RU39740U1 - ONE TIME SWITCH AND ELECTRIC HEATING ELEMENT WITH THERMAL SWITCH - Google Patents

Abstract

1. A one-time thermal switch containing a thermosensitive element in the form of a tube of fusible metal or a metal alloy, two contacts made of a metal tube, each of which is soldered by the extreme part of its internal surface to a thermosensitive element located at a distance from each other, providing a gap electrical circuit when the thermal switch is triggered, characterized in that each contact is connected to a thermosensitive element also at least the end surface and, to a large extent, the face and extreme part of the outer surfaces. 2. The temperature switch according to claim 1, characterized in that the thermally sensitive element is sealed in the end face of at least one side. The temperature switch according to claim 1, characterized in that it contains an activator substance introduced inside the heat-sensitive element, and the melting temperature and electrical conductivity of the activator substance is less than that of the material of the heat-sensitive element. The temperature switch according to claim 2, characterized in that it contains an activator substance introduced inside the thermosensitive element, the melting temperature and electrical conductivity of the activator substance being lower than that of the material, the thermosensitive element. The temperature switch according to claim 1, or 2, or 3, or 4, characterized in that it contains a plug installed and secured inside one of the contacts. The temperature switch according to claim 1, or 2, or 3, or 4, characterized in that it contains an electrical outlet made of metal wire, partially inserted into one of the contacts and clamped by it. Thermal switch

Description

The utility model relates to electrical engineering, namely to thermal switches designed to protect electrical appliances, including tubular electric heaters from overheating during abnormal operation, in conditions of limited heat dissipation, and to electric heating elements designed to equip tubular electric heaters (TENOV), protected from overheating during abnormal operation.

Known designs of single-action thermal switches according to patents of the Russian Federation No. 21115972, N 01 N 37/76, N 05 B 3/48, 1998; No. 2189658 H 01 H 37/76, H 05 B 3/48, 2002.

The disadvantage of these designs is the instability of the response time and the limitations of their application.

Known designs of electric heating elements with a thermal switch according to the patents of the Russian Federation No. 2097943, N 05 B 3/48, 1997; No. 214111745, H 05 B 3/48, 1/02 // H 01 H 37/76, 1999.

The disadvantage of these designs is the low reliability and limited application.

The closest technical solution for a one-time thermal switch is the design according to the patent of the Russian Federation No. 2299610 N 01 N 37/76, N 05 B 3/46 2003, paragraph 2 of the formula, figure 2. A one-time thermal switch, hereinafter referred to as a thermal switch, of this design contains a thermosensitive element in the form of a tube of fusible metal or an alloy of metals, two contacts made of a metal tube, each of which is soldered by the extreme part of its internal surface to a thermosensitive element, located from each other at a distance that ensures the break of the electric circuit when the thermal switch is triggered.

The disadvantage of this design is the complexity of manufacturing, which consists in ensuring small tolerances in the diameters of the connected

soldering parts, namely, the inner diameter of the contact and the outer diameter of the heat-sensitive element.

The closest technical solution for an electric heating element with a thermal switch is the design according to the patent of the Russian Federation No. 2299610 N 01 N 37/76, N 05 B 3/46 2003, paragraph 6 of the formula, Fig.7. An electric heating element with a thermal switch of this design comprises a thermal switch having a thermosensitive element in the form of a tube of fusible metal or an alloy of metals and two contacts made of metal tubes, each of which is soldered by the extreme part of its inner surface to a thermosensitive element located on each other on the distance that ensures the breaking of the electric circuit when the thermal switch is triggered, a spiral made of metal wire with high conductivity electrical resistance, electrically connected to one of the two contacts of the thermal switch, while the direct passage from the inner space of the spiral through this contact into the temperature-sensitive element is closed.

The disadvantage of this design is the complexity of manufacturing, which consists in ensuring small tolerances in the diameters of the soldered parts, namely, for the inner diameter of the contact +0.02 mm and for the outer diameter of the heat-sensitive element -0.02 mm. Standard tubes according to GOST 11383 and GOST 21931 are available with large tolerances. If for the manufacture of contacts using standard copper or brass tubes of increased accuracy according to GOST 11383, having tolerances from ± 0.03 mm to ± 0.04 mm in wall thickness and ± 0.05 mm in outer diameter, then for each batch of such tubes after measuring their transverse dimensions should be made of a tube of fusible alloy with the appropriate dimensions, ensuring the docking of a heat-sensitive element made of this tube with a contact. Such non-standard tubes can be manufactured only on specially designed and manufactured technological equipment for these purposes.

The problem solved by the proposed utility model of a thermal switch and an electric heating element with a thermal switch is to reduce the complexity of manufacturing.

The technical result from the use of a utility model of a thermal switch and an electric heating element with

thermal switch - reducing the complexity of manufacturing, through the use of standard purchased materials.

The specified technical result for the thermal switch is achieved due to the fact that in it each contact is connected to the heat-sensitive element also at least with the end surface, and at least with the end and extreme part of the outer surfaces. That is, the contacts before soldering are not worn on a heat-sensitive element. In this case, the outer diameter of the thermally sensitive element is larger than the inner diameter of the contact.

The hole in the heat-sensitive element may be sealed from at least one end.

The temperature switch may contain a plug inserted into one contact and fixed in it.

Sealing the end face of the thermosensitive element or equipping the thermal switch with a plug allows simplifying the connection of this thermal switch with the heater coil of the heater. The spiral, in this case, can be crimped on the contact. Such a thermal switch must be built into the heating element in such a way that the insulation of the heating element is filled with insulating bulk material from the contact side, the direct passage through which is closed by a septum made by sealing the end of the temperature sensitive element, or by a plug inserted into this contact.

In order to ensure better preservation of the thermal switch and the stability of its response time, it can be equipped with an activator substance with a melting temperature and electrical conductivity lower than that of the material of the thermosensitive element introduced inside this thermosensitive element.

To ensure docking with some heating elements, the thermal switch can be equipped with an electrical outlet made of metal wire, partially inserted into one of the contacts and clamped by it.

To ensure docking with the TEN contact pin, the thermal switch can be equipped with a spiral made of a metal wire partially inserted into another contact and clamped by it, while part of the spiral inserted into another thermal switch contact is made narrower with a smaller diameter of turns than the diameter of the turns the remaining part of the spiral, and inside this contact between the end of the spiral and the heat-sensitive element free space is formed, with a direct passage to this free space from the internal spaces spiral is blocked, for example, the turns of the spiral itself, located at the end of the narrowed part, executed with varying diameter decreasing toward this end.

The specified technical result for an electric heating element with a thermal switch is achieved due to the fact that each contact in it is connected to a thermosensitive element also with at least an end surface, and at least an end and extreme part of the outer surfaces.

A direct passage from the interior of the spiral through the contact of the thermoswitch to its thermosensitive element in various versions of the electric heating element with the thermoswitch can be blocked either by a partition formed at the end of the thermosensitive element from its material, or by an activator substance placed in it, the melting temperature and specific electric the conductivity of the activator is lower than that of the material of the thermosensitive element.

The activator also provides good safety and stability of the response time of the thermal switch of the heating element.

The connection of the end of the spiral with the contact of the thermal switch in various versions of the electric heating element with the thermal switch can be performed either by compressing a part of the spiral worn on the contact of the thermal switch, or by compressing the contact on the part

the spiral introduced into this contact, while this part is supported is made narrower, with turns, the diameter of which is less than the diameter of the turns of the other part of the spiral.

A direct passage from the inner space of the spiral through the contact of the thermal switch to the end of the thermally sensitive element can be blocked, for example, by a stopper. This prevents foreign particles from entering the contact, which could have a negative effect on the operation of the thermal switch.

To ensure the same type of connection of the electric heating element with the terminals of the heating element, it can contain a second spiral made of metal wire or partially worn on another contact of the thermal switch and crimped on it, or partially inserted into another contact of the thermal switch and clamped by it, and this part of the spiral is made narrower , with a diameter of turns smaller than the diameter of turns of another part of this spiral, while inside another contact between the end of the narrowed part of the second spiral and heat-sensitive lementom formed space.

To exclude any particles entering the free space inside another contact, the direct passage to this space from the inner space of the second spiral can be blocked, for example, by turns of this spiral located at the end of its narrowed part, made with a variable diameter decreasing to this the end.

Figure 1 shows a longitudinal section of a thermal switch;

Figure 2 shows a longitudinal section of a thermal switch, the hole in the heat-sensitive element of which is sealed from one end;

Figure 3 shows a longitudinal section of a thermal switch, one of the contacts of which is closed by a plug inserted inside;

Figure 4 shows a longitudinal section of a thermal switch containing an activator substance;

 Figure 5 shows a longitudinal section of a thermal switch containing an electrical outlet;

In Fig.6 shows a cross section of the thermal switch depicted in Fig.5;

7 shows a longitudinal section of a thermal switch containing an electrical outlet and a spiral with a plug;

On Fig shows a cross section of the thermal switch shown in Fig.7;

Figure 9 shows a longitudinal section of a term o switch containing an electrical outlet and a spiral with turns of variable diameter;

Figure 10 shows a longitudinal section of an electric heating element with a thermal switch containing a spiral, the end of which is crimped on the contact of the thermal switch;

11 shows a longitudinal section of an electric heating element with a thermal switch containing an activator substance;

On Fig shows a cross section of an electric heating element with a thermal switch depicted in figure 10;

On Fig shows a longitudinal section of an electric heating element with a thermal switch having a spiral, the end of which is clamped in contact with the thermal switch;

On Fig shows a cross section of an electric heating element with a thermal switch depicted in Fig.13;

On Fig shows a longitudinal section of an electric heating element with a thermal switch having a spiral, the end of which is crimped at the contact of the thermal switch, closed by a stopper;

On Fig shows a longitudinal section of an electric heating element with a thermal switch having a spiral, the turns on the part of which is brought into contact are made with a variable diameter decreasing towards the end;

On Fig shows a longitudinal section of an electric heating element with a thermal switch having two spirals, the ends of which are crimped on the contacts of the thermal switch;

On Fig shows a longitudinal section of an electric heating element with a thermal switch having two spirals, into the ends of which plugs are inserted and they are clamped in the contacts of the thermal switch;

On Fig shows a cross section of an electric heating element with a thermal switch depicted in Fig;

On Fig shows a longitudinal section of an electric heating element with a thermal switch having two spirals, in which the turns at the ends clamped in the contacts of the thermal switch are made with a variable diameter;

On Fig shows a longitudinal section of the heater with an integrated thermal switch depicted in Fig.9;

On Fig shows a longitudinal section of a heating element with a built-in electric heating element with a thermal switch depicted in Fig.17;

On Fig shows a longitudinal section of the heater with an integrated electric heating element with a thermal switch, shown in Fig.13;

On Fig shows a longitudinal section of a heating element with a built-in electric heating element with a thermal switch, shown in Fig;

On Fig shows a longitudinal section of the heater, shown in Fig in the state that occurred after the operation of the thermal switch;

On Fig shows a longitudinal section of the heater, shown in Fig in the state that occurred after the operation of the thermal switch.

The design of the thermal switch consists of a temperature-sensitive element 1 (see Fig. 1), in the form of a tube of fusible metal or an alloy of metals, for example, tin-lead alloy, two contacts 2, 3 made of metal, for example, copper or brass, tube. Each contact is partially soldered by the inner surface “B”, also by at least the end surface “T”, and at least by the end surface “T” and partly the outer surface “H” to the heat-sensitive element 1. Contacts 2, 3 are located one another from friend

at a distance of "L", providing a break in the electrical circuit when the thermal switch is triggered.

To prevent ingress of a loose insulating filler into the thermosensitive element of the thermal switch embedded in the heater, the hole in the thermosensitive element can be soldered - blocked by a partition 4 (see figure 2). From at least one end. In the case of using a thermal switch to protect the heating element, the packing of a loose insulating filler in its shell should be carried out from the sealed end of the thermosensitive element of the thermal switch.

Also, to prevent the inside of the thermosensitive element of the thermal switch embedded in the heater, loose insulating filler, it can be equipped with a stopper 5 (see figure 3), made, for example, of organosilicon sealant, inserted inside one of the contacts and fixed in it.

. In order to ensure better safety and stability of the response time, the thermoswitch can be equipped with an activator substance 6 (see Fig. 4), for example, rosin, with a melting point and electrical conductivity lower than that of the material of the thermosensitive element introduced inside this thermosensitive element.

To ensure docking with some versions of the heating elements, the thermal switch can be equipped with an electrical outlet 7 (see Fig. 5), made of metal wire, partially inserted into contact 2 and clamped by it (see Fig. 6).

- To ensure that the thermal switch is docked with the TEN contact pin, it may contain a spiral 8 (see Fig. 7) made of metal wire, partially inserted into contact 3, and clamped by it. The part of the spiral 9 introduced into the contact of the thermal switch is made narrower. The turns of the narrowed part 9 of the spiral 8 are made with a diameter D ₁ less than the diameter D _{2 of the} other part of the spiral. Inside the contact 3 between the end of the narrowed part 9 of the spiral 8 and the heat-sensitive element 1, a free space 10 is formed. The volume of the free space 10 is such that when it is filled with a melt of material

a heat-sensitive element in the zone between the contacts formed an electrical insulating gap, which ensures a reliable break in the electric circuit of the heater. Usually, this volume is approximately equal to the volume of the material of the heat-sensitive element located between the contacts 2 and 3. The direct passage into the free space 10 from the inner space of the spiral 8 is blocked by a plug 11 made, for example, of organosilicon material introduced into the end of the narrowed part 9 spiral 8 and fixed in it. The clamping of the narrowed part 9 of the spiral 8 in the contact 3 is made in such a way that between the contact 3 and the spiral 8 six exhaust channels 12 are formed (see Fig. 8) through which the free space 10 communicates with the external environment.

A direct passage into the free space 10 from the inner space of the spiral 8 can be blocked by turns 13 of the spiral 8 itself (see Fig. 9), located at the end of its narrowed part 9, made with a variable diameter decreasing towards this end.

An electric heating element with a thermal switch contains a thermal switch having a thermosensitive element 1 (see Fig. 10), made in the form of a tube of fusible metal or an alloy of metals, for example, of a tin-lead alloy, two contacts 2, 3 made of metal tubes, for example copper or brass. Contacts 2, 3 are connected by soldering with the extreme parts of their internal surfaces "B", also at least with the end surfaces "T", and at least with the end surfaces "T" and partially the outer surfaces "H" to the heat-sensitive element 1. Contacts 2, 3 are located from each other at a distance of "L", providing a break in the electrical circuit when the thermal switch is triggered. The design also contains a spiral 14 made of a metal wire with a high electrical resistivity, for example, of a nichrome wire. The end of the spiral 14 is electrically connected to the contact 2 of the thermal switch. A direct passage from the inner space of the spiral 14 through contact 2 into the thermally sensitive element 1 is blocked by a partition 4 formed by sealing the end face of the thermally sensitive element.

A direct passage from the inner space of the spiral 14 (see Fig. 11) through the contact 2 into the heat-sensitive element 1 can be blocked by an activating substance 6, for example rosin, with a melting point and electrical conductivity lower than that of the material of the heat-sensitive element inserted inside the heat-sensitive element 1.

The connection of the end of the spiral with the contact of the thermal switch can be made by squeezing the spiral 14 on the contact 2 of the thermal switch (see Fig. 12) or by pressing the contact 2 on the part 15 of the spiral 14 introduced into this contact (see Fig. 13, 14), while part 15 spiral 14 is made narrowed, with turns, the diameter of which is "D ₃ ", less than the diameter of "D ₄ " of the turns of the other part of the spiral.

A direct passage from the inner space of the spiral 14 through the contact 2 into the heat-sensitive element 1 can be blocked by a plug 16 (see Fig. 13) made, for example, of silicone sealant, inserted into the end of the narrowed part 15 of the spiral 14 and fixed therein.

A direct passage from the inner space of the spiral 14 (see Fig. 15) through the contact 2 into the heat-sensitive element 1 can be blocked by a plug 4 made, for example, of silicone sealant introduced into the contact 2 and fixed therein.

A direct passage from the inner space of the spiral 14 (see Fig. 16) through the contact 2 into the heat-sensitive element 1 can be blocked by turns 16 of the narrowed part 15 of the spiral 14, made with a variable diameter decreasing towards the end of the spiral.

An electric heating element with a thermal switch may comprise a second spiral 17 (see FIG. 17) made of metal wire, part of which is worn on terminal 3 of the thermal switch and crimped on it.

The electric heating element with a thermal switch may contain a second spiral 17 (see Fig. 18) made of metal wire, part 18 of which is made narrower, with a diameter of "D ₁ " turns

smaller than the diameter "D ₂ " of the turns of the other part of this spiral, and the narrowed part 18 of the second spiral 17 is brought into contact 3 of the thermal switch and clamped by it. Between the end of the narrowed part 18 of the second spiral 17 and the heat-sensitive element 1, a free space 10 is formed inside the contact 3. The volume of this free space is such that when the material is filled with the melt of the heat-sensitive element in the area between the contacts 2, 3, an insulating gap is formed, which ensures a reliable gap electric circuit TENA. Usually, this volume is approximately equal to the volume of the material of the heat-sensitive element 1 located between the contacts 2 and 3. The clamping of the narrowed part 18 of the second spiral 17 in the contact 3 is made so that between the contact and the spiral six exhaust channels 12 are formed (see Fig. 19), through which the free space 10 communicates with the external environment.

A direct passage into the free space 10, which is inside the contact 3, from the inner space of the second spiral 17 can be blocked by a plug 11 (see Fig. 18), made, for example, of organosilicon material inserted inside the second spiral 17 at the end of its narrowed part 18 , and fixed in it.

A direct passage into the free space 10 inside the contact 3 from the inner space of the second spiral 17 can be blocked by turns 20 (see FIG. 20) of this spiral located at the end of its narrowed part 18, made with a variable diameter decreasing towards this end .

The thermal switch is used for thermal protection of electric heating devices, including for the built-in protection of heating elements. Typically, the current-carrying conductors or the heater coil are connected to the terminals of the thermal switch by crimping. The thermal switch is electrically isolated from the body of the protected appliance.

As an example, consider the installation in the heater (see Fig. 21) of the thermal switch depicted in Fig. 7.

Before installation in the heater, the spiral 21 of the heater is connected to the contact terminal of the heater 22 and the electrical output of the thermal switch 7.

The spiral of the thermal switch 8 is connected to the contact terminal of the heating element 23. The connection can be welded or press. Spirals are stretched with a uniform pitch of turns to the desired length. The assembled unit is installed in the shell of the heater 24, made of a metal tube. The output of the contact terminals 22, 23 from the shell 24 can be through electrical insulating sleeves 25, 26. The contact leads, a spiral and a thermal switch are isolated from the shell by a bulk electrical insulating filler 27, for example, quartz sand or periclase. Stuffing of the insulating filler is carried out from the side of the electrical outlet 7 of the thermal switch. The shell of the heating element is crimped, for example, reduced to seal the bulk electrical insulating filler. To ensure the bending of the heating element, its shell can be annealed. Annealing should be performed with cooling of the location of the thermal switch.

When installing in the heater the design of the electric heating element with a thermal switch, shown in FIG. 17, the spirals 14, 17 are connected to the contact terminals of the heating element 22, 23. (see FIG. 22) The electrical insulating filler 27 is stuffed from the contact side 2.

When installing in the heater the design of the electric heating element with a thermal switch, shown in FIG. 13, the spiral 14 (see Fig. 23) is connected to the contact terminal of the heating element 22. The contact of the thermal switch 3 is passed through the insulating sleeve 26 and leaves the shell of the heating element 24. In this case, the contact 3 simultaneously performs the functions of the contact output of the heating element. Stuffing of the insulating filler 27 is carried out on the contact side 2. The plug 16 prevents the insulating filler 27 from getting inside the heat-sensitive element 1.

When the design of the electric heating element with a thermal switch shown in FIG. 18, the spirals 14, 17 (see Fig. 24) are connected to the contact terminals of the heater 22, 23. The electrical insulating filler 27 is stuffed from the contact side 2. The plug 16 prevents ingress

electrical insulating filler 27 to the end of the heat-sensitive element 1.

An electric heating element with a thermal switch built into the heater operates as follows:

To the contact terminals of the heating element 22, 23 (see Fig. 25, Fig. 26) the voltage of the electric network is supplied. The current heats the spiral 14 to a temperature of 400 ... 500 ° C. Heat is transferred from the spiral 14 to the thermosensitive element of the thermal switch. During normal operation, when the heater is cooled by a heated medium, such as water, the temperature on the shell of the heater 24 is approximately 105 ... 110 ° C. The temperature of the thermosensitive element of the thermal switch does not exceed the melting temperature of its material and the thermal switch does not operate. In the case of boiling water or turning on the heater without water, the heat flux from the spiral 14 to the thermosensitive element of the thermal switch increases. The thermosensitive element of the thermal switch melts. Under the influence of the capillary effect, the melt of the thermosensitive element 28 is drawn into the contacts of the thermal switch. The electric power circuit of the heating element is broken. When the electric circuit is broken, the temperature rise of the heating element stops. If the response time of the thermal switch is about 20 seconds, then the temperature of the heater shell usually does not exceed 200 ° C.

If the temperature switch contains an activator substance 6, then its melt 29 (see Figs. 25, 26), by cleaning the surfaces of the contacts and the thermosensitive element from oxides, helps the melt contact to retract the thermosensitive element, then is partially absorbed into the insulating filler.

The tests showed that the proposed design of the thermal switch and the electric heating element with the thermal switch are simple to manufacture, easy to integrate into the heating elements, reliable in operation.

The industrial applicability of the proposed designs is obvious. These designs have passed pilot tests at the enterprise ENTZ LLC in Nizhny Novgorod and have shown good results.

Claims (21)

1. A one-time thermal switch containing a thermosensitive element in the form of a tube of fusible metal or a metal alloy, two contacts made of a metal tube, each of which is soldered by the extreme part of its internal surface to a thermosensitive element located at a distance from each other, providing a gap electrical circuit when the thermal switch is triggered, characterized in that each contact is connected to a thermosensitive element also at least the end surface sti, and at most the end and extreme part of the outer surfaces. 2. The temperature switch according to claim 1, characterized in that the thermally sensitive element is sealed in the end face of at least one side. 3. The temperature switch according to claim 1, characterized in that it contains an activator substance introduced inside the thermosensitive element, and the melting temperature and electrical conductivity of the activator substance is less than that of the material of the thermosensitive element. 4. The temperature switch according to claim 2, characterized in that it contains an activator substance introduced inside the thermosensitive element, the melting temperature and electrical conductivity of the activator substance is less than that of the material, the thermosensitive element. 5. The temperature switch according to claim 1, or 2, or 3, or 4, characterized in that it contains a plug installed and secured inside one of the contacts. 6. The temperature switch according to claim 1, or 2, or 3, or 4, characterized in that it comprises an electrical outlet made of metal wire, partially inserted into one of the contacts and clamped by it. 7. The temperature switch according to claim 1, or 2, 3, or 4, characterized in that it is equipped with a spiral made of metal wire, partially inserted into one of the contacts and clamped by it in such a way that between the end of the spiral and the heat-sensitive element is formed free space, while the part of the spiral brought into contact is made narrower, with a diameter of turns smaller than the diameter of the turns of the other part of the spiral, and the direct passage into the free space from the inner space of the spiral is blocked, for example, by turns of the spiral itself, Assumption at the end of the narrowed part, executed with varying diameter decreasing towards the end of the spiral. 8. The temperature switch according to claim 1, or 2, or 3, or 4, characterized in that it comprises an electrical outlet made of metal wire, partially inserted into one of the contacts and clamped by it, a spiral made of metal wire, partially inserted into another contact and clamped by it in such a way that free space is formed between the end of the spiral and the heat-sensitive element, while the part of the spiral introduced into the contact is made narrower, with a diameter of turns less than the diameter of the turns of the other part of the spiral, a direct passage to one space from the inner space of the spiral is blocked, for example, by turns of the spiral itself, located at the end of its narrowed part, made with a variable diameter decreasing towards the end of the spiral. 9. An electric heating element with a thermal switch, comprising a thermal switch having a thermosensitive element in the form of a tube of fusible metal or an alloy of metals and two contacts made of metal tubes, each of which is soldered by the extreme part of its internal surface to a thermosensitive element located on each other on the distance that ensures the breakdown of the electric circuit when the thermal switch is triggered, a spiral made of metal wire with a high specific electric resistance, connected to one of the two contacts of the thermal switch, while the direct passage from the inner space of the spiral through the contact inside the thermosensitive element is closed, characterized in that each contact is connected to the thermosensitive element also at least the end surface, and at least the end and extreme part of the outer surfaces. 10. The element according to claim 9, characterized in that the thermal switch contains an activator substance introduced inside the thermosensitive element, the melting temperature and electrical conductivity of the activator substance being lower than that of the material of the thermosensitive element. 11. The element according to claim 9, characterized in that the thermosensitive element of the thermal switch is sealed in the end face at least from the side of the spiral. 12. The element according to claim 10, characterized in that the thermosensitive element of the thermal switch is sealed in the end face of at least one side. 13. The element according to claim 9, characterized in that the direct passage from the inner space of the spiral through the contact of the thermal switch to the end of the thermosensitive element is blocked, for example, by a stopper. 14. The element according to claim 10, characterized in that the direct passage from the inner space of the spiral through the contact of the thermal switch to the end of the thermosensitive element is blocked, for example, by a stopper. 15. The element according to claim 11, characterized in that the direct passage from the inner space of the spiral through the contact of the thermal switch to the end of the thermosensitive element is blocked, for example, by a stopper. 16. The element according to item 12, wherein the direct passage from the inner space of the spiral through the contact of the thermal switch to the end of the thermosensitive element is blocked, for example, by a stopper. 17. The element according to claim 9, or 10, or 11, or 12, or 13, or 14, or 15, or 16, characterized in that the connection of the spiral with the contact of the thermal switch is made by compressing part of the spiral worn on the contact of the thermal switch. 18. The element according to claim 9, or 10, or 11, or 12, or 13, or 14, or 15, or 16, characterized in that the connection of the spiral with the contact of the thermal switch is made by compressing part of the spiral worn on the contact of the thermal switch, and he contains a second spiral made of metal wire, partially worn on another contact of the thermal switch and crimped on it. 19. The element according to claim 9, or 10, or 11, or 12, or 13, or 14, or 15, or 16, characterized in that the connection of the spiral with the contact of the thermal switch is made by compressing the contact on the part of the spiral introduced into this contact, however, this part of the spiral is made narrower, with turns, the diameter of which is less than the diameter of the turns of the other part of the spiral. 20. The element according to claim 9, or 10, or 11, or 12, or 13, or 14, or 15, or 16, characterized in that the connection of the spiral with the contact of the thermal switch is made by squeezing the contact on the part of the spiral introduced into this contact, moreover, this part of the spiral is made narrower, with turns, the diameter of which is smaller than the diameter of the turns of the other part of the spiral, and it contains a second spiral made of metal wire, partially inserted into another contact, and clamped so that between the end of the second spiral and the heat-sensitive element formed free wandering, while the part of the second spiral, introduced into another contact, is made narrower, with a diameter of turns smaller than the diameter of the turns of another part of the second spiral. 21. The element according to claim 9, or 10, or 11, or 12, or 13, or 14, or 15, or 16, characterized in that the connection of the spiral with the contact of the thermal switch is made by compressing the contact on the part of the spiral inserted into this contact, moreover, this part of the spiral is made narrower, with turns, the diameter of which is smaller than the diameter of the turns of the other part of the spiral, and it contains a second spiral made of metal wire, partially inserted into another contact, and clamped so that between the end of the second spiral and the heat-sensitive element formed free wandering, while the part of the second spiral introduced into another contact is made narrower, with the diameter of the turns less than the diameter of the turns of the other part of the second spiral, the direct passage into the free space from the inner space of the second spiral is blocked, for example, by turns of this spiral located in the end of the narrowed part thereof, made with a variable diameter, decreasing towards the end of the spiral.