Pilot-channel apparatus is provided for guiding movements of runnered vehicles, equipment fitted with skid runners and containers with runners for three-dimensional displacements such as loading and transport on/off wheeled trailers and for two-dimensional displacements such as movements within a planar storage area. Unitary and multiple pilot channels incorporate characteristic forms with specified features for safe, reliable engagement with known runner profiles to control lateral and transverse powered movements, especially loading of snowmobiles onto a trailer. Pilot- channel apparatus is supplied in the form of formed shapes and bands of length up to approx. 10 meters which allows customized placement, mounting and spacing of specific pairs of fixed or moveable channels. Specific two- and three- dimensional pilot-channel arrays and kits with specific shapes of pilot channels are indicated for owner- installation on existing snowmobile trailers. Special all-purpose channel arrays adapted to engage a broad range of known runner profiles on snowmobiles can be factory installed on new trailer frames with attendant savings in trailer cost and weight.

BACKGROUND 
This invention relates to two-dimensional, 2D, and three-dimensional, 3D, 
arrays of pilot channels for the support and guidance of vehicles and 
containers which are moveable on elongated runners. 
Snowmobiles used in long-distance competition have been fitted with 
sharp-edged, wear-resistant carbide blade inserts for several years. These 
rail-like elements permit the machine to travel over extended patches of 
frozen sand/gravel without wearing off the sharp edge which is a 
significant benefit for directional control in high-speed turns. However, 
the sharp ends and edges of these elements "dig" into a typical wood 
trailer deck during sliding movements to load the sled. Provided enough 
brute force is available to force the sled, the usual loading/unloading 
process produces deep gouges in the trailer floor and reduces its life to 
a few uses. An alternative solution is to lift the machine with a hoist 
mounted on another vehicle. The pilot-channels and arrays of this 
invention have been developed after careful study of the profiles of skis 
and carbide blades and the safety factors related to driving one or more 
sleds directly into a secure position on the trailer. 
No patents or publications can be found which disclose: (a) pilot channels 
specifically shaped to engage only the upper-working-edge surfaces of 
snowmobile skis or (b) 2D or 3D pilot-channel arrays for guiding and 
supporting runner-supported vehicles such as snowmobiles. 
SUMMARY OF THE INVENTION 
This invention consists of pilot channels having a unique form for engaging 
the working surfaces and edges of load bearing runners and pilot-channel 
arrays which can be formed by positioning pilot-channel segments. 
The basic goal of this invention is further to provide pilot channels and 
pilot-channel arrays, either two dimensional (2D) or three dimensional 
(3D), which guide and support the runners of a vehicle or container during 
movements for loading and unloading. Since pilot channels engage the 
runners even when the sled is not moving forward, they provide lateral 
support for the sled during transport. In the context of this invention, 
2D denotes an array for guiding movements which fall approximately on one 
plane; 3D denotes an array for guiding movements within a 
three-dimensional space. Movements along the floor of a single-level 
showroom would be 2D; loading and unloading from a trailer, which involve 
movement along inclined planes from one level to another would be 3D. In 
the case of snowmobiles with a rear drive track and a pair of front 
steering runners fitted with carbide blade elements, the pilot channels of 
this invention have a runner-profile contacting shape which supports and 
guides each runner from its working faces and has a central recess which 
does not contact the wear-resistant carbide element. Because the size, 
spacing and shape of snowmobile runners and carbide blade attachments is 
highly variable, it is contemplated that several scaled versions and sizes 
of pilot channels must be provided to meet the needs of the marketplace. 
Because pilot channels and arrays of this invention tolerate contacts with 
the wear-resistant elements during forward or backward movement, they are 
a valuable addition to the list of snowmobile necessities. 
Another goal of this invention is to provide kits of pilot-channel segments 
or sections which can be attached by a hobbyist to an existing snowmobile 
trailer to create unique 2D and 3D pilot channel arrays. Care and 
attention have been given to selection of pilot-channel materials which 
are strong, durable, and able to be formed directly to the final shape. 
For many shapes, recycled polymers can be used for preparation of formed 
pilot channel sections with attendant cost savings and environmental 
benefits. 
Another goal of this invention is to provide multiple pilot-channels within 
a single formed strip 100-800 mm wide. Such strips can be applied at a 
predetermined spacing to conventional wood or metal trailer decking during 
the original manufacturing operations. For this case, the spacing distance 
would be selected to fit the standard track of popular snowmobiles. 
Still another goal of this invention is to provide a modular decking system 
consisting of multiple pilot channels to replace conventional lumber, 
plywood or sheet metal for snowmobile trailer decking. Such a deck can be 
assembled from 2-6 wide, interlocking strips or formed as a single piece 
by known plastic fabrication methods. For this embodiment, the deck 
surface would include a pattern of spaced parallel pilot-channel features 
for engaging the runner working edges of one or more popular snowmobiles. 
A further goal of this invention is to provide a system of 2D pilot 
channels to guide machines equipped with carbide-bladed runners in various 
types of office movements, i.e., sales rooms, repair shops, off-season 
storage halls, etc. For example, moving a snowmobile around the floor of a 
showroom or repair shop under its own power. Such a system would include 
pairs of pilot channels secured to a set of moveable sheets which can be 
positioned independently to guide the sled along a desired 2D path inside 
a building. 
The pilot channels of this invention are shaped to mate with selected 
working faces of runners used on sledges, pallets, stacked containers, 
snowmobiles, trail-grooming equiment, etc. The basic function of the 
pilot-channel arrays of this invention is to guide runnered vehicles and 
containers for secure, compact storage when moved slowly under power. 
Certain sharp-edged carbide blade elements of vehicles designed for 
operation on ice or frozen turf are extremely destructive of the surfaces 
of transport trailers. Pilot-channels of this invention are designed to 
lift the wear-resistant elements above the baseplane and to engage other 
non-carbide faces and edges of the runner to allow easy, controlled 
sliding movements under directional control. Pilot-channel arrays are 
prepared by fastening channel segments of selected lengths at a 
predetermined spacing to a baseplane structure. 
An alternative 2D array of pilot channels would be for "drive-in, 
drive-out" storage of snowmobiles on the floor of a display hall which 
would utilize sets of inter-related baseplanes each with a straight, 
curved or angled switching guide segment, combined into an assembly to 
direct the machines from the main aisle to a desired side branch. 
Another alternative 2D array of pilot channels would be for the movement of 
stacked containers or pallets inside a semitrailer. A further alternative 
2D array of pilot channels could be used for the movement of heavy 
equipment fitted with special skids within a factory as is common by 
millwrights. 
Still other alternative 2D pilot channel arrays can prepared by providing 
for one or more changeable baseplane zones. Moving or articulated segments 
of a pilot-channel array can be: (a) pivotable about a fixed axis, (b) 
short lengths fixed to a set of slideable baseplane strips or (c) 
deflectable elongated sections free to move on the baseplane whose 
position is controlled by sliding elements below the baseplane. 
An alternative 3D array of pilot channels would be a trailer for 
transporting snowmobiles with two runners; in this case there could be 
three sections or baseplanes, i.e., the working deck surface of a trailer, 
one or more pivoting "on-loading" ramps, and one or more pivoting or 
"off-loading" ramps, none of which are coplanar in use. For loading, each 
machine reaches the deck level by driving up on the loading ramp and into 
a storage location on the deck surface. For unloading, the sled is then 
driven off one of the unloading ramps. 
The benefit of pilot channels is that expensive machines can be safely 
loaded into a closely-spaced group on the trailer deck under icy 
conditions without risk of collisions, or scratches. An additional benefit 
of the pilot channels of this invention is that each sled is supported 
against lateral displacement across the surface of an ice-coated trailer 
deck, i.e., the machines will not slide together under sharp or high-speed 
turns of the vehicle.

DETAILED DESCRIPTION OF BEST-MODE EMBODIMENTS OF THE INVENTION 
The basic function of pilot-channel arrays is to facilitate placement and 
transport of runner-supported vehicles or containers, expecially 
snowmobiles fitted with wear-resistant cutter blades or wear rods on the 
skis. The essential purpose is to support the machine or goods on smooth, 
low-friction pilot channels which do not contact the ends/edges of the 
wear-resistant elements, thus avoiding "digging in" damage to the deck 
which would otherwise occur. 
FIG. 1 illustrates a typical large, non-tilting snowmobile trailer with 
tandem axles and shows a 3D array of pilot channels fixed to a rear 
"on-ramp", the main deck, and a front "off ramp". In this illustration, 
individual pilot-channels are shown in a spaced-apart layout, i.e., 
separated by the nominal average track of the runners, which is designated 
as L1. For the sake of convenience in this specification, all parameters 
of the pilot channels and pilot-channel arrays will be scaled or 
normalized by the characteristic L1 dimension. For example, many 
snowmobiles have an average ski-centerline spacing or track of about 1100 
mm; if this characteristic dimension is denoted as L1, and the width of a 
typical runner is about 100 mm, the L1-scaled width of the runner is thus 
100/1100 or 0.091, which is a non-dimensional runner-width parameter. 
FIG. 1 depicts a trailer with an dual pilot-channel array consisting of two 
sets of pilot channels for transporting two sleds in a side-by-side 
configuration; from the observer's view point the closest sled is denoted 
as "near" and the most remote as "far". As can be seen in FIG. 1, a 
portion of the length of the pilot channels is fixed in an arc of radius 
about 2-20 times the separation of the runners; expressed in scaled terms, 
an arc of radius 2 to 20 L1. This fixed curved zone facilitates driving 
the sled runners from the main section onto the moveable circular section 
to facilitate drive-off unloading. A moveable circular baseplane zone is 
shown in FIG. 1. This zone contains 2 fixed parallel straight segments of 
pilot channel and is shown as a circle of diameter between 1.3 L1 and 2 
L1. It is shown as having a center pivot pin and free rotation about that 
axis. The center pin is inserted into a prepared first receiver hole in 
the trailer deck to allow the zone to be rotated and placed in an 
orientation which blocks forward movement of the sled on the near-side. 
For unloading the near sled, the circular zone is rotated about 45 deg. 
clockwise (CW) from the position shown and moved into a second prepared 
receiver hole. This permits the near sled to be moved forward slowly under 
power with a steady turning moment applied to the handlebars. Under these 
combined forces, the moveable zone is progressively rotated to guide the 
sled off the front ramp of the trailer. For unloading the far sled there 
are two possible methods. The simplest is to leave the circular zone with 
its pivot pin in the first hole and rotate it so that one of its channels 
aligns with the inboard pilot channel for the far sled. As can be seen 
from FIG. 1, this will leave a short gap in the outboard channel; this gap 
is easily bridged by the runner as the far sled is moved slowly forward. 
This illustrates one possible layout for guidance of the sled along the 
"on-ramp" to the transport position and finally down and off the 
"off-ramp". In order to accommodate short-radius curves, the following 
factors must also be considered: length of runner, form of runner, 
size/placement of the wear-resistant blade, shape/size of pilot-channel, 
and local spacing distance L1. These same parameters must be considered 
when fixing the length and angles between adjacent straight segments as 
illustrated by the angle shown between the channels of the front 
"off-ramp" and the channels on the main deck. Transverse traction elements 
of any known form and pattern can be applied to the baseplane area between 
the pilot channels to assure maximum engagement of the drive track for 
controlled movement under power. For example short segments of the pilot 
channel formed material may be secured to ramps and/or the main deck 
surface 
FIGS. 2a-2f illustrate a few known profile shapes for runners or skis. 
Other known commercial runner shapes include vee-shapes, slabs, slats and 
numerous variants/combinations. The characteristic width of the runner is 
shown as L2. The characteristic size of the wear-resistant rod element is 
shown as L3. The characteristic depth of the recess in the runner working 
face is shown as L4, and the characteristic height dimension of a 
wear-resistant cutting-fin element is shown as L5. 
FIG. 2g depicts a typical cross-section of a snowmobile runner 2 with a 
replaceable wear rod 3 and a wear-resistant element 5, usually tungsten 
carbide, which is attached to the wear rod. In this configuration, the 
runner width is indicated by L2 and the convex vertical depth of the 
central portion is positive or downward from the top reference plane 1. 
The diamond-shaped carbide wear-resistant element 5 is frequently welded 
or brazed into a preformed vee-groove in the rod 3. L5 indicates the 
exposed portion of the wear-resistant element 5 below the bottom of the 
rod 3. This sharpened edge provides critical lateral stability for the 
snowmobile under sharp, flat turns at high speed. The width of the convex 
central portion, L6, is approximately 35% of L2, the overall width. For an 
average runner, L4 and L3 are approximately 10-15% of L2. 
FIGS. 3a-3f illustrate embodiments of several alternative pilot-channel 
profile shapes for supporting and guiding known runner profiles as shown 
in FIGS. 2a1-2a6. 
The pilot-channel upward-facing working surfaces are denoted generally as 
WS regions and specific individual features as F1, F2 and F3; these 
spaced-apart features engage the runner surfaces/edges and provide a 
recess to accommodate a variety of runner profiles and sizes/shapes of 
wear-resistant inserts. For a runnered vehicle, the outboard edges of the 
runners are those farthest from its longitudinal centerline; likewise the 
inboard edges are those which face toward the longitudinal centerline. 
These same concepts also apply to defining edge-specific pilot-channel 
zones, i.e., the top and bottom surfaces, relative to the baseplane, are 
referred to as the upper and lower facades, UF and LF; the inboard and 
outboard surfaces, relative to the runner centerline, CL, are referred to 
as inboard and outboard facades, IF and OF. The upper facade of the pilot 
channel includes the working regions WS. The lower facade, LF is in 
contact with and attached to the baseplane or alternatively to transverse 
members of the trailer frame. Pilot-channels of this invention have two 
important working features, inboard and outboard. For this specification, 
the outboard working feature is denoted F1 and the inboard feature as F2. 
These features may be assymetric in form from inboard to outboard; 
further, they may be planar, combinations of planes or complex curved 
surfaces. F3 is the prismatic connecting recess which lies between F1 and 
F2; F3 may be a complex curved plane or a combination of planes. 
FIG. 3a shows an embodiment of this invention wherein a pilot channel is 
divided into two inverted-vee semi-channels mounted at a spacing L20. In 
this example, each runner is supported by a pair of parallel 
semi-channels. This alternative is of significant value when the pilot 
channel is being curved over an arc in either the 2D or 3D sense. Such 
semi-channels can be attached to the baseplane with fasteners recessed 
into the WS regions. 
FIG. 3b shows an embodiment wherein an formed pilot channel shape includes 
the mounting flanges, MF, the specific working surface features, F1, F2, 
the general working surfaces, WS, and a central recess, F3 defined by two 
planes with an included angle A10, which falls in the range 50-150 deg. In 
this example, L12 is the depth of the lowest point of the recess below the 
level of working surfaces, WS. This figure defines the general meaning of 
outboard working surface feature, F1, the inboard working surface feature, 
F2, and the connecting prismatic recess feature F3. The basic meaning of 
the symbol WS is the entire working surface of the pilot channel. For a 
profile such as shown in FIG. 3b, the lateral extent of WS can be 
estimated by adding the lateral extents of the components, i.e., F1+F2+F3. 
In an example where L11-L12 is 5 mm and L10 is 65 mm, and A10 is 90 deg., 
the total extent of F3 amounts to approximately 78 mm. Thus the lateral 
extent of WS is approximately 5+5+78=88 mm. 
For a profile similar to FIG. 2b3 with L11-L12=5 mm, L12=30, and L15=30 the 
extent of WS for each semi-channel varys according to its specific bar 
spacing, i.e., with L13, L15, or L16. For the central semi-channel with 
L15=20 mm, the extent of WS is F1+F2+F3=90 mm with F3=20+2(30)=80 mm and 
F1=F2=5 mm. 
FIG. 3c shows a general multichannel embodiment wherein each pilot channel 
consists of a set of 2-10 spaced parallel bars with defined spacing 
distances, L13, L14 and L16 extending in a vertical plane upward from the 
mounting flange. In this case F3 recesses are U-channel surfaces of 
specific width which connect between and support the individual bars. 
FIG. 3f shows a U-form unitary pilot channel for thick-wall straight 
sections. This shape is particularly rigid and can be used over thin 
baseplane materials. The spacing between working surfaces, L13, is 
comparable to L10 and L20. 
FIG. 3e shows a multiple pilot channel with a set of spaced apart 
vee-grooves analogous to the unitary example described in 2b2 and the 
multiple pilot channel shown in 3c. 
FIG. 3d shows a unitary pilot channel with two broad working surfaces WS, 
separated by a groove of width L10. This type of pilot channel should be 
mounted with recessed fasteners or adhesive. 
FIG. 3g further details the specific zones of a multiple pilot channel 
analogous to that shown in FIG. 3c. The terms inboard and outboard 
represent directions relative to the centerline CL for the snowmobile 
runners. The overall width, L14, of the multiple channel shown is 
approximately 2-10 times the F1/F2 spacing, L10, of a unitary channel 
embodiment as shown in FIG. 3b. In this multichannel embodiment, variable 
spacing of adjacent F1/F2 features is shown by three separate dimensions, 
L13, L15, and L16. This provision enables a multiple pilot channel profile 
to accomodate a variety of runner profiles and spacings as shown in FIGS. 
2a-2g by adjustment, during mounting, of the lateral spacing between the 
multiple pilot channels, i.e., 2X the distance from the centerline, CL, to 
IF, the inboard facades. The three separate spacing dimensions, L13, L14 
and L16 correspond approximately to three different values of L10 in a 
unitary pilot channel. As in FIG. 3g, F1 and F2 denote the outboard and 
inboard features of the general working surface, WS. As shown in FIG. 3g, 
the transitions between adjacent F1/F2 features and the prismatic 
connecting-recess feature, F3, are planes connected by arc fillets. In 
FIG. 3g, the recess feature is a U-shaped channel consisting of two 
parallel walls, each standing at an angle of approximately 90 degrees to 
the baseplane. The function of the transition fillets and the F3 feature 
is to provide lateral guidance to a positive, convex runner profile such 
as shown in FIG. 2g. This is exactly analogous to the inclined planes 
forming F3 as shown in FIG. 3b. The depth from the uppermost WS zone to 
the lowest point of F3 corresponds to L12 as was also shown in FIGS. 3b 
and 3c. The variable lateral spacings between neighboring working pairs of 
F1 and F2 features in the multiple pilot channel embodiment are shown as 
L13, L15, and L16; this differs from single L10 for the unitary channel as 
shown in FIG. 3b. In all embodiments the F3 recess is prismatic whether 
formed by two planes at an angle A10 as shown in FIG. 3b, or by three 
perpendicular planes as shown in FIG. 3c, or by three perpendicular planes 
with arc fillets as shown in FIG. 3g. 
FIG. 3h shows a cross-section view of a multiple pilot channel with three 
different outside spacings 30, 35, and 36 between the bars which define 
the WS regions and at least two different bar heights above the mounting 
flange, MF. The function of this height difference is to provide a sturdy 
vertical barrier to prevent lateral overtravel of a runner which could 
mean costly damage due to a collision between sleds being loaded in a 
side-by-side arrangement. In this embodiment, the lateral spacing is 
depicted as a step function, i.e., the width of each channel is greater 
than its inboard neighbor by a geometric or logarithmic factor, starting 
with inboard spacing 36 as the initial value and moving in five steps up 
to spacing 30 at the outboard edge. In this embodiment the height of the 
extreme outboard bar above the mounting flange is shown as 32 and the 
height of the neighboring bar in the inboard direction is a smaller value, 
33. This height difference, 32-33, is in the range 0.5-1.5 times the 
smallest rod height, 33. An alternative embodiment would be to step both 
the spacing and rod height in geometric or logarithmic progression of six 
steps starting from the smallest value at the inboard edge and the largest 
value at the outboard edge. 
FIGS. 4a-c show schematic cross-sectional views of pilot channel-runner 
engagement between the F1 and F2 zones of the pilot channel working 
surface WS and the runner for a perfectly centered runner and pilot 
channel. FIG. 4(a) shows a typical flat runner profile from FIG. 2b with a 
finned wear rod engaged on a pilot channel profile from FIG. 3b. In this 
embodiment the sled is able to move laterally less than half the value of 
L10 before the rod contacts the F3 recess guide surface. FIG. 4b shows a 
typical concave runner with a negative L4 value. In this embodiment both 
outer edges of the F1 and F2 zones contact the sloping walls of the runner 
profile. This configuration results in minimal lateral movement. FIG. 4c 
shows a typical convex runner with a positive L4 value; the engagement of 
3c also allows only minimal lateral movement. 
FIG. 4d shows a cross-section of the engagement of a typical runner such as 
shown in FIG. 2g, with the F1, F2 and F3 zones of a unitary pilot channel 
as shown in FIG. 3b. The inclined planes of the prismatic F3 recess 
feature provide low-friction lateral guidance for the runner and the upper 
F1 and F2 zones provide low-friction vertical support for the runner and 
front portion of the snowmobile positioned about the centerline, CL. 
FIG. 4e shows a cross-section of the engagement of a runner as shown in 
FIG. 2g with a multiple pilot channel similar to the embodiment shown in 
FIG. 3c. In this embodiment, the height of all the vertical elements above 
the mounting flange, MF, is shown as 22; this corresponds to L12 of FIG. 
3b or 3c. This embodiment is shown with 7 vertical bars which form 6 pilot 
channels with inboard and outboard mounting flanges, MF. Inside channel 
width is denoted as L13, L15, and L16 for 3 of the channels. The outside 
width of the outermost channel is denoted as 20. This value is greater 
than any inner width value and can exceed the largest of L13, L15, or L16 
by an amount more than 50% of the largest of the three. In general, the 
wall thickness of the vertical elements is at least equal to the 
mounting-flange thickness; the maximum wall thickness of the vertical 
elements can be estimated by taking 0.5 (20-L16). The thickness of the 
mounting flange is given by the difference of 21-22. This value depands 
upon the type of lateral support provided by the baseplane across the 
width of the multiple pilot channel, 24. For a rigid wood deck baseplane 
at least 25 mm thick and a formed or extruded polyethylene multiple pilot 
channel, the MF value of 3-6 mm provides adequate strength for various 
types of threaded fasteners. For the case of multiple pilot channels 
attached directly to transverse structural members of the snowmobile 
trailer frame or to a flexible baseplane, provision should be made for a 
thicker MF value in the range 5-10 mm across the full width of each 
multiple pilot channel. Such a thick base also allows the use of separate 
metal longitudinal channel coupling strips to support adjacent pilot 
channels or the formation of integral mating-engagement features along 
both the longitudinal edges of the multiple pilot channels. Such integral 
mating engagement features include dowel pins, tongue and groove, 
half-thickness overlaps, etc. The overall width, 24, of a single formed 
multiple pilot channel can be in the range 120 to 500 mm. 
FIG. 4f shows engagement of a typical runner profile with a narrow-spaced, 
multiple pilot channel. In this embodiment the inside spacing L15 between 
adjacent F1 and F2 features is approx. 15% of the runner width or 2% of 
the runner track width. As already indicated, multiple pilot channel bands 
with such narrow-spaced features on the inboard edge and wider-spaced 
features on the outboard edge will permit many different combinations to 
accommodate different runner profiles and tracks. 
Other embodiments of the Concepts of this invention include a trailer deck 
with one or more pairs of pilot-channels formed integral. It is envisioned 
that the deck could be made in one or more wide sections, each including a 
pair of pilot channels; each section would accommodate one runnered 
vehicle or runnered containers/pallets. Another embodiment would be to 
form a pattern of pilot channels on a one-piece trailer deck. For these 
concepts the forms shown in FIGS. 3c, 3h and 4e prepared with graded 
spacing patterns would be of significant value. Formed-integral pilot 
channel trailer-deck sections would be useful for movements of stacked 
containers in a route-delivery truck, such as a van for bakery products 
which are carried in molded plastic trays. 
EXAMPLES 
Table 1. presents a compact summary of definitions of each item of special 
nomenclature used to define pilot channels and pilot-channel arrays. Table 
1 also presents dimensional data on runners and pilot channels including 
typical ranges of actual dimensions in millimeters or degrees and scaled 
by the track dimension, L1. The scaled values/ranges shown reflect a 
typical L1 value of 1100 mm. 
Pilot-channels of this invention have been fabricated from a variety of 
polymer materials, plastic composites with filament reinforcement, 
plastic/metal laminations; loading trials under extremes of weather 
conditions have been used to validate the optimum materials, forms and 
fastening technics. One combination which has proved to be reliable is 
extruded polyolefin, using virgin or recycled pellets, in the general 
shape as shown in FIG. 3b, 3h, 4c or 4f fastened to a conventional plywood 
trailer deck with self-tapping screws. 
This invention may be embodied in many other specific forms without 
departing from the spirit or essential characteristics thereof. 
TABLE 1 
__________________________________________________________________________ 
DIMENSIONAL AMETERS OF PILOT-CHANNELS & ARRAYS 
Actual dimension 
L1-Scaled 
Nomen- mm or deg. 
non-dimen 
clature 
Description FIG. 
min max min max 
__________________________________________________________________________ 
RUNNER AMETERS 
1 ref. plane, top surface runner profile 
2a7 
2 general runner profile 
2a7 
3 general replaceable wear rod 
2a7 
5 wear-resistant blade element, carbide 
2a7 
L1 runner track and scaling basis 
1 300 1300 1.000 
1.000 
L2 width of ski 2a1 90.00 
145.00 
.082 .132 
L3 wear element, char. dimension 
2a1 11.00 
16.00 
.010 .015 
L4 vertical depth, (+) convex or (-) concave 
2a3 -45.00 
45.00 
-.041 
.041 
L5 ht. of wear-resist. element 
2a5 .05 25.00 
.000 .023 
L6 outside width of convex runner zone 
2a7 50 100 .045 .091 
PILOT-CHANNEL AMETERS 
CL centerline of runners and pilot channels 
2b2 
LF lower facade of pilot channel 
2b2 
UF upper facade of pilot channal 
2b2 
OF outboard facade of pilot channel 
2b2 
IF inboard facade of pilot channel 
2b2 
WS working surface length, pilot channel 
2b1 5.00 150.00 
.005 .136 
F1 working surface outboard feature extent 
2b2 3 60 .003 .055 
F2 working surface inboard feature extent 
2b2 3 60 .003 .055 
F3 connecting prismatic recess, F1-F2, extent 
2b2 .01 100 .000 .091 
MF mounting flange extension, pilot channel 
2b2 .01 55.00 
.000 .050 
L10 outside width of pilot-channel facades 
2b2 20.00 
200.00 
.018 .182 
L11 total ht. of pilot channel betw.UF,LF 
2b2 5.00 100.00 
.005 .091 
L12 inside depth of pilot channel, below WS 
2b2 1.00 75.00 
.001 .068 
L13 inside F1/F2 width spacing1* 
2b3 12.00 
150.00 
.011 .136 
L14 overall width of pilot channel 
2b2 40.00 
300.00 
.036 .273 
L15 inside F1/F2 width spacing2* 
2b3 12.00 
150.00 
.011 .136 
L16 inside F1/F2 width spacing3* 
2b3 12.00 
150.00 
.011 .136 
A10 recess included angle 2b2 50.00 
150.00 
.045 .136 
L20 width of separated semi-channels 
2b1 50.00 
100.00 
.045 .091 
30 outside width of outboard multiple channel 
2b8 30 100 .027 .091 
31 total height of outboard vertical element 
2b8 20 80 .018 .073 
32 ht. of outboard vertical element above MF 
2b8 15 90 .014 .082 
33 ht. of vertical element above MF 
2b8 15 50 .014 .045 
34 overall width of multiple pilot channel band 
2b8 140 2500 .127 2.273 
35 outside width of mult.channel&lt;30 
2b8 29 99 .026 .090 
36 outside width of mult.channel&lt;35 
2b8 28 98 .025 .089 
__________________________________________________________________________ 
NOTE: *spacing1, spacing2, spacing3 all diff.