Difference between revisions of "Standard:Reference Track Configurations"

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The reference track configurations shown below can be useful for layout planning purposes or for just gaining greater insight into the LEGO® track system geometry.  The configurations shown are all intended to be built using standard/unmodified track products.  Almost all configurations conform to the conventions of 16-stud parallel track separation and nominally aligning to an 8-stud or 16-stud grid interval. 
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The track diagrams are illustrated in schematic form for easy interpretation.  All diagrams have a superimposed 8-stud grid for interpretation of scale and for recognizing baseplate boundaries.  Straight sections of track typically use the "standard" length 16-stud section shown as "1x"; these can represent LEGO® brand 9V or RC straights or the ME Models full straight.  Some diagrams show "1/2" and "1/4" length straight sections representing the ME Models half straight and a single LEGO® flex track segment respectively. 
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== Parallel Curves ==
 
== Parallel Curves ==
  
[[File:RefParallelCurves.png]]
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The L-Gauge track system has 5 recognized standard radii implemented directly with available track products.  These radii maintain 16-stud adjacent track centreline spacing.  Complete circles are made from 16 curve track elements for the R40, R56, and R72 radii; each curve element occupying a 22.5º sector angle.  Curve radii R88 and R104 are comprised of 32 curve track elements, each occupying a 11.25º sector angle.
  
== Reverse Curves ==
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[[File:RefParallelCurves.png|288px]]
  
=== R40 Reverse Curve ===
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== Reverse Loops ==
  
[[File:RefRevCurveR40.png]]
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Reverse loops are a convenient method of reversing the direction of travel of a complete train.  The loops are illustrated returning to an adjacent parallel track; however, they can all easily be adapted to return to a common arrival/departure track with the addition of a switch and a R40 return curve.  It is not recommended to use a common arrival/departure track with 9V or metal track because of the reversal of track polarity that occurs.  This can be avoided by substituting any element in the reverse loop with an equivalent plastic track element to serve as an electrical isolation gap.
  
=== R56 Reverse Curve ===
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=== R40 Reverse Loop ===
  
[[File:RefRevCurveR56.png]]
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[[File:RefRevCurveR40.png|320px]]
  
=== R72 Reverse Curve ===
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=== R56 Reverse Loop ===
  
[[File:RefRevCurveR72.png|1000px]]
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[[File:RefRevCurveR56.png|448px]]
  
=== R88 Reverse Curve ===
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=== R72 Reverse Loop ===
  
[[File:RefRevCurveR88.png|1000px]]
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[[File:RefRevCurveR72.png|545px]]
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=== R88 Reverse Loop ===
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[[File:RefRevCurveR88.png|673px]]
  
 
== S-Bends ==
 
== S-Bends ==
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S-bends are a useful track configuration to achieve a lateral shift of centreline or to introduce an aesthetic alternative to tracks following strictly orthogonal alignment.  S-bends are characterized by their lateral offset (shift of centreline) and transition length (distance required to perform lateral shift).  Most of the S-bends presented here conform to 8-stud grid interval alignment; however, a few are aligned to a less conventional 4-stud grid interval.
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=== Lateral Offset: 16 Studs / 8 Stud Grid ===
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'''Lateral centreline offset:''' 16 studs
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'''Transition length:''' 104 studs
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[[File:RefSBend16.png|306px]]
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=== Lateral Offset: 32 Studs / 8 Stud Grid ===
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'''Lateral centreline offset:''' 32 studs
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'''Transition length:''' 96 studs
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[[File:RefSBend32.png|306px]]
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=== Lateral Offset: 64 Studs / 8 Stud Grid ===
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'''Lateral centreline offset:''' 64 studs
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'''Transition length:''' 144 studs
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[[File:RefSBend64.png|387px]]
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=== Lateral Offset: 52 Studs / 4 Stud Grid ===
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'''Lateral centreline offset:''' 52 studs
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'''Transition length:''' 144 studs
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[[File:RefSBend52.png|384px]]
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=== Lateral Offset: 92 Studs / 4 Stud Grid ===
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'''Lateral centreline offset:''' 92 studs
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'''Transition length:''' 192 studs
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[[File:RefSBend92.png|481px]]
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=== Lateral Offset: 104 Studs  / 8 Stud Grid ===
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'''Lateral centreline offset:''' 104 studs
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'''Transition length:''' 176 studs
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[[File:RefSBend104.png|450px]]
  
 
== Crossovers ==
 
== Crossovers ==
  
[[File:RefCrossovers.png]]
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Crossover junctions are a very common and useful configuration seen on real prototype railways.  Typically, a crossover will be placed between two adjacent parallel tracks.  Unfortunately, due to the geometric design of the LEGO® switch, crossover track configurations cannot be implemented between conventional 16-stud separated parallel running lines.  Crossovers can only be implemented between parallel tracks separated by 32-studs.  This can be achieved in two ways shown below using either two R40 curves or a single full straight track between the switches.  Crossovers with 16-stud centreline separation can be made by modifying the LEGO® switch; however, that is an Expert topic requiring physical cutting and modification of the switch.
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[[File:RefCrossovers.png|290px]]
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== Return Curves ==
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Return curves are typically used to make parallel offset sidings adjacent to a running line.  Using the 5 available curve radii, it is possible to make several offset intervals that are grid-aligned.
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[[File:RefReturnCurves.png|385px]]
  
 
== Diagonal Track ==
 
== Diagonal Track ==
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=== 22.5º Diagonal Track ===
 
=== 22.5º Diagonal Track ===
  
[[File:RefDiagTrack22.png|1000px]]
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[[File:RefDiagTrack22.png|578px]]
  
 
=== 45º Diagonal Track ===
 
=== 45º Diagonal Track ===
  
[[File:RefDiagTrack45.png|1000px]]
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[[File:RefDiagTrack45.png|704px]]
  
 
== Junctions ==
 
== Junctions ==
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=== Y-Junctions ===
 
=== Y-Junctions ===
  
[[File:RefYJunctions.png|1000px]]
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[[File:RefYJunctions.png|480px]]
  
 
=== Junction Diamonds ===
 
=== Junction Diamonds ===
  
[[File:RefJunctionCrossing.png|1000px]]
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[[File:RefJunctionCrossing.png|609px]]
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== Yard Sidings ==
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=== Grid Aligned Yard Ladder ===
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[[File:RefYardLadder1.png|673px]]
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=== Compact Non-Aligned Yard Ladder ===
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[[File:RefYardLadder2.png|673px]]
  
== Return Curves ==
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=== Grid Aligned Diagonal Yard Ladder ===
  
[[File:RefReturnCurves.png]]
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[[File:RefYardDiag.png|1138px]]

Latest revision as of 15:19, 7 May 2015

The reference track configurations shown below can be useful for layout planning purposes or for just gaining greater insight into the LEGO® track system geometry. The configurations shown are all intended to be built using standard/unmodified track products. Almost all configurations conform to the conventions of 16-stud parallel track separation and nominally aligning to an 8-stud or 16-stud grid interval.

The track diagrams are illustrated in schematic form for easy interpretation. All diagrams have a superimposed 8-stud grid for interpretation of scale and for recognizing baseplate boundaries. Straight sections of track typically use the "standard" length 16-stud section shown as "1x"; these can represent LEGO® brand 9V or RC straights or the ME Models full straight. Some diagrams show "1/2" and "1/4" length straight sections representing the ME Models half straight and a single LEGO® flex track segment respectively.

Parallel Curves

The L-Gauge track system has 5 recognized standard radii implemented directly with available track products. These radii maintain 16-stud adjacent track centreline spacing. Complete circles are made from 16 curve track elements for the R40, R56, and R72 radii; each curve element occupying a 22.5º sector angle. Curve radii R88 and R104 are comprised of 32 curve track elements, each occupying a 11.25º sector angle.

RefParallelCurves.png

Reverse Loops

Reverse loops are a convenient method of reversing the direction of travel of a complete train. The loops are illustrated returning to an adjacent parallel track; however, they can all easily be adapted to return to a common arrival/departure track with the addition of a switch and a R40 return curve. It is not recommended to use a common arrival/departure track with 9V or metal track because of the reversal of track polarity that occurs. This can be avoided by substituting any element in the reverse loop with an equivalent plastic track element to serve as an electrical isolation gap.

R40 Reverse Loop

RefRevCurveR40.png

R56 Reverse Loop

RefRevCurveR56.png

R72 Reverse Loop

RefRevCurveR72.png

R88 Reverse Loop

RefRevCurveR88.png

S-Bends

S-bends are a useful track configuration to achieve a lateral shift of centreline or to introduce an aesthetic alternative to tracks following strictly orthogonal alignment. S-bends are characterized by their lateral offset (shift of centreline) and transition length (distance required to perform lateral shift). Most of the S-bends presented here conform to 8-stud grid interval alignment; however, a few are aligned to a less conventional 4-stud grid interval.

Lateral Offset: 16 Studs / 8 Stud Grid

Lateral centreline offset: 16 studs Transition length: 104 studs

RefSBend16.png

Lateral Offset: 32 Studs / 8 Stud Grid

Lateral centreline offset: 32 studs Transition length: 96 studs

RefSBend32.png

Lateral Offset: 64 Studs / 8 Stud Grid

Lateral centreline offset: 64 studs Transition length: 144 studs

RefSBend64.png

Lateral Offset: 52 Studs / 4 Stud Grid

Lateral centreline offset: 52 studs Transition length: 144 studs

RefSBend52.png

Lateral Offset: 92 Studs / 4 Stud Grid

Lateral centreline offset: 92 studs Transition length: 192 studs

RefSBend92.png

Lateral Offset: 104 Studs / 8 Stud Grid

Lateral centreline offset: 104 studs Transition length: 176 studs

RefSBend104.png

Crossovers

Crossover junctions are a very common and useful configuration seen on real prototype railways. Typically, a crossover will be placed between two adjacent parallel tracks. Unfortunately, due to the geometric design of the LEGO® switch, crossover track configurations cannot be implemented between conventional 16-stud separated parallel running lines. Crossovers can only be implemented between parallel tracks separated by 32-studs. This can be achieved in two ways shown below using either two R40 curves or a single full straight track between the switches. Crossovers with 16-stud centreline separation can be made by modifying the LEGO® switch; however, that is an Expert topic requiring physical cutting and modification of the switch.

RefCrossovers.png

Return Curves

Return curves are typically used to make parallel offset sidings adjacent to a running line. Using the 5 available curve radii, it is possible to make several offset intervals that are grid-aligned.

RefReturnCurves.png

Diagonal Track

22.5º Diagonal Track

RefDiagTrack22.png

45º Diagonal Track

RefDiagTrack45.png

Junctions

Y-Junctions

RefYJunctions.png

Junction Diamonds

RefJunctionCrossing.png

Yard Sidings

Grid Aligned Yard Ladder

RefYardLadder1.png

Compact Non-Aligned Yard Ladder

RefYardLadder2.png

Grid Aligned Diagonal Yard Ladder

RefYardDiag.png