CN1230772C - Process for contour control mochining of metal blocks - Google Patents
Process for contour control mochining of metal blocks Download PDFInfo
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- CN1230772C CN1230772C CN 00818783 CN00818783A CN1230772C CN 1230772 C CN1230772 C CN 1230772C CN 00818783 CN00818783 CN 00818783 CN 00818783 A CN00818783 A CN 00818783A CN 1230772 C CN1230772 C CN 1230772C
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- arc
- rotary table
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- turbine blade
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Abstract
The invention comprises a computer aided program for milling machine to machine precise concave and convex surfaces within a metal block to form the base section of a turbine blade called the root section (1). The root sectio n (1) of the turbine blade is designed to fit within precise tolerances upon a circular rotor. Because of the curvatures of the mating surface of the root section and the mating section of the circular rotor, the machining of the root section of the turbine blade requires convex movements of the form cutt er tool (9) and rotating of the rotary table (7) which holds the turbine blades . The invention teaches a method of determing machining instructions for machining of a workpiece using a machine having a cutter (9), the surfaces o f the workpiece being defined by a plurality of programmed instructions obtain ed by trigonometric analysis of the required surface curvatures.
Description
Technical field
The application requires the preferential of sequence number 60/114916 temporary patent application submitted on January 5th, 1999.
Background technology
The present invention relates to having the processing of the curved process component of complexity.Particularly object turbine blade root is such has the processing of a plurality of complex-curved elements on a single process component.
When the turbine blade root is carried out machine work, can adopt several steps, each step needs a specific installation to carry out independent process operation.These steps can comprise the thick moulding of raw-material cutting, raw material is milled the size that becomes to need, deburring, polishing, be machined to the size of requirement again: the root to turbine blade is rough milled, the thick finish-milling of root camber line, last tapering are processed and the edge are carried out the base portion final molding that manual grinding makes turbine blade.Turbine root after the moulding will satisfy the tolerance to size, thickness, shape and curvature.
At present, the method that the continuous process operation of many employings is made the turbine blade root all needs to carry out tolerance measurement, process operation separately and use a plurality of process equipments.The present invention has been conceived to cut down a large amount of independent step in the prior art of processing the turbine blade root as far as possible, and basic purpose is by the horizontal or vertical machining center with rotary table, improves the job operation of turbine blade root.
Summary of the invention
To a metal object such as turbine blade, have in the processing of machine gear of multiaspect profile, to obtain intersecting at grade and simultaneous composite surface, for example convex-concave surface according to designing requirement.Have continuous level and exist simultaneously in the manufacturing process of metal object of convex-concave surface, representational is to obtain high-precision smooth surface by milling machine milling metal parts.
The present invention includes a kind of profile control job operation of metal parts, by standard computer Digital Control process, control conventional milling machine at vertical machining center or only have on the horizontal machining center of whole rotary table and process concave-convex curved surface with rotary table.This method comprises, use has the machine of a rotational forming cutter and a rotary table, surface of the work is by a plurality of programmed instruction decisions that are used for described computer numerical control (CNC) milling machine, this programmed instruction obtains by the trigonometric function analysis is carried out in the motion of desired surface curve and described rotational forming cutter and described rotary table, the described motion of described rotational forming cutter is along convex path, simultaneously, the described motion of described rotary table is rotated from negative rotation corner of a positive rotation angle, also can rotate to a dextrorotation corner from a negative rotation corner.
Technology of the present invention is finished all metal cuttings and procedure of processing by permission on horizontal or vertical machining center, reduced the quantity of using conventional milling machine to process equipment needed thereby separately according to routine.All cuttings, grinding and processing are carried out on a milling machine, rather than use a plurality of cuttings, equipment for grinding and milling machine according to common process.
Description of drawings
Fig. 1 is mounted in the turbine blade skeleton view on the rolling clamp with forming tool;
Fig. 2 is mounted in the skeleton view that turbine blade arrival-Q ° angle on the rolling clamp with forming tool begins cutting operation;
The turbine blade that Fig. 3 is mounted on the rolling clamp with forming tool arrives the skeleton view that 0 ° of angle is carried out cutting operation;
Fig. 4 is mounted in the skeleton view of turbine blade arrival+Q ° of angle end cutting operation on the rolling clamp with forming tool;
Fig. 5 is Fig. 2,3,4 detail drawing;
Fig. 2,3,4 and 5 corresponding statements to the turbine blade parts are installed in require the turbine blade base portion to produce the control procedure of arc-shaped curved surface in the turbine rotating shaft;
Fig. 2,3,4 and 5 describes in detail programmed instruction under the milling machine, makes milling machine mill out the process that the final formation of convex-concave surface can accurately cooperate the turbine blade root of installation with the turbine rotating shaft.
Embodiment
The present invention is used for the milling machine computer aided program by one and constitutes, as is used for accurately processing convex-concave surface on metal parts, forms the equipment of the base portion of the turbine blade that is called root (1).Turbine blade root (1) is designed to have accurate tolerance fit with the turbine gyroscope wheel.In the use, the rotation of rotor produces powerful centrifugal force.The split structural requirement turbine blade of turbine blade is quite accurate with cooperating of rotor, and the turbine blade parts of monolithic will avoid relative turbine rotor to produce skew as far as possible, cause in operational process and vibrate.
The turbine blade root is designed to have accurate tolerance fit with revolving rotor.Because the matching surface of turbine blade root and the mating part of round rotor are curved surfaces, the root processing of turbine blade needs forming tool (9) to do the convex line motion, and clamping turbine and is rotated the rotary table (7) of sheet root.Forming tool (9) is done convex line motion (see center line accompanying drawing 5) to the L point along convex path (E+R) from the A point, forming tool rotates, rotary table rotates from-Q ° angle+Q ° of angle simultaneously, and (referring to accompanying drawing 5) this operation also can begin to finish to the A point from the L point.
What Fig. 2,3,4 and 5 described is above-mentioned motion process.Forming tool begins to contact with the null region (see figure 2) of root from A point (see figure 5), and by being arranged so that effectively it contacts with root through L point (see figure 5) and maintenance along convex line left.On the other hand and since rotary table from-Q ° to+Q ° rotation, forming tool will contact the mid point C that passes through among Fig. 5 left along convex path (E+R) with root.
Begin to rotate to dextrorotation corner+Q ° (of+Q ° of in the opposite rotaryangle) at C point rotary table, forming tool contacts with root along convex line to the L point from the C point.
Since need three same cutting surfaces of arc (holding hooks) to cut to forming fixedly, root will be close in the position of rotational forming cutter.Fig. 5 describes the motion of forming tool.As shown in Figure 5, radius R, R+D1 and R+D2 are three radius values on the cutting tip, referring to Fig. 1,2,3 and 4.
Fig. 5 specifically describes as follows:
E+R represents the convex line radius value (representing with center line) that obtains of ordering to A through the C point from the L point of parts;
The L point is determined bee-line P in+Q ° an angular direction and apart from M;
C o'clock at the definite bee-line E in place, 0 ° of angle;
The A point is determined bee-line F and distance Y in-Q ° an angular direction;
V represents to rotate to from L point (center cutter) distance at the edge of parts;
M represents the distance from the L point to rotation center;
S is the distance (size is determined according to Fig. 5) from the cone flank arm of angle to center of gravity;
K is the distance (size is determined according to Fig. 5) from the center of gravity to the straight flange;
G is less blade pitch (size is determined according to Fig. 5);
Y is the distance of point from the rotation center to A;
W is for rotating to the distance at parts edge from the A point;
D1 be from first arc to the distance (size according to Fig. 5 determine) of arc;
D2 is from the distance of first arc to the, three arcs (size is determined according to Fig. 5);
R is the fixedly radius of arc of first arc (size is determined according to Fig. 5);
E is to the fixing distance of arc (first hook holdinghood) of first arc from the rotary table center;
-Q ° is rotation angle (need select, make W greater than tool radius) to the right;
+ Q ° is rotation angle (need select, make V greater than tool radius) left;
P is the distance of ordering from the rotary table center to L;
F is the distance of ordering from the rotary table center to A;
J is along the distance (actual measurement distance) to the rotary table center from the blade edge after the processing;
The distance (size according to Fig. 5 determine) of N for recording at center line to first arc from the blade edge edge;
Technological process of the present invention adopts cost-effective computer program that the turbine blade root is processed.
Cost-effective program can be used as operating system on the horizontal or vertical machining center of employing of standard control.Program is based on the three-legged structure relation of expression among Fig. 2,3,4 and 5.As an embodiment, program is by the manual typing of operator, and the coordinate that A point and L are ordered, angle (+Q ° with-Q °) and radius (E+R) obtain by following CAD simulator program:
G00G90X0.Y-1.792122.A85.2
G00Z-1.7011M8;
G02X0.Y1.7921Z-1.7011R21.417A94.8F.003
The concrete grammar that generates the CAD simulator program is as follows:
Use the total system of the CAD simulator program of variable generation to be described as follows:
Radius R, R+D1 and R+D2 are the radiuses of processing on workpiece, describe in Fig. 5.
Three are extended radius (R, R+D1 and R+D2) and first trapezoidal (solid line) draws at 0 degree angle; D1 is the distance from first arc 10 to middle arc 11.D2 is the distance from first arc to the, three arcs 12.This operation can be applied on the turbine blade with arbitrarily individual arc.
To be first figure obtain to-Q ° angular direction a swivel replication along radius for three radiuses and second trapezoidal (dot-and-dash line).
To be first figure obtain to+Q ° angular direction a swivel replication along radius for three radiuses and the 3rd trapezoidal (dotted line).
Above rotation all be as rotation center with the center of rotary table.
The C point is determined by bee-line E
The A point is determined by bee-line F
The L point is determined by bee-line P
Can determine that by L, C and 3 mappings of A numerical value is the new radius of E+R
The new radius size that constitutes is radius E and radius R sum
Radius E is to be the distance of the arc of R to radius from rotation center (rotary table center).Numerical value is that the radius of E+R is that the triangle mapping obtains.
Radius R is a concave, and radius E+R is a convex line.Size E can select after installation or determine, but obtains by mapping.Size V and W by angle+Q ° and-Q ° determines.These sizes must make and can remove the workpiece part when cutter is started working greater than the radius of cutter.
Fig. 2,3,4 and 5 has described a processing working angles of being determined by the control program in using of Processing Curve on camber line.
Forming tool the A point with-a Q ° angle enters turbine blade.Root (1) is positioned at-Q ° angle on.As shown in Figure 2, forming tool runs to L point (cutter rotates simultaneously) with radius E+R (along convex line).Rotary table rotates to left+Q ° position, angle simultaneously shown in Fig. 3,4,5.This operation also can begin to finish to the A point from the L point.
Use the cut of the inventive method, the theoretical tangent line of center cutter line and the arc on cutting point remains 90 °.By realizing with two conventional methods of manual equipment along the arc Processing Curve.A kind of method is that axle is placed on the fulcrum.Cutter is controlled at processing radius on the arc to the distance of fulcrum.Make in this way, turbine blade is a fixed part.Another kind method is that turbine blade is installed on the rotary table, the radius of the radius positioning control arc in the universal stage work.Processing and on arc the CAD program of Processing Curve be crucial, it makes the processing of turbine blade finish on an equipment becomes possibility.
The above-mentioned CAD of use fully program technic, the root of processing rotation turbine blade is to finish at the vertical machining center of three-dimensional computer numerical control (CNC) with the rotary table that is used for micro-turbine machine blade processing, or have be used for the processing of large-scale turbine blade the integral body rotation as a comparison, what list below is prior art processes to the processing of turbine blade root:
1, cutting material
2, thickness processing (milling)
3, manual deburring
4, polishing thickness
5, width processing (milling)
6, manual deburring
7, polishing width
8, rough mill arc and cutter interradicular space
9, awl limit roughing (milling)
10, arc curve processing (thick finish-milling)
11, finishing awl limit (milling) on concave station
12, manual grinding corner on the dovetail groove
13, limit processing (milling)
When 14, needing, balance of steam processing
14 steps are carried out respectively, and each step all needs workpiece is moved on on another equipment from an equipment.
Among the present invention, can or have the horizontal machining center of main universal stage at a vertical machining center with universal stage (being used for vanelets processing) in steps (universal stage of this equipment is bigger, and rigidity is better, is fit to big blade is processed) finish according to following technology:
1, cutting material
2, polishing thickness (only in a side) is cleared up
3, a clamping is finished root processing (thick or smart)
A, awl limit processing (thick or smart)
B, straight flange finishing
C, roughing cambered surface and processing cutter interradicular space are used for withdrawing or standby
D, employing specific program be (thick smart) Processing Curve on arc
E, finishing side
F, processing edge (in original technology manual operations) on the dovetail groove
G, if desired can carry out the processing of balance of steam hole on this equipment
Two kinds of methods are compared, and visible method of the present invention can be saved manpower, and the product manufacturing accuracy is higher, and quality is easy to control in the production.In the technology of the present invention,, make the multistep operation to concentrate and finish by a clamping because step D can finish in a step.
In the prior art, the operation of step D must the branch multistep be finished.According to the method, workpiece is installed in the suitable radial location on the anchor clamps.Processing radius on the radial location decision arc.
In the method, blade is installed in outside the rotating shaft of anchor clamps shown in Fig. 1,2,3 and 4.On the position of a radius, radius can be processed arbitrarily.For with procedure operation D step, use CAD simulation (Fig. 5) to obtain the coordinate that A and L orders, the anglec of rotation+Q ° and-Q ° and convex arc radius E+R value.
In order to carry out the CAD simulation, use the radius R of first arc.All three radius Rs, R+D1, R+D2 draw (obtaining according to drawing) with one heart.It is identical with distance between arc that forming tool is used to process the distance that radius must guarantee to cut between the limit.This just means, if cutter be to keep 90 ° with theoretical tangent line on the cutting point of R at radius, be also to keep 90 ° with theoretical tangent line on the cutting point of R+D1 and R+D2 at radius.
Because this triangle relation has been used radius R, R+D1, R+D2.The size E that is used to map changes, and needs to measure the fan-shaped distance of rotation center to these radiuses.
As long as all radiuses are all drawn with one heart, the quantity of camber line is unrestricted in the method.
The embodiment of CAD only is for example.Yet, no matter how determine the radius sum of coordinate points, angle and E+R, the path that instrument is advanced is always identical.Referring to Fig. 5 and claim.
Promptly use extremely short straight line to replace the travel path of the arc of radius E+R as instrument, the coordinate of end points still will drop on the arc of radius E+R.Adopting extremely short straight line to replace the arc of radius E+R is the other method that realizes above-mentioned technology, can be used as the replacement of said method.
According to top operation, can realize that whole turbine root processes on one or more process equipment.
A, the processing of awl limit
B, straight flange processing
C, roughing cambered surface and processing cutter interradicular space are used for withdrawing or standby
D, employing said process Processing Curve on arc
E, finishing side
F, processing edge (in original technology manual operations) on the dovetail groove
G, if desired can carry out the processing of balance of steam hole on this equipment
The sequence of operation of A to G can change or increase and decrease step as required.
One of the whole processing technology employing or several the equipment (use miscellaneous equipment) of turbine blade root are viewpoints of the present invention.
Claims (5)
1. workpiece is being processed on metal parts, accurately to process in the process of convex-concave surface, for containing a kind of method that processing equipment is determined the processing instruction of milling of at least one three-dimensional computer numerical control (CNC) milling machine, this method comprises, use has the machine of a rotational forming cutter and a rotary table, surface of the work is by a plurality of programmed instruction decisions that are used for described computer numerical control (CNC) milling machine, this programmed instruction obtains by the trigonometric function analysis is carried out in the motion of desired surface curve and described rotational forming cutter and described rotary table, the described motion of described rotational forming cutter is along convex path, simultaneously, the described motion of described rotary table is rotated from negative rotation corner of a positive rotation angle, also can rotate to a dextrorotation corner from a negative rotation corner.
2. the method for claim 1, it is characterized in that: described programmed instruction determines by the trigonometric function analysis is carried out in the motion of the chart of the needed convex-concave surface of final turbine blade root and described rotational forming cutter and described rotary table, and described root has at least one first arc as one first fixing arc.
3. the method for claim 1, it is characterized in that: the described trigonometric function analysis that desired surface curve is carried out comprises, institute with respect to the root that described rotational forming cutter is applied to described turbine blade requires on the curved surface, analysis to the motion of the chart of desired surface curve mapping and described rotational forming cutter and described rotary table, described mapping is the trigonometric function analysis substantially, and described root comprises at least one fixedly arc.
4. the method for claim 1, it is characterized in that: described motion to desired surface curve and described rotational forming cutter and described rotary table is carried out the trigonometric function analysis and is determined that the path of described rotational forming cutter is that radius is the convex arc that E adds R, wherein E is the rotary table center to the fixing distance of arc of first arc, and R is the fixedly radius of arc of first arc.
5. the method for claim 1, it is characterized in that: described motion to desired surface curve and described rotational forming cutter and described rotary table is carried out the trigonometric function analysis and is determined that the path of described rotational forming cutter is that radius is the convex arc that E adds R, wherein radius E adds R by L, 3 of C and A determine, the L point is that rotary table rotates to+terminating point when forming tool cuts out turbine blade during Q ° angle, the L point to anticlockwise+a Q ° angular direction determines bee-line P and apart from M, the C point is rotary table cutting point during the forming tool cutting workpiece when rotating to 0 ° of angle, C o'clock at the definite bee-line E in place, 0 ° of angle, the A point is that rotary table rotates to-starting point during Q ° angle during forming tool incision workpiece, the A point is determined bee-line F and distance Y in dextrorotary-Q ° angular direction, E is the rotary table center to the fixing distance of arc of first arc, and R is the fixedly radius of arc of first arc.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US09/477,858 US6449529B1 (en) | 1999-01-05 | 2000-01-05 | Process for contour machining of metal blocks |
US09/477,858 | 2000-01-05 |
Publications (2)
Publication Number | Publication Date |
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CN1433551A CN1433551A (en) | 2003-07-30 |
CN1230772C true CN1230772C (en) | 2005-12-07 |
Family
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Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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CN 00818783 Expired - Fee Related CN1230772C (en) | 2000-01-05 | 2000-01-18 | Process for contour control mochining of metal blocks |
Country Status (4)
Country | Link |
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CN (1) | CN1230772C (en) |
CA (1) | CA2407002C (en) |
MX (1) | MXPA02007364A (en) |
ZA (1) | ZA200205855B (en) |
Families Citing this family (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN100395673C (en) * | 2004-10-08 | 2008-06-18 | 鸿富锦精密工业(深圳)有限公司 | Generating system and method of forming milling processing code |
CN100402209C (en) * | 2006-07-10 | 2008-07-16 | 潘毅 | Turbine blade reverse-T shaped blade bottom arc machining method |
CN101261105B (en) * | 2008-04-22 | 2010-06-02 | 无锡透平叶片有限公司 | Vane jigs and measuring tool calibration gage |
FR2997884B3 (en) * | 2012-11-09 | 2015-06-26 | Mecachrome France | METHOD AND DEVICE FOR MANUFACTURING TURBINE BLADES |
CN104475835B (en) * | 2014-11-12 | 2016-10-05 | 沈阳黎明航空发动机(集团)有限责任公司 | A kind of blade tenon rounding machining process |
CH712697A1 (en) * | 2016-07-05 | 2018-01-15 | Spitz & Tal Sa | Method of machining a relief model |
CN110497036B (en) * | 2019-08-28 | 2020-10-16 | 西安陕鼓动力股份有限公司 | Molding method and processing method of movable blade tooth-shaped special-shaped chamfer |
CN110889149B (en) * | 2019-10-12 | 2021-04-20 | 大连理工大学 | Method for predicting burr length of fiber reinforced composite material machined by fillet cutter |
-
2000
- 2000-01-18 MX MXPA02007364A patent/MXPA02007364A/en not_active IP Right Cessation
- 2000-01-18 CN CN 00818783 patent/CN1230772C/en not_active Expired - Fee Related
- 2000-01-18 CA CA002407002A patent/CA2407002C/en not_active Expired - Fee Related
-
2002
- 2002-07-22 ZA ZA200205855A patent/ZA200205855B/en unknown
Also Published As
Publication number | Publication date |
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CA2407002C (en) | 2008-05-06 |
ZA200205855B (en) | 2003-10-22 |
MXPA02007364A (en) | 2002-12-16 |
CA2407002A1 (en) | 2001-07-12 |
CN1433551A (en) | 2003-07-30 |
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