Polycrystalline diamond compact (PDC) Matrix body bits for Very
Hard Rocks for oil drilling
PDC drill bits
Polycrystalline diamond materials, for use in polycrystalline
diamond compact (PDC) bits, are one of the most important material
advances for oil drilling tools in recent years. Fixed-head bits
rotate as one piece and contain no separately moving parts. When
fixed-head bits use PDC cutters, they are commonly called PDC bits.
Since their first production in 1976, the popularity of bits using
PDC cutters has grown steadily, and they are nearly as common as
roller-cone bits in many drilling applications.
Polycrystalline diamond compact (PDC) styles
PDC bits are designed and manufactured in two structurally
dissimilar styles (Fig. 1 and Fig. 2):
Matrix-body bit
Steel-body bits
The two provide significantly different capabilities, and, because
both types have certain advantages, a choice between them would be
decided by the needs of the application.
Polycrystalline diamond compact (PDC) styles
PDC bits are designed and manufactured in two structurally
dissimilar styles (Fig. 1 and Fig. 2):
Matrix-body bit
Steel-body bits
The two provide significantly different capabilities, and, because
both types have certain advantages, a choice between them would be
decided by the needs of the application.
Fig. 1—Matrix-body bit.
Fig. 2—Steel-body
bit.
Matrix-body
“Matrix” is a very hard, rather brittle composite material
comprising tungsten carbide grains metallurgically bonded with a
softer, tougher, metallic binder. Matrix is desirable as a bit
material, because its hardness is resistant to abrasion and
erosion. It is capable of withstanding relatively high compressive
loads, but, compared with steel, has low resistance to impact
loading.
Matrix is relatively heterogeneous, because it is a composite
material. Because the size and placement of the particles of
tungsten carbide it contains vary (by both design and
circumstances), its physical properties are slightly less
predictable than steel.
Steel-body
Steel is metallurgically opposite of matrix. It is capable of
withstanding high impact loads, but is relatively soft and, without
protective features, would quickly fail by abrasion and erosion.
Quality steels are essentially homogeneous with structural limits
that rarely surprise their users.
Design of matrix and steel-body bits
Design characteristics and manufacturing processes for the two bit
types are, in respect to body construction, different, because of
the nature of the materials from which they are made. The lower
impact toughness of matrix limits some matrix-bit features, such as
blade height. Conversely, steel is ductile, tough, and capable of
withstanding greater impact loads. This makes it possible for
steel-body PDC bits to be relatively larger than matrix bits and to
incorporate greater height into features such as blades.
Advantage of matrix-body PDC bits
Matrix-body PDC bits are commonly preferred over steel-body bits
for environments in which body erosion is likely to cause a bit to
fail. For diamond-impregnated bits, only matrix-body construction
can be used.
The strength and ductility of steel give steel-bit bodies high
resistance to impact loading. Steel bodies are considerably
stronger than matrix bodies. Because of steel material
capabilities, complex bit profiles and hydraulic designs are
possible and relatively easy to construct on a multi-axis,
computer-numerically-controlled milling machine. A beneficial
feature of steel bits is that they can easily be rebuilt a number
of times because worn or damaged cutters can be replaced rather
easily. This is a particular advantage for operators in low-cost
drilling environments.
Development of PDC bits
Fortunately, both steels and matrix are rapidly evolving, and their
limitations are diminishing. As hard-facing materials improve,
steel bits are becoming extremely well protected with materials
that are highly resistant to abrasion and erosion. At the same
time, the structural and wear-resisting properties of matrix
materials are also rapidly improving, and the range of economic
applications suitable for both types is growing.
Today’s matrix has little resemblance to that of even a few years
ago. Tensile strengths and impact resistance have increased by at
least 33%, and cutter braze strength has increased by ≈80%. At the
same time, geometries and the technology of supporting structures
have improved, resulting in strong, productive matrix products.
Fig. 3 describes PDC bit nomenclature.
Fig. 3—PDC bit nomenclature.
Polycrystalline diamond compact (PDC) cutters
Diamond is the hardest material known. This hardness gives it
superior properties for cutting any other material. PDC is
extremely important to drilling, because it aggregates tiny,
inexpensive, manmade diamonds into relatively large, intergrown
masses of randomly oriented crystals that can be formed into useful
shapes called diamond tables. Diamond tables are the part of a
cutter that contacts a formation. Besides their hardness, PDC
diamond tables have an essential characteristic for drill-bit
cutters: They efficiently bond with tungsten carbide materials that
can be brazed (attached) to bit bodies. Diamonds, by themselves,
will not bond together, nor can they be attached by brazing.
Synthetic diamond
Diamond grit is commonly used to describe tiny grains (≈0.00004
in.) of synthetic diamond used as the key raw material for PDC
cutters. In terms of chemicals and properties, manmade diamond is
identical to natural diamond. Making diamond grit involves a
chemically simple process: ordinary carbon is heated under
extremely high pressure and temperature. In practice, however,
making diamond is far from easy.
Individual diamond crystals contained in diamond grit are diversely
oriented. This makes the material strong, sharp, and, because of
the hardness of the contained diamond, extremely wear resistant. In
fact, the random structure found in bonded synthetic diamond
performs better in shear than natural diamonds, because natural
diamonds are cubic crystals that fracture easily along their
orderly, crystalline boundaries.
Diamond grit is less stable at high temperatures than natural
diamond, however. Because metallic catalyst trapped in the grit
structure has a higher rate of thermal expansion than diamond,
differential expansion places diamond-to-diamond bonds under shear
and, if loads are high enough, causes failure. If bonds fail,
diamonds are quickly lost, so PDC loses its hardness and sharpness
and becomes ineffective. To prevent such failure, PDC cutters must
be adequately cooled during drilling.
Diamond tables
To manufacture a diamond table, diamond grit is sintered with
tungsten carbide and metallic binder to form a diamond-rich layer.
They are wafer-like in shape, and they should be made as thick as
structurally possible, because diamond volume increases wear life.
Highest-quality diamond tables are ≈2 to 4 mm, and technology
advances will increase diamond table thickness. Tungsten carbide
substrates are normally ≈0.5 in. high and have the same
cross-sectional shape and dimensions as the diamond table. The two
parts, diamond table and substrate, make up a cutter (Fig. 4).
Fig. 4—PDC cutter construction
File usage
The following 2 pages link to this file:
PDC drill bits
PEH:Introduction to Roller-Cone and Polycrystalline Diamond Drill
Bits
Forming PDC into useful shapes for cutters involves placing diamond
grit, together with its substrate, in a pressure vessel and then
sintering at high heat and pressure.
PDC cutters cannot be allowed to exceed temperatures of 1,382°F
[750°C]. Excessive heat produces rapid wear, because differential
thermal expansion between binder and diamond tends to break the
intergrown diamond grit crystals in the diamond table. Bond
strengths between the diamond table and tungsten carbide substrate
are also jeopardized by differential thermal expansion.
Important factors to consider before the use and design of PDC bits
. PDC bit design principles
. PDC bit profile
. PDC bit configurations
. Bit hydraulics
. Bit economics
. Bit classification
. Understanding of operating practices and conditions the bit will
be exposed to.
Rotary drill bits
PEH:Introduction to Roller-Cone and Polycrystalline Diamond Drill
Bits
| PDC Drill Bits Specifications |
| IADC Bit code | TFA sq.in. | Mud weight, ppg | Bit pressure drop, psi | Bit hydraulic horsepower hp | Hydraulic horsepower/sq in.hsi | Bottom hole pressure psi | Flow rate,gpm |
| M315 | 0.421 | 9.16 | 600 | 124 | 2.12 | 1,033 | 355 |
| M315 | 0.421 | 9.16 | 350 | 51.1 | 0.9 | 1,990 | 250 |
| M345 | 0.388 | 9 | 227 | 26.9 | 0.47 | 1,030 | 203 |
| M345 | 0.388 | 9.16 | 535 | 96.5 | 1.7 | 2,040 | 309 |
| M615 | 0.383 | 9.0 | 235 | 27.9 | 0.49 | 1,035 | 204 |
| M615 | 0.383 | 9.16 | 553 | 100 | 1.76 | 2,000 | 310 |
| M646 | 0.388 | 9.07 | 499 | 87.4 | 1.54 | 1,000 | 300 |
| M646 | 0.388 | 9.07 | 499 | 87.4 | 1.54 | 1,000 | 300 |
| M646 | 0.388 | 9.0 | 438 | 72.0 | 1.27 | 2,025 | 282 |
| M672 | 0.388 | 9.07 | 435 | 71.0 | 1.46 | 1,030 | 280 |
| M672 | 0.388 | 9.16 | 747 | 159 | 3.26 | 1,943 | 365 |
| S914 | 0.383 | 9.07 | 512 | 89.7 | 1.56 | 1,020 | 300 |
| S914 | 0.383 | 9.07 | 228 | 26.6 | 0.47 | 1,020 | 200 |
| S914 | 0.383 | 9.16 | 350 | 51.1 | 0.9 | 1,990 | 250 |
| M946 | 0.388 | 9.0 | 215 | 25.5 | 45 | 1,030 | 203 |
| M946 | 0.388 | 9.16 | 728 | 157 | 2.77 | 1,990 | 370 |
| M946 | 0.388 | 8.8 | 700 | 151 | 2.66 | 2,000 | 370 |
For more information please contact:
ROSCHEN INC.
ROSCHEN GROUP LIMITED
ROSCHEN HOLDINGS LIMITED
Skype: ROSCHEN.TOOL , ROSCHEN_GROUP
WeChat: +86-137 6419 5009 ; +86-135 8585 5390
WhatsApp: +86-137 6419 5009 ; +86-135 8585 5390
Email: roschen@roschen.com ; roschen@roschen.net
Website: http://www.roschen.com ; http://www.roschen.net
http://www.roschen.cn ; http://www.roschendrill.com
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