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Trykstøbt aluminium, Kobber, Rustfrit stål dele
Trykstøbning er en trykstøbningsdel: Brug af trykstøbemaskinen med støbeformen installeret, metallet såsom kobber, zink, aluminium, rustfrit stål eller aluminiumslegering opvarmet til en flydende tilstand hældes i støbeformen på trykstøbemaskinen til trykstøbning. Støbning af kobber, zink, aluminium eller aluminiumslegering dele af form og størrelse begrænset af formen, sådanne dele omtales ofte som trykstøbedele. Trykstøbningsdele kaldes forskelligt forskellige steder: såsom trykstøbningsdele, trykstøbt aluminium, trykstøbte zinkdele, trykstøbte kobberdele, trykstøbte dele af aluminiumslegering, etc.
Kategori: hurtig prototyping
Tags: aluminium fræsedele, CNC-bearbejdning, CNC fræsning, hurtig prototyping
Trykstøbning er en trykstøbningsdel: Brug af trykstøbemaskinen med støbeformen installeret, metallet såsom kobber, zink, aluminium, rustfrit stål eller aluminiumslegering opvarmet til en flydende tilstand hældes i støbeformen på trykstøbemaskinen til trykstøbning. Støbning af kobber, zink, aluminium eller aluminiumslegering dele af form og størrelse begrænset af formen, sådanne dele omtales ofte som trykstøbedele. Trykstøbningsdele kaldes forskelligt forskellige steder: såsom trykstøbningsdele, trykstøbt aluminium, trykstøbte zinkdele, trykstøbte kobberdele, trykstøbte dele af aluminiumslegering, etc.
Characteristics of Die Castings
Because the metal copper, zink, aluminum and aluminum alloy have good fluidity and plasticity, and the casting process is cast in a pressure die-casting machine. Derfor, aluminum die castings can be made into various complex shapes, as well as cast products with higher precision and smoothness. Thereby, the machining amount of the casting and the casting allowance of metal copper, zink, aluminum or aluminum alloy are greatly reduced. It not only saves electricity and metal materials, but also greatly saves labor costs; Kobber, zink, aluminum and aluminum alloys have excellent thermal conductivity, small specific gravity and high machinability; Som resultat, die castings are widely used in: Automobile manufacturing, internal combustion engine production, motorcycle manufacturing, motor manufacturing, oil pump manufacturing, transmission machinery manufacturing, precision instruments, landscaping, electric power construction, architectural decoration and other industries.
quality of die castings
The control of the surface temperature of the die-casting mold is very important for the production of high-quality die-casting parts. Uneven or inappropriate mold temperatures can also lead to dimensionally unstable castings. During the production process, the castings are pulled out and deformed, resulting in defects such as thermal pressure, mold sticking, surface depressions, internal shrinkage cavities and thermal bubbles. When the temperature difference of the mold is large, the variables in the production cycle, such as filling time, cooling time and spraying time, have different degrees of influence.
Frequently Asked Questions about Die Castings
The die casting part is not formed and the cavity is not full
cause:
1. The temperature of the die-casting mold is too low;
2. The temperature of the molten metal is low;
3. The pressure of the press is too small;
4. The metal liquid is insufficient; the injection speed is too high;
5, the air can not be discharged.
Adjustment method: 1- 2. Increase the temperature of die-casting mold and molten metal;
3. Replace the high pressure die casting machine;
4. Add enough molten metal to reduce the injection speed and increase the thickness of the feeding port.
Design specifications for die castings
The design of die-casting parts must take into account the wall thickness of the die-casting parts, the casting fillet of the die-casting parts, the draft angle, and the reinforcing ribs;
Casting holes on die castings;
Minimum hole-to-edge distance, oblong holes and slots on die castings, inserts in die castings, machining allowances in die castings, etc.
Specification for fillet design of castings
Som regel, the intersection of each part of the die casting should have rounded corners (except the parting surface), which can make the metal flow smoothly when filling, and the gas can be easily discharged, and can avoid cracks caused by sharp angles. For die castings that require electroplating and finishing, rounded corners provide a uniform coating to prevent paint build-up at sharp corners. The fillet radius R of the die casting should generally not be less than 1mm, and the minimum fillet radius is 0.5mm.
Specification for Design of Inserts in Die Castings
Først og fremmest, the number of inserts on the die casting should not be too much; For det andet, the connection between the insert and the die casting must be firm, og på samme tid, riller, protrusions, rifling, etc. are required on the insert; Again, the insert must avoid sharp corners for ease of placement and to prevent stress concentrations in the casting. If there is serious galvanic corrosion between the casting and the insert, the surface of the insert needs to be protected by plating; Endelig, heat treatment should be avoided for castings with inserts to avoid volume changes caused by the phase transition of the two metals, loosening the inserts.
Design specification for wall thickness of die castings
Thin-walled die castings have higher strength and better densification than thick-walled die castings. In view of this, the following principles should be followed in the design of die castings: On the premise of ensuring sufficient strength and rigidity of the casting, the wall thickness should be reduced as much as possible, and the wall thickness should be kept uniform. Practice has proved that the wall thickness design of die castings is generally 2.5-4mm, and the parts with wall thickness exceeding 6mm should not be produced by die casting process.
The performance of the influence of too thick and too thin walls of die castings on the quality of castings: If the wall of the casting is too thin in the design, the metal welding will not be good, which will directly affect the strength of the casting and cause difficulties in forming; When the wall is too thick or severely uneven, shrinkage and cracks are likely to occur. På den anden side, with the increase of wall thickness, the defects such as pores and shrinkage inside the casting also increase, which will also reduce the strength of the casting and affect the quality of the casting.
Design specification for machining allowance of die castings
Generelt, due to the limitations of the die-casting process, some dimensional accuracy, surface roughness or geometrical tolerances of the die-casting parts cannot meet the requirements of the product drawings. Enterprises should first consider the use of finishing methods such as correction, polering, extrusion, and shaping to repair. When finishing cannot completely solve these problems, CNC machining should be performed on some parts of the die casting. It should be noted here that a smaller machining allowance should be considered when performing CNC machining. På samme tid, try to use the surface that is not affected by the parting surface and active forming as the blank reference surface, so as not to affect the machining accuracy.
Design specification for draft angle of die castings
When designing die castings, the structural slope should be left on the structure; When there is no structural slope, there must be a process slope for demolding where necessary. The direction of the inclination must be consistent with the direction of demolding of the casting.
Die casting machine classification
Materials that can be processed by hot chamber die casting machine: zinklegering, magnesiumlegering, etc.;
Cold chamber die casting machine can process materials: zinklegering, magnesiumlegering, aluminiumslegering, copper alloy, etc.;
Materials that can be processed by vertical die casting machine: zink, aluminium, kobber, at føre, tin.
The difference between the hot chamber and the cold chamber is whether the injection system of the die casting machine is immersed in the metal solution. Die casting machines can also be divided into horizontal and vertical.
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Fræsemaskine og fræseteknologi
Fræsning refererer til brugen af roterende multi-edge værktøjer til at skære emner, og er en yderst effektiv behandlingsmetode. Når du arbejder, værktøjet roterer (gør hovedbevægelsen), og arbejdsemnet bevæger sig (foderbevægelsen). Arbejdsemnet kan også fikseres, men det roterende værktøj skal også bevæge sig (at fuldføre hovedbevægelsen og foderbevægelsen på samme tid). De værktøjsmaskiner, der bruges til fræsning, er horisontale fræsemaskiner eller vertikale fræsemaskiner, samt store portalfræsere. Disse værktøjsmaskiner kan være almindelige værktøjsmaskiner eller CNC værktøjsmaskiner. Brug en roterende fræser som skæreværktøj. Fræsning udføres generelt på en fræsemaskine eller en boremaskine. Velegnet til behandlingsplan, riller, forskellige formflader (blomsternøgle, gear og gevind) og specialformet overflade af formen og lignende.
Driftssikkerhed af CNC-bearbejdning af metaldele
CNC-værktøjsmaskiner er avanceret procesudstyr med en høj grad af automatisering og en mere kompleks struktur. For at give fuld spil til værktøjsmaskiners overlegenhed, forbedre produktionseffektiviteten, styre, brug, og reparation af CNC-værktøjsmaskiner, kvaliteten af teknisk personale og civiliseret produktion er særlig vigtig. Ud over at være bekendt med ydeevnen af CNC-værktøjsmaskiner, operatører skal også dyrke gode arbejdsvaner og stringente arbejdsstile i civiliseret produktion, og har gode faglige egenskaber, ansvarsfølelse og samarbejdsånd. Følgende skal gøres under drift:
Drejede dele af fritskærende stål, kulstofstål, og miljøvenligt jern
vores virksomhed producerer også forskellige friskærende stålkulstofståldrejedele. Disse kulstofstål omfatter:
Free cutting steel 12L14
The picture on the left is a representative carbon steel turning part of our company. Overfladen er sort og oxideret. Generelt, drejedele af kulstofstål kræver overfladebehandling for at forhindre rust. Tilgængelige overfladebehandlinger inkluderer:
Galvaniseret (herunder miljøvenlig blå og hvid zink og miljøvenlig farvezink), forniklet, sort oxid (som vist på venstre billede), etc.