PX5
PX5 is a modified P20, high performance, high precision, mold steel.
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PX5 is a modified P20, high performance, high precision, mold steel.
Features:
- Machines 30- to 40 percent faster than P20
- Pre-hardened to 29-33 HRC
- Uniform microstructure & hardness with extremely improved machined surface finish
- Never needs stress relieving
- Improved weldability and greatly reduced susceptibility to weld cracking
- Reduced surface-hardened layer in EDM making finishing operations easier
Applications include:
Plastic Molds
Rubber Molds
Press Plates
Dies
- Exceptionally clean steel with uniform microstructure – no pin holes, inclusions or hard spots.
- 30-33 HRc hardness.
- Uniform hardness throughout, even in heavy sections.
- 75% tougher than typical chrome-moly steels.
- Patented chemistry suppresses weld cracking and hardness elevation in the heat affected zone, eliminating the need for pre-heating and post-heating in most welding situations.
- Machines 30-50% faster than any other P20-type steel.
- Never needs stress relieving, even after heavy machining.
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Benefits
Welding
Superior mold quality after welding. Low hardness of heat affected zone eases post-weld cutting and grinding operations and minimizes mold distortion, etch unevenness, and differences in luster upon mirror finishing. Unique composition eliminates weld cracking.
Machining
Rough machines up to 50% faster than P20 (30% overall) to a superior surface with negligible dimensional change. Use of PX5 assures the longest cutting tool life of any 30 HRc, P20-type material. Consistent hardness and microstructure allow dependable, unattended machining.
EDM
EDM surface hardness is about 70% of that produced by typical P20-type steels. Post-EDM grinding and polishing operations are simpler and more consistent, and problems
such as surface layer cracking or peeling are reduced.
Stability
Uniform hardness and refined grain structure assure the highest level of dimensional stability (after machining) of any P20-type mold steel.
Surface Enhancements
Can be ion-nitrided to produce a surface hardness over 60 HRc with negligible distortion or dimensional change.
Texturing and Polishing
Uniform microstructure and hardness give PX5 the best surface-finish characteristics of any P20-type material. Low chemical segregation eliminates the occurrence of photo etch unevenness.
Toughness
Exceptional toughness reduces cracking problems in molds.
Mechanical Properties
- Isotropy and Uniform Strength PX5’s strength is approximately the same at the center and surface of the material, and that isotropy (T/L) is at least 0.05.
Tensile Properties
When designing deep cavities in molds, PX5’s consistent toughness assures the mold center will have sufficient strength, and cracking problems are dramatically reduced.
Toughness
Physical Properties
Coefficient of thermal expansion (x10-6/F°) | |||||
86-212°F | 86-392°F | 86-572°F | 86-752°F | 86-1112°F | |
PX5 | 6.6 | 7.1 | 7.3 | 7.5 | 7.8 |
Thermal conductivity (btu/ft.·hr.·F°) | |||||
68°F | 68°F | 68°F | 572°F | 752°F | |
PX5 | 24.53 | 24.48 | 24.31 | 22.42 | 22.42 |
Specific heat (btu/lb.·F°) | |||||
68°F | 68°F | 68°F | 572°F | 752°F | |
PX5 | 0.027 | 0.028 | 0.031 | 0.032 | 0.036 |
Young’s modulus (lbs./in²) | |||||
68°F | 212°F | 392°F | 572°F | 752°F | |
PX5 | 30269 | 29768 | 28909 | 28051 | 26977 |
General Design Guidelines
- Compressive Strength
Uniform hardness (approximately 32 HRc) from surface to core assures that strength and hardness at the mold center are the same as at the surface. Exceptional toughness reduces cracking problems while increasing flexibility in mold design.
- Stability PX5 is substantially more stable than common P20-type steels. Since it has a unique heat treating process, it does not have the stresses inherent in typical quenched and tempered steels. PX5 never needs stress relieving, even after heavy machining. It has excellent dimensional stability and consistency during the machining process, and during the heating and cooling cycles of injection or compression molding.
Processing Guidelines
Machining
Use of PX5 assures the longest cutting tool life of any 30 HRc, P20-type material and an overall 20-30% improvement in machining efficiency.
A recent machining test was performed on PX5 material at a mold base manufacturer. Listed below are the tool settings for P20 and the results achieved with PX5.
1.250 Diameter DIJET Ballnose Endmill
P20 | PX5 | |
RPM | 986 | 1600 |
Feed (in/min) | 11.83 | 27.60 |
Depth | .120 | .120 |
Program time was reduced from 38 minutes to 15.2 minutes
1.000 Diameter Waukesha Ballnose Endmill
P20 | PX5 | |
RPM | 1600 | 3000 |
Feed (in/min) | 16.6 | 33.0 |
Depth (Contour) | .160-.180 | .160-.180 |
Program time was reduced from 5.7 minutes to 2.85minutes
.750 Sandvik Ballnose Endmill
P20 | PX5 | |
RPM | 2660 | 3000 |
Feed (in/min) | 18.2 | 36.0 |
Depth (Step Over) | .160 | .160 |
Program time was reduced from 4.91 minutes to 2.5 minutes
(Finish cutter) 1.000 Diameter Iscar Ballnose Endmill
P20 | PX5 | |
RPM | 2419 | 3000 |
Feed (in/min) | 19.35 | 40.00 |
Depth | .060 | .060 |
Program time was reduced from 10 minutes to 4.85 minutes
A 40″ x 41″ x 87″ block of PX5 was forged and heat treated. The piece was cut through 61″ into the 87″ length. The following hardness readings were taken across the face of the test piece.
Sectional Hardness Rockwell C Scale:
The recast layer from EDM for PX5 is soft, approximately 70% of that produced with typical chrome-moly steels. Because the EDM white layer must be removed, the subsequent stoning or grinding of PX5 is much easier than with other steels. There is also a significant reduction in the incidence of problems involving the hardened layer, such as surface layer cracking or peeling. Consequently, no post EDM stress relieving is needed.
PX5’s exceptional cleanliness, uniform microstructure, and uniform through hardness facilitate excellent and consistent surface finishing characteristics. PX5 polishes faster and easier to a superior mirror finish than common P20-type steels. PX5 will polish to a 6000-7000 grit finish, while P20 polishes to only a 5000 grit finish.
PX5 is an excellent steel for photo etching. Low chemical segregation of the alloying elements results in a clean, homogenous steel. Absolutely no etch unevenness will occur due to chemical segregation. PX5’s uniform hardness and refined grain structure also provide a consistent surface condition for texturing. A reduction in work time and cost can be anticipated due to the elimination of etch unevenness problems.
Ion-nitriding increases wear resistance and creates a hard surface ideal for slides or molds which will be molding abrasive or mineral-filled thermoplastics. PX5 can be ion-nitrided to produce a surface hardness over 60 HRc without distortion or dimensional changes. This ion-nitrided surface also improves part release and corrosion resistance.
It is essential that no rod other than PX5 should be used in all welding situations. All other rods are incompatible with the base metal chemistry of PX5 and will produce unacceptable results.
In most cases, PX5 can be welded with no pre- or post-heating procedures. However, this is not true in all situations. We suggest that in the event a polished surface must be welded (such as a lens or chrome-plated parts), pre-heat the block to between 650-900°F. Weld with PX5 rod, then post-heat to between 1040-1050°F. Final draw temperature for PX5 mold steel is 1117°F.
DO NOT, under any circumstances, exceed final draw temperature.
We recognize that many mold welders apply heat locally with torches as a means of pre-heating the welded area. While this is a commonly used procedure, and generally produces acceptable results on non-polished surfaces, it is not recommended for post-heating welded blocks. The result of localized heat of this type is an actual flame-hardening of the weld that will produce an inconsistent increase in hardness by as much as 10-12 points (Rockwell C).
The compositional balance of PX5 was designed to suppress crack sensitivity. The weld will not shrink and crack at the marriage line, even without pre- and post-heating, as long as basic welding conditions are observed.
(determines cracking susceptibility)
Welding method | MAG |
Filler rod | PX5 Weld Rod |
Filler rod Diameter | 0.047″ |
Welding Current | 280 A |
Gas flow rate | 25 /min |
Pre/post heating | None |
Results
PX5
Weld cracking will not occur as long as basic welding conditions and procedures are observed.
PX5 has the lowest level of hardness in the heat-affected zone of any P20-type mold steel. This relatively low increase in hardness reduces post-weld cutting and grinding times (i.e., high-speed steel end mills can be used).
After weld repair, typical P20 will have etch unevenness due to its increased hardness. This requires many hours to correct. PX5’s relatively small increase in hardness in the heat affected zone reduces the incidence of etch unevenness and requires minimal correction work.
Post-weld distortion is the lowest for any P20-type material, due to the relatively small increase in hardness in the weld area. Post-repair dimensional correction work is simplified.
Test Conditions
Welding method | TIG |
Filler rod | PX5 Weld Rod |
Filler rod Diameter | 0.094″ |
Welding Current | 125 A |
Gas flow rate | 7 /min |
Pre/post heating | None |
Test Method
Results
While undercutting or “sink” surrounding the weld will always occur to some degree, PX5 has only a small degree of undercutting, dramatically reducing the amount of repair time.
Test Conditions TIG: 160A, no filler Test piece: 10 degree slant
Weld Sink at Heat Affected Zone
PX5
P20
4140
Technical Center
International Mold Steel specializes in pre-hardened mold and tool steels that are considered to be the finest available in the market place today. Because of their unique and homogenous make-up, deviation in hardness or hard spots is a thing of the past. When machining these materials it will become immediately apparent that much faster metal removal rates can be achieved.
Material Removal Rates
Consider this: material removal rate during this time span in approximately 300 pounds of steel. It showed that we could remove a lot of steel with moderate surface feet but a heavy chip load. Once again, the clean make-up of the material made this possible.
To Calculate Surface Feed
Surface speed is usually given in feet per minute. It is the distance (in feet) that the outermost cutting edge of a rotating tool (circumference) covers in the span of 1-minute.
To understand how this translates into spindle speed, or revolutions per minute (rpm) that the cutting tool is revolving, review this example:
Example:
Surface feet 400 feet per minute Diameter of cutting tool is 4 inches. Revolutions per minute (rpm) if cutting tool is ____
Equation:
C = Surface feet per minute (feet) D = Diameter of cutting tool (inches) R = Revolutions per minute of cutting tool (rpm)
R = (C x 12) = (400 x 12) = 4800 = 382 rpm
(D x Pi) (4 in. x 3.14) 12.56
If you need to know surface feet per minute and the cutter diameter and spindle speed is known, you will have this equation:
C = | Pi x D x R __________ 12 | = | 3.14 x 4 x 382 __________ 12 | = 400 sf. |
To Calculate Chip Load
Chip load is the amount of materials (in .001 inches) that each cutting flute or cutting insert of a rotating tool removes.
Chip load is calculated by dividing the distance of the table travel or feed per minute in inches by the spindle speed of the machine. This will give you the distance the cutter traveled in one revolution. This number is then divided by the number of cutting flutes or inserts.
Example:
Spindle speed is 450 rpm. Table travel or feed rate is 60 inches per minute. Number of flutes or cutting inserts is 6.
Equation:
R = Spindle speed (rpm)
I = Number of cutting flutes or inserts
S = Distance of feed rate or table travel in inches.
C = Chip load
C = | ( | S ___ | ) ( | 60 ____ | ) | = | .13333 __________ 6 | = .0222 |
I |
To Calculate Feed Rate
S = C x I x R =
S = .0222 x 6 x 450
To find rpm of spindle or R with chip load and feed rate known:
R = | S _____ I x C | = | 60 __________ 6 x .0222 | = 450 rpm |
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