You may find this useful.
A GUIDE TO TUNING
WEBER CARBURETTORS
A BORG-WARNER EDUCATIONAL PUBLICATION
2nd EDITION 1976
TABLE No. 2
Size per cylinder in cc's Idle Jet Fuel Bleed Hole Size
in mm.
200 .35 or .40
250 .40 or .45
300-350 .45 or .50
400 .50
450-500-550 .50 or .55
600 .55 or .60
650 .60 or .65
700 .65 or .70
750-800-850 .70 or .75
TABLE No. 3
'F' Number One Hole Type Two Hole Type
Hole Size in mm Hole Size in mm
F1 1.35
F2 1.30
F 3 1.60
F 4 1.30
F5 1.60
F6 0.70
F 7 1.20
F8 1.20
F9 1.00
F10 No hole for use in I DA carburettors where air correction is in
idle jet carrier or holder.
F11 1.20
F12 0.90
F13 0.90
F14 1.20
TABLE No. 4
Idle jet air correction or bleed holes arranged from rich to lean
Rich F6
F12
F9
F8-F 11--F 14
F13
F2-F4
F5
F7
F1
Lean F3
PART 2
IDLE JET
Both the DCOE and IDA carburettors have an idle jet assembly which meters both fuel and air into the idle circuit.
At idling speed the idle mixture adjustment can be set to control the volume of mixed or emulsified fuel and air provided by the idle jet assembly and if a correct jet has been selected the setting of the idle mixture screw should be between a half and one full turn open.
As the throttle is opened from the idling position the throttle disc crosses a series of holes which are referred to as the secondary idle bleed cir-cuit or progression ports. These are fixed holes having no adjustment and are also fed by the idle jet assembly. Naturally it is important that a controlled mixture is fed through them so that smooth acceleration takes place from idle until the main jet assembly comes into operation. The control of this mixture is very closely associated with the idle jet air bleed (the 'F' number in DCOE units or the idle jet carrier in IDA models).
SELECTION
To determine these jet hole sizes, tables have been prepared, table
number 2 deals with the fuel bleed hole designated by the numbers 35, 40, 45, 50, 55 etc. and the sizes are given in mm. against the capacity of each cylinder. Where an engine has Siamese inlet ports it may be necessary to go one size larger than quoted.
Table number 3 gives the size of the idle jet air correction or bleed hole or holes against each 'F' number in mm's. It will be seen that the 'F' numbers do not run in sequence, but in table number 4 they have been arranged in their order from rich to lean.
EXAMPLE
Take a four cylinder engine of 1275 c.c., divide by 4, this is 319 c.c., per cylinder. From TABLE No. 2 it shows that both 300 and 350 c.c., can use, as a starting point, either a 45 or 50 idle fuel bleed hole size, but as the example has siamesed ports, 50 is the jet to start with.
To get a reading for the correct selection of the idle air bleed or 'F' number hole size, it is recommended that a midway choice, say F8 (1.20MM) be used which will give an idle jet assembly number of 50F8.
To check this selection, start engine and bring it up to normal operating temperature; leaving chokes, secondary venturi, mains, emulsions, air cor-rections, etc., as fitted. Carefully set the idle mixture screws (diagrams 1 & 2) to obtain the most even idling. This is done in conjunction with the idle speed screw (diagrams 1 & 2). Take time to allow engine to settle down after each adjustment-due allowance should be made if a competition camshaft is fitted as this generally produces rough idling.
PROGRESSION PORT CHECK. Having correctly set the idle speed mixture and rate, increase engine speed, by turning idle speed screw, to a point just below that at which mixture is seen to come from the secondary venturi discharge nozzle. To check for correct progression port mixture, turn idle mixture in and out.
If mixture is correct, turning screw either way will drop engine speed. Should speed increase when screw is turned in, it means the mixture is too rich. Conversely, if speed increases when screw is turned out, the mixture is too lean.
Correction of lean mixture may be accomplished by increasing the idle fuel jet diameter or reducing the idle air jet diameter. Determination for either of these can be found by reference to the number of turns out the the idle mixture screw had to be turned to achieve a smooth idle. Optimum set-ting on an idle mixture screw should be 1/2-1 turn out; if it was necessary to go beyond this setting and progression stage as outlined above is weak in-crease fuel jet diameter. If idle mixture screw setting was acceptable and progression stage is lean-decrease the idle air jet diameter. Should progres-sion port mixture be rich, obviously the reverse procedure would apply.
This setting is very critical to ensure a smooth changeover from idle to main jet operation.
I don't know how to rearrange the tables so I hope its not confusing.
Hope this helps
RonR
