Steve (Correze)
Established Member
(Character limit in the title, should really be
"Accuracy, Precision and Tolerances in (industrial) woodworking."
Was reading through some documents at work the other day that I thought may be of interest here.
For those who don't already know, I work for a fairly large furniture manufacturer in the upper end of the market, we make hotel bedrooms, offices, bars and similar, either assembled or in flat-pack, depending on price and shipping.
We work mostly in MDF and chipboard, either melamine or laminate finished.
Anyway... the other day I was looking at the guideline tolerances we use when designing pieces and deciding on machining processes, these are figures obtained through real shop-floor experience rather than the manufacturer's specifications and I think they may surprise some people...
Any machine/process can be accurate, assuming a skilled operator, but precision depends as much on the design and operating principles of the machine as the operator.
In no particular order.
CNC panel (beam) saw: 0.4mm (+/-0.2mm)
CNC router: 0.2mm (+/-0.1mm)
Wall saw: 1mm (+/-0.5mm)
Table (panel) saw: 0.5mm (+/-0.25mm)
Spindle moulder*: 0.5mm (+/-0.25mm)
Shaper*: 0.4mm (+/-0.2mm)
Edgebander* 0.4mm (+/-0.2mm)
"Festool" rail-guided saw: 1mm (+/-0.5mm)
SCMS: 1mm (+/-0.5mm)
The Festo (or similar) and SCMS are considered only suitable for one-off pieces or for use on site, the wall saw is only used for rough sizing of panels for small orders, though it's just as quick to load the beam saw and programme it.
*These machines are dependant on the precision of the stock arriving from the previous operation.
Most of the machines are actually or theoretically capable of producing work to far higher tolerances, but these figures assume average set-up and operation.
So, for example, pieces that have to fit together "perfectly" (no visible gaps/joints) are only rough-sized on the beam saw before being cut to their final dimensions by the CNC routers, it takes longer, but the result is noticeable. In another example, our beam saws are always set to cut 0.2mm undersize for production runs, as a piece with undersized components will assemble more successfully than one with oversized parts. A really skilled operator or designer/programmer will work out which pieces should err toward undersized and which would be better oversized and adjust the dimensions accordingly.
I don't have any figures for hand tools, though I suspect that so much depends on the operator...
"Accuracy, Precision and Tolerances in (industrial) woodworking."
Was reading through some documents at work the other day that I thought may be of interest here.
For those who don't already know, I work for a fairly large furniture manufacturer in the upper end of the market, we make hotel bedrooms, offices, bars and similar, either assembled or in flat-pack, depending on price and shipping.
We work mostly in MDF and chipboard, either melamine or laminate finished.
Anyway... the other day I was looking at the guideline tolerances we use when designing pieces and deciding on machining processes, these are figures obtained through real shop-floor experience rather than the manufacturer's specifications and I think they may surprise some people...
Any machine/process can be accurate, assuming a skilled operator, but precision depends as much on the design and operating principles of the machine as the operator.
In no particular order.
CNC panel (beam) saw: 0.4mm (+/-0.2mm)
CNC router: 0.2mm (+/-0.1mm)
Wall saw: 1mm (+/-0.5mm)
Table (panel) saw: 0.5mm (+/-0.25mm)
Spindle moulder*: 0.5mm (+/-0.25mm)
Shaper*: 0.4mm (+/-0.2mm)
Edgebander* 0.4mm (+/-0.2mm)
"Festool" rail-guided saw: 1mm (+/-0.5mm)
SCMS: 1mm (+/-0.5mm)
The Festo (or similar) and SCMS are considered only suitable for one-off pieces or for use on site, the wall saw is only used for rough sizing of panels for small orders, though it's just as quick to load the beam saw and programme it.
*These machines are dependant on the precision of the stock arriving from the previous operation.
Most of the machines are actually or theoretically capable of producing work to far higher tolerances, but these figures assume average set-up and operation.
So, for example, pieces that have to fit together "perfectly" (no visible gaps/joints) are only rough-sized on the beam saw before being cut to their final dimensions by the CNC routers, it takes longer, but the result is noticeable. In another example, our beam saws are always set to cut 0.2mm undersize for production runs, as a piece with undersized components will assemble more successfully than one with oversized parts. A really skilled operator or designer/programmer will work out which pieces should err toward undersized and which would be better oversized and adjust the dimensions accordingly.
I don't have any figures for hand tools, though I suspect that so much depends on the operator...
