The Horizontal Directional Drilling (HDD) Industry has experienced
so much growth in the past two decades that HDD has become
commonplace as a method of installation. One source reported
that the number of units in use increased by more than a hundredfold
in the decade following 1984. This growth has been driven
by the benefits offered to utility owners (such as the elimination
of traffic disruption and minimal surface damage) and by the
ingenuity of contractors in developing this technology. To date,
HDD pipe engineering has focused on installation techniques, and
rightfully so. In many cases, the pipe experiences its maximum
lifetime loads during the pullback operation.
Knowledge of the directional drilling process by the reader is assumed, but some
review may be of value in establishing common terminology. Briefly, the HDD
process begins with boring a small, horizontal hole (pilot hole) under the crossing
obstacle (e.g. a highway) with a continuous string of steel drill rod. When the bore
head and rod emerge on the opposite side of the crossing, a special cutter, called a
back reamer, is attached and pulled back through the pilot hole. The reamer bores
out the pilot hole so that the pipe can be pulled through. The pipe is usually pulled
through from the side of the crossing opposite the drill rig.
Pilot Hole
Pilot hole reaming is the key to a successful directional drilling project. It is as
important to an HDD pipeline as backfill placement is to an open-cut pipeline.
Properly trained crews can make the difference between a successful and an
unsuccessful drilling program for a utility. Several institutions provide operatortraining
programs, one of which is University of Texas at Arlington Center for
Underground Infrastructure Research and Education (CUIRE). Drilling the pilot holeestablishes the path of the drill rod (“drill-path”) and subsequently the location of
the PE pipe. Typically, the bore-head is tracked electronically so as to guide the hole
to a pre-designed configuration. One of the key considerations in the design of the
drill-path is creating as large a radius of curvature as possible within the limits of
the right-of-way, thus minimizing curvature. Curvature induces bending stresses
and increases the pullback load due to the capstan effect. The capstan effect is the
increase in frictional drag when pulling the pipe around a curve due to a component
of the pulling force acting normal to the curvature. Higher tensile stresses reduce
the pipe’s collapse resistance. The drill-path normally has curvature along its vertical
profile. Curvature requirements are dependent on site geometry (crossing length,
required depth to provide safe cover, staging site location, etc.) But, the degree
of curvature is limited by the bending radius of the drill rod and the pipe. More
often, the permitted bending radius of the drill rod controls the curvature and thus
significant bending stresses do not occur in the pipe. The designer should minimize
the number of curves and maximize their radii of curvature in the right-of-way
by carefully choosing the entry and exit points. The driller should also attempt to
minimize extraneous curvature due to undulations (dog-legs) from frequent overcorrecting
alignment or from differences in the soil strata or cobbles.
Source: http://www.mears.net/horizontal-directional-drilling/files/1912/7739/1406/HDD-2-Illustration---large.jpg
Pilot Hole Reaming
The REAMING operation consists of using an appropriate tool to open the pilot
hole to a slightly larger diameter than the carrier pipeline. The percentage oversize
depends on many variables including soil types, soil stability, depth, drilling mud,
borehole hydrostatic pressure, etc. Normal over-sizing may be from 1.2 to 1.5 times
the diameter of the carrier pipe. While the over-sizing is necessary for insertion, it
means that the inserted pipe will have to sustain vertical earth pressures without
significant side support from the surrounding soil.
Prior to pullback, a final reaming pass is normally made using the same sized
reamer as will be used when the pipe is pulled back (swab pass). The swab pass
cleans the borehole, removes remaining fine gravels or clay clumps and can compact
the borehole walls.
Drilling Mud
Usually a “drilling mud” such as fluid bentonite clay is injected into the bore during
cutting and reaming to stabilize the hole and remove soil cuttings. Drilling mud
can be made from clay or polymers. The primary clay for drilling mud is sodium
montmorillonite (bentonite). Properly ground and refined bentonite is added to
fresh water to produce a “mud.” The mud reduces drilling torque, and gives stability
and support to the bored hole. The fluid must have sufficient gel strength to keep
cuttings suspended for transport, to form a filter cake on the borehole wall that contains the water within the drilling fluid, and to provide lubrication between the
pipe and the borehole on pullback. Drilling fluids are designed to match the soil
and cutter. They are monitored throughout the process to make sure the bore stays
open, pumps are not overworked, and fluid circulation throughout the borehole is
maintained. Loss of circulation could cause a locking up and possibly overstressing
of the pipe during pullback.
Drilling muds are thixotropic and thus thicken when left undisturbed after pullback.
However, unless cementitious agents are added, the thickened mud is no stiffer than
very soft clay. Drilling mud provides little to no soil side-support for the pipe.
Pullback
The pullback operation involves pulling the entire pipeline length in one segment
(usually) back through the drilling mud along the reamed-hole pathway. Proper pipe
handling, cradling, bending minimization, surface inspection, and fusion welding
procedures need to be followed. Axial tension force readings, constant insertion
velocity, mud flow circulation/exit rates, and footage length installed should be
recorded. The pullback speed ranges usually between 1 to 2 feet per minute.
Source: http://www.apollotrenchless.com/SiteAssets/services1/horizontal-directional-drilling/HDD.ht5.jpg
Mini-Horizontal Directional Drilling
The Industry distinguishes between mini-HDD and conventional HDD, which is
sometimes referred to as maxi-HDD. Mini-HDD rigs can typically handle pipes up
to 10” or 12” diameter and are used primarily for utility construction in urban areas,
whereas HDD rigs are typically capable of handling pipes as large as 48”diamter.
These machines have significantly larger pullback forces ranging up to several
hundred thousand pounds
General Guidelines
The designer will achieve the most efficient design for an application by consulting
with an experienced contractor and a qualified engineer. Here are some general
considerations that may help particularly in regard to site location for PE pipes:
1. Select the crossing route to keep it to the shortest reasonable distance.
2. Find routes and sites where the pipeline can be constructed in one continuous
length; or at least in long multiple segments fused together during insertion.
3. Although compound curves have been done, try to use as straight a drill path as
possible.
4. Avoid entry and exit elevation differences in excess of 50 feet; both points should
be as close as possible to the same elevation.
5. Locate all buried structures and utilities within 10 feet of the drill-path for miniHDD
applications and within 25 feet of the drill-path for maxi-HDD applications.
Crossing lines are typically exposed for exact location.
6. Observe and avoid above-ground structures, such as power lines, which might
limit the height available for construction equipment.
7. The HDD process takes very little working space versus other methods.
However, actual site space varies somewhat depending upon the crossing
distance, pipe diameter, and soil type.
8. Long crossings with large diameter pipe need bigger, more powerful equipment
and drill rig.
9. As pipe diameter increases, large volumes of drilling fluids must be pumped,
requiring more/larger pumps and mud-cleaning and storage equipment.
10. Space requirements for maxi-HDD rigs can range from a 100 feet wide by 150 feet
long entry plot for a 1000 ft crossing up to 200 feet wide by 300 feet long area for a
crossing of 3000 or more feet.
11. On the pipe side of the crossing, sufficient temporary space should be rented to
allow fusing and joining the PE carrier pipe in a continuous string beginning
about 75 feet beyond the exit point with a width of 35 to 50 feet, depending on the
pipe diameter. Space requirements for coiled pipe are considerably less. Larger
pipe sizes require larger and heavier construction equipment which needs more
maneuvering room (though use of PE minimizes this). The initial pipe side “exit”
location should be about 50’ W x 100’ L for most crossings, up to 100’ W x 150’ L
for equipment needed in large diameter crossings.
12. Obtain “as-built” drawings based on the final course followed by the reamer
and the installed pipeline. The gravity forces may have caused the reamer to go
slightly deeper than the pilot hole, and the buoyant pipe may be resting on the
crown of the reamed hole. The as-built drawings are essential to know the exact
pipeline location and to avoid future third party damage
Safety
Safety is a primary consideration for every directionally drilled project. While this
chapter does not cover safety, there are several manuals that discuss safety including
the manufacturer’s Operator’s Manual for the drilling rig and the Equipment
Manufacturer’s Institute (EMI) Safety Manual: Directional Drilling
Tracking Equipment.
This video shows how HDD works.
Source: https://www.youtube.com/watch?v=cl8BBoCV7gU
Source:
- https://plasticpipe.org/pdf/chapter12.pdf
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