines of input planet carriers which can ensure the precision of axial processing

Country Status (1)

Country Link
AU (1) AU2017100751A4 (en)

Similar Documents

Publication Publication Date Title
RU2013111882A (en) T-SHAPED MILLING MACHINE HAVING SEPARATE CENTERING AND TORQUE TRANSMISSIONS
RU2012120871A (en) MILLER
AU2017100751A4 (en) Tooling for linearly cutting internal splines of input planet carriers which can ensure the precision of axial processing
AU2017100747A4 (en) Tooling for linearly cutting internal splines of input planet carriers
CN104827316B (en) A kind of gear box end cover processing positioning tool
AU2017100752A4 (en) Easily-fixed tooling for linearly cutting internal splines of input planet carriers
AU2017100750A4 (en) Tooling with a boss for linearly cutting internal splines of input planet carriers
AU2017100749A4 (en) High-precision tooling for linearly cutting internal splines of input planet carriers
CN103470688B (en) Counterweight-discrete flywheel
CN102248417B (en) Multi-workpiece assembling counter gear groove cutting fixture
AU2017100748A4 (en) Tooling for linearly cutting internal splines of input planet carriers which is convenient for compressing a workpiece
CN203818037U (en) Magnetic assembling tool structure for round work-pieces
CN103600242A (en) Elastic clamping and positioning device
US9476495B2 (en) Fluted sprocket/cog bore for reduced machining cycle times and reduced tool wear
CN107598590A (en) A kind of accurate frock for processing valve pocket hole and a kind of valve pocket process equipment
CN205074828U (en) Outer circular slot of annular work piece mills uses frock
CN203738086U (en) Drill jig for thrust bearings
CN204321665U (en) A kind of for the inner locking device of the mach Internet of Things of lever
CN204195284U (en) A kind of tool structure of processing automobile vavuum pump housing cover
CN103350262B (en) A kind of axle sleeve internal spline gear-shaping clamp
CN208895338U (en) The simple clamped device of regular tap
CN204372113U (en) A kind of bearing unit of output shaft of speed reducer
CN102837171A (en) Threaded hole processing method with positioning function
AU2017100743A4 (en) High-precision lathe tooling
CN203141149U (en) Machining and positioning device for cylinder bearing of garden machine

Legal Events

Date Code Title Description
FGI Letters patent sealed or granted (innovation patent)
MK22 Patent ceased section 143a(d), or expired - non payment of renewal fee or expiry