1.75 filament hobbed bolt
Posted by peach303
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1.75 filament hobbed bolt September 05, 2013 02:01PM |
Hi, i want to manufacture a hobbed bolt for 1.75 filament. I know i could buy some, but i have access to a workshop, and thats faster. 
What is a common thread diameter for the die? M2 od M1.6?
ps: I've found nothing by search, so excuse me if there are threads out there.
What is a common thread diameter for the die? M2 od M1.6?
ps: I've found nothing by search, so excuse me if there are threads out there.
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Re: 1.75 filament hobbed bolt December 10, 2013 06:43AM |
The need for speed! 
@peach303
Your hob looks great.
I agree.
It's possible with your setup to extrude at 300 mm/s, will it make good parts, I don't know, and yes you have an error in your function.
Dale Dunn is correct, you are at the limit of your extruders feed rate because the temperature is to low.
This is evident due to the facts that you have missed steps, the filament is stripping, and the large extrudate diameter caused from the die swell.
To achieve your goal of 300 mm/s you will need to increase the temperature, which will reduce the extrudate diameter caused by the die swell.
Variables:
Filament diameter: 1.75 mm.
Filament cross sectional area: (1.75 mm / 2)² * Pi = 2.40 mm².
Extrudate diameter (realized): 1.50 mm.
Nozzle orifice diameter: 0.5 mm.
Layer thickness: 0.1 mm.
Print head speed: 300 mm/s.
Temperature: 000 C?.
Upper filament feed rate: 6.00 mm/s.
Material: PLA, ABS, ?
Filament feed rate given: 0.1 mm layer hight @ temp 000C at a rate of 300 mm/s:
Volume of a cylinder = pi r² h
Extrudate vol/s = 3.14 x (1.5mm/2)² x 0.1 mm h x 300 mm/s = 52.99 mm³/s
h = v/(pi r²)
Filament feed rate (h)/s = 52.99 mm³/(3.14 x (1.75 mm/2)²) =
Filament feed rate (h)/s = 52.99 mm³/2.40 mm² = 22.07 mm/s
Because you are occasionally stripping filament with a freed rate of 6.00 mm/s,
we will assume that a rate of 22.07 mm/s is not achievable with the current parameters, and that some thing needs to be adjusted or changed.
Your goal is rate of travel, so lets keep the filament diameter, temperature, and orifice diameter constant,
and adjust the extrudate diameter to a size that works with a feed rate of 6.00 mm/s, and then determine if the orifice diameter is up to the task.
Rearrange your formula, work in reverse, solve for extrudate diameter:
Filament feed rate (h)/s = ? mm³/2.40 mm² = 6.00 mm/s
v = mm/s x a
Extrudate vol/s = 6.00 mm/s x 2.40 mm² = 14.4 mm³/s
Extrudate vol/s = 3.14 x (?mm/2)² x 0.1 mm h x 300 mm/s = 14.4 mm³/s
3.14 x (?mm/2)² x 0.1 mm h x 300 mm/s = 14.4 mm³/s
(?mm/2)² = 14.4 mm³/s /( 3.14 x 0.1 mm h x 300 mm/s)
?mm/2 = sqrt(14.4 mm³/s /( 3.14 x 0.1 mm h x 300 mm/s))
Extrudate diameter = (sqrt(14.4 mm³/s /( 3.14 x 0.1 mm h x 300 mm/s))) x 2
Extrudate diameter = (sqrt(14.4 mm³/s /94.2)) x 2
Extrudate diameter = sqrt(.152866) x 2
Extrudate diameter = .39098 x 2
Extrudate diameter = 0.782 mm
An extrudate diameter of 0.782 mm is achievable with a Dia. 0.50 mm orifice.
So now you need to increase the temperature to help increase the flow rate.
Goal: increase the temperature until you extrude a Dia 0.782 mm extrudate.
If the temperature exceeds the plastics melt temperature, you will need to switch to a different material that has a higher flow rate,
and/or increase the orifice diameter. I suggest that you create a matrix of your empirical test results to help guide you.
Hob:
If you have access to a machine shop, and your goal is speed
I would not use a tap as the hob profile, as it has a helix, which will impart a lateral, and torsional force components to the filament.
The lateral force will tend to push the filament out of the hobbed profile,
and the torsional force will apply a shearing action to the groves in the filament, which will cause the filament to strip.
The lateral and torsional forces reduces your ability to push the filament through the die at maximum feed rate.
If speed is your game, then the helix is working against you.
Ideas for a redesigned hob:
1. Straight knurl: grind a knurling die to the desired width (use a steady rest).
3. If you don't like the profile generated from the straight knurl (rounded crest), make an OD broach using a wire EDM to form a straight helix.
Machine it from a tool steel and have it heat treated.
If the tooth profile is deep, machine two broaches.
Locate washers on either side to guide the filament.
HTH
A2
Edited 1 time(s). Last edit at 12/10/2013 06:51AM by A2.
@peach303
Your hob looks great.
Quote
Dale Dunn
if you're grinding filament you're at the limit of your grip. That enormous die swell suggests that you should try a higher temperature.
I agree.
Quote
peach303
Is this print speed not possible with my hobbed bolt? Or do i have an error in my calculation?
It's possible with your setup to extrude at 300 mm/s, will it make good parts, I don't know, and yes you have an error in your function.
Dale Dunn is correct, you are at the limit of your extruders feed rate because the temperature is to low.
This is evident due to the facts that you have missed steps, the filament is stripping, and the large extrudate diameter caused from the die swell.
To achieve your goal of 300 mm/s you will need to increase the temperature, which will reduce the extrudate diameter caused by the die swell.
Variables:
Filament diameter: 1.75 mm.
Filament cross sectional area: (1.75 mm / 2)² * Pi = 2.40 mm².
Extrudate diameter (realized): 1.50 mm.
Nozzle orifice diameter: 0.5 mm.
Layer thickness: 0.1 mm.
Print head speed: 300 mm/s.
Temperature: 000 C?.
Upper filament feed rate: 6.00 mm/s.
Material: PLA, ABS, ?
Filament feed rate given: 0.1 mm layer hight @ temp 000C at a rate of 300 mm/s:
Volume of a cylinder = pi r² h
Extrudate vol/s = 3.14 x (1.5mm/2)² x 0.1 mm h x 300 mm/s = 52.99 mm³/s
h = v/(pi r²)
Filament feed rate (h)/s = 52.99 mm³/(3.14 x (1.75 mm/2)²) =
Filament feed rate (h)/s = 52.99 mm³/2.40 mm² = 22.07 mm/s
Because you are occasionally stripping filament with a freed rate of 6.00 mm/s,
we will assume that a rate of 22.07 mm/s is not achievable with the current parameters, and that some thing needs to be adjusted or changed.
Your goal is rate of travel, so lets keep the filament diameter, temperature, and orifice diameter constant,
and adjust the extrudate diameter to a size that works with a feed rate of 6.00 mm/s, and then determine if the orifice diameter is up to the task.
Rearrange your formula, work in reverse, solve for extrudate diameter:
Filament feed rate (h)/s = ? mm³/2.40 mm² = 6.00 mm/s
v = mm/s x a
Extrudate vol/s = 6.00 mm/s x 2.40 mm² = 14.4 mm³/s
Extrudate vol/s = 3.14 x (?mm/2)² x 0.1 mm h x 300 mm/s = 14.4 mm³/s
3.14 x (?mm/2)² x 0.1 mm h x 300 mm/s = 14.4 mm³/s
(?mm/2)² = 14.4 mm³/s /( 3.14 x 0.1 mm h x 300 mm/s)
?mm/2 = sqrt(14.4 mm³/s /( 3.14 x 0.1 mm h x 300 mm/s))
Extrudate diameter = (sqrt(14.4 mm³/s /( 3.14 x 0.1 mm h x 300 mm/s))) x 2
Extrudate diameter = (sqrt(14.4 mm³/s /94.2)) x 2
Extrudate diameter = sqrt(.152866) x 2
Extrudate diameter = .39098 x 2
Extrudate diameter = 0.782 mm
An extrudate diameter of 0.782 mm is achievable with a Dia. 0.50 mm orifice.
So now you need to increase the temperature to help increase the flow rate.
Goal: increase the temperature until you extrude a Dia 0.782 mm extrudate.
If the temperature exceeds the plastics melt temperature, you will need to switch to a different material that has a higher flow rate,
and/or increase the orifice diameter. I suggest that you create a matrix of your empirical test results to help guide you.
Hob:
If you have access to a machine shop, and your goal is speed
I would not use a tap as the hob profile, as it has a helix, which will impart a lateral, and torsional force components to the filament.
The lateral force will tend to push the filament out of the hobbed profile,
and the torsional force will apply a shearing action to the groves in the filament, which will cause the filament to strip.
The lateral and torsional forces reduces your ability to push the filament through the die at maximum feed rate.
If speed is your game, then the helix is working against you.
Ideas for a redesigned hob:
1. Straight knurl: grind a knurling die to the desired width (use a steady rest).
3. If you don't like the profile generated from the straight knurl (rounded crest), make an OD broach using a wire EDM to form a straight helix.
Machine it from a tool steel and have it heat treated.
If the tooth profile is deep, machine two broaches.
Locate washers on either side to guide the filament.
HTH
A2
Edited 1 time(s). Last edit at 12/10/2013 06:51AM by A2.
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