CN111553039B - Cosine line tooth profile non-circular gear pair three-dimensional solid modeling method - Google Patents

Abstract

The invention discloses a three-dimensional solid modeling method of a non-circular gear pair with a cosine line tooth profile, which comprises the steps of obtaining point coordinate values on pitch curves of a driving wheel and a driven wheel in the non-circular gear pair in an EXCEL table according to a transmission ratio function and a center distance, leading the point coordinate values into UGNX software to obtain pitch curves of the driving wheel and the driven wheel, creating a gear blank on the basis, obtaining a solid model of the non-circular gear by defining the initial position and the relative motion of the gear blank and a slotting cutter model and adopting a motion simulation means, wherein the transmission precision of the obtained three-dimensional model is superior to that of a reduced tooth profile method; the modeling process is simple, no complex calculation process is needed, and the calculated amount is small; the three-dimensional model of the non-circular gear pair is obtained by adopting the UG NX motion simulation technology, programming is not required to be performed by a design algorithm, and development difficulty is low.

Description

Cosine line tooth profile non-circular gear pair three-dimensional solid modeling method

Technical Field

The invention belongs to the field of mechanical design, and relates to a cosine line tooth profile non-circular gear pair three-dimensional solid modeling method.

Background

The non-circular gear is a special mechanical transmission part and can realize non-linear motion and power transmission. The non-circular gear has a complex structure, the difficulty in creating a three-dimensional solid model of a non-circular gear pair is high, and the existing non-circular gear three-dimensional modeling methods comprise the following steps:

(1) The tooth profile conversion method: the core idea of the conversion tooth profile method is to convert each gear tooth of the non-circular gear into the tooth profile of the equivalent circular gear, and the method is an approximate design method and is difficult to meet the requirement of high-precision transmission ratio.

(2) Tooth profile normal method: the tooth profile normal method is a drawing method, and in order to obtain an accurate tooth profile, enough tooth profile normals need to be made, so that the modeling process is too complicated.

(3) An analytical method: the analytic method is that according to the gear meshing principle, a tooth profile equation is constructed, the data point coordinates of the tooth profile are obtained through calculation, a tooth profile curve is established in three-dimensional modeling software according to the data point coordinates, and stretching forming is carried out on the basis of the tooth profile curve.

(4) A cutter enveloping method: the tool enveloping method comprises two methods, wherein one method is to carry out secondary development in three-dimensional design software and generate a non-circular gear three-dimensional model through a generating method principle; and the other method is to program to obtain a machining process track envelope graph, and design an algorithm to extract tooth profile points of the non-circular gear, wherein the method has higher requirements on programming.

In summary, the existing design method requires complicated calculation and drawing, and the application of the non-circular gear is limited to a great extent.

Disclosure of Invention

The invention aims to provide a simple three-dimensional solid modeling method for a non-circular gear pair with a cosine tooth profile, which has the advantages of simple process, small calculated amount and high transmission precision of the obtained three-dimensional model.

In order to realize the purpose, the technical scheme adopted by the invention is as follows:

a three-dimensional solid modeling method for a non-circular gear pair with a cosine line tooth profile comprises the following steps:

(1) Setting a center distance and a transmission ratio function between a driving wheel and a driven wheel of the non-circular gear pair, and listing equations of a driving wheel pitch curve and a driven wheel pitch curve under a polar coordinate system;

(2) Coordinate conversion is carried out, and equations of the driving wheel pitch curve and the driven wheel pitch curve under a polar coordinate system are converted into equations under a Cartesian coordinate system;

(3) Make the driving wheel turn angle phi ₁ Performing linear interpolation between 0 pi and 2 pi, and calculating point coordinate values on a driving wheel pitch curve and a driven wheel pitch curve corresponding to different rotation angle values in an EXCEL table;

(4) Respectively storing the point coordinate values on the driving wheel pitch curve and the driven wheel pitch curve obtained by calculation in a note file, and modifying the suffix name of the note file from txt to dat;

(5) Opening UG NX software, importing the dat note file obtained in the step (4), and respectively generating a driving wheel pitch curve and a driven wheel pitch curve in a point-to-line mode;

(6) Creating a tooth blank

Measuring pitch curve length L of the driving wheel or the driven wheel in UG NX, setting the number of teeth of a cylindrical gear shaper cutter conjugated with the driving wheel and the driven wheel as z, and then determining the modulus of the gear shaper cutter

Selecting a driving wheel pitch curve to carry out curve offset, and setting the crest height coefficient ha ^* The offset distance is ha = ha ^* X M to obtain the tooth top curve of the driving wheel, and aligning the tooth top curve along the negative direction of the Z axisStretching to obtain a driving wheel tooth blank; the same method is adopted, a driven wheel pitch curve is selected as an object, and the offset distance is ha = ha ^* Obtaining a tooth top curve of the driven wheel by multiplying M, stretching the tooth top curve along the Z-axis negative direction by the same stretching distance as the tooth blank of the driving wheel, and obtaining a tooth blank of the driven wheel;

(7) Creating a three-dimensional model of a slotting cutter

Creating a model file in UG NX software, creating a cylindrical slotting tool entity model with a tooth profile being a cosine line, calculating the diameter D = Mxz of a reference circle of a slotting tool, and drawing a sketch of the reference circle on one end face of the slotting tool by taking the center of the end face as the center of a circle and D as the diameter;

(8) Assembling the gear blank and the gear shaper cutter

Newly building an assembly file in UG NX software, assembling a driving gear blank and a gear shaper cutter together, wherein a pitch curve of a driving wheel is tangent to a pitch circle of the gear shaper cutter, an intersection point of an X-axis negative semi-axis and the pitch curve is taken as an object on the driving gear blank, a central point of any gear tooth on the pitch circle is taken as an object on the gear shaper cutter, and the two points are superposed to obtain the assembly file of the driving gear blank and the gear shaper cutter;

when the driven wheel tooth blank is assembled with the gear shaper cutter, the pitch curve of the driven wheel is tangent to the reference circle of the gear shaper cutter, in addition, the intersection point of the X-axis negative half shaft and the pitch curve is taken as a starting point on the driven wheel tooth blank, and the arc length from the starting point is taken as the arc length on the pitch curve

Taking the central point of any gear tooth on the reference circle on the gear shaping cutter as an object, and overlapping the two points to obtain an assembly file of a driven wheel gear blank and the gear shaping cutter;

(9) Motion simulation

Opening an assembly file of a driving wheel gear blank and a slotting cutter in UG NX, switching to a motion simulation module, performing motion simulation according to the steps of setting a connecting rod, setting a motion pair, setting a drive, setting a constraint, setting a tracking, setting a resolving scheme and solving calculation, and storing the position and the model of the slotting cutter in each calculating step in the solving process of the motion simulation;

in the same way, the motion simulation process of an assembly model of the driven wheel gear blank and the gear shaper cutter is carried out;

(10) Solid model extraction

After the motion simulation solving of the driving wheel tooth blank and the pinion cutter assembly model is completed, clicking a geometric body-lifting body to operate, selecting the driving wheel tooth blank as a lifting target object in a dialog box of the lifting body, and clicking to confirm to complete the setting of the lifting body; selecting a lifting body in a part navigator as a target to obtain a three-dimensional model of a driving wheel;

the extraction mode and the steps of the three-dimensional solid model of the driven wheel are the same as those of the driving wheel, and the three-dimensional model of the driven wheel is obtained;

(11) Creation of non-circular gear pairs

And newly building an assembly file in UG NX to complete the assembly of the driving wheel and the driven wheel, and ensuring that the tooth grooves of the driving wheel are just meshed with the gear teeth of the driven wheel at a zero line to obtain a non-circular gear pair three-dimensional model.

Further, the step (8) of assembling the gear blank and the pinion cutter is as follows:

newly building an assembly file in UG NX software, assembling a driving wheel gear blank and a gear shaper cutter together, wherein a pitch curve of a driving wheel is tangent to a pitch circle of the gear shaper cutter, an intersection point of an X-axis negative half shaft and the pitch curve is taken as an object on the driving wheel gear blank, a central point of any gear tooth on the pitch circle is taken as an object on the gear shaper cutter, and the two points are overlapped to obtain the assembly file of the driving wheel gear blank and the gear shaper cutter;

when the driven wheel tooth blank is assembled with the gear shaper cutter, the pitch curve of the driven wheel is tangent to the reference circle of the gear shaper cutter, besides, the intersection point of the X-axis negative half shaft and the pitch curve is taken as a starting point on the driven wheel tooth blank, and the arc length from the starting point is taken as

The center point of any gear tooth on the reference circle is used as an object on the gear shaping cutter, and the two points are superposed to obtain an assembly file of a driven wheel tooth blank and the gear shaping cutter.

The invention has the following advantages:

according to the transmission ratio function and the center distance, point coordinate values on pitch curves of a driving wheel and a driven wheel in a non-circular gear pair are obtained in an EXCEL table, UG NX software is imported to obtain pitch curves of the driving wheel and the driven wheel, a gear blank is created on the basis, the initial position and the relative motion of the gear blank and a gear shaper cutter model are defined, and a solid model of the non-circular gear is obtained by means of motion simulation. The three-dimensional model obtained by the method is superior to a conversion tooth form method in transmission precision; the method has a relatively simple drawing process in three-dimensional software, and is convenient and fast to draw compared with a tooth profile method; the method has no complex calculation process, can complete all calculations in the EXCEL, and has small calculation amount compared with an analytical method; the method adopts UG NX motion simulation technology to obtain the three-dimensional model of the non-circular gear pair, does not need to design an algorithm for programming, and has small development difficulty compared with a cutter enveloping method.

The three-dimensional solid modeling method of the non-circular gear pair with the residual chord line tooth profile provides a foundation and a support for theoretical analysis, processing and manufacturing and engineering application of the non-circular gear pair, and the obtained accurate three-dimensional digital model of the non-circular gear pair can be directly applied to analysis and manufacturing.

Drawings

FIG. 1 is a flow chart of the modeling process of the present invention

FIG. 2a Driving track Curve

FIG. 2b driven wheel pitch curve

Figure 3a drive wheel tooth blank

FIG. 3b driven wheel tooth blank

Figure 4 slotting cutter and reference circle thereof

FIG. 5 Assembly of driver gear blank and pinion cutter

FIG. 6 Assembly of driven wheel tooth blank and pinion cutter

FIG. 7 shows the result of the simulation of the motion of the gear blank of the driving wheel and the pinion cutter

FIG. 8 shows the result of the simulation of the movement of the driven wheel gear blank and the gear shaper cutter

FIG. 9 three-dimensional model of driving wheel

FIG. 10 three-dimensional model of driven wheel

FIG. 11 non-circular gear set

Detailed Description

The present invention will be described in further detail with reference to specific examples, but the present invention is not limited thereto.

As shown in FIG. 1, the three-dimensional solid modeling method for the non-circular gear pair with the chordal tooth profile comprises the following steps:

(1) Setting the central distance between the driving wheel and the driven wheel and the transmission ratio function, listing the equations of the driving wheel and the driven wheel under the polar coordinate system

For example, the center-to-center distance is set to a =50mm

Function of transmission ratio of i ₂₁ ＝1-0.5cosφ ₁ ，φ ₁ ∈[0,2π]

Wherein phi is ₁ Is a corner of the driving wheel

Under the polar coordinate system, the pitch curve equation of the driving wheel is as follows:

wherein r is ₁ Is radial of a driving wheel

The pitch curve equation of the driven wheel is:

wherein r is ₂ Is directed radially from the driven wheel ₂ For turning the driven wheel

(2) Coordinate conversion is carried out, and the equation of the driving wheel and the driven wheel under a polar coordinate system is converted into the equation under a Cartesian coordinate system

The equation of the driving wheel pitch curve in a Cartesian coordinate system is as follows:

wherein x is ₁ 、y ₁ 、z ₁ Is the coordinate value of the point on the driving wheel pitch curve in a Cartesian coordinate system

The equation of the driven wheel pitch curve in the Cartesian coordinate system is

Wherein x is ₂ 、y ₂ 、z ₂ As a coordinate value of a point on the slave wheel pitch curve in a Cartesian coordinate system

(3) Make the rotation angle phi of the driving wheel ₁ And performing linear interpolation between 0 pi and 2 pi, and calculating point coordinate values on the driving wheel pitch curve and the driven wheel pitch curve corresponding to different rotation angle values in EXCEL.

TABLE 1 active wheelset curve data

φ ₁ (°) is the angle of rotation of the driving wheel

φ ₁ (rad) is the angle of rotation (radian) of the driving wheel

r ₁ Is radial of a driving wheel

x ₁ 、y ₁ 、z ₁ Is the coordinate value of the point on the driving wheel pitch curve in a Cartesian coordinate system

TABLE 2 slave wheel section Curve data

φ ₂ (rad) for the driven wheel corner (radian)

r ₂ Radial direction for driven wheel

x ₂ 、y ₂ 、z ₂ As a coordinate value of a point on the slave wheel pitch curve in a Cartesian coordinate system

(4) And respectively storing the point coordinate values on the driving wheel pitch curve and the driven wheel pitch curve which are obtained by calculation in a note file, and modifying the suffix name of the note file from txt to dat.

(5) And (3) opening UG NX software, selecting the dat file generated in the step (4) by clicking splines, points in the file, and after clicking is determined, respectively generating a driving wheel pitch curve and a driven wheel pitch curve in a point-to-line mode, wherein the driving wheel pitch curve and the driven wheel pitch curve are as shown in a figure 2a and a figure 2b, and storing the files.

(6) Creating a tooth blank

Measuring the pitch curve length of the driving wheel or the driven wheel in UG NX, and obtaining the length of the two pitch curves L =155.0814mm by measurement

The number of teeth of a cylindrical gear shaping cutter conjugated with a driving wheel and a driven wheel is set to be z =20

Modulus of the pinion cutter

Selecting a driving wheel pitch curve to carry out curve offset, and setting the crest height coefficient ha ^* =1, the offset distance is ha = ha ^* Obtaining the addendum curve of the driving wheel by multiplying by M =2.4694mm, stretching the addendum curve, wherein the stretching direction is the Z-axis negative direction, the stretching distance is 20mm, obtaining a driving wheel tooth blank as shown in figure 3a, and storing a file.

And selecting a driven wheel pitch curve as an object by the same method, wherein the offset distance is 2.4694mm, obtaining a driven wheel tooth crest curve, stretching the driven wheel tooth crest curve, wherein the stretching direction is a Z-axis negative direction, the stretching distance is 20mm, obtaining a driven wheel tooth blank as shown in figure 3b, and storing a file.

(7) Creating a three-dimensional model of a slotting cutter

Creating a model file in UG NX software, creating a cosine line tooth profile sketch map, wherein the cosine line tooth profile equation is

xt, yt, zt are coordinate values of points on the tooth profile of the cosine line in a Cartesian coordinate system

M is the modulus of the pinion cutter

z is the number of teeth of the slotting cutter

H is the tooth crest height of the pinion cutter, and the value of the tooth crest height is deviated from the pitch curve in the step (6)Set distance h _a Are identical to each other

t is an expression variable in UG NX, and the variation range is 0-1

Substituting the parameter values into calculation to obtain a cosine line tooth profile equation of the gear shaper cutter as

And stretching the cosine line tooth profile sketch of the slotting cutter, wherein the stretching direction is the Z-axis negative direction, and the stretching distance is 20mm, so as to generate a solid model of the slotting cutter.

Calculating the pitch circle diameter D = M multiplied by z =49.3880mm of the pinion cutter

On one end face of the pinion cutter, a reference circle sketch is drawn by taking the center of the end face as the center of a circle and taking 49.3880mm as the diameter, and a file is stored as shown in figure 4.

(8) Assembling the gear blank and the gear shaper cutter

In addition, the intersection point of the X-axis negative half shaft and the pitch curve is taken as an object on the driving wheel tooth blank, the central point of any one gear tooth on the pitch circle is taken as an object on the gear shaper cutter, the two points are superposed as shown in figure 5, and the file is saved.

When the driven wheel tooth blank is assembled with the gear shaper cutter, the pitch curve of the driven wheel is tangent to the reference circle of the gear shaper cutter, besides, the intersection point (point A) of the negative half shaft of the X axis and the pitch curve is taken as a starting point on the driven wheel tooth blank, and the arc length from the starting point is taken as

The center point (B point) of any gear tooth on the reference circle on the slotting cutter is used as an object, and the two points are overlapped as shown in fig. 6, and a file is stored.

(9) Motion simulation

Opening an assembly file of a driving wheel gear blank and a gear shaper cutter in UG NX, switching to a motion simulation module, and performing motion simulation according to the steps of setting a connecting rod, setting a kinematic pair, setting a drive, setting a constraint, setting a tracking, setting a solution scheme and solving calculation.

Setting a connecting rod: setting a driving wheel gear blank and a pitch curve as a fixed connecting rod L001, setting a connecting rod L002 as a connecting line of an original point of the driving wheel gear blank and the circle center of the gear slotting cutter, and setting a gear slotting cutter and a reference circle as a connecting rod L003;

setting a kinematic pair: a rotating pair J001 is arranged on the connecting rod L002, and the rotating center of the rotating pair J001 is the origin of the driving wheel gear blank;

drive setting: a constant drive is arranged on the rotating pair J001, and the rotating speed is 360 DEG/s;

setting a constraint: selecting the center of a reference circle of a connecting rod L003 as a target point, and defining a connecting line between the origin of the driving wheel gear blank and the center of a gear shaper cutter as a target line; selecting a pitch curve on a driving wheel gear blank as a first target curve, selecting a reference circle of a pinion cutter as a second target curve, setting locking sliding, and defining a line upper pair;

setting and tracking: selecting a pinion cutter as a tracking object;

setting a resolving scheme: setting the simulation time to be 1s and the step number to be 200;

solving and calculating: and (4) solving the motion simulation, wherein the position and the model of the slotting cutter are automatically backed up in each calculation step.

The motion simulation result of the driving wheel gear blank and the gear shaper cutter is shown in figure 7, and a file is saved.

The motion simulation creation mode and the steps of the assembly model of the driven wheel gear blank and the gear shaper cutter are the same as those described above. The motion simulation result of the driven wheel gear blank and the gear shaper cutter is shown in figure 8, and a file is saved.

(10) Solid model extraction

And after the motion simulation solving of the driving wheel tooth blank and the pinion cutter assembly model is completed, clicking the geometric body-lifting body to operate, selecting the driving wheel tooth blank as a lifting target object in a dialog box of the lifting body, and clicking to confirm to complete the setting of the lifting body.

Clicking a geometry body, combining and subtracting, entering a difference dialog box, selecting a lifting body in the part navigator as a target, selecting a feature group in the part navigator as a tool, clicking to determine that a driving wheel and a slotting cutter appear in a view window. The three-dimensional model of the capstan selected in the view window is shown in FIG. 9 and stored as a separate file.

The extraction method and steps of the three-dimensional entity model of the driven wheel are the same as those of the driving wheel, and the three-dimensional entity model of the driven wheel is obtained and stored as an independent file as shown in figure 10.

(11) Creation of non-circular gear pairs

And (3) newly building an assembly file in UG NX to complete the assembly of the driving wheel and the driven wheel, ensuring that the tooth grooves of the driving wheel are just meshed with the gear teeth of the driven wheel at a zero line, and forming a non-circular gear pair after the assembly as shown in figure 11.

The present invention is described in detail with reference to the above embodiments, and those skilled in the art should understand that: modifications and equivalents may be made to the embodiments of the invention without departing from the spirit and scope of the invention, which is to be covered by the claims.

Claims (2)

1. A three-dimensional solid modeling method for a non-circular gear pair with a cosine line tooth profile is characterized by comprising the following steps:

(1) Setting a center distance and a transmission ratio function between a driving wheel and a driven wheel of the non-circular gear pair, and listing equations of a driving wheel pitch curve and a driven wheel pitch curve under a polar coordinate system;

(2) Coordinate conversion is carried out, and equations of the driving wheel pitch curve and the driven wheel pitch curve under a polar coordinate system are converted into equations under a Cartesian coordinate system;

(3) Make the driving wheel turn angle phi ₁ Linear interpolation is carried out between 0 pi and 2 pi, and point coordinate values on a driving wheel pitch curve and a driven wheel pitch curve corresponding to different rotation angle values are calculated in an EXCEL table;

(4) Respectively storing the point coordinate values on the driving wheel pitch curve and the driven wheel pitch curve obtained by calculation in a note file, and modifying the suffix name of the note file from txt to dat;

(5) Opening UG NX software, importing the dat note file obtained in the step (4), and respectively generating a driving wheel pitch curve and a driven wheel pitch curve in a point-to-line mode;

(6) Creating a tooth blank

Measuring pitch curve length L of the driving wheel or the driven wheel in UG NX, setting the number of teeth of a cylindrical gear shaper cutter conjugated with the driving wheel and the driven wheel as z, and then determining the modulus of the gear shaper cutter

Selecting a driving wheel pitch curve to carry out curve offset, and setting the crest height coefficient ha ^* The offset distance is ha = ha ^* Obtaining a tooth top curve of the driving wheel by multiplying M, and stretching the tooth top curve along the Z-axis negative direction to obtain a driving wheel tooth blank; by the same method, a driven wheel pitch curve is selected as an object, and the offset distance is ha = ha ^* Obtaining a driven wheel tooth top curve by multiplying M, stretching the driven wheel tooth top curve along the Z-axis negative direction, wherein the stretching distance is the same as that of the driving wheel tooth blank, and obtaining a driven wheel tooth blank;

(7) Creating a three-dimensional model of a slotting cutter

Creating a model file in UG NX software, creating a solid model of the cylindrical slotting tool with the tooth profile being a cosine line, calculating the reference circle diameter D = Mxz of the slotting tool, and drawing a reference circle sketch on one end face of the slotting tool by taking the center of the end face as the center of a circle and D as the diameter;

(8) Assembling the gear blank and the gear shaper cutter

Newly building an assembly file in UG NX software, assembling a driving wheel gear blank and a gear shaper cutter together, wherein a pitch curve of a driving wheel is tangent to a pitch circle of the gear shaper cutter, an intersection point of an X-axis negative half shaft and the pitch curve is taken as an object on the driving wheel gear blank, a central point of any gear tooth on the pitch circle is taken as an object on the gear shaper cutter, and the two points are overlapped to obtain the assembly file of the driving wheel gear blank and the gear shaper cutter;

when the driven wheel tooth blank is assembled with the gear shaper cutter, the pitch curve of the driven wheel is tangent to the reference circle of the gear shaper cutter, besides, the intersection point of the X-axis negative half shaft and the pitch curve is taken as a starting point on the driven wheel tooth blank, and the arc length from the starting point is taken as

Taking the central point of any gear tooth on the reference circle on the gear shaping cutter as an object, and overlapping the two points to obtain an assembly file of a driven wheel gear blank and the gear shaping cutter;

(9) Motion simulation

Opening an assembly file of a driving wheel gear blank and a slotting cutter in UG NX, switching to a motion simulation module, performing motion simulation according to the steps of setting a connecting rod, setting a motion pair, setting a drive, setting a constraint, setting a tracking, setting a calculation scheme and solving and calculating, and storing the position and the model of the slotting cutter in each calculation step in the solving process of the motion simulation;

in the same way, the motion simulation process of an assembly model of the driven wheel gear blank and the gear shaper cutter is carried out;

(10) Non-circular gear solid model extraction

After the motion simulation solving of the driving wheel tooth blank and the pinion cutter assembly model is completed, clicking a geometric body-lifting body to operate, selecting the driving wheel tooth blank as a lifting target object in a dialog box of the lifting body, and clicking to confirm to complete the setting of the lifting body; selecting a lifting body in a part navigator as a target to obtain a three-dimensional model of a driving wheel;

the extraction mode and the steps of the three-dimensional solid model of the driven wheel are the same as those of the driving wheel, and a three-dimensional model of the driven wheel is obtained;

(11) Creation of non-circular gear pairs

And (4) newly building an assembly file in UG NX, completing the assembly of the driving wheel and the driven wheel, and ensuring that the tooth grooves of the driving wheel are just meshed with the gear teeth of the driven wheel at a zero line to obtain a non-circular gear pair three-dimensional model.

2. The method of three-dimensional solid modeling of a non-circular gear pair with a cosine line profile as claimed in claim 1, wherein: and (8) assembling the gear blank and the gear shaper cutter specifically as follows:

newly building an assembly file in UG NX software, assembling a driving gear blank and a gear shaper cutter together, wherein a pitch curve of a driving wheel is tangent to a pitch circle of the gear shaper cutter, an intersection point of an X-axis negative semi-axis and the pitch curve is taken as an object on the driving gear blank, a central point of any gear tooth on the pitch circle is taken as an object on the gear shaper cutter, and the two points are superposed to obtain the assembly file of the driving gear blank and the gear shaper cutter;

when the driven wheel tooth blank is assembled with the gear shaper cutter, the pitch curve of the driven wheel is tangent to the reference circle of the gear shaper cutter, besides, the intersection point of the X-axis negative half shaft and the pitch curve is taken as a starting point on the driven wheel tooth blank, and the arc length from the starting point is taken as

The center point of any gear tooth on the reference circle is used as an object on the gear shaping cutter, and the two points are superposed to obtain an assembly file of a driven wheel tooth blank and the gear shaping cutter.

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