CA1238116A - Stable high temperature cables and devices made therefrom - Google Patents
Stable high temperature cables and devices made therefromInfo
- Publication number
- CA1238116A CA1238116A CA000480703A CA480703A CA1238116A CA 1238116 A CA1238116 A CA 1238116A CA 000480703 A CA000480703 A CA 000480703A CA 480703 A CA480703 A CA 480703A CA 1238116 A CA1238116 A CA 1238116A
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- cable according
- high temperature
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01K—MEASURING TEMPERATURE; MEASURING QUANTITY OF HEAT; THERMALLY-SENSITIVE ELEMENTS NOT OTHERWISE PROVIDED FOR
- G01K7/00—Measuring temperature based on the use of electric or magnetic elements directly sensitive to heat ; Power supply therefor, e.g. using thermoelectric elements
- G01K7/02—Measuring temperature based on the use of electric or magnetic elements directly sensitive to heat ; Power supply therefor, e.g. using thermoelectric elements using thermoelectric elements, e.g. thermocouples
- G01K7/04—Measuring temperature based on the use of electric or magnetic elements directly sensitive to heat ; Power supply therefor, e.g. using thermoelectric elements using thermoelectric elements, e.g. thermocouples the object to be measured not forming one of the thermoelectric materials
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- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Measuring Temperature Or Quantity Of Heat (AREA)
- Insulated Conductors (AREA)
- Resistance Heating (AREA)
- Cable Accessories (AREA)
Abstract
ABSTRACT
Compacted mineral insulated integrally sheathed electrically conductive cables, thermocouple sensors, heat detectors and heating elements utilizing nickel-base alloys are disclosed, characterized in that the cable includes at least one thermoelement composed of a type N alloy, and the sheath is composed of an alloy having similar characteristics to the alloy of which the or at least one thermoelement is composed.
Compacted mineral insulated integrally sheathed electrically conductive cables, thermocouple sensors, heat detectors and heating elements utilizing nickel-base alloys are disclosed, characterized in that the cable includes at least one thermoelement composed of a type N alloy, and the sheath is composed of an alloy having similar characteristics to the alloy of which the or at least one thermoelement is composed.
Description
STABLE HIGH TEMPERATURE CABLES AND
DEVICES MADE THEREFROM
This invention relates to electrically conductive cables, including thermocouple cables, and also includes thermocouple sensors made from the said thermocouple cables. The electrically conductive cables 10 of the invention also include heat detectors and heating elements that are particularly useful at high temperatures.
The invention utilizes nickel-base alloys, including those alloys which are used in -the thermocouple 15 system designated "type N" by such standards bodies as the Instrument Society of America, the American Society for Testing and Materials, the International Electrotechnical Commission and the British Standards Institution.
In one aspect the invention provides nickel-base thermocouple cables, and nickel-base thermocouple sensor systems made therefrom, having superior oxidation resistance, greater longevity and greater thermoelectric stability under longer time periods and over a range of 10 higher temperatures up to 1300C, than existing base-metal cables and sensor systems of the same general kind.
The invention also provides electrically conductive cables including such cables suitable for use as heat detectors and heating elements.
Nickel-base alloys have been used as thermocouples since the early part of this century. One of the commonly used thermocouples is the type K
thermocouple (so designated by the Instrument Society of America). The positive type K thermoelement is a 20 nickel-base alloy containing 9.25 percent by weight of chromium and 0.4 percent by weight of silicon, balance essentially nickel. The negative type K thermoelement is a nickel-base alloy containing 3 percent by weight of manganese, 2 percent by weight of aluminum, 1 percent by 25 weight of silicon, with small amounts of iron and cobalt, and the balance essentially nickel.
The type K thermocouple is recommended to be used in an air atmosphere. At the higher temperatures the type K thermocouple fails because of its relatively 30 poor oxidation resistance. One way in which attempts have been made to overcome this problem is to incorporate the type K thermocouple in a compacted ceramic-insulated thermocouple sensor assembly.
OR
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As is well known in the art a first step in the manufacture of such thermocouple sensors is to produce the so-called "MI" (mineral insulated) cable which comprises a sheath containing one or more thermoelement 5 conductor wires electrically insulated from the sheath (and from each other when two or more conductor wires are used) by compacted mineral insulation material.
In the accompanying drawings:-Fig. 1 illustrates a typical MI cable 10 containing two conductor wires (thermoelements);
Fig. 2 illustrates two basic designs for stagnation temperature probes as more fully discussed below; and Fig. 3 illustrates the large negative 15 temperature coefficient of resistance of the densely compacted insulation in heat sensors according to the invention as more fully discussed below.
The MI cable illustrated in Fig. 1 is of a conventional type comprising a sheath 1, compacted 20 insulation 2 and conductor wires (thermoelements) 3.
Further details of the manufacture of MI cable as illustrated in Fig. 1 are given in Example 1 below.
To make an actual sensor from this cable, the cable is cut and the ends of the conductors are exposed 25 by removing some of the insulation therefrom. The exposed ends of the conductors are then joined to form a thermojunction, which may be accomplished for example by crimping and/or welding.
The thermojunction may simply be left exposed 30 for use in appropriate environments or may be protected by capping -the sheath over the thermojunction with or without insolent.
The latter type of thermocouple sensor has come into common use because it isolates the thermocouple 35 wires from environments that may cause rapid OR
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deterioration and it provides excellent high-temperature insulation for the thermocouple conductor wires. The sheath can be made of a material which, hopefully, is compatible with the environments and processes in which 5 it is being used and which provides a measure of mechanical protection. There are numerous commercial suppliers of type K thermocouples in compacted ceramic-insulated integrally-sheathed forms.
At temperatures above about 1050C known types 10 of compacted ceramic-insulated integrally-sheathed cables and thermocouples fail prematurely because of factors such as-(i) the materials of which their sheaths are made such as inconel and stainless steel, fail by 15 deterioration due to oxidation or other accelerated interaction with their gaseous environment;
(ii) the individual alloys of the type K
thermocouple fail as a result of accelerated oxidation by low-pressure air residual in the compacted ceramic 20 insulation;
(iii) the thermoelement conductor wires fail mechanically because of substantial alternating strains imposed during thermal cycling. These strains are caused primarily by longitudinal stresses which arise because of 25 substantially different temperature coefficients of linear expansion of the sheath and thermoelement materials. Some typical average values of these coefficients of expansion are -OR
isle Component Material 10-6 o -1 ( 11 sheath stainless steel 20 thermals type K 17 (iv) the thermoelement conductor alloys are 5 contaminated by dissolution of extraneous elements received from a different sheath alloy by thermal diffusion through the compacted insulating material.
These elements, ego My, Fe, Mow Cut cause substantial changes in the thermoelectromotive force of the 10 thermocouple.
(v) the composition of the thermoelement conductor wires is altered by exposure of the thermocouple to prolonged nuclear irradiation, which results in the transmutation of one or more elements in the alloy.
As a result, there is a need for a new integral compacted ceramic-insulated cable suitable as a heating element or for production of thermocouple sensors which is substantially free of the degradative influences described above and which demonstrates enhanced 20 environmental and thermoelectric stability at temperatures significantly in excess of 1050C.
It is believed, therefore, that a new compacted ceramic-insulated integrally-sheathed cable, substantially free of degradative influences such as 25 accelerated oxidation, differential thermal stresses cross-contamination by diffusion, and transmutations and demonstrating enhanced resistance to environmental interactions and to drifts in thermal em and resistivity at temperatures up to 1300C in a variety of 30 different atmospheres, is an advancement in the art.
It is also an advancement of the art that certain causes of thermoelectric instability which plague conventional base-metal thermocouple transducers, namely accelerated oxidation, in homogeneous short-range OR
lo structural ordering, nuclear transmutations, and magnetic transformations, are virtually eliminated in the new thermocouple sensor of this invention. This is because the compositions of the type N thermoelement conductor 5 wires incorporated in the new integral compacted ceramic-insulated thermocouple sensor are such as to virtually eliminate thermal-emf shifts due to oxidation, in particular internal oxidation, and short-range order, contain no strongly transmuting component elements, and 10 have magnetic transformations below room temperatures.
OBJECTS AND SUMMARY OF INVENTION
It is one of the objects of this invention to provide an integral compacted base-metal thermocouple cable and sensor which are thermoelectrically stable up 15 to 1300C. It is a further object of this invention to provide an integral compacted base-metal thermocouple cable and sensor which are highly oxidation resistant up to 1300C~
It is another object of the invention to 20 provide electrically conductive cables and heating elements which have similar advantages at high temperatures.
It is a further object of this invention to provide electrically conductive cables and heat detectors 25 which have similar advantages at high temperatures.
These and other objects of this invention are achieved, in one aspect of the invention, by the use of two specific alloys, and certain compositional variants of these alloys, as sheath materials. The said alloys 30 are similar to those which are suitable for use as the positive and negative thermoelements of the thermocouple.
The chemical compositional tolerances (percentages by OR
3~1~6 weight) for the alloying constituents of the alloys for the positive and negative thermoelements of the thermocouple conductors are -Positive Alloy Element Negative Alloy . _ 14.2 + 0.15 -I ----- Or ------------- 0.02 max.
1.4 + 0.05 ----------- So ------------- 4.4 0.2 0.1 _ 0.03 ----------- Fe ------------- 0.1 + 0.03 0.03 max. ----------- C -------------- 0.03 lax.
My ------------- 0.1 + 0.05 Balance ----------- No ------------- Balance Thermocouples of these alloys are designated 'type N' by the Instrument Society of America and other such bodies.
The first sheath alloy of this invention 15 consists essentially of:-(a) from about 13.0 weight percent to about 15.0 weight percent of chromium, from about 1.0 weight percent to about 2.0 weight percent of silicon, from about 0.03 weight percent to about 0.25 weight percent of magnesium, 20 and the balance nickel.
The second sheath alloy of this invention consists essentially of:-(b) from about 3.0 weight percent to about 5.0 weight percent of silicon, from about 0.03 weight percent 25 to about 0.25 weight percent of magnesium and the balance nickel.
The refractory insulating materials for the integral compacted base-metal thermocouple sensor include magnesium oxide, beryllium oxide, aluminum oxide, 30 zirconium oxide and other suitable refractory oxides.
This invention also includes several applications of the novel device. One of these applications relates to the measurement of the OR
do g _ temperature of moving gases such as are encountered in gas-turbines, flues, pipes, chimneys and other confined spaces intended for the conveyance of gases.
If an attempt is made to use a solid sensor 5 element or probe to measure temperatures in a body of gas moving relative to the element or probe, a heating effect due to adiabatic compression of the gaseous layer contiguous to the surface of the sensitive probe results in an elevated temperature measurement error. This 10 problem is conventionally combated by the use of a 'stagnation-temperature probe'. Basic designs of such a probe are exemplified in Figure 2, wherein the components are:-a, h thermoelement conductor wires b, i, n stagnation tube components c plastic d hold screw e, m measurement thermojunction f, 1 vent holes g tight fit j silica tube k cement The construction usually consists of a stem protruding into the gas stream with a thermoelectric 25 junction in some sort of cup at its end. The thermoelectric junction is located in the 'stagnation zone' of the gas-flow disturbance produced by this cup and its associated orifices. These devices, in general, are characterized by flow restrictions suited to nearly 30 stopping the gas-flow at the location of the measuring thermoelectric junction. The idea is to obtain the temperature reading that would occur were there no relative velocity between the gas and the sensor probe, that is, the temperature that would prevail in the 35 absence of the thermoelectric stagnation probe.
OR
-81~6 Stagnation probe thermocouples, particularly those employed to measure gas temperatures in high-performance gas-turbine engines, suffer from several inherent error sources additional to that attributed 5 above to adiabatic compression. Examples of these additional error sources include thermal em drift in base-metal thermocouple alloys due to high-temperature corrosion, catalysis of incompletely combusted air/fuel mixtures by conventional rare-metal thermocouples, and 10 heat radiation to and from thermocouple measuring thermojunctions from and to the internal surfaces of the gas containment vessel.
These errors in temperature measurement additional to the adiabatic compression error will be 15 largely eliminated by the use of type N thermocouples as the temperature sensor incorporated in the stagnation probe, more particularly the type N thermocouples in the form of the integral compacted thermocouple sensor of this invention.
Such a stagnation temperature probe incorporating a type N thermocouple, either as a bare-wire thermocouple or as an integral compacted thermocouple sensor of this invention, is a significant advancement in the art. A further advancement still is 25 to utilize one or any of the alloys specified (a), (at), (a), (a), (b), (by), (by), (by) below as the stagnation tube of the stagnation probe in lieu of any of the stainless steels or any of the other alloys conventionally used.
Another application of the novel device relates to the detection, location and monitoring of expected or unexpected sources of heat such as may be encountered in machinery, storage spaces such as bins, kilns, silos, etc.; pipelines, buildings, instruments, ships, aircraft, 35 nuclear reactors, and in many other locations. Such OR
,, devices, which are in most respects similar in construction to the conventional MI cable described above, are well known in the art. One essential difference is that the densely compacted insulation has 5 insulating properties including a large negative temperature coefficient of resistance, as is illustrated in principle in Fig. 3.
Incipient local sources of heat are detected by this device because the conductivity of the compacted 10 insulation in the vicinity of such sources increases, over the temperature range up to about 900C, causing local short-circuiting of the thermoelectric conductors to form a local measuring thermojunction. This reversible effect allows the location, intensity and 15 duration of a temporal heat source to be determined and monitored.
Unfortunately, conventional heat sensors of this kind show the same tendency to premature failure, by the same causes shown by MI cables of the conventional 20 kind, when exposed to high temperatures for prolonged periods of time. Novel heat sensors made from type N
alloys, in the manner provided by this invention, are a significant advancement in the art in that they are virtually free of the degradative influences described 25 above for conventional MI cable. The virtual freedom shown by the novel heat detectors from nuclear transmutations is of singular importance, as they are thus suitable for use inside nuclear reactors for substantial periods of time. Conventional heat sensors 30 of MI cable form are not free of transmutational effects.
Conventional heat detectors will fail electrically when heated for periods of time at temperatures above about 1100C. The novel heat detector OR
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will withstand temperatures up to 1300C, such as might be caused by the direct impingement of flame, for prolonged periods of time.
A further application of the novel device 5 relates to resistive heating elements such as are used for raising the temperature of heated enclosures such as furnaces, ovens, baths, etc., and other spaces. Such heating devices, which are in most respects similar in construction to conventional MI cable described above, 10 are well known in the art. One essential difference is that the conductor elements are made of a conventional resistor alloy such as 'nichrome' (nichrome is a trade mark of the Driver-Harris Company of U.K.~Italy, France, Australia and U.S.A.) which provides resistive heating on 15 the passage of electric current.
Unfortunately conventional heater elements of this kind show the same tendency to premature failure from the same causes as shown by MI cables of the conventional kind. Novel heater elements made from type 20 N alloys in the manner provided by this invention are a significant advancement in the art in that they are virtually free of the degradative influences described above for conventional MI cable.
It is fortuitous that the resistivity and the 25 temperature coefficient of resistance of the positive type N alloys are comparable with those of nichrome.
Such type N alloys can thus most efficaciously be used as the resistive heating element in the novel invention at high temperatures.
OR
.. . . .. . . ..
1;~3lS~1~6 AlloyResistivity at Temperature Coefficient -20C of Resistance (~Q.cm) - (Q Q -1 ouzel) nichrome110 - 0.00004 ) *
+ 0.00~07 positive N 95 + 0.00011 *different reports The net effects of these properties are to make the resistivity of a positive N alloy comparable with 10 that of nichrome at elevated temperatures.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
For a better understanding of the present invention together with other and further objects, advantages, and capabilities thereof, reference is made 15 to the following disclosure.
The integral base-metal thermocouple sensor of the present invention has excellent oxidation resistance and thermoelectric stability at temperatures up to 1300C. It has been found that the alloys of this 20 invention change very little both in thermal em output and degree of oxidation even after about 1000 hours of exposure at 1250C. When compared with the conventional thermals of type K and sheath alloys of inconel and stainless steel, which materials are 25 conventionally used in existing integral compacted thermocouple sensors; the integral compacted thermocouple sensor of this invention incorporating the type N
specified thermoelements and sheaths of alloys (a) and (b) described above show markedly better thermoelectric 30 and environmental stability to a degree hitherto unattainable with conventionally used base-metal alloys.
OR
, I
The thermoelectric conductor alloys to be incorporated in this invention consist essentially of the type N alloys specified above. The sheath alloys to be incorporated in this invention consist essentially of the 5 elemental compositions (a) and (b) described above.
Preferred compositions of type (a) consist essentially of:-(at) from about 13.9 weight percent to about 14.5 weight percent of chromium, from about 1.3 weight percent 10 to about 1.5 weight percent of silicon, from about 0.05 weight percent to about 0.20 weight percent of magnesium, and the balance nickel, or more preferably -(a) from about 14.05 percent weight to about 14.35 percent weight of chromium, from about 1.35 percent 15 weight to about 1.45 percent weight of silicon, from about 0.10 weight percent to about 0.20 weight percent of magnesium, about 0.15 percent weight maximum of iron, about 0.05 percent weight maximum of carbon, and the balance nickel.
A specific preferred composition of type (a) consists essentially, within the usual limits of manufacturing tolerance of:-(a) 14.2 weight percent chromium, 1.4 weight percent silicon, 0.1 weight percent iron, 0.03 weight percent magnesium and the balance nickel.
Preferred compositions of type (b) consist essentially of:-30 (by) from about 4.0 weight percent to about 4.8 weight percent of silicon, from about 0.05 weight percent to about 0.20 weight percent of magnesium, and the balance nickel, or more preferably -OR
.
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(by) from about 4.2 percent weight to about 4.6 percent weight silicon, from about 0.10 weight percent to about 0.20 weight percent magnesium, about 0.05 weight percent maximum chromium, about 0.15 weight percent 5 maximum iron, about 0.05 percent weight maximum of carbon, and the balance nickel.
A specific preferred composition of type (b) consists essentially, within the usual limits of manufacturing tolerance of:-10 (by) 4.4 weight percent silicon, 0.1 weight percent iron, 0.1 weight percent magnesium and the balance nickel It will be clearly understood that when the 15 cable contains a single thermoelement, the most preferred sheath material is the thermoelectrically opposite alloy to the said single thermoelement. In this case a sensor is formed by joining the thermoelement to the sheath.
When more than one thermoelement is employed and the 20 thermoelements are made of dissimilar alloys, the sheath material is most preferably made of the same alloy as any one of the thermoelements.
In a further modification of the invention, of particular value in hostile environments such as are 25 encountered in the chemical and petroleum industries, the sheath may be fabricated of appropriate corrosion resistant material.
The invention will be further illustrated by the following non-limiting examples.
The integral compacted thermocouple cable of this Example is fabricated using existing manufacturing procedures. They begin with thermoelectrically matched thermoelement wires surrounded by non-compacted ceramic OR
insulating material held within a metal tube. By rolling, drawing, swaying, or other mechanical reduction processes the tube is reduced in diameter and the insulation is compacted around the wires. The 5 manufacturing process parameters are adjusted so that the ratios of sheath diameter to wire-size and sheath wall-thickness offer a balance between maximum wall-thickness and suitable insulation spacing for effective insulation resistance at elevated temperatures.
An important feature of the fabrication process is that considerable attention is given to the initial cleanliness and chemical purity of the components and retention of a high degree of cleanliness and dryness throughout fabrication. As already noted above, to make 15 an actual sensor from this cable, the cable is cut and the ends of the conductors are exposed by removing some of the insulation therefrom. The exposed ends of the conductors are then joined to form a thermojunction, which may be accomplished for example by crimping and/or 20 welding.
The thermojunction may simply be left exposed for use in appropriate environments, or may be protected by capping the sheath over the thermojunction with or without insolent. The measuring thermojunction of the 25 thermocouple is usually, but not always, electrically isolated from the end of the sheath.
In this example, the alloys for the thermocouple conductor wires are those specified above as type N and the alloy for the sheath is that specified in 30 (a) above.
An important feature of the finished product of this example is that the essential similarity between the properties of the sheath alloy and the thermocouple conductor alloys virtually eliminates the destructive 35 influences of -thermocouple contamination by cross-OR
diffusion, mechanical failure due to differential thermal stresses, and accelerated oxidation above about 1050C.
The strains caused by longitudinal stresses arising during thermal cycling are small because of the very small dip-furnaces in the temperature coefficients of lineal expansion between the materials of the sheath and of the thermoelement conductors. Some typical average values of these coefficients of expansion are -Component Material lo OKAY 1 (1200C) sheath alloy (a) above 17.5 thermals type N 17.0 (average of positive and negative) EXAMPLE 2.
- The integral compacted thermocouple cable and sensor of this Example is the same as described in Example 1, except that the alloy for the sheath is that specified (at) above used in lieu of that alloy specified (a) above.
EXAMPLE 3.
The integral compacted thermocouple cable and sensor of this Example is the same as described in Example 1, except that the alloy for the sheath is that specified (a) above used in lieu of that alloy specified (a) above.
- EXAMPLE 4.
An integral compacted thermocouple cable is made as in Example 1, the composition of the components being:-positive thermoelement - alloy (a) negative thermoelement - alloy (by) sheath - alloy (a) ISLE
EXAMPLES 5 to 8 The thermocouple cables of these Examples are the same, respectively, as those described in Examples 1 to 4 except that the sheath alloys are strengthened by addition of one or more components known for the purpose of increase in mechanical strength of said alloys at high temperature for example one or more of manganese, iron, molybdenum, cobalt, tungsten, and oxide-particle dispersions.
EXAMPLES 9 to 16 The integral compacted thermocouple cables and sensors of these Examples are the same, respectively, as those described in Examples 1 to 8, except that the sheath alloys are coated to further inhibit chemical high-temperature corrosive degradation. Such coatings include those deposited by a wide variety of conventional protective coating processes such as electrolytic deposition from aqueous solution or fused salts or other electrolytic liquids, such as metallic diffusion processes including aluminizing, chromizing, valorizing and similar processes, such as overlay coatings, and other protective coating processes.
a LOWE
.
The integral compacted thermocouple cable and sensor of this Example is the same as described in Example 1, except that the alloy for the sheath is that specified (b) above used in lieu of that alloy specified (a) above.
_ AMPLE 18 The integral compacted thermocouple cable and sensor of this Example is the same as described in Example 1, except that the alloy for the sheath is that specified (blue above used in lieu of that alloy specified (a) above.
The integral compacted thermocouple cable and sensor of this Example is the same as described in Example 1, except that the alloy for the sheath is that specified It (by) above used in lieu of that alloy specified (a) above.
The integral compacted thermocouple cable of this example is the same as Example 4 except that the sheath is composed of alloy by instead of alloy (a).
I lo Jo EXAMPLES 21 to 24 The integral compacted thermocouple cables and sensors of these Examples are the same, respectively, as those described in Examples 17 to 20 except that the sheath alloys contain in addition up to 1.0 weight percent of one or more elements known for the purpose of inhibiting metal-surgical grain growth, occurring at high temperature, for example niobium or titanium.
EXAMPLES 25 to 28 The integral compacted thermocouple cables and sensors of these Examples are the same, respectively, as those described in Examples 17 to 20, except that the sheath alloys contain in addition an appropriate amount of one or more components known for the purpose of increase in mechanical strength of said alloys at high temperature, for example manganese, iron, molybdenum, cobalt, tungsten, and oxide-particle dispersions.
EXAMPLES 29 to 32 .
The integral compacted thermocouple cables and sensors of these Examples are the same as those described, respectively, in Examples 17 to 20, except that the sheath alloys contain in addition up to 1.0 weight percent of one or more elements known for the purpose of inhibiting metal-surgical grain growth occurring at hick temperature, for example niobium or titanium; and also an appropriate amount of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, for example manganese, iron, molybdenum, cobalt, tungsten, and oxide-particle dispersions.
~L23~16 _ 21 _ EXAMPLES 33 to 48 .
The integral compacted thermocouple cables and sensors of these Examples are the same, respectively, as those described in Examples 17 through 32, except that the sheath alloys are coated my any of the processes and for the purposes describe din Example 9 through Example 16.
EXAMPLES 49 to 96 Heat detectors in accordance with the invention are produced in the same manner as the integral compacted cables of examples 1 through 48 except that the refractory compacted insolent incorporates insulating properties with a high negative temperature coefficient of resistance.
EXAMPLES 97 to 576 Heating elements in accordance with the invention are produced in the same manner as the integral compacted cables of examples 1 through 96, except that a single resistive heating conductor is used in each case and the said conductor is composed of an alloy which is respect-lively: positive type N, (a), (at), (a) or (a).
It will be clearly understood that the invention in its general aspects is not limited to the specific details referred to hereinabove.
.
DEVICES MADE THEREFROM
This invention relates to electrically conductive cables, including thermocouple cables, and also includes thermocouple sensors made from the said thermocouple cables. The electrically conductive cables 10 of the invention also include heat detectors and heating elements that are particularly useful at high temperatures.
The invention utilizes nickel-base alloys, including those alloys which are used in -the thermocouple 15 system designated "type N" by such standards bodies as the Instrument Society of America, the American Society for Testing and Materials, the International Electrotechnical Commission and the British Standards Institution.
In one aspect the invention provides nickel-base thermocouple cables, and nickel-base thermocouple sensor systems made therefrom, having superior oxidation resistance, greater longevity and greater thermoelectric stability under longer time periods and over a range of 10 higher temperatures up to 1300C, than existing base-metal cables and sensor systems of the same general kind.
The invention also provides electrically conductive cables including such cables suitable for use as heat detectors and heating elements.
Nickel-base alloys have been used as thermocouples since the early part of this century. One of the commonly used thermocouples is the type K
thermocouple (so designated by the Instrument Society of America). The positive type K thermoelement is a 20 nickel-base alloy containing 9.25 percent by weight of chromium and 0.4 percent by weight of silicon, balance essentially nickel. The negative type K thermoelement is a nickel-base alloy containing 3 percent by weight of manganese, 2 percent by weight of aluminum, 1 percent by 25 weight of silicon, with small amounts of iron and cobalt, and the balance essentially nickel.
The type K thermocouple is recommended to be used in an air atmosphere. At the higher temperatures the type K thermocouple fails because of its relatively 30 poor oxidation resistance. One way in which attempts have been made to overcome this problem is to incorporate the type K thermocouple in a compacted ceramic-insulated thermocouple sensor assembly.
OR
~23~
As is well known in the art a first step in the manufacture of such thermocouple sensors is to produce the so-called "MI" (mineral insulated) cable which comprises a sheath containing one or more thermoelement 5 conductor wires electrically insulated from the sheath (and from each other when two or more conductor wires are used) by compacted mineral insulation material.
In the accompanying drawings:-Fig. 1 illustrates a typical MI cable 10 containing two conductor wires (thermoelements);
Fig. 2 illustrates two basic designs for stagnation temperature probes as more fully discussed below; and Fig. 3 illustrates the large negative 15 temperature coefficient of resistance of the densely compacted insulation in heat sensors according to the invention as more fully discussed below.
The MI cable illustrated in Fig. 1 is of a conventional type comprising a sheath 1, compacted 20 insulation 2 and conductor wires (thermoelements) 3.
Further details of the manufacture of MI cable as illustrated in Fig. 1 are given in Example 1 below.
To make an actual sensor from this cable, the cable is cut and the ends of the conductors are exposed 25 by removing some of the insulation therefrom. The exposed ends of the conductors are then joined to form a thermojunction, which may be accomplished for example by crimping and/or welding.
The thermojunction may simply be left exposed 30 for use in appropriate environments or may be protected by capping -the sheath over the thermojunction with or without insolent.
The latter type of thermocouple sensor has come into common use because it isolates the thermocouple 35 wires from environments that may cause rapid OR
LOWE
deterioration and it provides excellent high-temperature insulation for the thermocouple conductor wires. The sheath can be made of a material which, hopefully, is compatible with the environments and processes in which 5 it is being used and which provides a measure of mechanical protection. There are numerous commercial suppliers of type K thermocouples in compacted ceramic-insulated integrally-sheathed forms.
At temperatures above about 1050C known types 10 of compacted ceramic-insulated integrally-sheathed cables and thermocouples fail prematurely because of factors such as-(i) the materials of which their sheaths are made such as inconel and stainless steel, fail by 15 deterioration due to oxidation or other accelerated interaction with their gaseous environment;
(ii) the individual alloys of the type K
thermocouple fail as a result of accelerated oxidation by low-pressure air residual in the compacted ceramic 20 insulation;
(iii) the thermoelement conductor wires fail mechanically because of substantial alternating strains imposed during thermal cycling. These strains are caused primarily by longitudinal stresses which arise because of 25 substantially different temperature coefficients of linear expansion of the sheath and thermoelement materials. Some typical average values of these coefficients of expansion are -OR
isle Component Material 10-6 o -1 ( 11 sheath stainless steel 20 thermals type K 17 (iv) the thermoelement conductor alloys are 5 contaminated by dissolution of extraneous elements received from a different sheath alloy by thermal diffusion through the compacted insulating material.
These elements, ego My, Fe, Mow Cut cause substantial changes in the thermoelectromotive force of the 10 thermocouple.
(v) the composition of the thermoelement conductor wires is altered by exposure of the thermocouple to prolonged nuclear irradiation, which results in the transmutation of one or more elements in the alloy.
As a result, there is a need for a new integral compacted ceramic-insulated cable suitable as a heating element or for production of thermocouple sensors which is substantially free of the degradative influences described above and which demonstrates enhanced 20 environmental and thermoelectric stability at temperatures significantly in excess of 1050C.
It is believed, therefore, that a new compacted ceramic-insulated integrally-sheathed cable, substantially free of degradative influences such as 25 accelerated oxidation, differential thermal stresses cross-contamination by diffusion, and transmutations and demonstrating enhanced resistance to environmental interactions and to drifts in thermal em and resistivity at temperatures up to 1300C in a variety of 30 different atmospheres, is an advancement in the art.
It is also an advancement of the art that certain causes of thermoelectric instability which plague conventional base-metal thermocouple transducers, namely accelerated oxidation, in homogeneous short-range OR
lo structural ordering, nuclear transmutations, and magnetic transformations, are virtually eliminated in the new thermocouple sensor of this invention. This is because the compositions of the type N thermoelement conductor 5 wires incorporated in the new integral compacted ceramic-insulated thermocouple sensor are such as to virtually eliminate thermal-emf shifts due to oxidation, in particular internal oxidation, and short-range order, contain no strongly transmuting component elements, and 10 have magnetic transformations below room temperatures.
OBJECTS AND SUMMARY OF INVENTION
It is one of the objects of this invention to provide an integral compacted base-metal thermocouple cable and sensor which are thermoelectrically stable up 15 to 1300C. It is a further object of this invention to provide an integral compacted base-metal thermocouple cable and sensor which are highly oxidation resistant up to 1300C~
It is another object of the invention to 20 provide electrically conductive cables and heating elements which have similar advantages at high temperatures.
It is a further object of this invention to provide electrically conductive cables and heat detectors 25 which have similar advantages at high temperatures.
These and other objects of this invention are achieved, in one aspect of the invention, by the use of two specific alloys, and certain compositional variants of these alloys, as sheath materials. The said alloys 30 are similar to those which are suitable for use as the positive and negative thermoelements of the thermocouple.
The chemical compositional tolerances (percentages by OR
3~1~6 weight) for the alloying constituents of the alloys for the positive and negative thermoelements of the thermocouple conductors are -Positive Alloy Element Negative Alloy . _ 14.2 + 0.15 -I ----- Or ------------- 0.02 max.
1.4 + 0.05 ----------- So ------------- 4.4 0.2 0.1 _ 0.03 ----------- Fe ------------- 0.1 + 0.03 0.03 max. ----------- C -------------- 0.03 lax.
My ------------- 0.1 + 0.05 Balance ----------- No ------------- Balance Thermocouples of these alloys are designated 'type N' by the Instrument Society of America and other such bodies.
The first sheath alloy of this invention 15 consists essentially of:-(a) from about 13.0 weight percent to about 15.0 weight percent of chromium, from about 1.0 weight percent to about 2.0 weight percent of silicon, from about 0.03 weight percent to about 0.25 weight percent of magnesium, 20 and the balance nickel.
The second sheath alloy of this invention consists essentially of:-(b) from about 3.0 weight percent to about 5.0 weight percent of silicon, from about 0.03 weight percent 25 to about 0.25 weight percent of magnesium and the balance nickel.
The refractory insulating materials for the integral compacted base-metal thermocouple sensor include magnesium oxide, beryllium oxide, aluminum oxide, 30 zirconium oxide and other suitable refractory oxides.
This invention also includes several applications of the novel device. One of these applications relates to the measurement of the OR
do g _ temperature of moving gases such as are encountered in gas-turbines, flues, pipes, chimneys and other confined spaces intended for the conveyance of gases.
If an attempt is made to use a solid sensor 5 element or probe to measure temperatures in a body of gas moving relative to the element or probe, a heating effect due to adiabatic compression of the gaseous layer contiguous to the surface of the sensitive probe results in an elevated temperature measurement error. This 10 problem is conventionally combated by the use of a 'stagnation-temperature probe'. Basic designs of such a probe are exemplified in Figure 2, wherein the components are:-a, h thermoelement conductor wires b, i, n stagnation tube components c plastic d hold screw e, m measurement thermojunction f, 1 vent holes g tight fit j silica tube k cement The construction usually consists of a stem protruding into the gas stream with a thermoelectric 25 junction in some sort of cup at its end. The thermoelectric junction is located in the 'stagnation zone' of the gas-flow disturbance produced by this cup and its associated orifices. These devices, in general, are characterized by flow restrictions suited to nearly 30 stopping the gas-flow at the location of the measuring thermoelectric junction. The idea is to obtain the temperature reading that would occur were there no relative velocity between the gas and the sensor probe, that is, the temperature that would prevail in the 35 absence of the thermoelectric stagnation probe.
OR
-81~6 Stagnation probe thermocouples, particularly those employed to measure gas temperatures in high-performance gas-turbine engines, suffer from several inherent error sources additional to that attributed 5 above to adiabatic compression. Examples of these additional error sources include thermal em drift in base-metal thermocouple alloys due to high-temperature corrosion, catalysis of incompletely combusted air/fuel mixtures by conventional rare-metal thermocouples, and 10 heat radiation to and from thermocouple measuring thermojunctions from and to the internal surfaces of the gas containment vessel.
These errors in temperature measurement additional to the adiabatic compression error will be 15 largely eliminated by the use of type N thermocouples as the temperature sensor incorporated in the stagnation probe, more particularly the type N thermocouples in the form of the integral compacted thermocouple sensor of this invention.
Such a stagnation temperature probe incorporating a type N thermocouple, either as a bare-wire thermocouple or as an integral compacted thermocouple sensor of this invention, is a significant advancement in the art. A further advancement still is 25 to utilize one or any of the alloys specified (a), (at), (a), (a), (b), (by), (by), (by) below as the stagnation tube of the stagnation probe in lieu of any of the stainless steels or any of the other alloys conventionally used.
Another application of the novel device relates to the detection, location and monitoring of expected or unexpected sources of heat such as may be encountered in machinery, storage spaces such as bins, kilns, silos, etc.; pipelines, buildings, instruments, ships, aircraft, 35 nuclear reactors, and in many other locations. Such OR
,, devices, which are in most respects similar in construction to the conventional MI cable described above, are well known in the art. One essential difference is that the densely compacted insulation has 5 insulating properties including a large negative temperature coefficient of resistance, as is illustrated in principle in Fig. 3.
Incipient local sources of heat are detected by this device because the conductivity of the compacted 10 insulation in the vicinity of such sources increases, over the temperature range up to about 900C, causing local short-circuiting of the thermoelectric conductors to form a local measuring thermojunction. This reversible effect allows the location, intensity and 15 duration of a temporal heat source to be determined and monitored.
Unfortunately, conventional heat sensors of this kind show the same tendency to premature failure, by the same causes shown by MI cables of the conventional 20 kind, when exposed to high temperatures for prolonged periods of time. Novel heat sensors made from type N
alloys, in the manner provided by this invention, are a significant advancement in the art in that they are virtually free of the degradative influences described 25 above for conventional MI cable. The virtual freedom shown by the novel heat detectors from nuclear transmutations is of singular importance, as they are thus suitable for use inside nuclear reactors for substantial periods of time. Conventional heat sensors 30 of MI cable form are not free of transmutational effects.
Conventional heat detectors will fail electrically when heated for periods of time at temperatures above about 1100C. The novel heat detector OR
~.Z3~
will withstand temperatures up to 1300C, such as might be caused by the direct impingement of flame, for prolonged periods of time.
A further application of the novel device 5 relates to resistive heating elements such as are used for raising the temperature of heated enclosures such as furnaces, ovens, baths, etc., and other spaces. Such heating devices, which are in most respects similar in construction to conventional MI cable described above, 10 are well known in the art. One essential difference is that the conductor elements are made of a conventional resistor alloy such as 'nichrome' (nichrome is a trade mark of the Driver-Harris Company of U.K.~Italy, France, Australia and U.S.A.) which provides resistive heating on 15 the passage of electric current.
Unfortunately conventional heater elements of this kind show the same tendency to premature failure from the same causes as shown by MI cables of the conventional kind. Novel heater elements made from type 20 N alloys in the manner provided by this invention are a significant advancement in the art in that they are virtually free of the degradative influences described above for conventional MI cable.
It is fortuitous that the resistivity and the 25 temperature coefficient of resistance of the positive type N alloys are comparable with those of nichrome.
Such type N alloys can thus most efficaciously be used as the resistive heating element in the novel invention at high temperatures.
OR
.. . . .. . . ..
1;~3lS~1~6 AlloyResistivity at Temperature Coefficient -20C of Resistance (~Q.cm) - (Q Q -1 ouzel) nichrome110 - 0.00004 ) *
+ 0.00~07 positive N 95 + 0.00011 *different reports The net effects of these properties are to make the resistivity of a positive N alloy comparable with 10 that of nichrome at elevated temperatures.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
For a better understanding of the present invention together with other and further objects, advantages, and capabilities thereof, reference is made 15 to the following disclosure.
The integral base-metal thermocouple sensor of the present invention has excellent oxidation resistance and thermoelectric stability at temperatures up to 1300C. It has been found that the alloys of this 20 invention change very little both in thermal em output and degree of oxidation even after about 1000 hours of exposure at 1250C. When compared with the conventional thermals of type K and sheath alloys of inconel and stainless steel, which materials are 25 conventionally used in existing integral compacted thermocouple sensors; the integral compacted thermocouple sensor of this invention incorporating the type N
specified thermoelements and sheaths of alloys (a) and (b) described above show markedly better thermoelectric 30 and environmental stability to a degree hitherto unattainable with conventionally used base-metal alloys.
OR
, I
The thermoelectric conductor alloys to be incorporated in this invention consist essentially of the type N alloys specified above. The sheath alloys to be incorporated in this invention consist essentially of the 5 elemental compositions (a) and (b) described above.
Preferred compositions of type (a) consist essentially of:-(at) from about 13.9 weight percent to about 14.5 weight percent of chromium, from about 1.3 weight percent 10 to about 1.5 weight percent of silicon, from about 0.05 weight percent to about 0.20 weight percent of magnesium, and the balance nickel, or more preferably -(a) from about 14.05 percent weight to about 14.35 percent weight of chromium, from about 1.35 percent 15 weight to about 1.45 percent weight of silicon, from about 0.10 weight percent to about 0.20 weight percent of magnesium, about 0.15 percent weight maximum of iron, about 0.05 percent weight maximum of carbon, and the balance nickel.
A specific preferred composition of type (a) consists essentially, within the usual limits of manufacturing tolerance of:-(a) 14.2 weight percent chromium, 1.4 weight percent silicon, 0.1 weight percent iron, 0.03 weight percent magnesium and the balance nickel.
Preferred compositions of type (b) consist essentially of:-30 (by) from about 4.0 weight percent to about 4.8 weight percent of silicon, from about 0.05 weight percent to about 0.20 weight percent of magnesium, and the balance nickel, or more preferably -OR
.
~;238~
(by) from about 4.2 percent weight to about 4.6 percent weight silicon, from about 0.10 weight percent to about 0.20 weight percent magnesium, about 0.05 weight percent maximum chromium, about 0.15 weight percent 5 maximum iron, about 0.05 percent weight maximum of carbon, and the balance nickel.
A specific preferred composition of type (b) consists essentially, within the usual limits of manufacturing tolerance of:-10 (by) 4.4 weight percent silicon, 0.1 weight percent iron, 0.1 weight percent magnesium and the balance nickel It will be clearly understood that when the 15 cable contains a single thermoelement, the most preferred sheath material is the thermoelectrically opposite alloy to the said single thermoelement. In this case a sensor is formed by joining the thermoelement to the sheath.
When more than one thermoelement is employed and the 20 thermoelements are made of dissimilar alloys, the sheath material is most preferably made of the same alloy as any one of the thermoelements.
In a further modification of the invention, of particular value in hostile environments such as are 25 encountered in the chemical and petroleum industries, the sheath may be fabricated of appropriate corrosion resistant material.
The invention will be further illustrated by the following non-limiting examples.
The integral compacted thermocouple cable of this Example is fabricated using existing manufacturing procedures. They begin with thermoelectrically matched thermoelement wires surrounded by non-compacted ceramic OR
insulating material held within a metal tube. By rolling, drawing, swaying, or other mechanical reduction processes the tube is reduced in diameter and the insulation is compacted around the wires. The 5 manufacturing process parameters are adjusted so that the ratios of sheath diameter to wire-size and sheath wall-thickness offer a balance between maximum wall-thickness and suitable insulation spacing for effective insulation resistance at elevated temperatures.
An important feature of the fabrication process is that considerable attention is given to the initial cleanliness and chemical purity of the components and retention of a high degree of cleanliness and dryness throughout fabrication. As already noted above, to make 15 an actual sensor from this cable, the cable is cut and the ends of the conductors are exposed by removing some of the insulation therefrom. The exposed ends of the conductors are then joined to form a thermojunction, which may be accomplished for example by crimping and/or 20 welding.
The thermojunction may simply be left exposed for use in appropriate environments, or may be protected by capping the sheath over the thermojunction with or without insolent. The measuring thermojunction of the 25 thermocouple is usually, but not always, electrically isolated from the end of the sheath.
In this example, the alloys for the thermocouple conductor wires are those specified above as type N and the alloy for the sheath is that specified in 30 (a) above.
An important feature of the finished product of this example is that the essential similarity between the properties of the sheath alloy and the thermocouple conductor alloys virtually eliminates the destructive 35 influences of -thermocouple contamination by cross-OR
diffusion, mechanical failure due to differential thermal stresses, and accelerated oxidation above about 1050C.
The strains caused by longitudinal stresses arising during thermal cycling are small because of the very small dip-furnaces in the temperature coefficients of lineal expansion between the materials of the sheath and of the thermoelement conductors. Some typical average values of these coefficients of expansion are -Component Material lo OKAY 1 (1200C) sheath alloy (a) above 17.5 thermals type N 17.0 (average of positive and negative) EXAMPLE 2.
- The integral compacted thermocouple cable and sensor of this Example is the same as described in Example 1, except that the alloy for the sheath is that specified (at) above used in lieu of that alloy specified (a) above.
EXAMPLE 3.
The integral compacted thermocouple cable and sensor of this Example is the same as described in Example 1, except that the alloy for the sheath is that specified (a) above used in lieu of that alloy specified (a) above.
- EXAMPLE 4.
An integral compacted thermocouple cable is made as in Example 1, the composition of the components being:-positive thermoelement - alloy (a) negative thermoelement - alloy (by) sheath - alloy (a) ISLE
EXAMPLES 5 to 8 The thermocouple cables of these Examples are the same, respectively, as those described in Examples 1 to 4 except that the sheath alloys are strengthened by addition of one or more components known for the purpose of increase in mechanical strength of said alloys at high temperature for example one or more of manganese, iron, molybdenum, cobalt, tungsten, and oxide-particle dispersions.
EXAMPLES 9 to 16 The integral compacted thermocouple cables and sensors of these Examples are the same, respectively, as those described in Examples 1 to 8, except that the sheath alloys are coated to further inhibit chemical high-temperature corrosive degradation. Such coatings include those deposited by a wide variety of conventional protective coating processes such as electrolytic deposition from aqueous solution or fused salts or other electrolytic liquids, such as metallic diffusion processes including aluminizing, chromizing, valorizing and similar processes, such as overlay coatings, and other protective coating processes.
a LOWE
.
The integral compacted thermocouple cable and sensor of this Example is the same as described in Example 1, except that the alloy for the sheath is that specified (b) above used in lieu of that alloy specified (a) above.
_ AMPLE 18 The integral compacted thermocouple cable and sensor of this Example is the same as described in Example 1, except that the alloy for the sheath is that specified (blue above used in lieu of that alloy specified (a) above.
The integral compacted thermocouple cable and sensor of this Example is the same as described in Example 1, except that the alloy for the sheath is that specified It (by) above used in lieu of that alloy specified (a) above.
The integral compacted thermocouple cable of this example is the same as Example 4 except that the sheath is composed of alloy by instead of alloy (a).
I lo Jo EXAMPLES 21 to 24 The integral compacted thermocouple cables and sensors of these Examples are the same, respectively, as those described in Examples 17 to 20 except that the sheath alloys contain in addition up to 1.0 weight percent of one or more elements known for the purpose of inhibiting metal-surgical grain growth, occurring at high temperature, for example niobium or titanium.
EXAMPLES 25 to 28 The integral compacted thermocouple cables and sensors of these Examples are the same, respectively, as those described in Examples 17 to 20, except that the sheath alloys contain in addition an appropriate amount of one or more components known for the purpose of increase in mechanical strength of said alloys at high temperature, for example manganese, iron, molybdenum, cobalt, tungsten, and oxide-particle dispersions.
EXAMPLES 29 to 32 .
The integral compacted thermocouple cables and sensors of these Examples are the same as those described, respectively, in Examples 17 to 20, except that the sheath alloys contain in addition up to 1.0 weight percent of one or more elements known for the purpose of inhibiting metal-surgical grain growth occurring at hick temperature, for example niobium or titanium; and also an appropriate amount of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, for example manganese, iron, molybdenum, cobalt, tungsten, and oxide-particle dispersions.
~L23~16 _ 21 _ EXAMPLES 33 to 48 .
The integral compacted thermocouple cables and sensors of these Examples are the same, respectively, as those described in Examples 17 through 32, except that the sheath alloys are coated my any of the processes and for the purposes describe din Example 9 through Example 16.
EXAMPLES 49 to 96 Heat detectors in accordance with the invention are produced in the same manner as the integral compacted cables of examples 1 through 48 except that the refractory compacted insolent incorporates insulating properties with a high negative temperature coefficient of resistance.
EXAMPLES 97 to 576 Heating elements in accordance with the invention are produced in the same manner as the integral compacted cables of examples 1 through 96, except that a single resistive heating conductor is used in each case and the said conductor is composed of an alloy which is respect-lively: positive type N, (a), (at), (a) or (a).
It will be clearly understood that the invention in its general aspects is not limited to the specific details referred to hereinabove.
.
Claims (157)
1. A compacted mineral-insulated integrally sheathed cable, characterized in that the cable includes at least one thermoelement composed of a type N alloy, and the sheath is composed of an alloy chosen from the group consisting of (a) and (b), wherein (a) consists essentially of from 13.0 weight percent to 15.0 weight percent of chromium, from 1.0 weight percent to 2.0 weight percent of silicon, from 0.03 weight percent to 0.25 weight percent of magnesium and the balance nickel, and (b) consists essentially of from 3.0 weight percent to 5.0 weight percent of silicon, from 0.03 weight percent to 0.25 weight percent of magnesium and the balance nickel.
2. A cable according to Claim 1, characterized in that the sheath is composed of an alloy (a1) consisting essentially of from 13.9 weight percent to 14.5 weight percent of chromium, from 1.3 weight percent to 1.5 weight percent of silicon, from 0.05 weight percent to 0.20 weight percent of magnesium, and the balance nickel.
3. A cable according to Claim 1, characterized in that the sheath is composed of an alloy (a2) consisting essentially of from 14.05 weight percent to 14.35 weight percent of chromium, from 1.35 weight percent to 1.45 weight percent of silicon, from 0.10 weight percent to 0.20 weight percent of magnesium, 0.15 weight percent maximum of iron, 0.05 weight percent maximum of carbon, and the balance nickel.
4. A cable according to Claim 1, characterized in that the sheath is composed of an alloy (a3) consisting essentially of 14.2 weight percent chromium, 1.4 weight percent silicon, 0.1 weight percent iron, 0.03 weight percent magnesium and the balance nickel.
5. A cable according to Claim 1, characterized in that the sheath is composed of an alloy (b1) consisting essentially of from 4.0 weight percent to 4.8 weight percent of silicon, from 0.05 weight percent to 0.20 weight percent of magnesium, and the balance nickel.
6. A cable according to Claim 1, characterized in that the sheath is composed of an alloy (b2) consisting essentially of from 4.2 weight percent to 4.6 weight percent silicon, from 0.10 weight percent to 0.20 weight percent magnesium, 0.05 weight percent maximum chromium, 0.15 weight percent maximum iron, 0.05 weight percent maximum of carbon, and the balance nickel.
7. A cable according to Claim 1, characterized in that the sheath is composed of an alloy (b3) consisting essentially of 4.4 weight percent silicon, 0.1 weight percent iron, 0.1 weight percent magnesium and the balance nickel.
8. A cable according to Claim 1, characterized in that the cable includes a thermoelement composed of a positive type N
alloy and a thermoelement composed of a negative type N alloy and the sheath is composed of a positive type N alloy.
alloy and a thermoelement composed of a negative type N alloy and the sheath is composed of a positive type N alloy.
9. A cable according to Claim 1, characterized in that the cable includes a thermoelement composed of a positive type N
alloy and a thermoelement composed of a negative type N alloy and the sheath is composed of a negative type N alloy.
alloy and a thermoelement composed of a negative type N alloy and the sheath is composed of a negative type N alloy.
10. A cable according to Claim 1, characterized in that the cable includes one only thermoelement, said thermoelement is composed of a positive type N alloy and the sheath is composed of a negative type N alloy.
11. A cable according to Claim 1, characterized in that the cable contains one only thermoelement, said thermoelement is composed of a negative type N alloy and the sheath is composed of a positive type N alloy.
12. A cable according to Claim 1, characterized in that the cable includes a thermoelement composed of a positive type N
alloy and a thermoelement composed of a negative type N alloy.
alloy and a thermoelement composed of a negative type N alloy.
13. A cable according to Claim 2, characterized in that the cable includes a thermoelement composed of a positive type N
alloy and a thermoelement composed of a negative type N alloy.
alloy and a thermoelement composed of a negative type N alloy.
14. A cable according to Claim 3, characterized in that the cable includes a thermoelement composed of a positive type N
alloy and a thermoelement composed of a negative type N alloy.
alloy and a thermoelement composed of a negative type N alloy.
15. A cable according to Claim 4, characterized in that the cable includes a thermoelement composed of a positive type N
alloy and a thermoelement composed of a negative type N alloy.
alloy and a thermoelement composed of a negative type N alloy.
16. A cable according to Claim 5, characterized in that the cable includes a thermoelement composed of a positive type N
alloy and a thermoelement composed of a negative type N alloy.
alloy and a thermoelement composed of a negative type N alloy.
17. A cable according to Claim 6, characterized in that the cable includes a thermoelement composed of a positive type N
alloy and a thermoelement composed of a negative type N alloy.
alloy and a thermoelement composed of a negative type N alloy.
18. A cable according to Claim 7, characterized in that the cable includes a thermoelement composed of a positive type N
alloy and a thermoelement composed of a negative type N alloy.
alloy and a thermoelement composed of a negative type N alloy.
19. A cable according to Claim 1, characterized in that the cable includes one only thermoelement, said thermoelement is composed of a positive type N alloy and the sheath is composed of an alloy selected from the group consisting of (b), (b1), (b2) and (b3) wherein (b) consists essentially of from 3.0 weight percent to 5.0 weight percent of silicon, from 0.03 weight percent to 0.25 weight percent of magnesium and the balance nickel;
(b1) consists essentially of from 4.0 weight percent to 4.8 weight percent of silicon, from 0.05 weight percent to 0.20 weight percent of magnesium, and the balance nickel;
(b2) consists essentially of from 4.2 weight percent to 4.6 weight percent silicon, from 0.10 weight percent to 0.20 weight percent magnesium, 0.05 weight percent maximum chromium, 0.15 weight percent maximum iron, 0.05 weight percent maximum of carbon, and the balance nickel;
(b3) consists essentially of 4.4 weight percent silicon, 0.1 weight percent iron, 0.1 weight percent magnesium and the balance nickel.
(b1) consists essentially of from 4.0 weight percent to 4.8 weight percent of silicon, from 0.05 weight percent to 0.20 weight percent of magnesium, and the balance nickel;
(b2) consists essentially of from 4.2 weight percent to 4.6 weight percent silicon, from 0.10 weight percent to 0.20 weight percent magnesium, 0.05 weight percent maximum chromium, 0.15 weight percent maximum iron, 0.05 weight percent maximum of carbon, and the balance nickel;
(b3) consists essentially of 4.4 weight percent silicon, 0.1 weight percent iron, 0.1 weight percent magnesium and the balance nickel.
20. A cable according to Claim 1, characterized in that the cable contains only one thermoelement, said thermoelement is composed of a negative type N alloy and the sheath is composed of an alloy selected from the group consisting of (a), (a1), (a2) and (a3) wherein (a) consists essentially of from 13.0 weight percent to 15.0 weight percent of chromium, from 1.0 weight percent to 2.0 weight percent of silicon, from 0.03 weight percent to 0.25 weight percent of magnesium, and the balance nickel;
(a1) consists essentially of from 13.9 weight percent to 14.5 weight percent of chromium, from 1.3 weight percent to 1.5 weight percent of silicon, from 0.05 weight percent to 0.20 weight percent of magnesium, and the balance nickel;
(a2) consists essentially of from 14.05 weight percent to 14.35 weight percent of chromium, from 1.35 weight percent to 1.45 weight percent of silicon, from 0.10 weight percent to 0.20 weight percent of magnesium, 0.15 weight percent maximum of iron, 0.05 weight percent maximum of carbon, and the balance nickel;
(a3) consists essentially of from 14.2 weight percent chromium, 1.4 weight percent silicon, 0.03 weight percent magnesium and the balance nickel.
(a1) consists essentially of from 13.9 weight percent to 14.5 weight percent of chromium, from 1.3 weight percent to 1.5 weight percent of silicon, from 0.05 weight percent to 0.20 weight percent of magnesium, and the balance nickel;
(a2) consists essentially of from 14.05 weight percent to 14.35 weight percent of chromium, from 1.35 weight percent to 1.45 weight percent of silicon, from 0.10 weight percent to 0.20 weight percent of magnesium, 0.15 weight percent maximum of iron, 0.05 weight percent maximum of carbon, and the balance nickel;
(a3) consists essentially of from 14.2 weight percent chromium, 1.4 weight percent silicon, 0.03 weight percent magnesium and the balance nickel.
21. A resistive heating element particularly useful for operation at high temperatures comprising a cable according to Claim 1, containing one or more thermoelements and a sheath, characterized in that the thermoelements and the sheath are composed of alloys which may be the same or different, and said alloys are chosen from the group consisting of positive type N
alloys, negative type N alloys, and alloys (a), (a1), (a2), (a3), (b), (b1), (b2) and (b3) as defined in Claim 19.
alloys, negative type N alloys, and alloys (a), (a1), (a2), (a3), (b), (b1), (b2) and (b3) as defined in Claim 19.
22. A resistive heating element particularly useful for operation at high temperatures comprising a cable according to Claim 1, containing one or more thermoelements and a sheath, characterized in that the thermoelements and the sheath are composed of alloys which may be the same or different, and said alloys are chosen from the group consisting of positive type N
alloys, negative type N alloys, and alloys (a), (a1), (a2), (a3), (b), (b1), (b2) and (b3) as defined in Claim 20.
alloys, negative type N alloys, and alloys (a), (a1), (a2), (a3), (b), (b1), (b2) and (b3) as defined in Claim 20.
23. A compacted mineral-insulated integrally sheathed thermocoupled cable, characterized in that the cable includes at least one thermoelement composed of a type N alloy, and the sheath is composed of a type N alloy, further characterized in that the alloy of which the sheath is composed is thermoelectrically opposite to the alloy of which the or at least one thermoelement is composed.
24. A heat detector operable at temperatures above about 1100°C comprising an elongated compacted mineral insulated integrally sheathed cable as defined in Claim 23, disposed in an environment where local rises in temperature may occur, causing local increase in the conductivity of the insulating material, said detector including means for determining the location of the said local increase in conductivity and hence the location of the said rise in temperature.
25. A stagnation temperature probe incorporating a type N
thermocouple as the temperature sensor, said thermocouple being made from a cable as defined in Claim 1.
thermocouple as the temperature sensor, said thermocouple being made from a cable as defined in Claim 1.
26. A stagnation temperature probe incorporating a type N
thermocouple as the temperature sensor, said thermocouple being made from a cable as defined in Claim 2.
thermocouple as the temperature sensor, said thermocouple being made from a cable as defined in Claim 2.
27. A stagnation temperature probe incorporating a type N
thermocouple as the temperature sensor, said thermocouple being made from a cable as defined in Claim 3.
thermocouple as the temperature sensor, said thermocouple being made from a cable as defined in Claim 3.
28. A stagnation temperature probe incorporating a type N
thermocouple as the temperature sensor, said thermocouple being made from a cable as defined in Claim 4.
thermocouple as the temperature sensor, said thermocouple being made from a cable as defined in Claim 4.
29. A stagnation temperature probe incorporating a type N
thermocouple as the temperature sensor, said thermocouple being made from a cable as defined in Claim 5.
thermocouple as the temperature sensor, said thermocouple being made from a cable as defined in Claim 5.
30. A stagnation temperature probe incorporating a type N
thermocouple as the temperature sensor, said thermocouple being made from a cable as defined in Claim 6.
thermocouple as the temperature sensor, said thermocouple being made from a cable as defined in Claim 6.
31. A stagnation temperature probe incorporating a type N
thermocouple as the temperature sensor, said thermocouple being made from a cable as defined in Claim 7.
thermocouple as the temperature sensor, said thermocouple being made from a cable as defined in Claim 7.
32. A cable according to Claim 1, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
33. A cable according to Claim 2, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
34. A cable according to Claim 3, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
35. A cable according to Claim 4, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
36. A cable according to Claim 5, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
37. A cable according to Claim 6, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
38. A cable according to Claim 7, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
39. A cable according to Claim 8, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
40. A cable according to Claim 9, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
41. A cable according to Claim 10, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
42. A cable according to Claim 11, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
43. A cable according to Claim 12, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
44. A cable according to Claim 13, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
45. A cable according to Claim 14, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
46. A cable according to Claim 15, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
47. A cable according to Claim 16, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
48. A cable according to Claim 17, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
49. A cable according to Claim 18, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
50. A cable according to Claim 19, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
51. A cable according to Claim 20, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
52. A cable according to Claim 21, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
53. A cable according to Claim 22, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
54. A cable according to Claim 23, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
55. A cable according to Claim 24, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
56. A cable according to Claim 25, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
57. A cable according to Claim 26, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
58. A cable according to Claim 27, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
59. A cable according to Claim 28, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
60. A cable according to Claim 29, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
61. A cable according to Claim 30, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
62. A cable according to Claim 31, in which the sheath alloy is strengthened by addition of one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature.
63. A cable according to Claim 32, 33 or 34, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions.
64. A cable according to Claim 35, 36 or 37, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions.
65. A cable according to Claim 38, 39 or 40, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions.
66. A cable according to Claim 41, 42 or 43, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide particle dispersions.
67. A cable according to Claim 44, 45 or 46, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions.
68. A cable according to Claim 47, 48 or 49, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions.
69. A cable according to Claim 50, 51 or 52, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions.
70. A cable according to Claim 53, 54 or 55, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions.
71. A cable according to Claim 56, 57 or 58, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions.
72. A cable according to Claim 59, 60 or 61, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions.
73. A cable according to Claim 62, in which the said components are chosen from the group consisting of manganese, iron, molybdenum cobalt, tungsten and oxide-particle dispersions.
74. A cable according to Claim 1, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
75. A cable according to Claim 2, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
76. A cable according to Claim 3, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
77. A cable according to Claim 4, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
78. A cable according to Claim 5, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
79. A cable according to Claim 6, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
80. A cable according to Claim 7, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
81. A cable according to Claim 8, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
82. A cable according to Claim 9, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
83. A cable according to Claim 10, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
84. A cable according to Claim 11, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
85. A cable according to Claim 12, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
86. A cable according to Claim 13, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
87. A cable according to Claim 14, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
88. A cable according to Claim 15, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
89. A cable according to Claim 16, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
90. A cable according to Claim 17, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
91. A cable according to Claim 18, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
92. A cable according to Claim 19, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
93. A cable according to Claim 20, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
94. A cable according to Claim 21, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
95. A cable according to Claim 22, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
96. A cable according to Claim 23, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
97. A cable according to Claim 24, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
98. A cable according to Claim 25, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
99. A cable according to Claim 26, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
100. A cable according to Claim 27, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
101. A cable according to Claim 28, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
102. A cable according to Claim 29, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
103. A cable according to Claim 30, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
104. A cable according to Claim 31, in which the sheath alloy contains in addition one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
105. A cable according to Claim 74, 75 or 76, in which the said elements are chosen from the group consisting of niobium and titanium.
106. A cable according to Claim 77, 78 or 79, in which the said elements are chosen from the group consisting of niobium and titanium.
107. A cable according to Claim 80, 81 or 82, in which the said elements are chosen from the group consisting of niobium and titanium.
108. A cable according to Claim 83, 84 or 85, in which the said elements are chosen from the group consisting of niobium and titanium.
109. A cable according to Claim 86, 87 or 88, in which the said elements are chosen from the group consisting of niobium and titanium.
110. A cable according to Claim 89, 90 or 91, in which the said elements are chosen from the group consisting of niobium and titanium.
111. A cable according to Claim 92, 93 or 94, in which the said elements are chosen from the group consisting of niobium and titanium.
112. A cable according to Claim 95, 96 or 97, in which the said elements are chosen from the group consisting of niobium and titanium.
113. A cable according to Claim 98, 99 or 100, in which the said elements are chosen from the group consisting of niobium and titanium.
114. A cable according to Claim 101, 102 or 103, in which the said elements are chosen from the group consisting of niobium and titanium.
115. A cable according to Claim 104, in which the said elements are chosen from the group consisting of niobium and titanium.
116. A cable according to Claim 1, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
117. A cable according to Claim 2, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
118. A cable according to Claim 3, in which the sheath alloy contains in addition one or more components known for the purpose increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
119. A cable according to Claim 4, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
120. A cable according to Claim 5, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
121. A cable according to Claim 6, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
122. A cable according to Claim 7, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
123. A cable according to Claim 8, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
124. A cable according to Claim 9, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
125. A cable according to Claim 10, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
126. A cable according to Claim 11, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
127. A cable according to Claim 12, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
128. A cable according to Claim 13, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
129. A cable according to Claim 14, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
130. A cable according to Claim 15, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
131. A cable according to Claim 16, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
132. A cable according to Claim 17, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
133. A cable according to Claim 18, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
134. A cable according to Claim 19, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
135. A cable according to Claim 20, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
136. A cable according to Claim 21, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
137. A cable according to Claim 22, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
138. A cable according to Claim 23, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
139. A cable according to Claim 24, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
140. A cable according to Claim 25, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
141. A cable according to Claim 26, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
142. A cable according to Claim 27, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
143. A cable according to Claim 28, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
144. A cable according to Claim 29, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
145. A cable according to Claim 30, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
146. A cable according to Claim 31, in which the sheath alloy contains in addition one or more components known for the purpose of increasing mechanical strength of said alloys at high temperature, and one or more elements known for the purpose of inhibiting metallurgical grain growth occurring at high temperature.
147. A cable according to Claim 116, 117 or 118, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions, and the said elements are chosen from the group consisting of niobium and titanium.
148. A cable according to Claim 119, 120 or 121, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions, and the said elements are chosen from the group consisting of niobium and titanium.
149. A cable according to Claim 122, 123 or 124, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions, and the said elements are chosen from the group consisting of niobium and titanium.
150. A cable according to Claim 125, 126 or 127, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions, and the said elements are chosen from the group consisting of niobium and titanium.
151. A cable according to Claim 128, 129 or 130, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions, and the said elements are chosen from the group consisting of niobium and titanium.
152. A cable according to Claim 131, 132 or 133, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions, and the said elements are chosen from the group consisting of niobium and titanium.
153. A cable according to Claim 134, 135 or 136, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions, and the said elements are chosen from the group consisting of niobium and titanium.
154. A cable according to Claim 137, 138 or 139, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions, and the said elements are chosen from the group consisting of niobium and titanium.
155. A cable according to Claim 140, 141 or 142, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions, and the said elements are chosen from the group consisting of niobium and titanium.
156. A cable according to Claim 143, 144 or 145, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions, and the said elements are chosen from the group consisting of niobium and titanium.
157. A cable according to Claim 146, in which the said components are chosen from the group consisting of manganese, iron, molybdenum, cobalt, tungsten and oxide-particle dispersions, and the said elements are chosen from the group consisting of niobium and titanium.
Applications Claiming Priority (4)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| AUPG486584 | 1984-05-07 | ||
| AUPG4865 | 1984-05-07 | ||
| AUPG9368 | 1985-02-20 | ||
| AUPG936885 | 1985-02-20 |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1238116A true CA1238116A (en) | 1988-06-14 |
Family
ID=25642794
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA000480703A Expired CA1238116A (en) | 1984-05-07 | 1985-05-03 | Stable high temperature cables and devices made therefrom |
Country Status (6)
| Country | Link |
|---|---|
| AT (1) | ATE80223T1 (en) |
| CA (1) | CA1238116A (en) |
| DE (1) | DE3516260A1 (en) |
| FR (1) | FR2563937B1 (en) |
| GB (1) | GB2159663B (en) |
| IT (1) | IT8520586A0 (en) |
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US9702764B2 (en) | 2010-03-31 | 2017-07-11 | Cambridge Enterprise Limited | Thermocouple apparatus and method |
Families Citing this family (10)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| AU613902B2 (en) * | 1987-05-14 | 1991-08-15 | Nicrobell Pty Limited | Stable high-temperature thermocouple cable |
| DE10340636B3 (en) * | 2003-09-03 | 2005-01-13 | Epcos Ag | Moisture-proof sensor manufacturing method, by splitting cable sheath into two halves, connecting cable conductors to sensor head, and heating halves of sheath to form hermetic seal |
| DE102004034186B3 (en) * | 2004-07-15 | 2005-08-25 | Sensotherm Temperatursensorik Gmbh | Protecting mineral insulated metal clad instrumentation cables from their environments, melts exposed insulation at ends using laser to form seal |
| GB201019567D0 (en) | 2010-11-19 | 2010-12-29 | Zenith Oilfield Technology Ltd | High temperature downhole gauge system |
| GB2495132B (en) | 2011-09-30 | 2016-06-15 | Zenith Oilfield Tech Ltd | Fluid determination in a well bore |
| GB2496863B (en) | 2011-11-22 | 2017-12-27 | Zenith Oilfield Tech Limited | Distributed two dimensional fluid sensor |
| GB2511739B (en) | 2013-03-11 | 2018-11-21 | Zenith Oilfield Tech Limited | Multi-component fluid determination in a well bore |
| DE102016118595B4 (en) | 2016-09-30 | 2018-07-26 | Heraeus Sensor Technology Gmbh | Cable, temperature measuring device and method of making a cable |
| CN111799013B (en) * | 2020-07-27 | 2022-12-09 | 昆山安胜达微波科技有限公司 | Flexible high-precision N-type thermocouple sensor cable |
| CN111863320B (en) * | 2020-07-27 | 2022-04-29 | 昆山安胜达微波科技有限公司 | Flexible high-precision K-type thermocouple sensor cable |
Family Cites Families (6)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| GB674068A (en) * | 1949-04-29 | 1952-06-18 | Pyrotenax Ltd | Improvements in or relating to electric cables |
| GB1037049A (en) * | 1962-11-09 | 1966-07-27 | Engelhard Ind Inc | Improvements in or relating to thermocouple assemblies |
| GB1347236A (en) * | 1970-01-30 | 1974-02-20 | Central Electr Generat Board | Thermocouples |
| US3942242A (en) * | 1973-08-22 | 1976-03-09 | Engelhard Minerals & Chemicals Corporation | Thermocouple structure and method of manufacturing same |
| GB2107516A (en) * | 1981-10-14 | 1983-04-27 | Atomic Energy Authority Uk | Thermocouple |
| US4491822A (en) * | 1981-11-02 | 1985-01-01 | Xco International, Inc. | Heat sensitive cable |
-
1985
- 1985-05-03 CA CA000480703A patent/CA1238116A/en not_active Expired
- 1985-05-06 IT IT8520586A patent/IT8520586A0/en unknown
- 1985-05-06 AT AT85400871T patent/ATE80223T1/en not_active IP Right Cessation
- 1985-05-06 FR FR8506831A patent/FR2563937B1/en not_active Expired
- 1985-05-07 GB GB08511525A patent/GB2159663B/en not_active Expired
- 1985-05-07 DE DE19853516260 patent/DE3516260A1/en active Granted
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US9702764B2 (en) | 2010-03-31 | 2017-07-11 | Cambridge Enterprise Limited | Thermocouple apparatus and method |
| US10168228B2 (en) | 2010-03-31 | 2019-01-01 | Cambridge Enterprise Limited | Thermocouple apparatus and method |
Also Published As
| Publication number | Publication date |
|---|---|
| FR2563937B1 (en) | 1988-12-02 |
| GB2159663A (en) | 1985-12-04 |
| IT8520586A0 (en) | 1985-05-06 |
| GB2159663B (en) | 1989-01-18 |
| GB8511525D0 (en) | 1985-06-12 |
| DE3516260C2 (en) | 1992-08-13 |
| ATE80223T1 (en) | 1992-09-15 |
| FR2563937A1 (en) | 1985-11-08 |
| DE3516260A1 (en) | 1986-01-02 |
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Legal Events
| Date | Code | Title | Description |
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| MKEX | Expiry |