It has long been acknowledged that pressing or stamping is a cost-effective way to create intricate pieces. Deep drawn stamping is usually less expensive and always faster than other techniques like machining, fabrication, and injection moulding, notwithstanding the comparatively high initial cost of tooling.
Deep drawing goes a step further in that it allows for the production of pieces that are longer or deeper than what is possible with regular stamping techniques.
Deep Drawing: What Is It?
In the process of deep drawing, which is a type of metal stamping, the draw’s depth is often higher than its diameter. In reality, it is feasible to fabricate long, narrow, cylindrical pieces with lengths that are noticeably longer than their exterior diameters.
Because the materials cannot extend enough during conventional stamping methods, uneven wall thickness, thinning, and tears develop. As a result, such deep draws cannot be achieved. By carefully designing the tools used in deep drawing, it is possible to circumvent this difficulty by forcing material to flow into the die during the early phases of the deep drawing process. By doing this, it is guaranteed that there will be enough material to maintain the necessary wall thickness while achieving the intended shape.
The Process Deep Drawn
Deep drawing is carried out in stages. The blank will be moulded into a cup form that is bigger in diameter than the finished part diameter during the first stage. The diameter of the portion gradually decreases as it progresses, while its depth rises. In order to perform all operations on a single press, tooling is typically ganged together with some kind of component transfer.
With the use of these methods, a part that is more than ten times longer than its outside diameter can be produced via deep drawing.
Deep drawn tooling must be carefully designed. The initial die and punch radii must be properly estimated in order to prevent excessive stretching, which calls for extra caution. Material will not flow properly if the die radius is too tiny, and wrinkling will happen if it is too large. High-strength tool steel should be utilised for the radius at the die entry and all tooling should be finely polished to help with material flow.
In order to guarantee the proper final ratios of stretch, flow, and work hardening, the clearance between the cup and tool is also essential. The press speed is crucial because a high press speed can lead to corner cracking, while a low press speed can interfere with material flow.
Deep Drawn Methodology Advantages
Deep draw has two primary advantages. First off, production rates are high and are only constrained by the press’s speed, which typically has a capacity of more than 2,000 components per hour. Second, the finish obtained eliminates the need for additional processing, and the deep draw tooling can handle auxiliary operations like beading, notching, chamfering, and piercing.
These two elements make the cost per part cheap even after accounting for tooling expenses.
Assessment of Deep Drawn Parts
Deep drawing is typically a viable option for parts that are symmetrical, round or oval, and have a length to diameter ratio under 10. Additionally, an almost infinite variety of materials, including steels, alloys, aluminium, brass, and copper, can be used for deep drawn stamping. Parts are strong, light, and can be made to precise tolerances because of the inherent work hardening that occurs. Most significantly, deep drawn components are frequently those that are expensive and challenging to produce using other methods.
We Sharma Presses are one of the renowned Deep Draw Press manufacturer which produce deep drawing machines. Several businesses require heavy duty frame type deep draw presses. We use pillar-style heavy-duty, high-performance machines used to make deep drawing press components. Deep draw presses are ideal for deep drawing stainless steel kitchen sinks, mudguards, oil tanks, and other sheet metal parts for automobiles.