Melting Plastic and Manufacturing

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Discussion Overview

The discussion revolves around the feasibility of melting plastics for prototype manufacturing and the suitability of injection molding for producing small plastic objects in large quantities. Participants explore various manufacturing methods, including injection molding and extrusion, while considering costs and material properties.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested

Main Points Raised

  • One participant inquires about the possibility of melting plastics for prototyping and whether high pressure is necessary to prevent burning.
  • Another participant clarifies the intention to use injection molding for producing a prototype of about 1000 units, with potential future production scaling to hundreds of thousands or millions.
  • Cost factors for injection molding are noted to depend on size, design, and the number of parts needed for the mold.
  • A participant recommends injection molding as the best option and suggests contacting a specific local company for assistance with mold creation and production.
  • One participant considers an alternative method of extruding plastic and cutting it to length, questioning its effectiveness compared to injection molding.
  • Another participant asserts that injection molding is superior for high-volume production.
  • A participant explains the distinction between thermoplastic and thermosetting polymers, noting that thermoplastics can be melted and reformed, with a specific mention of Polycaprolactone as a suitable material for melting in a hot water bath.

Areas of Agreement / Disagreement

Participants express varying opinions on the best manufacturing method, with some advocating for injection molding while others propose alternatives like extrusion. There is no consensus on the most effective approach for the specific application discussed.

Contextual Notes

Participants mention specific materials and methods without resolving the implications of using different types of plastics or the exact costs associated with injection molding versus other methods.

Who May Find This Useful

Individuals interested in plastic manufacturing techniques, prototyping methods, and cost considerations for production runs may find this discussion relevant.

Wetmelon
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Hey PF,

I normally frequent the EE portion of this board, but I had a question about plastics and plastic injection molding.

A buddy and I have an idea to create a rather small and specific plastic object in large quantities. We thought that to create small prototype quantities, we could melt plastics and re-pour them into our mold. Is this even possible, or do I need a high pressure to stop the plastics from burning instead of melting?

As for injection molding, what kind of costs are associated with tooling a mold and doing a production run (say of a few thousand objects of volume ~140mm^3 ABS plastic with designs on the surface)? Is there a better method to do what I'm thinking?
 

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Perhaps I should re-phrase. I want to use injection molding to produce the item in the post above. I would need to produce only about 1000 as a prototype, but production would require hundreds of thousands (to millions eventually). Is injection molding the right path, or should I look at some other technology?
 
The injection molding cost depends on the size and design as well as the parts needed for creating the molded material.
 
Injection molding is certainly your best bet. I've worked with a local company called BOJO (http://www.bojoinc.com/) who can answer all the questions, make molds, and make your parts. The mold cost will be based on the projected volumes, as one mold could make 1-up or 100-up of these at the same time. Ask for Matt.
 
Actually, in the period since i posted this, I though perhaps extruding the plastic, rounding the end, then cutting to length would be more effective. Any thoughts?

Note that the pellet is 6mm diameter (approx)
 
In high volume, nothing beats injection molding.
 
If you do try to make them in your mold, there are certain types of plastics/polymers that can be melted. Basically you have thermoplastic polymers and thermosetting polymers. Thermoplastic can be melted and reformed, but don't use a direct flame or they might catch fire. A simple one to use depending on what it's used for is Polycaprolactone (google it) because you can essentially melt it in a hot water bath. Anyway, this is all just fyi. Good luck!

P.S. Polycaprolactone is sold as polymorph, shape lock, and a couple other brand names.
 
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