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Scroll down for available products and ordering information.
Single Element,
Duplex
Element, Metric Single Element,
Ordering Worksheet
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Tempco offers a wide variety of sheathed, mineral insulated,
thermocouple cable. We stock many varieties of sheath diameters and
materials in ANSI recognized thermocouple types and can manufacture a
multitude of non-stock combinations of sheath materials, O.D.'s,
insulations, wire types and wire configurations on special request,
consult Tempco with your specific requirements.
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Tempco-Pak Thermocouples and cable are manufactured using premium
quality materials along with rigid quality control standards to insure a
reliable product that is state-of-the-art. The metal outer sheath
protects the thermocouple wires and insulation from contamination and
mechanical damage, hostile and oxidizing environments, while allowing it
to be moisture proof, formable, weldable, compact and have fast
response. The mineral insulation isolates the conductors from the sheath
and each other while providing excellent high temperature insulation
resistance.
Tempco offers a wide variety of sheath materials to choose from as
there is no single sheath material that is suitable for all conditions.
The most commonly stocked sheath materials are 304 S.S., 316 S.S. and
alloy 600. These are offered in all ANSI recognized thermocouple
calibrations.
As a standard, Tempco-Pak Thermocouple cable is made with high purity
94% minimum MgO insulation. Other types and purities are available;
however, when selecting a mineral insulation, the environment,
temperature rating and cost must be taken into consideration.
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All Tempco-Pak Thermocouple cable is
inspected for appearance, physical and electrical
characteristics, as well as conformance to
calibration.
Each coil or batch of Tempco-Pak is made from the same
production lot of raw materials and processed
together. This eliminates the need to calibrate each
length cut from the same coil. Samples from each coil
are calibrated as shown in the chart. |
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Tempco-Pak Thermocouple Calibration
Temperatures
ANSI
Calibration |
Standard
Calibration Points
|
Optional
Points |
|
T |
200ºF (93ºC), 400ºF (204ºC) |
-- |
|
T |
200ºF (93ºC), 400ºF (204ºC) |
-- |
|
T |
200ºF (93ºC), 400ºF (204ºC) |
-- |
|
J |
200ºF (93ºC), 500ºF (260ºC),
1000ºF (537ºC), 1500ºF (815ºC) |
-- |
|
E |
300ºF (149ºC), 500ºF (260ºC),
1000ºF (537ºC), 1600ºF (871ºC) |
-- |
|
K |
300ºF (149ºC), 500ºF (260ºC),
1000ºF (537ºC), 1600ºF (871ºC), 2000ºF (1093ºC)* |
2200ºF (1204ºC) |
|
R |
1000ºF (537ºC), 1600ºF (871ºC),
2000ºF (1093ºC)* |
2600ºF (1426ºC) |
|
S |
1000ºF (537ºC), 1600ºF (871ºC),
2000ºF (1093ºC)* |
2600ºF (1426ºC) |
|
B |
1600ºF (871ºC), 2000ºF (1093ºC)*,
2600ºF (1426ºC)* |
2600ºF (1426ºC) |
|
N |
300ºF (149ºC), 500ºF (260ºC),
1000ºF (537ºC), 1600ºF (871ºC), 2000ºF (1093ºC)* |
2200ºF (1204ºC) |
* These calibration points will
be checked if the sheath and insulation are rated to this temperature.
Tempco-Pak
Thermocouple Data, Care and Handling
Calibration
Tempco-Pak Thermocouple Cable is normally supplied to ANSI standard
limits (tolerances) of error as set forth in ANSI circular MC96.1-1982
and duplicated in ASTM E230. Special limits (tolerances) per ANSI MC96.1
are available at extra cost. (See
Table 1 below.)
Annealing
Unless otherwise specified all Tempco-Pak will be furnished
in a fully annealed condition.
Formability
Because Tempco-Pak is fully annealed it can normally be formed around a
mandrel 4 times the sheath diameter without loss of insulation
resistance or the sheath's integrity.
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Weldability
Tempco-Pak can be brazed, soldered or welded upon its sheath. However,
because of the delicate nature of the fabricating of hot junctions, it
is recommended they be done at the factory. Brazing or soldering
material should not come in contact with the mineral insulation as the
flux or resin will contaminate the insulation.
Insulation Resistance
Tempco-Pak should have a minimum insulation resistance wire to wire and
wire to sheath at room temperature of 100 megohms at 50 VDC for
0.093" O.D. and smaller and 100 megohms at 100 VDC for .100"
O.D. and larger.
Shipping and Packaging
Tempco-Pak is stocked in random lengths with the maximum stock lengths
listed in the tables showing the varieties of commonly available
material. Tempco reserves the right to supply random lengths of our
choice unless specific lengths are specified on your order. Tempco-Pak
can be furnished in coil form or in straight lengths. Normally
.375" diameter and .312" diameter are shipped in straight
lengths. Longer lengths are available on special order.
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Handling and Storage
To prevent moisture from being absorbed by the hydroscopic insulation,
both ends of the lengths of Tempco-Pak are sealed at the factory with a
suitable sealer. Under some conditions, moisture absorption could take
place which would lower the insulation resistance and may prove to be
troublesome in subsequent assembly and welding, so it is advisable to
store Tempco-Pak in a dry place. Slight moisture penetration can be
remedied by removing approximately 3 inches from each end. Apply heat
(approx 300ºF) 6 to 7 inches from the open end and slowly work heat
toward and over the open end. Allow end to cool to approximately 180ºF
and reseal end. When pieces are cut from stock lengths, the exposed ends
should be squared and resealed immediately to prevent contamination or
moisture absorption. For deeper moisture penetration, bake entire length
of material with both ends open for 24 hours at 250ºF to 300ºF to
remove moisture and bring up insulation resistance. If baking does not
bring the insulation resistance to acceptable levels, discard the
material. As an option Tempco can provide Tempco-Pak with the ends seal
welded . |
Selecting the M.I. Thermocouple
Cable suited to your requirement
Tempco offers a wide variety of sheathed, mineral insulated, thermocouple
cable. We stock many varieties of sheath diameters and materials in ANSI
recognized thermocouple types and can manufacture a multitude of non-stock
combinations of sheath materials, O.D.'s, insulations, wire types and wire
configurations on special request. Consult Tempco with your specific
requirements.
When selecting a cable for an application there are four things that must be
considered:
| 1 |
|
Sheath
Material |
The outer sheath protects the insulation and
wires from physical damage, contamination and the environment, all of
which affect the service life and cost. As there isn't any one
particular sheath material that is appropriate for all conditions,
Tempco offers you a choice.
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The insulation material isolates the wires from each other
and the sheath. Because the wires are used as conductors the insulating
material becomes important in preventing electrical shorts and
dielectric breakdown particularly at elevated temperatures.
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| 3 |
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Wire
Types (Calibration) |
Selecting the proper conductors can be crucial to the
function the MI cable is to perform. Where thermocouple cable is
concerned, selecting the appropriate calibration for the temperature to
be measured, the instrumentation available, and the environment will be
a significant factor in the accuracy, life and cost.
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The four main physical characteristics of the MI cable
that should be taken into account are:
a. Sheath Diameter
b. Sheath Wall Thickness
c. Conductor Size
d. Conductor Location (4 and 6 wires)
These will directly affect service life, flexibility, time response,
weldability, strength and cost.
The following pages will serve as a guide for sheath materials,
insulation materials and the various ANSI thermocouple calibrations. |
 |
The following information is designed to be used as a guide and may
not be correct in every application. If in doubt, consult with your
Tempco sales engineer or the factory. Temperatures shown are maximum
recommended operating temperatures.
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Sheath
Material
Note: Letters in parenthesis
following the sheath material are used with the
Ordering
Worksheet.
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Alloy 600 (A)
Maximum temperature: 1177ºC (2150ºF). Most
widely used thermocouple sheath material. Good high temperature
strength, corrosion resistance, resistance to chloride-ion stress
corrosion cracking and oxidation resistance to high temperatures. Do not
use in sulfur bearing environments. Good in nitriding environments. |
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304 SS (B)
Maximum temperature: 900ºC (1650ºF). Most
widely used low temperature sheath material. Extensively used in food,
beverage, chemical and other industries where corrosion resistance is
required. Subject to damaging carbide precipitation in 482º to 871ºC
(900º to 1600ºF) range. Lowest cost corrosion resistant sheath
material available.
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316 SS (C)
Maximum temperature: 900ºC (1650ºF). Best
corrosion resistance of the austenitic stainless steel grades. Good
corrosion resistance in H2S. Widely used in the food and chemical
industry. Subject to damaging carbide precipitation in 482º to 871ºC
(900º to 1600ºF) range.
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304L (D)
Maximum temperature: 900ºC (1650ºF). Low
carbon version of 304 SS (B). Low carbon content allows this material to
be welded and heated in the 482º to 871ºC (900º to 1600ºF) range
without damage to corrosion resistance.
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316L (E)
Maximum temperature: 900ºC (1650ºF). Same as
316 SS (C) except low carbon version allows for better welding and
fabrication.
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310 SS (F)
Maximum temperature: 1150ºC (2100ºF).
Mechanical and corrosion resistance, similar to but better than 304 SS.
Very good heat resistance. This alloy contains 25% Cr, 20% Ni. Not as
ductile as 304 SS.
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321 SS (G)
Maximum temperature: 871ºC (1600ºF). Similar
to 304 SS except titanium stabilized for intergranular corrosion. This
alloy is designed to overcome susceptibility to carbide precipitation in
the 482º to 871ºC (900º to 1600ºF) range. Used in aerospace and
chemical applications.
|
347 SS (H)
Maximum temperature: 871ºC (1600ºF). Similar
to 304 SS except nickel columbium stabilized. This alloy is designed to
overcome susceptibility to carbide precipitation in the 482º to 871ºC
(900º to 1600ºF) range. Used in aerospace and chemical applications. |
Nickel 200 (J)
Maximum temperature: 315ºC (600ºF).
Commercially pure wrought Nickel with good resistance to a wide range of
corrosive materials. For temperatures above 600ºF use Nickel 201 to
prevent embrittlement by intergranular corrosion. |
|
Nickel 201 (K)
Maximum temperature: 1093ºC (2000ºF).
Commercially pure wrought nickel with low carbon. Used in molten salt
bath furnaces. Offers good resistance to caustic alkalines and fluorine.
|
446 SS (L)
Maximum temperature: 1150ºC (2100ºF).
Ferritic stainless steel, which has good resistance to sulfurous
atmospheres at high temperatures. Good corrosion resistance to nitric
acid, sulfuric acid and most alkalies. 27% chromium content gives this
alloy the highest heat resistance of any ferritic stainless steel. |
|
Pure Platinum (M)
Maximum temperature: 1482ºC (2700ºF).
Platinum is the only metallic material capable of operating in an
oxidizing atmosphere above 1260ºC (2300ºF) for extended periods of
time. Normally used with type R, S or B conductors. Used in glass
manufacturing, high temperature furnaces and as control standards.
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Platinum 10% Rhodium (N)
Maximum temperature: 1552ºC (2825ºF).
Excellent oxidation resistance. Same type of uses as platinum 20%
rhodium except lower cost and reduced operating range.
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Platinum 20% Rhodium (P)
Maximum temperature: 1649ºC (3000ºF).
Excellent oxidation resistance. Very expensive oxidation resistant alloy
used in glass manufacturing and in research applications. Also used for
gas turbine test thermocouples.
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Hastelloy X® (Q)
Maximum temperature: 1204ºC (2200ºF). Widely
used in aerospace applications. Resistant to oxidizing, reducing and
neutral atmospheric conditions. Excellent high temperature strength
along with superior oxidation resistance. Resistant to stress corrosion
cracking in petrochemical applications.
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Inconel® 601 (R)
Maximum temperature: 1177ºC (2150ºF)
Continuous; 1260ºC (2300ºF) Intermittent. Similar to Alloy 600 with
the addition of aluminum for outstanding oxidation resistance. Designed
for high temperature corrosion resistance. This material is good in
carburizing environments, and has good creep rupture strength. Do not
use in vacuum furnaces! Susceptible to intergranular attack by prolonged
heating in 538º to 760ºC (1000º to 1400ºF) temperature range.
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Incoloy® 800 (S)
Maximum temperature: 1093ºC (2000ºF). Widely
used as heater sheath material. Minimal use in thermocouples. Superior
to Alloy 600 in sulfur, cyanide salts and fused neutral salts.
Susceptible to intergranular attack in some applications by exposure to
the temperature range of 538 to 760ºC (1000º to 1400ºF).
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Incoloy® 800HT (T)
Maximum temperature: 1093ºC (2000ºF). Same
as Incoloy 800® (S) except carbon content is limited to upper end of
range. This provides significantly higher creep and rupture strength.
Used in the chemical and petrochemical industry for long term exposure
to high temperatures.
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Tantalum (U)
Maximum temperature in air: 482ºC (900ºF).
Melting point: 2996ºC (5425ºF). Refractory metal. Very ductile. Use
only in inert or very good vacuums--10-3 torr or better. Most commonly
used with BeO and Tungsten Rhenium conductors. Do
not use in environments containing nitrogen above 371ºC (700ºF). |
|
Molybdenum (V)
Maximum temperature in air: 399ºC (750ºF).
Melting point: 2610ºC (4730ºF). Refractory metal. Brittle; cannot be
bent. Use only in inert, vacuum or reducing atmospheres. Most commonly
used with BeO insulation and Tungsten Rhenium conductors. Uncompacted
assemblies only.
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Insulation
Note: Letters
in parenthesis following the insulation material are used with the
Ordering
Worksheet.
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Magnesium Oxide--MgO 94% Typical
(M)
This insulation is widely used in thermocouple
and heater applications below 2000ºF. SiO2
is the major impurity which provides excellent insulation resistance. Do
not use with platinum or in nuclear application. |
High Purity Magnesium Oxide--MgO
-- 99.4% Minimum Purity (H)
Low impurity levels make this
insulation very useful for all thermocouple calibrations up to 2500ºF.
Above 2500ºF we recommend using Beryllium Oxide insulation because of
MgO's low resistivity. This material meets the requirements established
in ASTM E-235-82. |
Alumina Oxide--Al2O399.6% Minimum
Purity (A)
Although this material is comparable to
MgO in its electrical properties and cost, it does not compact as well
and tends to "powder out." This undesirable characteristic has
made this insulation unpopular in industry so cable with this type of
insulation is available only as a "special." |
|
Beryllium Oxide--BeO 99.7% Minimum
Purity (B)
This excellent high temperature
insulation is used primarily with tungsten rhenium conductors and either
a molybdenum or tantalum sheath. Beryllia is the only material other
than diamond which combines excellent electrical insulating properties
along with high thermal conductivity. The two disadvantages of this
material are cost, (approximately 10x greater than MgO), and the
toxicity of BeO. Beryllia dust can cause potential health problems if it
is inhaled. We highly recommend that assemblies containing Beryllium
insulation be made at Tempco where our work stations are designed for
handling this material. Maximum recommended temperature is 1900ºC (3452ºF).
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Calibration
Note: Standard and Special
Tolerance Calibration information to be used with the
Ordering
Worksheet.
|
ANSI Type
(J)
Standard; Special Tolerance (3)
Type J is composed of a positive leg (JP)
which is iron and a negative leg (JN) which is approximately 45% nickel,
55% copper. When protected by the compacted mineral insulation and
appropriate outer sheath, Type J is usable from 32º to 1500ºF. Type J
is not susceptible to short range ordering in the 700 to 1000ºF
temperature range, (+2ºF to +4ºF drift) which occurs with ANSI Type E
and K. This low-cost, stable thermocouple calibration is primarily used
with 94% minimum purity MgO insulation and a stainless steel sheath. |
ANSI Type
(K)
Standard; Special Tolerance (4)
Type K is composed of a positive leg (KP) which is
approximately 90% nickel, 10% chromium and a negative leg (KN) which is
approximately 95% nickel, 2% aluminum, 2% manganese and 1% silicon. When
protected by the compacted mineral insulation and appropriate outer
sheath, Type K is usable from 32ºF to 2300ºF and is one of Tempco's
most popular calibration types. If the application temperature is
between 600 and 1100ºF, we recommend using Type J or Type N because of
short range ordering which can cause drift of +2ºF to +4ºF in a few
hours' time. Type K is relatively stable to radiation transmutation and
is used in nuclear environments. For applications below 32ºF, special
alloy selections are usually required. |
ANSI Type
(E)
Standard; Special Tolerance (5)
Type E is composed of a positive leg (EP) which is
approximately 90% nickel, 10% chromium and a negative leg (EN) which is
approximately 45% nickel, 55% copper. When protected by the compacted
mineral insulation and appropriate outer sheath, Type E is usable from
32ºF to 1650ºF. This thermocouple has the highest EMF output per
degree of all ANSI recognized thermocouples. If the application
temperature is between 600 and 1100ºF, we recommend using Type J or
Type N because of short range ordering which can cause drift of +2ºF to
+4ºF in a few hours' time. For applications below 32ºF, special alloy
selections may be required. |
ANSI Type (T)
Standard; Special Tolerance (6)
Type T is composed of a positive leg (TP) which is pure
copper and a negative leg (TN) which is approximately 45% nickel, 55%
copper. When protected by the compacted mineral insulation and
appropriate outer sheath, Type T is usable from 32ºF to 662ºF. Type T
is very stable and is used in a wide variety of cryogenic and low
temperature applications. For applications below 32ºF special alloy
selections may be required. |
ANSI Type (N)
Standard; Special Tolerance (7)
Type N is composed of a positive leg (Nicrosil) which is
approximately 14% chromium, 1.4% silicon, 84.6% nickel and a negative
leg (Nisil) which is approximately 4.4% silicon, 95.6% nickel. When
protected by compacted mineral insulation and appropriate outer sheath,
Type N is usable from 32ºF to 2300ºF. Type N was designed to overcome
several problems inherent in Type K thermocouples. Short range ordering
(+2 to +4ºF drift) in the 600ºF to 1100ºF temperature range is
greatly reduced, and the drift rate at high temperatures is considerably
less. Type N has also been found to be more stable than Type K in
nuclear environments. |
ANSI Type (R) Standard Tolerance
Type R is composed of a positive leg (RP) which is 87%
platinum, 13% rhodium and a negative leg (RN) which is 100% platinum.
When protected by compacted mineral insulation and appropriate outer
sheath, Type R is usable from 32ºF to 2700ºF. Type R is available as
standard limits only, ITS90. |
ANSI Type (S)
Standard Tolerance
Type S is composed of a positive leg (SP) which is 90%
platinum 10% rhodium and a negative leg (SN) which is 100% platinum.
When protected by compacted mineral insulation and appropriate outer
sheath, Type S is usable from 32ºF to 2700ºF. Type S has a lower EMF
output than Type R and is available as standard limits only, ITS90. |
ANSI Type (B)
Standard Tolerance
Type B is composed of a positive leg (BP) which is
approximately 70% platinum, 30% rhodium and a negative leg (BN) which is
approximately 94% platinum, 6% rhodium. When protected by compacted
mineral insulation and appropriate outer sheath, Type B is usable from
1600ºF to 3100ºF. Type B is available as standard limits only, IPTS
1968 scale. |
Tungsten--5% Re/Tungsten, 26% Re
(W)
This calibration has not been given a letter designation
by ANSI. When this calibration is protected by mineral insulation and
appropriate outer sheath, it is usable from 32ºF to 4200ºF. This
calibration is used most often with Beryllium Oxide insulation and
either molybdenum or tantalum sheath. These combinations can only be
used in an inert or vacuum environment. |
Miscellaneous
Consult Tempco with your requirements. |
ASTM E230
Tolerances
& temperatures
|
Table
1
|
Tolerances
on Initial Values of Emf vs. Temperature |
| NOTE 1 |
Tolerances in this table apply to new essentially homogeneous
thermocouple wire, normally in the size range 0.25 mm to 3 mm in
diameter (No. 30 to No. 8 Awg) and used at temperatures not exceeding
the recommended limits of Table 1. If used at higher temperatures these
tolerances may not apply.
|
| NOTE 2 |
The Fahrenheit tolerance is 1.8 times larger than the ºC tolerance
at the equivalent ºC temperature. Note particularly that percentage
tolerances apply only to temperatures that are expressed in ºC.
|
| NOTE 3 |
Caution: Users should be aware that certain characteristics of
thermocouple materials, including the emf versus temperature
relationship may change with time in use; consequently, test results and
performance obtained at time of manufacture may not necessarily apply
throughout an extended period of use. Tolerances given in this table
apply only to new wire or MI cable or thermocouples as delivered to the
user and do not allow for changes in characteristics with use. The
magnitude of such changes will depend on such factors as wire size,
temperature, time of exposure, and environment. It should be further
noted that due to possible changes in homogeneity, attempting to
recalibrate used thermocouples is likely to yield irrelevant results,
and is not recommended. However, it may be appropriate to compare used
thermocouples in-situ with new or known good ones to ascertain their
suitability for further service under the conditions of the comparison.
|
| |
Tolerances--Reference
Junction 0ºC (32ºF) |
Thermocouple
Type |
Temperature Range |
Standard
Tolerances |
Special Tolerances |
|
ºC |
ºF |
ºC
(whichever
is greater) |
ºF |
ºC
(whichever
is greater) |
ºF |
|
T |
0 to 370 |
32 to 700 |
±1 or ±0.75% |
Note 2 |
±0.5 or 0.4% |
Note 2 |
|
J |
0 to 760 |
32 to 1400 |
±2.2 or ±0.75% |
±1.1 or 0.4% |
|
E |
0 to 870 |
32 to 1600 |
±1.7 or ±0.5% |
±1 or ±0.4% |
|
K or N |
0 to 1260 |
32 to 2300 |
±2.2 or ±0.75% |
±1.1 or ±0.4% |
|
R or S |
0 to 1480 |
32 to 2700 |
±1.5 or ±0.25% |
±0.6 or ±0.1% |
|
B |
870 to 1700 |
1600 to 3100 |
±0.5% |
|
|
TA |
–200 to 0 |
–328 to 32 |
±1 or ±1.5% |
|
B |
|
|
EA |
–200 to 0 |
–328 to 32 |
±1.7 or ±1% |
B |
|
KA |
–200 to 0 |
–328 to 32 |
±2.2 or ±2% |
B |
A Thermocouples and
thermocouple materials are normally supplied to meet the tolerances specified in
the table for temperatures above 0ºC. The same materials, however, may not fall
within the tolerances given for temperatures below 0ºC in the second section of
the table. If materials are required to meet the tolerances stated for
temperatures below 0ºC the purchase order must so state. Selection of materials
usually will be required.
B Special tolerances for
temperatures below 0ºC are difficult to justify due to limited available
information. However, the following values for Types E and T thermocouples are
suggested as a guide for discussion between purchaser and supplier:
Type E -200 to 0ºC ±1ºC or ±0.5% (whichever is greater)
Type T -200 to 0ºC ±0.5ºC or ±0.8% (whichever is greater)
Initial values of tolerance for Type J thermocouples at temperatures below 0ºC
and special tolerances for Type K thermocouples below 0ºC are not given due to
the characteristics of the materials.
|
Table
2
|
Suggested
Upper Temperature Limits for Protected Thermocouples |
| NOTE 1 |
This table gives the recommended upper temperature limits for the
various thermocouples and wire sizes. These limits apply to protected
thermocouples; that is, thermocouples in conventional closed-end
protecting tubes. They do not apply to sheathed thermocouples having
compacted mineral oxide insulation.
|
| NOTE 2 |
The temperature limits given here are intended only as a guide to the
user and should not be taken as absolute values nor as guarantees of
satisfactory life or performance. These types and sizes are sometimes
used at temperatures above the given limits, but usually at the expense
of stability or life or both. In other instances, it may be necessary to
reduce the given limits in order to achieve adequate service. ASTM
MNL-125 and other
literature sources should be consulted for additional applications
information.
|
| Upper Temperature limit for Various Wire
Sizes (Awg), ºC (ºF) |
Thermocouple
Type |
No. 8 Gage |
No. 14 Gage |
No. 20 Gage |
No. 24 Gage |
No. 28 Gage |
No. 30 Gage |
| 3.25 mm |
1.63 mm |
0.81 mm |
0.51 mm |
0.33 mm |
0.25 mm |
| (0.128 in) |
(0.064 in) |
(0.032 in) |
(0.020 in) |
(0.013 in) |
(0.010 in) |
| T |
760 (1400) |
370 (700) |
260 (500) |
200 (400) |
200 (400) |
150 (300) |
| J |
590 (1100) |
480 (900) |
370 (700) |
370 (700) |
320 (600) |
| E |
870 (1600) |
650 (1200) |
540 (1000) |
430 (800) |
430 (800) |
370 (700) |
| K and N |
1260 (2300) |
1090 (2000) |
980 (1800) |
870 (1600) |
870 (1600) |
760 (1400) |
| R and S |
|
1480 (2700) |
|
| B |
1700 (3100) |
5 "Manual on the Use
of Thermocouples in Temperature Measurement," ASTM MNL-12, 1993.
Tables courtesy ASTM
 |
Single Element Standard Size List
|
|
O.D.
(in.) |
Part
Number |
ANSI
Calibration |
Insulation
(Min. Purity) |
Sheath
Material |
Nom. Wall
Thickness (in.)
|
Nom.
B&S
Wire Ga. |
Max.
Operating
Temp. (ºF) |
Max.
Stock
Length (ft.) |
.020
±.001 |
MTC00001 |
J |
99.4% MgO |
Alloy 600 |
.003 |
39 |
1500 |
50 |
|
MTC00002 |
K |
99.4% MgO |
Alloy 600 |
.003 |
39 |
1650 |
50 |
|
MTC00003 |
J |
99.4% MgO |
304 |
.003 |
39 |
1500 |
50 |
|
MTC00004 |
K |
99.4% MgO |
304 |
.003 |
39 |
1650 |
50 |
.032
±.001 |
MTC00005 |
J |
99.4% MgO |
Alloy 600 |
.005 |
36 |
1500 |
150 |
|
MTC00006 |
K |
99.4% MgO |
Alloy 600 |
.005 |
36 |
1800 |
150 |
|
MTC00007 |
J |
99.4% MgO |
304 |
.005 |
36 |
1500 |
150 |
|
MTC00008 |
K |
99.4% MgO |
304 |
.005 |
36 |
1650 |
150 |
.040
±.001 |
MTC00009 |
J |
99.4% MgO |
Alloy 600 |
.006 |
33 |
1500 |
175 |
|
*MTC00010 |
K |
99.4% MgO |
Alloy 600 |
.006 |
33 |
2000 |
175 |
|
*MTC00011 |
J |
99.4% MgO |
304 |
.006 |
33 |
1500 |
175 |
|
*MTC00012 |
K |
99.4% MgO |
304 |
.006 |
33 |
1650 |
175 |
|
MTC00013 |
E |
99.4% MgO |
304 |
.006 |
33 |
1600 |
175 |
|
MTC00014 |
T |
99.4% MgO |
304 |
.006 |
33 |
650 |
175 |
|
MTC00015 |
J |
99.4% MgO |
316 |
.006 |
33 |
1500 |
175 |
|
MTC00016 |
K |
99.4% MgO |
316 |
.006 |
33 |
1650 |
175 |
.062
±.001 |
*MTC00017 |
J |
94.0% MgO |
Alloy 600 |
.008 |
30 |
1500 |
500 |
|
MTC00018 |
J |
99.4% MgO |
Alloy 600 |
.008 |
30 |
1500 |
500 |
|
*MTC00019 |
K |
94.0% MgO |
Alloy 600 |
.008 |
30 |
2000 |
500 |
|
*MTC00020 |
K |
99.4% MgO |
Alloy 600 |
.008 |
30 |
2000 |
500 |
|
*MTC00021 |
J |
94.0% MgO |
304 |
.008 |
30 |
1500 |
500 |
|
MTC00022 |
J |
99.4% MgO |
304 |
.008 |
30 |
1500 |
500 |
|
*MTC00023 |
K |
94.0% MgO |
304 |
.008 |
30 |
1650 |
500 |
|
*MTC00024 |
K |
99.4% MgO |
304 |
.008 |
30 |
1650 |
500 |
|
MTC00025 |
E |
94.0% MgO |
304 |
.008 |
30 |
1600 |
500 |
|
MTC00026 |
T |
99.4% MgO |
304 |
.008 |
30 |
650 |
500 |
|
MTC00027 |
J |
94.0% MgO |
316 |
.008 |
30 |
1500 |
500 |
|
MTC00028 |
J |
99.4% MgO |
316 |
.008 |
30 |
1500 |
500 |
|
MTC00029 |
K |
94.0% MgO |
316 |
.008 |
30 |
1650 |
500 |
|
MTC00030 |
K |
99.4% MgO |
316 |
.008 |
30 |
1650 |
500 |
.093
±.002 |
MTC00031 |
J |
94.0% MgO |
Alloy 600 |
.010 |
27 |
1500 |
450 |
|
MTC00032 |
J |
99.4% MgO |
Alloy 600 |
.010 |
27 |
1500 |
450 |
|
MTC00033 |
K |
94.0% MgO |
Alloy 600 |
.010 |
27 |
2000 |
450 |
|
MTC00034 |
K |
99.4% MgO |
Alloy 600 |
.010 |
27 |
2150 |
450 |
|
MTC00035 |
J |
94.0% MgO |
304 |
.010 |
27 |
1500 |
450 |
|
MTC00036 |
J |
99.4% MgO |
304 |
.010 |
27 |
1500 |
450 |
|
MTC00037 |
K |
94.0% MgO |
304 |
.010 |
27 |
1650 |
450 |
|
MTC00038 |
K |
99.4% MgO |
304 |
.010 |
27 |
1650 |
450 |
.125
±.002 |
MTC00039 |
J |
94.0% MgO |
Alloy 600 |
.014 |
24 |
1500 |
250 |
|
MTC00040 |
J |
99.4% MgO |
Alloy 600 |
.014 |
24 |
1500 |
250 |
|
*MTC00041 |
K |
94.0% MgO |
Alloy 600 |
.014 |
24 |
2000 |
250 |
|
*MTC00042 |
K |
99.4% MgO |
Alloy 600 |
.014 |
24 |
2150 |
250 |
|
*MTC00043 |
J |
94.0% MgO |
304 |
.014 |
24 |
1500 |
250 |
|
MTC00044 |
J |
99.4% MgO |
304 |
.014 |
24 |
1500 |
250 |
|
*MTC00045 |
K |
94.0% MgO |
304 |
.014 |
24 |
1650 |
250 |
|
*MTC00046 |
K |
99.4% MgO |
304 |
.014 |
24 |
1650 |
250 |
|
MTC00047 |
E |
94.0% MgO |
304 |
.014 |
24 |
1600 |
250 |
|
MTC00048 |
T |
94.0% MgO |
304 |
.014 |
24 |
650 |
250 |
|
MTC00049 |
J |
94.0% MgO |
316 |
.014 |
24 |
1500 |
250 |
|
MTC00050 |
J |
99.4% MgO |
316 |
.014 |
24 |
1500 |
250 |
|
MTC00051 |
K |
94.0% MgO |
316 |
.014 |
24 |
1650 |
250 |
|
MTC00052 |
K |
99.4% MgO |
316 |
.014 |
24 |
1650 |
250 |
|
MTC00053 |
E |
94.0% MgO |
316 |
.014 |
24 |
1600 |
250 |
|
MTC00054 |
T |
94.0% MgO |
316 |
.014 |
24 |
650 |
250 |
|
MTC00055 |
J |
94.0% MgO |
310 |
.014 |
24 |
1500 |
250 |
|
MTC00056 |
K |
94.0% MgO |
310 |
.014 |
24 |
2000 |
250 |
|
MTC00057 |
R |
99.4% MgO |
Alloy 600 |
.020 |
24 |
2150 |
25 |
|
MTC00058 |
S |
99.4% MgO |
Alloy 600 |
.020 |
24 |
2150 |
25 |
|
|
Single Element Standard Size List
continued...
|
|
O.D.
(in.) |
Part
Number |
ANSI
Calibration |
Insulation
(Min. Purity) |
Sheath
Material |
Nom.
Wall
Thickness
(in.) |
Nom.
B&S
Wire Ga. |
Max.
Operating
Temp. (ºF) |
Max.
Stock
Length
(ft.) |
.188
±.002 |
MTC00059 |
J |
94.0% MgO |
Alloy 600 |
.022 |
21 |
1500 |
120 |
|
MTC00060 |
J |
99.4% MgO |
Alloy 600 |
.022 |
21 |
1500 |
120 |
|
*MTC00061 |
K |
94.0% MgO |
Alloy 600 |
.022 |
21 |
2000 |
120 |
|
*MTC00062 |
K |
99.4% MgO |
Alloy 600 |
.022 |
21 |
2150 |
120 |
|
*MTC00063 |
J |
94.0% MgO |
304 |
.022 |
21 |
1500 |
120 |
|
MTC00064 |
J |
99.4% MgO |
304 |
.022 |
21 |
1500 |
120 |
|
*MTC00065 |
K |
94.0% MgO |
304 |
.022 |
21 |
1650 |
120 |
|
*MTC00066 |
K |
99.4% MgO |
304 |
.022 |
21 |
1650 |
120 |
|
MTC00067 |
E |
94.0% MgO |
304 |
.022 |
21 |
1600 |
120 |
|
MTC00068 |
T |
94.0% MgO |
304 |
.022 |
21 |
650 |
120 |
|
MTC00069 |
J |
94.0% MgO |
316 |
.022 |
21 |
1500 |
120 |
|
MTC00070 |
J |
99.4% MgO |
316 |
.022 |
21 |
1500 |
120 |
|
MTC00071 |
K |
94.0% MgO |
316 |
.022 |
21 |
1650 |
120 |
|
MTC00072 |
K |
99.4% MgO |
316 |
.022 |
21 |
1650 |
120 |
|
MTC00073 |
E |
94.0% MgO |
316 |
.022 |
21 |
1600 |
120 |
|
MTC00074 |
T |
94.0% MgO |
316 |
.022 |
21 |
650 |
120 |
|
MTC00075 |
J |
94.0% MgO |
310 |
.022 |
21 |
1500 |
120 |
|
MTC00076 |
K |
94.0% MgO |
310 |
.022 |
21 |
2000 |
120 |
.250
+.003
-.002 |
*MTC00077 |
J |
94.0% MgO |
Alloy 600 |
.029 |
18 |
1500 |
70 |
|
MTC00078 |
J |
99.4% MgO |
Alloy 600 |
.029 |
18 |
1500 |
70 |
|
*MTC00079 |
K |
94.0% MgO |
Alloy 600 |
.029 |
18 |
2000 |
70 |
|
*MTC00080 |
K |
99.4% MgO |
Alloy 600 |
.029 |
18 |
2150 |
70 |
|
*MTC00081 |
J |
94.0% MgO |
304 |
.029 |
18 |
1500 |
70 |
|
MTC00082 |
J |
99.4% MgO |
304 |
.029 |
18 |
1500 |
70 |
|
*MTC00083 |
K |
94.0% MgO |
304 |
.029 |
18 |
1650 |
70 |
|
*MTC00084 |
K |
99.4% MgO |
304 |
.029 |
18 |
1650 |
70 |
|
MTC00085 |
E |
94.0% MgO |
304 |
.029 |
18 |
1600 |
70 |
|
MTC00086 |
T |
94.0% MgO |
304 |
.029 |
18 |
650 |
70 |
|
MTC00087 |
J |
94.0% MgO |
316 |
.029 |
18 |
1500 |
70 |
|
MTC00088 |
J |
99.4% MgO |
316 |
.029 |
18 |
1500 |
70 |
|
MTC00089 |
K |
94.0% MgO |
316 |
.029 |
18 |
1650 |
70 |
|
MTC00090 |
K |
99.4% MgO |
316 |
.029 |
18 |
1650 |
70 |
|
MTC00091 |
E |
94.0% MgO |
316 |
.029 |
18 |
1600 |
70 |
|
MTC00092 |
T |
94.0% MgO |
316 |
.029 |
18 |
650 |
70 |
|
MTC00093 |
J |
94.0% MgO |
310 |
.029 |
18 |
1500 |
70 |
|
MTC00094 |
K |
94.0% MgO |
310 |
.029 |
18 |
2000 |
70 |
.313
+.003
-.002 |
MTC00095 |
J |
94.0% MgO |
Alloy 600 |
.036 |
17 |
1500 |
40 |
|
MTC00096 |
J |
94.0% MgO |
304 |
.036 |
17 |
1500 |
40 |
|
MTC00097 |
K |
94.0% MgO |
Alloy 600 |
.036 |
17 |
2000 |
40 |
|
MTC00098 |
K |
94.0% MgO |
304 |
.036 |
17 |
1650 |
40 |
|
MTC00099 |
E |
94.0% MgO |
304 |
.036 |
17 |
1600 |
40 |
|
MTC00100 |
E |
94.0% MgO |
316 |
.036 |
17 |
1600 |
40 |
|
MTC00101 |
J |
94.0% MgO |
316 |
.036 |
17 |
1500 |
40 |
|
MTC00102 |
K |
94.0% MgO |
316 |
.036 |
17 |
1650 |
40 |
.375
+.003
-.002 |
MTC00103 |
J |
94.0% MgO |
Alloy 600 |
.045 |
15 |
1500 |
30 |
|
*MTC00104 |
J |
94.0% MgO |
304 |
.045 |
15 |
1500 |
30 |
|
*MTC00105 |
K |
94.0% MgO |
Alloy 600 |
.045 |
15 |
2000 |
30 |
|
*MTC00106 |
K |
94.0% MgO |
304 |
.045 |
15 |
1650 |
30 |
|
MTC00107 |
J |
94.0% MgO |
316 |
.045 |
15 |
1500 |
30 |
|
MTC00108 |
K |
94.0% MgO |
316 |
.045 |
15 |
1650 |
30 |
|
|
Duplex Element -- Diagonal
Standard Size List
|
|
O.D.
(in.) |
Part
Number |
ANSI
Calibration |
Insulation
(Min. Purity) |
Sheath
Material |
Nom.
Wall
Thickness
(in.) |
Nom.
B&S
Wire Ga. |
Max.
Operating
Temp. (ºF) |
Max.
Stock
Length
(ft.) |
.063
±.001 |
MTC00109 |
J |
99.4% MgO |
Alloy 600 |
.009 |
30 |
1500 |
500 |
|
MTC00110 |
K |
99.4% MgO |
Alloy 600 |
.009 |
30 |
2000 |
500 |
|
MTC00111 |
J |
99.4% MgO |
304 |
.009 |
30 |
1500 |
500 |
|
MTC00112 |
K |
99.4% MgO |
304 |
.009 |
30 |
1650 |
500 |
.125
±.002 |
MTC00113 |
J |
94.0% MgO |
Alloy 600 |
.016 |
24 |
1500 |
250 |
|
*MTC00114 |
K |
94.0% MgO |
Alloy 600 |
.016 |
24 |
2000 |
250 |
|
*MTC00115 |
J |
94.0% MgO |
304 |
.016 |
24 |
1500 |
250 |
|
*MTC00116 |
K |
94.0% MgO |
304 |
.016 |
24 |
1650 |
250 |
|
MTC00117 |
E |
94.0% MgO |
304 |
.016 |
24 |
1600 |
250 |
|
MTC00118 |
J |
94.0% MgO |
316 |
.016 |
24 |
1500 |
250 |
|
MTC00119 |
K |
94.0% MgO |
316 |
.016 |
24 |
1650 |
250 |
.188
±.002 |
MTC00120 |
J |
94.0% MgO |
Alloy 600 |
.024 |
21 |
1500 |
120 |
|
*MTC00121 |
K |
94.0% MgO |
Alloy 600 |
.024 |
21 |
2000 |
120 |
|
*MTC00122 |
J |
94.0% MgO |
304 |
.024 |
21 |
1500 |
120 |
|
*MTC00123 |
K |
94.0% MgO |
304 |
.024 |
21 |
1650 |
120 |
|
MTC00124 |
E |
94.0% MgO |
304 |
.024 |
21 |
1600 |
120 |
|
MTC00125 |
T |
94.0% MgO |
304 |
.024 |
21 |
650 |
120 |
|
MTC00126 |
J |
94.0% MgO |
316 |
.024 |
21 |
1500 |
120 |
|
MTC00127 |
K |
94.0% MgO |
316 |
.024 |
21 |
1650 |
120 |
.250
+.003
-.002 |
MTC00128 |
J |
94.0% MgO |
Alloy 600 |
.031 |
19 |
1500 |
70 |
|
*MTC00129 |
K |
94.0% MgO |
Alloy 600 |
.031 |
19 |
2000 |
70 |
|
*MTC00130 |
J |
94.0% MgO |
304 |
.031 |
19 |
1500 |
70 |
|
*MTC00131 |
K |
94.0% MgO |
304 |
.031 |
19 |
1650 |
70 |
|
MTC00132 |
E |
94.0% MgO |
304 |
.031 |
19 |
1600 |
70 |
|
MTC00133 |
T |
94.0% MgO |
304 |
.031 |
19 |
650 |
70 |
|
MTC00134 |
J |
94.0% MgO |
316 |
.031 |
19 |
1500 |
70 |
|
MTC00135 |
K |
94.0% MgO |
316 |
.031 |
19 |
1650 |
70 |
.313
+.003
-.002 |
MTC00136 |
J |
94.0% MgO |
Alloy 600 |
.039 |
17 |
1500 |
40 |
|
MTC00137 |
K |
94.0% MgO |
Alloy 600 |
.039 |
17 |
2000 |
40 |
|
MTC00138 |
J |
94.0% MgO |
304 |
.039 |
17 |
1500 |
40 |
|
MTC00139 |
K |
94.0% MgO |
304 |
.039 |
17 |
1650 |
40 |
|
MTC00140 |
E |
94.0% MgO |
304 |
.039 |
17 |
1600 |
40 |
|
MTC00141 |
T |
94.0% MgO |
304 |
.039 |
17 |
650 |
40 |
.375
+.003
-.002 |
MTC00142 |
J |
94.0% MgO |
Alloy 600 |
.047 |
15 |
1500 |
30 |
|
*MTC00143 |
K |
94.0% MgO |
Alloy 600 |
.047 |
15 |
2000 |
30 |
|
*MTC00144 |
J |
94.0% MgO |
304 |
.047 |
15 |
1500 |
30 |
|
*MTC00145 |
K |
94.0% MgO |
304 |
.047 |
15 |
1650 |
30 |
|
MTC00146 |
E |
94.0% MgO |
304 |
.047 |
15 |
1600 |
30 |
|
MTC00147 |
T |
94.0% MgO |
304 |
.047 |
15 |
650 |
30 |
|
|
Metric -- Single Element
Standard Size List
|
|
O.D.
(mm) |
Part
Number |
ANSI
Calibration |
Insulation
(Min. Purity) |
Sheath
Material |
Nom.
Wall
Thickness
(mm) |
Nom.
Wire
Dia. (mm) |
Max.
Operating
Temp. (ºC) |
Max.
Stock
Length (M) |
1.5
±.03 |
MTC00148 |
J |
99.4% MgO |
Alloy 600 |
0.20 |
0.28 |
815 |
167 |
|
MTC00149 |
K |
99.4% MgO |
Alloy 600 |
0.20 |
0.28 |
1093 |
167 |
|
MTC00150 |
J |
99.4% MgO |
304 |
0.20 |
0.28 |
815 |
167 |
|
MTC00151 |
K |
99.4% MgO |
304 |
0.20 |
0.28 |
898 |
167 |
2.0
±.03 |
MTC00152 |
J |
94.0% MgO |
Alloy 600 |
0.25 |
0.36 |
815 |
93 |
|
MTC00153 |
K |
94.0% MgO |
Alloy 600 |
0.25 |
0.36 |
1093 |
93 |
|
MTC00154 |
J |
94.0% MgO |
304 |
0.25 |
0.36 |
815 |
93 |
|
MTC00155 |
K |
94.0% MgO |
304 |
0.25 |
0.36 |
898 |
93 |
|
MTC00156 |
J |
94.0% MgO |
316 |
0.25 |
0.36 |
815 |
93 |
|
MTC00157 |
K |
94.0% MgO |
316 |
0.25 |
0.36 |
898 |
93 |
3.0
±.05 |
MTC00158 |
J |
94.0% MgO |
Alloy 600 |
0.33 |
0.46 |
815 |
84 |
|
MTC00159 |
K |
94.0% MgO |
Alloy 600 |
0.33 |
0.46 |
1093 |
84 |
|
MTC00160 |
J |
94.0% MgO |
304 |
0.33 |
0.46 |
815 |
84 |
|
MTC00161 |
K |
94.0% MgO |
304 |
0.33 |
0.46 |
898 |
84 |
|
MTC00162 |
E |
94.0% MgO |
304 |
0.33 |
0.46 |
871 |
84 |
|
MTC00163 |
T |
94.0% MgO |
304 |
0.33 |
0.46 |
343 |
84 |
|
MTC00164 |
J |
94.0% MgO |
316 |
0.33 |
0.46 |
815 |
84 |
|
MTC00165 |
K |
94.0% MgO |
316 |
0.33 |
0.46 |
898 |
84 |
4.5
±.05 |
MTC00166 |
J |
94.0% MgO |
Alloy 600 |
0.53 |
0.69 |
815 |
37 |
|
MTC00167 |
K |
94.0% MgO |
Alloy 600 |
0.53 |
0.69 |
1093 |
37 |
|
MTC00168 |
J |
94.0% MgO |
304 |
0.53 |
0.69 |
815 |
37 |
|
MTC00169 |
K |
94.0% MgO |
304 |
0.53 |
0.69 |
898 |
37 |
6.0
+.07
-.05 |
MTC00170 |
J |
94.0% MgO |
Alloy 600 |
0.69 |
0.94 |
815 |
21 |
|
MTC00171 |
K |
94.0% MgO |
Alloy 600 |
0.69 |
0.94 |
1093 |
21 |
|
MTC00172 |
J |
94.0% MgO |
304 |
0.69 |
0.94 |
815 |
21 |
|
MTC00173 |
K |
94.0% MgO |
304 |
0.69 |
0.94 |
898 |
21 |
8.0
+.07
-.05 |
MTC00174 |
J |
94.0% MgO |
Alloy 600 |
0.91 |
1.22 |
815 |
12 |
|
MTC00175 |
K |
94.0% MgO |
Alloy 600 |
0.91 |
1.22 |
1093 |
12 |
|
MTC00176 |
J |
94.0% MgO |
304 |
0.91 |
1.22 |
815 |
12 |
|
MTC00177 |
K |
94.0% MgO |
304 |
0.91 |
1.22 |
898 |
12 |
|
How
To Order |
|
Stock
Thermocouple Cable |
Custom
Manufactured Thermocouple Cables |
|
Order by Part Number from the Stock Lists shown
above.
Thermocouple wire is sold by the foot and subject to
minimum billing.
Tempco-Pak is stocked in random lengths with the
maximum stock lengths listed in the tables showing the varieties of
commonly available material. Tempco reserves the right to supply
random lengths of our choice unless specific lengths are specified on
your order. Tempco-Pak can be furnished in coil form or in straight
lengths. Normally .375" diameter and .312" diameter are
shipped in straight lengths. Longer lengths are available on special
order.
|
Understanding that
Mineral Insulated Thermocouple Cables can be very application specific
for sizes not listed TEMPCO will design and manufacture a Cable to
meet your requirements. Standard lead time is 4 weeks.
Please contact Thermal Tech
Equipment for further assistance.
816-468-7577 |
|
