PRuggiero
Mechanical
- Oct 8, 2007
- 64
Guys,
I am designing a small container, ~ 4" x 2" x 1.5" that can hold liquid without leaking out. This device basically consists of a base that has a lip around the perimeter and a cover which fits over that lip making a tight seal (think of a typical plastic tote you use around the house). Before the product goes into production (injection molding) we want to ensure that the seal remains tight throughout the products use (~2 week disposable). I've found plenty of documentation on press fit designs with plastic but they typically talk about a shaft in a hole. One advantage I have is that we have prototypes made of a SLA resin, but the question is how can I ensure the design is good before spending big money on tooling.
Some of the things I'm interested in:
1. What material properties play into the lid/base fit design?
Flexural modulus, flexural strength, creep resistance....
2. What's the best way to estimate the force required to make the interference
Any guidance would be appreciated.
Thanks,
Pete
I am designing a small container, ~ 4" x 2" x 1.5" that can hold liquid without leaking out. This device basically consists of a base that has a lip around the perimeter and a cover which fits over that lip making a tight seal (think of a typical plastic tote you use around the house). Before the product goes into production (injection molding) we want to ensure that the seal remains tight throughout the products use (~2 week disposable). I've found plenty of documentation on press fit designs with plastic but they typically talk about a shaft in a hole. One advantage I have is that we have prototypes made of a SLA resin, but the question is how can I ensure the design is good before spending big money on tooling.
Some of the things I'm interested in:
1. What material properties play into the lid/base fit design?
Flexural modulus, flexural strength, creep resistance....
2. What's the best way to estimate the force required to make the interference
Any guidance would be appreciated.
Thanks,
Pete
