hi, I just bough some Fostex fe127en and was planning to build the fonkens.
I have plenty of birch plywood to build the speakers.
I have 15 mm birch ply, will it be fine for my baffle?
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And can I use the rest of my 15mm ply to make the ports? or the ply I have is too thick? so I need to get different wood for the ports and spacers?
the spacers: what kind of wood and at what thickness.
I have a couple of questions:
1-What type of glue you guys are using?
2- what sort of joints are you doing?
3-what stuffing to use to isolate inside of the fonkens/and how do you make it stick to the interior? By glue?
4-What sort of nail?
Yeah, stupid questions, but can't seem to see a definite answer
Thank you very much
I have plenty of birch plywood to build the speakers.
I have 15 mm birch ply, will it be fine for my baffle?
?6
And can I use the rest of my 15mm ply to make the ports? or the ply I have is too thick? so I need to get different wood for the ports and spacers?
the spacers: what kind of wood and at what thickness.
I have a couple of questions:
1-What type of glue you guys are using?
2- what sort of joints are you doing?
3-what stuffing to use to isolate inside of the fonkens/and how do you make it stick to the interior? By glue?
4-What sort of nail?
Yeah, stupid questions, but can't seem to see a definite answer
Thank you very much
Jason,
I'll answer the questions relating to design choices. I've pinged the expert on building these to answer your other questions,
15 mm birch ply will be fine for the baffle even with a rebate which is optional with the FE127.
The Vent spacers need to be 9.5 mm (3/8") thick. Thi was originally choosen because ideally the vent spacers are a different material (MDF or solid wood) and 3/8" MDF scrap can usually be found for free,
The best stuffing is 1/2" wool or cotton felt. This is outlined in the plans (i think)
dave
I'll answer the questions relating to design choices. I've pinged the expert on building these to answer your other questions,
15 mm birch ply will be fine for the baffle even with a rebate which is optional with the FE127.
The Vent spacers need to be 9.5 mm (3/8") thick. Thi was originally choosen because ideally the vent spacers are a different material (MDF or solid wood) and 3/8" MDF scrap can usually be found for free,
The best stuffing is 1/2" wool or cotton felt. This is outlined in the plans (i think)
dave
A simple butt joint, used with a good quality wood-glue, (Wellbond &c. &c) will achieve all the strength necessary, IMHO. I've built Fonkens using straight butt joints, and also with biscuits.
Dave's covered the rest. (Chris!?)
Good Luck!
Don
Dave's covered the rest. (Chris!?)
Good Luck!
Don
After building a few pairs of this particular design topology, I've arrived at the following routine:
Use 3/8" MDF for the port spacers -actually this is one of several aspects of Dave's designs that are adapted as much as possible to dimensions of standard materials.
As Don noted, ordinary butt joints are more than adequate - there are 3 layers of material in the side panel assemblies, providing over 1 1/2" ( i.e. 39mm) of glue surface area for the top and bottom.
Inset the back panel and extend the port spacer blocks to contact same for additional glue surface area and bracing.
There is more than enough surface area on all glue joints to allow for complete assembly without any mechanical fasteners (nails/screws), except obviously for those mounting drivers and input terminals. I've built at least a few that way myself, such as those in bamboo plywood. It does however require a lot more time for glue to cure at each step, so depending on the exterior finishing, there's no reason not to use nails or screws. I use an air powered nailer and #18 finishing brads on all cabinets that will be post veneered or painted.
Just be careful to carefully measure extent of chamfer, and locate any such fasteners to not be in the tool path it's cut after assembly. I prefer this method as it's very quick and I have access to large enough tools for the task. Clamp a sacrificial scrap to trailing edge the enclosure to prevent chipping at tail end of cut.
Standard yellow PVA carpenters glue (Dural / Titebond, etc.) are more than adequate for assembly, and have much quicker tack / cure times than moisture cured polyurethanes such as Gorilla. PURs are great, but they have several disadvantages: - slow cure (overnight is best); swelling that can be used to advantage for filling small gaps, but requires very firm clamping during cure period to avoid part creep; and penetrating stains.
After playing with several materials for internal damping, we've found the 1/2" bonded Ultratouch insulation available from Bob at CSS to be ideal. It's a dream to work with in terms of cutting, and easily glued with white PVA (Weldbond or "melamine" glue).
Creative Sound - Product Details
Build the 3 layered side panels as sub assemblies, using bench clamped jigs and spacers to ensure uniformity of alignment, and glue the damping pads to the inside surface before attaching the tops and bottoms.
The vertical brace that connects 4 panels of this cabinet should not be considered "optional", but it certainly does complicate assembly and particularly the installation of damping material, as the working space gets pretty tight inside the box once it's in place.
Carefully measure and fit the brace with the driver mounted to front baffle, and the completed side panels & top/bottom clamped together. Including the cutting of holes and fitting of magnet contact surface and this other dry-fitting, this is easily the most complicated part of the assembly, but IMHO is key to the integrity and resonance characteristics of the design.
Use 3/8" MDF for the port spacers -actually this is one of several aspects of Dave's designs that are adapted as much as possible to dimensions of standard materials.
As Don noted, ordinary butt joints are more than adequate - there are 3 layers of material in the side panel assemblies, providing over 1 1/2" ( i.e. 39mm) of glue surface area for the top and bottom.
Inset the back panel and extend the port spacer blocks to contact same for additional glue surface area and bracing.
There is more than enough surface area on all glue joints to allow for complete assembly without any mechanical fasteners (nails/screws), except obviously for those mounting drivers and input terminals. I've built at least a few that way myself, such as those in bamboo plywood. It does however require a lot more time for glue to cure at each step, so depending on the exterior finishing, there's no reason not to use nails or screws. I use an air powered nailer and #18 finishing brads on all cabinets that will be post veneered or painted.
Just be careful to carefully measure extent of chamfer, and locate any such fasteners to not be in the tool path it's cut after assembly. I prefer this method as it's very quick and I have access to large enough tools for the task. Clamp a sacrificial scrap to trailing edge the enclosure to prevent chipping at tail end of cut.
Standard yellow PVA carpenters glue (Dural / Titebond, etc.) are more than adequate for assembly, and have much quicker tack / cure times than moisture cured polyurethanes such as Gorilla. PURs are great, but they have several disadvantages: - slow cure (overnight is best); swelling that can be used to advantage for filling small gaps, but requires very firm clamping during cure period to avoid part creep; and penetrating stains.
After playing with several materials for internal damping, we've found the 1/2" bonded Ultratouch insulation available from Bob at CSS to be ideal. It's a dream to work with in terms of cutting, and easily glued with white PVA (Weldbond or "melamine" glue).
Creative Sound - Product Details
Build the 3 layered side panels as sub assemblies, using bench clamped jigs and spacers to ensure uniformity of alignment, and glue the damping pads to the inside surface before attaching the tops and bottoms.
The vertical brace that connects 4 panels of this cabinet should not be considered "optional", but it certainly does complicate assembly and particularly the installation of damping material, as the working space gets pretty tight inside the box once it's in place.
Carefully measure and fit the brace with the driver mounted to front baffle, and the completed side panels & top/bottom clamped together. Including the cutting of holes and fitting of magnet contact surface and this other dry-fitting, this is easily the most complicated part of the assembly, but IMHO is key to the integrity and resonance characteristics of the design.
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what are the dimensions of those spacers?? Is it refering to the cutting plan, name as inner side?
thanks guys. I hope that you guys will be able to follow my work and prevents errors!
I just got the wood!
My wood experience limits me to ikea build, so any help will be great.
I just got the wood!
My wood experience limits me to ikea build, so any help will be great.
is it normal that the back panel is too small wide-wise for the bottom wide panel? IT isnt like wide enough, so the back is not covering both side???
This is weird, or normal?
This is weird, or normal?
A few words from the Fonken-ator:
I've built dozens of pairs of this design over the past 5 yrs or so, and for various reasons ( experimenting with material thickness, driver models, and refining of port & internal bracing details ), several of them have finished at slightly different dimensions than the stock drawings that I assume you're working from.
I don't have a set of said drawings in front of me, but do have about 4 pairs of the Fostex & Mark Audio versions of this design in my room, as well as a tape measure.
Let's assume for convenience sake that you're using 15mm plywood for panels and 3/8" (9.5mm) MDF for the spacers between inner and outer side walls - which are the materials used for the pair of FE127E Fonkens I have in at my desk, and from which the following measurements are taken. (We'll ignore allowance for .5mm thick veneer on all sides)
The finished outside dimensions are 227mmW x 354mmH x 302mmD (9"x 13 15/16" x 11 7/8") . These are constructed using butt joints, with the top and bottoms overlaying all panels, and assembled with the front panel full width - the chamfers are cut after all except the back panel are assembled.
Top / bottom = 227mmW X 302mmD
Outside wall panels = 324mmH x 287mm W
Inner wall panels = 324mmH x 242mmW
Brace = 324mmH x 272mmW
Front panel = 324mmH 227mmW
Back panel= 324mmH x 197mmW
Width of Port spacers can adjusted for aesthetic variation of location of port slots, but using 9.5mm thick material the 3 slots per side need to be 75mmH. There will be 4 spacers per side - 2 between the slots, and one at each end. Cut these parts to 272mm long to provide additional glue surface area and bracing for the fully inset back panel.
If you're overlaying the back panel, the width of outside panels will need to be reduced to 272mm and the back panel increased to 227mm wide. This might be make assembly a little bit easier, but if all parts are precisely cut, insetting the back is not the most complicated part of the fabrication, and provides a more well braced joint.
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And in each build one needs to be prepared to adjust for material that varies from its nominal thickness (ie a sheet of 15mm could be as much as 15.5mm (say) or as thin as 14.5mm. One can even get a sheet with varying thickness thruout the sheet. You need to measure the actual sheet purchased.
There are also potential rounding errors on the plans, and i'm not perfect, outright mistakes have popped up in the drawings.
dave
What I forgot to mention is that to optimize cut plans and prepare DXF for export to CNC routing software, I tend to redraw these in my own CAD ( vintage Autosketch). Occasionally I'll catch some dimensional discrepancies or notational artifacts from his numerous revisions remain on sketches published on the P10 site. I note for example that the Fonken127 sketch still refers to 12mm material (nominally 1/2") and 18mm for front baffle. Several years ago we standardized our own construction to 15mm for cases, and 18mm or more as required* for driver panels.
* Mark Audio drivers very thick flange (over 9mm on some models) leaves very little material depth for mounting hardware when drivers are rebated for flush mounting. I generally laminate a small square of 9mm ply surrounding the rear of driver cut-out area to accommodate.
Okay, I'll take the pictures to show you, but it doesnt make sense!
Thanks btw, such help in here!
Thanks btw, such help in here!
If I'm not mistaken, the back panel wide is 190.2, and the bottom is 229.7. How can both arrive flush? is doesnt make sense, is it when the sides are done?
How wide is the sides when finish (inner, outer and ports).
I have time this evening to build my speakers! First of all, what did you do first?
the sides, then fix them to the bottom?
thanks!
How wide is the sides when finish (inner, outer and ports).
I have time this evening to build my speakers! First of all, what did you do first?
the sides, then fix them to the bottom?
thanks!
Also I'm not able to post the pictures in here.
BUT logically, how can both arrive flsuh when they are not the same wide?
BTW, received my drivers by dave! It sounds a bit harsh, I guess its because my box are not made! lol
BUT logically, how can both arrive flsuh when they are not the same wide?
BTW, received my drivers by dave! It sounds a bit harsh, I guess its because my box are not made! lol
I followed dave plans, and I still dont get it.
how can the top and back panel fit togetehr, they are not the same size!
help anyone?
wow, I'm embarrassed, I didnt thought of putting the side panel, with the side panel "on", theirs about half an inch that not covered. and now I'm being careful, since this should have been obvious for me, but it wasnt!
now, this half an inch is cause by what? is it because the spacers will take this extra place?
now, this half an inch is cause by what? is it because the spacers will take this extra place?
Pictures! Pictures!
If I'm reading this correctly, and you're referring to the two (vertical) front edges of the box, remember they're getting cut off at a 45deg. after assembly anyway.
Don
If I'm reading this correctly, and you're referring to the two (vertical) front edges of the box, remember they're getting cut off at a 45deg. after assembly anyway.
Don
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oh yeah and since I dont know how to put up the pictures in here, I can send the picture to anyone asking me 😛
thank you and sorry for me noobiness
thank you and sorry for me noobiness
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