Difference between revisions of "Geo Setups"

From TechWiki
Jump to navigation Jump to search
 
(73 intermediate revisions by 15 users not shown)
Line 1: Line 1:
== Some standard Geo settings ==
+
== Standard Setups ==
  
<table x:str border=0 cellpadding=0 cellspacing=0 width=655 style='border-collapse:
+
===Elise/Exige===
collapse;table-layout:fixed;width:493pt'>
 
<tr height=17 style='height:12.75pt'>
 
  <td height=17 class=xl24 width=158 style='height:12.75pt;width:119pt'>Geometry</td>
 
  <td class=xl25 width=122 style='width:92pt'>Standard S1 &amp; S2</td>
 
  <td class=xl25 width=125 style='width:94pt'>S2 135R</td>
 
  <td class=xl25 width=125 style='width:94pt'>340R Road</td>
 
  <td class=xl25 width=125 style='width:94pt'>340R Track</td>
 
  <td class=xl25 width=125 style='width:94pt'>Exige S1</td>
 
  <td class=xl25 width=125 style='width:94pt'>Msport</td>
 
</tr>
 
<tr height=17 style='height:12.75pt'>
 
  <td height=17 class=xl26 style='height:12.75pt'>Ride Height F/R</td>
 
  <td class=xl27>130/130mm</td>
 
  <td class=xl27>120/120mm</td>
 
  <td class=xl27>100/110mm</td>
 
  <td class=xl27>100/110mm</td>
 
  <td class=xl27>112/122mm</td>
 
  <td class=xl27>100/110mm</td>
 
</tr>
 
<tr height=17 style='height:12.75pt'>
 
  <td height=17 class=xl26 style='height:12.75pt'>Steering axis inclination</td>
 
  <td class=xl27>12°</td>
 
  <td class=xl27>12°</td>
 
  <td class=xl27>12°</td>
 
  <td class=xl27>12°</td>
 
  <td class=x127>12°</td>
 
  <td class=x127>12°</td>
 
</tr>
 
<tr height=17 style='height:12.75pt'>
 
  <td height=17 class=xl26 style='height:12.75pt'>Front Castor</td>
 
  <td class=xl27 x:str="'+3.8°">+3.8°</td>
 
  <td class=xl27 x:str="'+3.7°">+3.7°</td>
 
  <td class=xl27 x:str="'+3.8°">+3.8°</td>
 
  <td class=xl27 x:str="'+3.8°">+3.8°</td>
 
  <td class=xl27 x:str="'+3.8°">+3.8°</td>
 
  <td class=xl27 x:str="'+3.8°">+3.8°</td>
 
</tr>
 
<tr height=17 style='height:12.75pt'>
 
  <td height=17 class=xl26 style='height:12.75pt'>Front Camber</td>
 
  <td class=xl27 x:str="'-0.1°">-0.1°</td>
 
  <td class=xl27>0°</td>
 
  <td class=xl27 x:str="-0.5° "><span lang=EN-GB>-0.5°<span
 
  style='mso-spacerun:yes'> </span></span></td>
 
  <td class=xl27 x:str="'-1.8° "><span lang=EN-GB>-1.8°<span
 
  style='mso-spacerun:yes'> </span></span></td>
 
  <td class=xl27 x:str="'-0.5°">-0.5°</td>
 
  <td class=xl27 x:str="'0.3°">-0.3°</td>
 
</tr>
 
<tr height=17 style='height:12.75pt'>
 
  <td height=17 class=xl26 style='height:12.75pt'>Front alignment/toe</td>
 
  <td class=xl27 x:str="'0.2mm OUT Overall">0.2mm OUT Overall</td>
 
  <td class=xl27>0 mm</td>
 
  <td class=xl27>0.2mm OUT overall</td>
 
  <td class=xl27>0.5mm OUT overall</td>
 
  <td class=xl27>0.1mm OUT overall</td>
 
  <td class=xl27>0.2mm OUT overall</td>
 
</tr>
 
<tr height=17 style='height:12.75pt'>
 
  <td height=17 class=xl26 style='height:12.75pt'>Rear Camber</td>
 
  <td class=xl27 x:str="'-1.8°">-1.8°</td>
 
  <td class=xl27 x:str="'-1.8°">-1.8°</td>
 
  <td class=xl27 x:str="'-2.0° "><span lang=EN-GB>-2.0°<span
 
  style='mso-spacerun:yes'> </span></span></td>
 
  <td class=xl27 x:str="'-2.7° "><span lang=EN-GB>-2.7°<span
 
  style='mso-spacerun:yes'> </span></span></td>
 
  <td class=xl27 x:str="'-2.4° "><span lang=EN-GB>-2.4°<span
 
  style='mso-spacerun:yes'> </span></span></td>
 
  <td class=xl27 x:str="'-2.4° "><span lang=EN-GB>-2.0°<span
 
  style='mso-spacerun:yes'> </span></span></td>
 
</tr>
 
<tr height=17 style='height:12.75pt'>
 
  <td height=17 class=xl26 style='height:12.75pt'>Rear alignment/toe</td>
 
  <td class=xl27 x:str="'1.2mm IN Overall">1.2mm IN each side</td>
 
  <td class=xl27>1.2mm IN each side</td>
 
  <td class=xl27>1.5mm IN each side</td>
 
  <td class=xl27>2.5mm IN each side</td>
 
  <td class=xl27>1.2mm IN each side</td>
 
  <td class=xl27>1.2mm IN each side</td>
 
</tr>
 
<tr height=17 style='height:12.75pt'>
 
  <td height=17 class=xl26 style='height:12.75pt'>Bump Steer</td>
 
  <td class=xl27></td>
 
  <td class=xl27></td>
 
  <td class=xl27>2.0° to 2.5° toe in</td>
 
  <td class=xl28></td>
 
  <td class=xl27></td>
 
</tr>
 
<tr height=0 style='display:none'>
 
  <td width=158 style='width:119pt'></td>
 
  <td width=122 style='width:92pt'></td>
 
  <td width=125 style='width:94pt'></td>
 
  <td width=125 style='width:94pt'></td>
 
  <td width=125 style='width:94pt'></td>
 
</tr>
 
</table>
 
  
 +
{| border=1 cellpadding=5 align=center
 +
|- style="background-color:#fed200; face:bold;"
 +
| rowspan=2 | Geometry || rowspan=2 | Ride Height<br />Front/Rear || colspan=3 align=center | Front || colspan=2 align=center | Rear
 +
|- style="background-color:#fed200;"
 +
| Castor || Camber || Toe [Degrees] || Camber || Toe [Degrees]
 +
|-
 +
| Standard S1 & S2 || 130/130mm || +3.8° || -0.1° || 0.2mm OUT Overall [-0.03°] || -1.8° || 1.2mm IN each side [0.16°]
 +
|-
 +
| S2 135R          || 120/120mm || +3.7° || 0°    || 0mm [0.00°]              || -1.8° || 1.2mm IN each side [0.16°]
 +
|-
 +
| 340R Road        || 100/110mm || +3.8° || -0.5° || 0.2mm OUT Overall [-0.03°] || -2.0° || 1.5mm IN each side [0.20°]
 +
|-
 +
| 340R Track      || 100/110mm || +3.8° || -1.8° || 0.5mm OUT Overall [-0.07°]|| -2.7° || 2.5mm IN each side [0.33°]
 +
|-
 +
| Exige S1        || 112/122mm || +3.8° || -0.5° || 0.1mm OUT Overall [-0.01°]|| -2.4° || 1.2mm IN each side [0.16°]
 +
|-
 +
| Exige S2        || 130/130mm || +3.8° || -0.3° || 0mm [0.00°]              || -1.8° || 1.5mm IN each side [0.20°]
 +
|-
 +
| Exige 240R      || 120/120mm || +3.8° || -0.3° || 0mm [0.00°]              || -1.8° || 1.5mm IN each side [0.20°]
 +
|-
 +
| Exige V6 Cup      || 130/136mm || +2.8° || -0.4° || 0.4mm OUT Overall mm [-0.06°]              || -1.9° || 2.5mm IN each side [0.30°]
 +
|-
 +
| Exige 380/410/430 Cup  || 130/136mm || +2.8° || -0.8° || x.xmm OUT Overall mm [-0.12°]              || -2.10° || x,xmm IN each side [0.6°]
 +
|-
 +
| 111R            || 130/130mm || +3.8° || -0.1° || 0mm [0.00°]              || -1.8° || 1.2mm IN each side [0.16°]
 +
|-
 +
| 211              || 100/110mm || +4.0° || -1.4° || 0mm [0.00°]              || -2.5° || 1.2mm IN each side [0.16°]
 +
|-
 +
| Msport          || 100/110mm || +3.8° || -0.3° || 0.2mm OUT Overall [-0.03°] || -2.0° || 1.2mm IN each side [0.16°]
 +
|-style="background-color:#fed200;"
 +
| colspan=7 | Non-Standard Geo Settings
 +
|-
 +
| a forum hero S2 race || 110/115mm || +3.6° || -2.0° || 0.5 mm OUT each side [-0.07°] || -3.0° || 1 mm IN each side [0.13°]
 +
|}
  
These settings is to be used when car is loaded with 2x 75kg passengers and half tank of fuel.Converting from mm to degrees: 1. Multiply rim diameter in inches by 25.4 to get rim diameter in mm. 2. Multiply the result by PI to get the circumference. 3. Divide the result by 360 to get mm per degree. 4. Divide the toe mm by the mm/degree result to get toe in decimal degrees
+
The standard settings are used when car is loaded with 2x75kg passengers and half tank of fuel.
 +
 
 +
===Evora===
 +
 
 +
{| border=1 cellpadding=5 align=center
 +
|- style="background-color:#fed200; face:bold;"
 +
| rowspan=2 | Geometry || rowspan=2 | Ride Height<br />Front/Rear || colspan=3 align=center | Front || colspan=2 align=center | Rear
 +
|- style="background-color:#fed200;"
 +
| Castor || Camber || Toe || Camber || Toe
 +
|-
 +
| Standard || 125/147mm || +5.2° || -0.3° || 0mm || -1.6° || 1.5mm IN each side
 +
|-
 +
|}
 +
 
 +
 
 +
Converting toe from mm to degrees:
 +
 
 +
# Measure the rim diameter in mm as the size e.g. 17" is not the actual diameter your measurements are based on.
 +
# Multiply the result by PI to get the circumference.
 +
# Divide the result by 360 to get mm per degree.
 +
# Divide the toe mm by the mm/degree result to get toe in decimal degrees
 +
 
 +
 
 +
Or Excel =DEGREES( ASIN( TOE_IN_MM / ( RIM_DIA_INCHES * 25.4 )))
 +
 
 +
 +
Or use the calculator on this page, hypotenuse is the rim diameter the toe  per wheel (total toe divided by 2) in mm is width (or toe in degrees is angle A). * http://joyfulcoder.net/sohcahtoa/
  
 
== Geo setting X does Y ==
 
== Geo setting X does Y ==
 
Some starter guidelines although its really really complex stuff and dependent on many other factors;
 
Some starter guidelines although its really really complex stuff and dependent on many other factors;
  
Increasing front camber from the default -0.1° to -0.5° each side will dramatically improve the understeer, although the inside edges of the tyres will wear slightly faster. Increasing past -1.0° is great for high speed corners but will compromise low speed cornering, will reduce breaking effectiveness and it will tramline on the road.
+
* Increasing front camber from the default -0.1° to -0.5° each side will dramatically improve the understeer, although the inside edges of the tyres will wear slightly faster. Increasing past -1.0° is great for high speed corners but can compromise low speed cornering, will reduce braking effectiveness and it will tramline on the road.
  
Increasing rear camber from the default -1.8° to -2.0° (or higher) makes the car more neutral after you've removed the under steer.
+
* Increasing rear camber from the default -1.8° to -2.0° (or higher) makes the car more neutral after you've removed the under steer with front camber. Look at the ratios on the standard settings and maintain the front/rear % delta.
  
Front toe affects stability or responsiveness of turn in. Front Toe out (standard) makes the car more responsive turn in but causes additional drag in straights. Front toe in is more stable in straight line.
+
* Front toe affects stability or responsiveness of turn in. Front Toe out (standard) makes the car more responsive turn in but causes additional drag in straights. Front toe in is more stable in straight line.
  
Rear Toe controls the stability of the rear through the corner. Rear toe in (standard) makes the car more stable and apparently the elise toes in more at the rear as the suspension compresses. Rear toe out causes the rear to steer out from the corner, reducing stability.
+
* Rear Toe controls the stability of the rear through the corner. Rear toe in (standard) makes the car more stable and apparently the elise toes in more at the rear as the suspension compresses. Rear toe out causes the rear to steer out from the corner, reducing stability.
  
== Setting your own geo ==
+
== Factors affecting Geo ==
Whilst a race prep specialist can charge £200 for a Geo you can DIY castor, camber and toe settings.
+
When asking questions on the forums about "the best geo for ..." the following need to be considred so make an effort to specify;
  
1. To baseline your current setup http://www.alignmycar.co.uk will find a local place with a Hunter alignment system who will provide a setup sheet showing castor, camber and toe (probably in dd:mm:ss rather than decimal degrees) for £15
+
* What you are using the car for (road, sprint race, endurance race)
 +
* Tyre spec (section & compound)
 +
* Spring rates
 +
* Damper spec and settings
 +
* Ride height
 +
* Current Geo settings
 +
* Perceived problems with current setup
  
2. If you dont have the S1 or S2 service manual suspension sections you really should get them as this is only a small part.
+
== Setting your own geo ==
 +
Whilst a race prep specialist can charge £200 for a Geo you can DIY castor, camber and toe settings. With a lot of variability in quality at alignment centres (and Lotus dealers !) for the best results put the effort in yourself and build a string based alignment rig which can be more accurate than a computerised laser system. To make a DIY geo/alignmnet rig see:[[Geo Alignment Rig (Home Made)]]
  
3. Set the front castor by "shuffeling washers" on the top wishbone pivots (caster is not actually that important).
 
  
4. Set the front and rear camber by adding & removing shims; removing a 1mm shim plate will alter camber by approximately -0.25° at the front and -0.30° at the rear (see above for camber effects).
+
1. The Hunter computerised laser alignment system is one of the best (the variabiltiy is quality of the operator) http://www.alignmycar.co.uk will find a local place with a Hunter alignment system who will provide a setup sheet showing castor, camber and toe (probably in dd:mm:ss rather than decimal degrees) for £15 and can set the front and rear toe for another £30.
  
5. You could set the toe yourself, but since a quarter turn of the track rod can alter the toe by 2mm its a damned delicate affair without a real time readout (toe settings are crtical for handling).
 
  
6. Back to the alignment centre to check your config for another £15 and set your front and rear toe for another £30. You can now alter the camber without materially affecting toe.
+
2. If you are going to DIY you must have the relevant S1 or S2 service manual suspension sections. Setting castor and camber is straightforward as a caster washer and camber shim have fixed values, whereas toe is delicate - which way do you wind the flats and a quarter turn of the track rod can alter the toe by 2mm (e.g. just tightening the locknuts).
  
  
MEMO: Someone else can explain how to create a DIY geo rig and set bump steer !
+
'''Absolutley critical to getting a good geo is having the right ballast in the seats e.g. for a 780Kg race Elise the difference between empty and an 85Kg driver is 5mm ride height, 0.2° camber and 1mm toe. (Depending on Spring rates used) Don't let your alignment place guess'''
  
 
==See Also==
 
==See Also==
 
+
* http://arc.seloc.org/viewthread.php?tid=52913 - The pole & string thread by Randy
http://forums.seloc.org/viewthread.php?tid=106461
+
* http://arc.seloc.org/viewthread.php?tid=49382
 
+
* http://arc.seloc.org/viewthread.php?tid=106461
 
+
* http://forums.pelicanparts.com/porsche-911-technical-forum/581498-stringless-wheel-alignment-diyers.html
  
 
[[Category:Suspension]]
 
[[Category:Suspension]]
 +
[[Category:Lotus Elise]]
 +
[[Category:S1]]
 +
[[Category:S2]]
 +
[[Category:Lotus 2-Eleven]]
 +
[[Category:S2 Exige]]
 +
[[Category:Lotus Europa]]
 +
[[Category:Lotus Evora]]
 +
[[Category:VX220]]

Latest revision as of 13:44, 4 August 2023

Standard Setups

Elise/Exige

Geometry Ride Height
Front/Rear
Front Rear
Castor Camber Toe [Degrees] Camber Toe [Degrees]
Standard S1 & S2 130/130mm +3.8° -0.1° 0.2mm OUT Overall [-0.03°] -1.8° 1.2mm IN each side [0.16°]
S2 135R 120/120mm +3.7° 0mm [0.00°] -1.8° 1.2mm IN each side [0.16°]
340R Road 100/110mm +3.8° -0.5° 0.2mm OUT Overall [-0.03°] -2.0° 1.5mm IN each side [0.20°]
340R Track 100/110mm +3.8° -1.8° 0.5mm OUT Overall [-0.07°] -2.7° 2.5mm IN each side [0.33°]
Exige S1 112/122mm +3.8° -0.5° 0.1mm OUT Overall [-0.01°] -2.4° 1.2mm IN each side [0.16°]
Exige S2 130/130mm +3.8° -0.3° 0mm [0.00°] -1.8° 1.5mm IN each side [0.20°]
Exige 240R 120/120mm +3.8° -0.3° 0mm [0.00°] -1.8° 1.5mm IN each side [0.20°]
Exige V6 Cup 130/136mm +2.8° -0.4° 0.4mm OUT Overall mm [-0.06°] -1.9° 2.5mm IN each side [0.30°]
Exige 380/410/430 Cup 130/136mm +2.8° -0.8° x.xmm OUT Overall mm [-0.12°] -2.10° x,xmm IN each side [0.6°]
111R 130/130mm +3.8° -0.1° 0mm [0.00°] -1.8° 1.2mm IN each side [0.16°]
211 100/110mm +4.0° -1.4° 0mm [0.00°] -2.5° 1.2mm IN each side [0.16°]
Msport 100/110mm +3.8° -0.3° 0.2mm OUT Overall [-0.03°] -2.0° 1.2mm IN each side [0.16°]
Non-Standard Geo Settings
a forum hero S2 race 110/115mm +3.6° -2.0° 0.5 mm OUT each side [-0.07°] -3.0° 1 mm IN each side [0.13°]

The standard settings are used when car is loaded with 2x75kg passengers and half tank of fuel.

Evora

Geometry Ride Height
Front/Rear
Front Rear
Castor Camber Toe Camber Toe
Standard 125/147mm +5.2° -0.3° 0mm -1.6° 1.5mm IN each side


Converting toe from mm to degrees:

  1. Measure the rim diameter in mm as the size e.g. 17" is not the actual diameter your measurements are based on.
  2. Multiply the result by PI to get the circumference.
  3. Divide the result by 360 to get mm per degree.
  4. Divide the toe mm by the mm/degree result to get toe in decimal degrees


Or Excel =DEGREES( ASIN( TOE_IN_MM / ( RIM_DIA_INCHES * 25.4 )))


Or use the calculator on this page, hypotenuse is the rim diameter the toe per wheel (total toe divided by 2) in mm is width (or toe in degrees is angle A). * http://joyfulcoder.net/sohcahtoa/

Geo setting X does Y

Some starter guidelines although its really really complex stuff and dependent on many other factors;

  • Increasing front camber from the default -0.1° to -0.5° each side will dramatically improve the understeer, although the inside edges of the tyres will wear slightly faster. Increasing past -1.0° is great for high speed corners but can compromise low speed cornering, will reduce braking effectiveness and it will tramline on the road.
  • Increasing rear camber from the default -1.8° to -2.0° (or higher) makes the car more neutral after you've removed the under steer with front camber. Look at the ratios on the standard settings and maintain the front/rear % delta.
  • Front toe affects stability or responsiveness of turn in. Front Toe out (standard) makes the car more responsive turn in but causes additional drag in straights. Front toe in is more stable in straight line.
  • Rear Toe controls the stability of the rear through the corner. Rear toe in (standard) makes the car more stable and apparently the elise toes in more at the rear as the suspension compresses. Rear toe out causes the rear to steer out from the corner, reducing stability.

Factors affecting Geo

When asking questions on the forums about "the best geo for ..." the following need to be considred so make an effort to specify;

  • What you are using the car for (road, sprint race, endurance race)
  • Tyre spec (section & compound)
  • Spring rates
  • Damper spec and settings
  • Ride height
  • Current Geo settings
  • Perceived problems with current setup

Setting your own geo

Whilst a race prep specialist can charge £200 for a Geo you can DIY castor, camber and toe settings. With a lot of variability in quality at alignment centres (and Lotus dealers !) for the best results put the effort in yourself and build a string based alignment rig which can be more accurate than a computerised laser system. To make a DIY geo/alignmnet rig see:Geo Alignment Rig (Home Made)


1. The Hunter computerised laser alignment system is one of the best (the variabiltiy is quality of the operator) http://www.alignmycar.co.uk will find a local place with a Hunter alignment system who will provide a setup sheet showing castor, camber and toe (probably in dd:mm:ss rather than decimal degrees) for £15 and can set the front and rear toe for another £30.


2. If you are going to DIY you must have the relevant S1 or S2 service manual suspension sections. Setting castor and camber is straightforward as a caster washer and camber shim have fixed values, whereas toe is delicate - which way do you wind the flats and a quarter turn of the track rod can alter the toe by 2mm (e.g. just tightening the locknuts).


Absolutley critical to getting a good geo is having the right ballast in the seats e.g. for a 780Kg race Elise the difference between empty and an 85Kg driver is 5mm ride height, 0.2° camber and 1mm toe. (Depending on Spring rates used) Don't let your alignment place guess

See Also