RU92573U1 - THERMOELECTRIC CONVERTER (OPTIONS) - Google Patents

Abstract

1. A thermoelectric transducer containing a temperature-sensitive element in the form of, for example, a chromel-alumel thermocouple made of a thermocouple wire with interelectrode insulation and/or placed in a protective sheath in the form of a braid of threads made of a dielectric material, characterized in that the braid of the interelectrode insulation and/or the protective sheath of the thermocouple is made of threads, for example, silica grade K11S6-250 BA (250 tex), or ceramic grade 3M™Nextel™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or quartz grade EC9 34 Z 160×2 S 150 GOST 8325-93, the number of threads for the braid is at least 4, the number of insulation layers is 1-10, and the diameter of the thermocouple wire is 0.81-4 mm. ! 2. A thermoelectric transducer containing a temperature-sensitive element in the form of, for example, a chromel-alumel thermocouple made of thermocouple wire with interelectrode insulation and/or placed in a protective cover in the form of a braid of threads made of a dielectric material, characterized in that the thermocouple is installed in a metal or ceramic sleeve, wherein the braid of the interelectrode insulation and/or protective cover is made of threads, for example, silica grade K11S6-250 BA (250 tex), or ceramic grade 3M™Nextel™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or quartz grade EC9 34 Z 160×2 S 150 GOST 8325-93, the number of threads for the braid is at least 4, the number of insulation layers 1-10, and the diameter of the thermocouple wire is 0.81-4 mm. ! 3. A thermoelectric converter containing a temperature-sensitive element in the form of, for example, a chromel-alumel thermocouple made of a thermocouple wire with an interelectrode �

Description

The proposed utility models relate to thermoelectric devices, in particular, their structural elements, namely to thermocouples installed in equipment used to measure temperatures in technological processes of various industries.

Known thermoelectric converter, including a thermosensitive element made in the form of a thermocouple made in the form of a chromel-alumel thermocouple made of thermoelectrode wire or thermocouple cable (RF, PM No. 41190, IPC H01L 35/02, dated 29.06.2004, publ. 10/10/2004).

The disadvantage of this thermoelectric converter is the small resource of the thermosensitive element - thermocouple.

This design is selected by the applicant as the closest analogue (prototype).

The technical task of the proposed utility models is to increase the durability of sensitive elements (thermocouples) used in the thermoelectric converter.

The problem is achieved in that in a thermoelectric converter containing a thermosensitive element in the form of, for example, a chromel-alumel thermocouple made of a thermoelectrode wire with interelectrode insulation and / or placed in a protective cover in the form of a braid with threads of dielectric material, according to a utility model, the braid interelectrode insulation and / or thermocouple protective cover is made of threads, for example, silica grade K11C6-250 BA (250 tex), or 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or EC9 quartz grade 34 Z 160 × 2 S 150 GOST 8325-93, the number of braiding threads is at least 4, the number of insulation layers is 1-10, and the diameter of the thermoelectrode wire is 0.81-4 mm.

Braiding of interelectrode insulation and / or protective cover from, for example, silica filament grade K11C6-250 BA (250 tex), or 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or quartz grade EC9 34 Z 160 × 2 S 150 GOST 8325-93, allows you to protect the sensitive element (thermocouple) from aggressive effects and the temperature of the measured medium when braiding the declared silica thread up to 1200 ° C, ceramic - up to 1400 ° C, quartz - up to 600 ° C .

The implementation of the braid, which is formed by the claimed number of threads, i.e. not less than 4, allows to obtain a braid with an optimal density, which is changed depending on the technological conditions under which a braided thermocouple is used. The greater the number of threads that form the braid, the greater the density of the braid, which increases its reliability and durability when using thermocouples in aggressive environments.

The implementation of the braid with the claimed number of layers, allows to increase the reliability and durability by selecting the required thickness depending on the technological conditions.

The minimum number of braiding layers, i.e. 1 - provides sufficient thickness, but the braid of such a thickness is short-lived.

The optimal number of braiding layers, i.e. 5 or more layers - provides its reliability and durability.

The maximum number of braiding layers, i.e. 10 layers - provides reliability and durability of the braid, but such a braid is uneconomical.

The use of a thermocouple in a thermocouple with the claimed range of diameters allows to increase the thermocouple's life by selecting the optimal diameter depending on the technological conditions for its use.

The use of a thermoelectrode wire with a diameter of 0.81 mm in a thermocouple does not provide a sufficient thermocouple resource when used in conditions of high aggressiveness and ambient temperature.

The use of a thermoelectrode wire with a diameter of 2.4 mm in a thermocouple is optimal for ensuring durability when used in conditions of high aggressiveness and ambient temperature.

The use of a thermoelectrode wire with a diameter of 4 mm in a thermocouple can increase the resource, but a thermocouple with such a thermoelectrode is uneconomical.

In a thermoelectric converter containing a thermosensitive element in the form of, for example, a chromel-alumel thermocouple made of a thermoelectrode wire with interelectrode insulation and / or placed in a protective cover in the form of a braid with threads of dielectric material, according to a utility model, the thermocouple is installed in a metal or ceramic sleeve , while the braid of the interelectrode insulation and / or the protective cover is made of threads, for example, silica grade K11C6-250 BA (250 tex), or 3M ™ Nextel ™ Continuous ceramic grade Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or EC9 quartz grade 34 Z 160 × 2 S 150 GOST 8325-93, the number of braiding threads is at least 4, the number of insulation layers is 1-10, and the diameter of the thermoelectrode wire is 0.81-4 mm.

Installing a thermocouple from a thermoelectrode wire in a metal or ceramic sleeve allows you to increase the durability of the thermocouple when installing it for measurements in an aggressive environment, due to the additional protection of the thermocouple, while even if the sleeve is not tight during wear, the braid continues to protect the thermocouple from the influence of the measured medium.

Braiding of interelectrode insulation and / or protective cover from, for example, silica filament grade K11C6-250 BA (250 tex), or 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or quartz grade EC9 34 Z 160 × 2 S 150 GOST 8325-93, allows you to protect the sensitive element (thermocouple) from aggressive effects and the temperature of the measured medium when braiding the declared silica thread up to 1200 ° C, ceramic - up to 1400 ° C, quartz - up to 600 ° C .

The implementation of the braid, which is formed by the claimed number of threads, i.e. not less than 4, allows to obtain a braid with an optimal density, which is changed depending on the technological conditions under which a braided thermocouple is used. The greater the number of threads that form the braid, the greater the density of the braid, which increases its reliability and durability when using thermocouples in aggressive environments.

The implementation of the braid with the claimed number of layers, will increase reliability and durability by selecting the required thickness depending on the technological conditions.

The minimum number of braiding layers, i.e. 1 - provides sufficient thickness, but the braid of such a thickness is short-lived.

The optimal number of layers of braid; those. 5 or more layers - provides its reliability and durability.

The maximum number of braiding layers, i.e. 10 layers - provides reliability and durability of the braid, but such a braid is uneconomical.

The use of a thermocouple in a thermocouple with the claimed range of diameters allows to increase the thermocouple's life by selecting the optimal diameter depending on the technological conditions for its use.

The use of a thermoelectrode wire with a diameter of 0.81 mm in a thermocouple does not provide a sufficient thermocouple resource when used in conditions of high aggressiveness and ambient temperature.

The use of a thermoelectrode wire with a diameter of 2.4 mm in a thermocouple is optimal for ensuring durability when used in conditions of high aggressiveness and ambient temperature.

The use of a thermoelectrode wire with a diameter of 4 mm in a thermocouple can increase the resource, but a thermocouple with such a thermoelectrode is uneconomical.

In a thermoelectric converter containing a thermosensitive element in the form of, for example, a chromel-alumel thermocouple made of a thermoelectrode wire with interelectrode insulation and / or placed in a protective sheath of dielectric material, according to a utility model, the thermocouple is installed in a metal or ceramic sleeve containing a protective sheath in the form of a braid or a removable cover, while the interelectrode insulation and / or the protective cover and the protective shell of the sleeve are made of threads, for example, silica m arches K11S6-250 BA (250 tex), or 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720 ceramic grades, or EC9 34 Z 160 × 2 S 150 grade GOST 8325-93, number of threads for the braid and removable cover is at least 4, the number of insulation layers is 1-10, and the diameter of the thermoelectrode wire is 0.81-4 mm.

Installing a thermocouple from a thermoelectrode wire in a metal or ceramic sleeve allows you to increase the durability of the thermocouple when installing it for measurements in an aggressive environment, due to the additional protection of the thermocouple, while even if the sleeve is not tight during wear, the braid continues to protect the thermocouple from the influence of the measured medium.

The presence of a protective shell for the sleeve increases the life of the thermocouple, as with prolonged use of the thermocouple in an aggressive environment, local burnouts may appear in the sleeve through which the sleeve is filled, for example, with a molten metal, and the thermocouple (cable or from thermoelectrodes in the braid) is protected from exposure to, for example, the metal melt in this case is braided thermocouple protection against mechanical impact of slag - sleeve. The sleeve used for protection may have a diameter of 2 to 70 mm, depending on the process conditions.

The implementation of the protective shell in the form of a braid or in the form of a removable cover allows you to increase the life of the thermocouple due to additional protection against high aggressiveness of the environment and temperatures. In addition, the implementation of the protective shell, including in the form of a removable cover, allows its quick replacement in case of failure, for example, of the initial braid.

The implementation of interelectrode insulation, and / or a protective cover and a protective shell of the sleeve, including removable cover made of, for example, silica filament grade K11C6-250 BA (250 tex), or 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or EC9 34 Z 160 × 2 S quartz 150 GOST 8325-93, allows you to protect the sensitive element (thermocouple) from aggressive influences and the temperature of the medium when braid or placed in a removable cover declared silica thread up to 1200 ° C, ceramic - up to 1400 ° C, quartz - up to 600 ° C.

The braiding of interelectrode insulation, and / or the protective cover and the protective shell of the sleeve, the claimed number of threads, i.e. at least 4, allows you to get a braid or fabric for a removable cover with an optimal density, which is changed depending on the technological conditions under which a thermocouple is used. The greater the number of threads forming a braid or web for a removable cover, the greater the density of weaving, which increases the reliability and durability of thermocouples when used in aggressive and high-temperature environments.

The implementation of the braid or web with the claimed number of layers, will increase reliability and durability by selecting the required thickness depending on the technological conditions.

The minimum number of layers for the braid or web, i.e. 1 - provides sufficient thickness, but the braid or web of this thickness is short-lived.

The optimal number of braiding layers, i.e. 5 or more layers, ensures its reliability and durability.

The maximum number of layers for a braid or web, i.e. 10 layers - provides reliability and durability of the braid or web, but they are uneconomical.

The use of a thermocouple in a thermocouple with the claimed range of diameters allows to increase the thermocouple's life by selecting the optimal diameter depending on the technological conditions for its use.

The use of a thermoelectrode wire with a diameter of 0.81 mm in a thermocouple does not provide a sufficient thermocouple resource when used in conditions of high aggressiveness and ambient temperature.

The use of a thermoelectrode wire with a diameter of 2.4 mm in a thermocouple is optimal for ensuring durability when used in conditions of high aggressiveness and ambient temperature.

The use of a thermoelectrode wire with a diameter of 4 mm in a thermocouple can increase the resource, but a thermocouple with such a thermoelectrode is uneconomical.

In a thermoelectric converter containing a thermosensitive element in the form of, for example, a chromel-alumel thermocouple made of a thermocouple cable in a metal sheath, according to a utility model, the metal sheath of the thermocouple contains a protective sheath in the form of a braid or a removable sheath of threads, for example, silica, K11C6 -250 BA (250 tex), or 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or EC9 quartz grade 34 Z 160 × 2 S 150 GOST 8325-93, the number of braiding threads or a removable cover is not less than 4, the number of insulation layers 1-10, while the diameter of the metal sheath of the thermocouple cable is 1-20 mm.

The presence of a protective shell in the form of a braid or a removable cover allows you to increase the durability of the thermocouple.

In case of a broken sheath in the form of a braid, it is possible to put on a thermocouple metal sheath woven in advance, i.e. removable cover, which is technologically advanced.

Braiding a protective shell or web for a removable cover from, for example, silica filament grade K11C6-250 BA (250 tex), or 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or quartz grade EC9 34 Z 160 × 2 S 150 GOST 8325-93, allows you to protect the thermocouple from aggressive influences and the temperature of the medium measured by the declared silica thread up to 1200 ° C, ceramic - up to 1400 ° C, quartz - up to 600 ° C.

The implementation of the braid or removable cover, which are formed by the claimed number of threads, i.e. at least 4, allows you to get a braid or a removable cover with an optimal density, which is changed depending on the technological conditions under which a thermocouple is used. The greater the number of threads forming a braid or web for a removable cover, the greater the density, which increases the reliability and durability when using thermocouples in aggressive environments.

The implementation of the braid or fabric for a removable cover with the claimed number of layers, allows you to increase reliability and durability by selecting the required thickness depending on the technological conditions.

The minimum number of layers in the braid or web for a removable cover, i.e. 1 - provides sufficient thickness, but the braid or removable cover of such a thickness is short-lived.

The optimal number of layers, i.e. 5 or more layers - provides reliability and durability.

The maximum number of layers, i.e. 10 layers - provides reliability and durability, but such a braid and a removable cover are uneconomical.

The use of a thermocouple metal sheath in a thermocouple with the claimed range of diameters allows increasing the life of the thermocouple by selecting the optimal diameter depending on the technological conditions for its use.

The use of a thermocouple metal sheath in a thermocouple with a diameter of 1 mm does not provide a sufficient thermocouple resource when used in conditions of high aggressiveness and ambient temperature.

The use of a metal sheath of a thermal cable with a diameter of 10.5 mm in a thermocouple is optimal for ensuring the durability of the thermocouple when used in conditions of high aggressiveness and ambient temperature.

The use of a metal sheath of a thermal cable with a diameter of 20 mm in a thermocouple allows an increase in resource, but such a thermocouple is uneconomical.

In a thermoelectric converter containing a thermosensitive element in the form of, for example, a chromel-alumel thermocouple made of a thermocouple cable in a metal sheath, according to a utility model, the metal sheath of the thermocouple contains a protective sheath, while the thermocouple is installed in a metal or ceramic sleeve, the protective sheath is made in as a braid with threads, for example, silica, K11C6-250 BA grade (250 tex), or 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or EC9 quartz grade 34 Z 160 × 2 S 150 GOST 8325-93, the number of braiding threads is at least 4, the number of insulation layers is 1-10, and the diameter of the metal sheath of the thermocouple cable is 1-20 mm.

The presence of a protective sheath in the form of a braid allows to increase the durability of the thermocouple.

Installing a thermocouple in a metal or ceramic sleeve allows you to protect the thermocouple from aggressive environmental influences.

Braiding from, for example, silica filament grade K11C6-250 BA (250 tex), or ceramic grade 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or quartz grade EC9 34 Z 160 × 2 S 150 GOST 8325-93, allows you to protect the thermocouple from aggressive influences and the temperature of the medium being measured when braiding with the declared silica thread up to 1200 ° C, ceramic - up to 1400 ° C, quartz - up to 600 ° C.

The implementation of the braid, which is formed by the claimed number of threads, i.e. not less than 4, allows to obtain a braid with an optimal density, which is changed depending on the technological conditions under which a braided thermocouple is used. The greater the number of threads that form the braid, the greater the density of the braid, which increases its reliability and durability when using thermocouples in aggressive environments.

The implementation of the braid with the claimed number of layers, increases reliability and durability by selecting the required thickness depending on the technological conditions.

The minimum number of braiding layers, i.e. 1 - provides sufficient thickness, but the braid of such a thickness is short-lived.

The optimal number of braiding layers, i.e. 5 or more layers - provides its reliability and durability.

The maximum number of braiding layers, i.e. 10 layers - provides reliability and durability of the braid, but such a braid is uneconomical.

The use of a thermocouple metal sheath in a thermocouple with the claimed range of diameters allows increasing the life of the thermocouple by selecting the optimal diameter depending on the technological conditions for its use.

The use of a thermocouple metal sheath in a thermocouple with a diameter of 1 mm does not provide a sufficient thermocouple resource when used in conditions of high aggressiveness and ambient temperature.

The use of a metal sheath of a thermal cable with a diameter of 10.5 mm in a thermocouple is optimal for ensuring the durability of the thermocouple when used in conditions of high aggressiveness and ambient temperature.

The use of a thermocouple metal sheath with a diameter of 20 mm in a thermocouple allows for an increase in resource, but a thermocouple with such a thermoelectrode is uneconomical.

In a thermoelectric converter containing a thermosensitive element in the form of, for example, a chromel-alumel thermocouple made of a thermocouple cable in a metal sheath, according to a utility model, the thermocouple is installed in a metal or ceramic sleeve containing a protective sheath in the form of a braid or a removable cover of threads, for example silica grade K11C6-250 BA (250 tex) or 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or EC9 quartz grade 34 Z 160 × 2 S 150 GOST 8325-93 , number of threads for braid sludge and a removable cover is at least 4, the number of insulation layers is 1-10, while the diameter of the metal sheath of the thermocouple cable is 1-20 mm.

Installing a thermocouple in a metal or ceramic sleeve allows you to increase the durability of the thermocouple when installed for measurements in an aggressive environment, due to the additional protection of the thermocouple, while even if the sleeve is not tight during wear, the braid continues to protect the thermocouple from the influence of the measured medium.

The presence of a protective shell for the sleeve increases the life of the thermocouple, as with prolonged use of the thermocouple in an aggressive environment, local burnouts may appear in the sleeve through which the sleeve is filled, for example, with a molten metal, and the thermocouple (cable or from thermoelectrodes in the braid) is protected from exposure to, for example, the metal melt in this case is braided, and thermocouple protection against mechanical impact of slag - sleeve. The sleeve used for protection may have a diameter of 2 to 70 mm, depending on the process conditions.

The implementation of the protective shell in the form of a braid or in the form of a removable cover allows you to increase the life of the thermocouple due to additional protection against high aggressiveness of the environment and temperatures. In addition, the implementation of the protective shell, including in the form of a removable cover, allows its quick replacement in case of failure, for example, of the initial thermocouple braid.

The implementation of the protective shell liner, including removable cover made of, for example, K11C6-250 BA silica yarn (250 tex), or 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or EC9 34 Z 160 × 2 S quartz 150 GOST 8325-93, allows you to protect the thermocouple from aggressive influences and the temperature of the medium when braid or placed in a removable cover declared silica thread up to 1200 ° C, ceramic - up to 1400 ° C, quartz - up to 600 ° C.

The implementation of the braid or fabric for a removable cover sleeve, the claimed number of threads, i.e. at least 4, allows you to get a braid or fabric for a removable cover with an optimal density, which is changed depending on the technological conditions under which a thermocouple is used. The greater the number of threads forming a braid or web for a removable cover, the greater the density of weaving, which increases the reliability and durability of thermocouples when used in aggressive and high-temperature environments.

The implementation of the braid or web with the claimed number of layers, will increase reliability and durability by selecting the required thickness depending on the technological conditions.

The minimum number of layers for the braid or web for a removable cover, i.e. 1 - provides sufficient thickness, but the braid or web for a removable cover of such thickness is short-lived.

The optimal number of layers, i.e. 5 or more layers - provides reliability and durability.

The maximum number of layers for the braid or web for a removable cover, i.e. 10 layers - provides reliability and durability of the braid or web, but they are uneconomical.

The use of a thermocouple metal sheath in a thermocouple with the claimed range of diameters allows increasing the life of the thermocouple by selecting the optimal diameter depending on the technological conditions for its use.

The use of a thermocouple metal sheath in a thermocouple with a diameter of 1 mm does not provide a sufficient thermocouple resource when used in conditions of high aggressiveness and ambient temperature.

The use of a metal sheath of a thermal cable with a diameter of 10.5 mm in a thermocouple is optimal for ensuring the durability of the thermocouple when used in conditions of high aggressiveness and ambient temperature.

The use of a metal sheath of a thermal cable with a diameter of 20 mm in a thermocouple allows for an increase in resource, but a thermocouple with such a thermoelectrode.

As a result of the patent research, no similar technical solutions were identified, characterized by the claimed combination of features, which allows us to conclude that the claimed technical solutions have a "novelty" and can find application in industry, i.e. "Industrially applicable."

The essence of the utility models is illustrated by drawings, where in Fig.1 is a thermoelectric converter, in Fig.2 is a thermocouple (option 1); figure 3 - thermocouple (option 2); figure 4 - thermocouple (option 3); figure 5 - thermocouple (option 4); figure 6 - thermocouple (option 5); Fig.7 - thermocouple (option 6).

The thermoelectric converter contains a head 1, a terminal block 2, a sensing element (thermocouple) 3 with a braid 4, protective fittings 5, a connecting sleeve 6, a metal cup 7.

The thermocouple (figure 2) contains a thermoelectrode wire 8, interelectrode insulation 9, a protective cover 10.

The thermocouple (figure 3) contains a thermoelectrode wire 11 interelectrode insulation 12, a protective cover 13, a sleeve 14.

The thermocouple (figure 4) contains a thermoelectrode wire 15 interelectrode insulation 16, a protective cover 17, a sleeve 18, a protective sheath 19.

The thermocouple (figure 5) contains a thermoelectrode cable 20, in a metal sheath 21, with a filler 22 in the form of, for example periclase, a protective cover 23.

The thermocouple (Fig.6) contains a thermoelectrode cable 24, in a metal sheath 25 a protective cover 26, a sleeve 27.

The thermocouple (Fig.7) contains a thermoelectrode cable 28 in a metal sheath 29, a sleeve 30, a protective cover 31.

The thermoelectric converter operates as follows.

The measurement of temperature, for example, a molten metal, is based on the phenomenon of the appearance of a thermoelectromotive force in the circuit of a thermal converter at a temperature difference between its working and free ends.

The magnitude of the thermoelectromotive force depends on this temperature difference and is fixed by a potentiometer (not shown in FIG.). The measuring unit of the thermocouple is a thermocouple sensing element, consisting, for example, of a thermoelectrode wire or a thermocouple cable. The free ends of the sensing element are connected to the contacts of the pads 2 located in the head 1 of the thermal converter. From the contacts of the pads 2, the signal enters the indicating device or other device for monitoring and (or) regulation (not shown in Fig.).

Depending on the technological conditions in which the thermoelectric converter operates, the claimed variants of thermocouples are used as a sensitive element in it.

According to the first embodiment (figure 2), a thermocouple made of thermoelectrode wire 8, with interelectrode insulation 9 and a protective cover in the form of a braid 10.

The braid of the interelectrode insulation and the protective cover made of the claimed types of threads, the number of them in the braid, the number of braid layers, as well as the claimed diameter range of the thermoelectrode wire for this thermocouple, allows you to create a reliable and durable sensing element for the thermoelectric transducer and, thus, expand the scope application depending on technological conditions.

In the second embodiment (figure 3)

Thermocouple made of thermoelectrode wire 11, with interelectrode insulation 12, protective cover 13, sleeve 14.

The braid of the interelectrode insulation 12 and the protective cover 13 made of the claimed types of threads, the number of them in the braid, the number of braid layers, as well as the claimed diameter range of the thermoelectrode wire for this thermocouple, allows you to create a reliable and durable sensor element for the thermoelectric converter. The thermocouple resource is increased by the presence of a sleeve 14 into which the thermocouple is installed. The diameter of the sleeve 14 is selected depending on the specific process conditions and may be 2-70 mm.

According to the third embodiment (figure 4)

A thermocouple made of thermoelectrode wire 15 with interelectrode insulation 16, a protective cover 17, a sleeve 18, a protective sheath 19.

The braid of the interelectrode insulation 16 and the protective cover 17 made of the claimed types of threads, the number of them in the braid, the number of braid layers, as well as the claimed diameter range of the thermoelectrode wire for this thermocouple, allows you to create a reliable and durable sensor element for the thermoelectric converter. The thermocouple's life is increased by the presence of the sleeve 18, and the protective shell 19, which is used to braid the sleeve 18 or to put on a removable cover from the fabric formed above the threads. The diameter of the sleeve 18 is selected depending on the specific process conditions and may be 2-70 mm.

In the fourth embodiment (figure 5)

A thermocouple containing a thermoelectrode cable 20, in a metal sheath 21, with a filler 22 in the form of, for example periclase, a protective cover 23.

The presence of a protective cover 23 for the metal sheath 21 of the thermocouple in the form of a braid made of the claimed types of threads, the number of them in the braid, the number of layers in the braid, allows to increase the durability of the thermocouple, and the claimed range of diameters of the metal sheath of the thermocouple cable allows you to expand the scope of the thermoelectric converter depending from technological conditions.

According to the fifth embodiment (Fig.6)

A thermocouple containing a thermoelectrode cable 24 in a metal sheath 25, a filler in the form, for example, periclase 26, a protective cover 27, a sleeve 28.

The presence of a protective cover 27 on the metal sheath 25 of the thermocouple in the form of a braid made of the claimed types of threads, the number of them in the braid, the number of layers in the braid, allows to increase the durability of the thermocouple, and the claimed range of diameters of the metal sheath of the thermocouple cable allows you to expand the scope of the thermoelectric converter depending from technological conditions. The sleeve 28 in which the thermocouple is placed increases the life of the thermocouple. The diameter of the sleeve 28 is selected depending on the specific process conditions and may be 2-70 mm.

According to the sixth embodiment (Fig.7)

A thermocouple containing a thermoelectrode cable 28 in a metal sheath 29 placed in a sleeve 30 having a protective sheath 31 in the form of a braid or a removable cover.

The presence of a protective cover 31 at the sleeve 30, in which a thermocouple is placed from a thermoelectrode cable 28 in a metal sheath 29, in the form of a braid made of the claimed types of threads or a removable cover obtained from a fabric woven from the claimed threads, their number, the number of layers in the braid or fabric for a removable cover, allows you to increase the durability of the thermocouple, and the claimed range of diameters of the metal sheath of the thermocouple cable, allows you to expand the scope of the thermoelectric converter depending from technological conditions. The diameter of the sleeve 30 is selected depending on the specific process conditions and may be 2-70 mm.

Thus, the thermoelectric converter with the claimed variants of thermocouples can increase durability by increasing the reliability of thermocouples, expand the scope depending on the technological conditions.

Claims (6)

1. Thermoelectric converter containing a thermosensitive element in the form of, for example, chromel-alumel thermocouple made of thermoelectrode wire with interelectrode insulation and / or placed in a protective cover in the form of a braid with threads of dielectric material, characterized in that the braid of interelectrode insulation and / or thermocouple cover is made of threads, for example, silica grade K11C6-250 BA (250 tex), or 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or EC9 34 Z 160 × quartz 2 S 150 GO ST 8325-93, the number of braiding threads is at least 4, the number of insulation layers is 1-10, and the diameter of the thermoelectrode wire is 0.81-4 mm. 2. Thermoelectric converter containing a thermosensitive element in the form, for example, of a chromel-alumel thermocouple made of thermoelectrode wire with interelectrode insulation and / or placed in a protective cover in the form of a braid with threads of dielectric material, characterized in that the thermocouple is installed in a metal or ceramic a sleeve, while the braid of the electrode insulation and / or the protective cover is made of threads, for example, silica grade K11C6-250 BA (250 tex), or 3M ™ Nextel ™ Continuous Filament ceramic mark Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or EC9 quartz grade 34 Z 160 × 2 S 150 GOST 8325-93, the number of braiding threads is at least 4, the number of insulation layers is 1-10, and the diameter of the thermoelectrode wire is 0.81-4 mm. 3. Thermoelectric converter containing a thermosensitive element in the form, for example, of a chromel-alumel thermocouple made of a thermoelectrode wire with interelectrode insulation and / or placed in a protective cover made of dielectric material, characterized in that the thermocouple is installed in a metal or ceramic sleeve containing a protective a sheath in the form of a braid or a removable cover, while the interelectrode insulation and / or the protective cover and the protective shell of the sleeve are made of threads, for example, silica grade K11C6-250 BA (250 tex), or 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or EC9 34 Z 160 × 2 S 150 GOST 8325-93, the number of threads for the braid and removable cover is at least 4, the number of insulation layers is 1-10, and the diameter of the thermoelectrode wire is 0.81-4 mm. 4. Thermoelectric converter containing a thermosensitive element in the form, for example, of a chromel-alumel thermocouple made of a thermocouple cable in a metal sheath, characterized in that the metal sheath of the thermocouple contains a protective sheath in the form of a braid or a removable sheath of threads, for example, K11C6 silica grade -250 BA (250 tex), or 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or EC9 quartz grade 34 Z 160 × 2 S 150 GOST 8325-93, the number of braiding threads or removable cover is at least 4, the number of insulation layers is 1-10, while the diameter of the metal sheath of the thermocouple cable is 1-20 mm. 5. Thermoelectric converter containing a thermosensitive element in the form of, for example, a chromel-alumel thermocouple made of a thermocouple cable in a metal sheath, characterized in that the metal sheath of the thermocouple contains a protective sheath, while the thermocouple is installed in a metal or ceramic sleeve, the protective sheath is made in as a braid with threads, for example, silica grade K11C6-250 BA (250 tex), or 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or EC9 quartz grade 34 Z 160 × 2 S 150OST 8325-93, number of strands for braiding is not less than 4, the number of insulation layers 1-10, and the diameter of cladding metal thermocouple cable is 1-20 mm. 6. A thermoelectric converter containing a thermosensitive element in the form of, for example, a chromel-alumel thermocouple made of a thermocouple cable in a metal sheath, characterized in that the thermocouple is installed in a metal or ceramic sleeve containing a protective sheath in the form of a braid or a removable cover made of threads, for example, silica grade K11C6-250 BA (250 tex), or 3M ™ Nextel ™ Continuous Filament Ceramic Oxide Fibers 312, 440, 550, 610 and 720, or EC9 quartz grade 34 Z 160 × 2 S 150 GOST 8325-93 , the number of threads to braid or eat a lot of cover is at least 4, the number of insulation layers is 1-10, while the diameter of the metal sheath of the thermocouple cable is 1-20 mm.