RU145587U1 - TEMPERATURE REGULATOR - Google Patents

Abstract

1. The temperature controller, comprising a housing with pipelines for supplying and discharging water, a cylinder located in the housing with a piston of a locking device, which lower end is connected to the locking body; a saddle integrated in the housing and a continuation of the pipeline for supplying hot water; a thermal bulb with a working fluid communicated over the piston of the locking device with its discharge cavity and interacting with a controlled flow of water; an external fluid pressure regulator installed outside the housing, comprising a power cylinder with an adjusting piston equipped with a mechanism for its extension, while the discharge cavity under the adjusting piston is in communication with a thermowell, characterized in that the working fluid pressure regulator is capable of depressing the adjusting piston upward during a pressure jump the working fluid in the bulb, in addition, the locking device is a valve in the form of a disk, the diameter of which exceeds the diameter of the seat, fixed minutes at the lower end of the piston of the locking device, the upper end of the rod is withdrawn out of the temperature regulator body to a length equal to the maximum value of the gap between the seat and klapanom.2. The temperature regulator according to claim 1, characterized in that a spring-loaded rod interacting with the adjusting piston is inserted into the working fluid pressure regulator, the end of which interacting with the piston is made in the form of a disk whose diameter exceeds the diameter of the adjusting piston, in addition, the spring-loaded rod is placed into a hollow cylindrical body, the inner diameter of which ensures the movement of the stem disc with

Description

The utility model relates to temperature control of circulating media, namely: direct-acting temperature controllers, which are used to automatically maintain the temperature of hot water supply, return water, heating, etc.

Closest to the proposed one is a temperature controller (RF patent No. 2138842, G05D 23/12, G05D 23/01, 09/27/1999), which contains a housing with inlet and outlet channels. The body contains a thermo-cylinder filled with a thermosensitive liquid, a locking member and a saddle. The thermal bulb has a piston, the stem of which is connected with a locking member. The locking element forms a passage section for the medium. Outside the regulator case, a power cylinder with a piston is installed, the rod of which has a screw mechanism for its extension. The discharge cavity of the power cylinder is connected via a pipeline to the discharge cavity of the thermowell. Using a screw mechanism, the thermal bulb is adjusted to maintain a given temperature and a certain pressure drop of the controlled medium. At the same time, under the action of the piston, the thermosensitive fluid is supplied from the power cylinder through the pipeline to the injection cavity of the thermoballion, the piston of which is installed in the position corresponding to the formation of the necessary passage section between the locking member and the seat. The piston of the power cylinder is in a constant position during operation of the regulator, keeping the volume of fluid in its discharge cavity unchanged.

A disadvantage of the known temperature controller is the lack of means to prevent the temperature controller from failing with a sharp increase in pressure in the thermowell of the temperature controller, for example, due to overheating, which reduces the reliability of the device. This is because the piston rod in the power cylinder has a screw extension mechanism, i.e. the piston is pressed against the top of the screw and is rigidly fixed, therefore, the volume for the heat-sensitive fluid in the discharge cavity of the piston of the power cylinder is also fixed. With a sharp change in pressure in the bulb, for example, due to overheating, the latter generates excess heat-sensitive fluid, which tends to move into the pressure chamber of the piston of the power cylinder, the volume of which, as shown above, is fixed, which leads to an emergency and the device exits system.

In addition, in the known temperature controller there is no means of visual control of the gap between the seat and valve, which does not allow to prevent the malfunction of the device in advance, to determine the cause of the malfunction without dismantling, worsens the operating conditions and reduces the reliability.

The proposed utility model solves the problem of creating a temperature controller, the implementation of which ensures the achievement of a technical result, which consists in increasing reliability due to the possibility of preventing failure due to a sharp increase in the pressure of the working fluid. in the thermoset of the temperature controller, as well as in improving operating conditions.

The essence of the utility model is that in the temperature controller, comprising a housing with pipelines for supplying and discharging water, a cylinder located in the housing with a piston of a locking device, which lower end is connected to the locking body; a saddle integrated in the housing and a continuation of the pipeline for supplying hot water; a thermal bulb with a working fluid communicated over the piston of the locking device with its discharge cavity and interacting with a controlled flow of water; installed outside the housing, a working fluid pressure regulator comprising a power cylinder with an adjusting piston provided with a mechanism for extending it, while the discharge cavity under the adjusting piston is in communication with a thermal bulb, new is that the working fluid pressure regulator is capable of pushing the adjusting piston upward during a jump pressure of the working fluid in the bulb, in addition, the locking device is a valve in the form of a disk, the diameter of which exceeds the diameter of the saddle, fixed at the lower end of the piston of the locking device, the upper end of the rod of which is brought out from the body of the temperature controller by a length equal to the maximum clearance between the seat and valve. In addition, a spring-loaded rod is introduced into the pressure regulator of the working fluid, which interacts with the adjustment piston, and whose end interacts with the piston and is made in the form of a disk whose diameter exceeds the diameter of the adjustment piston; in addition, the spring-loaded rod is placed in a hollow cylindrical body, inner the diameter of which ensures the displacement of the stem disc with force, in addition, the stem housing in the lower part is threaded and wound externally onto the power cylinder, while the upper part of the housing is covered with a cover in the form of a cylinder, the side walls of which are supported by a stepped circular recess made along the outer circumference of the housing, a threaded hole is made in the middle part of the lid along the axial side to fix the free end of the stem, which is locked with a nut. At the same time, in the upper part of the adjusting piston, an open axial cavity is made in the form of a cup facing the bottom towards the discharge cavity of the adjusting piston, and communicating with its delivery cavity through a through axial channel made in the piston, tightly closed with a plug on the side of the upper axial cavity. In addition, in the pressure regulator inside the upper part of the adjusting piston, an axial cavity is made in the form of a body of revolution, having a cone in the lower part that communicates with the discharge cavity of the adjusting piston through the through axial channel made in it, a safety valve is installed in the cavity, consisting of upper and lower parts, with a side surface congruent with each part of the side cylindrical surface of the cavity, the upper and lower parts of the valve are interconnected at a distance from each other and along the axial adjusting piston by a spring, while the lower part of the valve has the shape of a cone, the top of which overlaps the through axial channel of the adjusting piston, and the upper part of the valve abuts against the nut screwed on top of the power cylinder, while the nut is made in the form of a cylindrical cover on the inside the side surface of which is made thread.

The technical result is achieved as follows.

Salient features of the utility model formula: “A temperature controller comprising a housing with pipelines for supplying and discharging water, a cylinder located in the housing with a piston of a locking device, which lower end is connected to the locking body; a saddle integrated in the housing and a continuation of the pipeline for supplying hot water; a thermal bulb with a working fluid communicated over the piston of the locking device with its discharge cavity and interacting with a controlled flow of water; installed outside the housing, a working fluid pressure regulator containing a power cylinder with an adjustment piston equipped with a mechanism for its extension, while the discharge cavity under the adjustment piston is in communication with a thermal bulb ... ”are an integral part of the claimed device and ensure its operability, and, therefore, achieve the declared technical result.

In the claimed temperature controller, the locking device is a valve in the form of a disk, mounted on the lower end of the piston of the locking device. The diameter of the valve disc of the locking device exceeds the diameter of the seat, which allows you to withstand the same amount of clearance over the entire cross-sectional area of the seat. This, in turn, eliminates the distortion of the piston of the locking device under the action of pressure in the pipeline for hot water, and, therefore, increases the reliability of the temperature controller.

In addition, since the upper end of the piston rod of the locking device is brought out from the temperature controller body by a length equal to the maximum gap between the seat and valve, this allows visual control of the gap. As a result, the number of controlled operating parameters of the temperature controller increases, the information content increases, it becomes possible to determine the cause of a malfunction in the temperature controller without dismantling the device. The result is increased reliability and improved operating conditions of the temperature controller.

The implementation of the pressure regulator of the working fluid with the ability to squeeze the adjusting piston when the pressure jump of the working fluid gives the following positive effect. After setting the working pressure in the discharge cavity of the piston of the locking device, the position of the adjustment piston in the normal mode of operation of the temperature controller remains unchanged. However, with a sharp increase in the pressure of the working fluid in the bulb, caused, for example, by its overheating, the adjustment piston, as it is not fixed, is pushed upward by excess pressure of the working fluid. In this case, the volume of the piston injection cavity increases in accordance with the increase in the volume of the working fluid, due to which the differential pressure that arises is compensated and the operability of the temperature controller is maintained. After the return of the working fluid pressure to normal, its effect on the adjusting piston is weakened and it returns to its original state corresponding to the normal mode. As a result, the operating conditions of the temperature controller are improved and its reliability is increased.

When a spring-loaded rod is used in the pressure regulator of the working fluid, the housing in which the spring-loaded rod is placed is fixed directly to the power cylinder of the adjustment piston by screwing the lower part of the spring-loaded rod housing outside onto the power cylinder. This ensures that the adjusting piston is set to its initial position under the action of the compression force of the spring. In this case, the upper part of the body is covered with a cylinder-shaped lid, the side walls of which are supported by a stepped circular recess made along the outer circumference of the body, and a threaded hole is made in the middle part of the lid to fix the free end of the stem, which is locked with a nut. This provides freedom of movement of the rod inside the housing under the action of the spring, namely when it is compressed as a result of the occurrence of excessive pressure of the working fluid.

The execution of the end of the spring-loaded rod interacting with the adjusting piston in the form of a disk, the diameter of which exceeds the diameter of the piston, makes it possible to return the piston to its normal position under the action of an expanding spring after working out an emergency situation.

Since the internal diameter of the housing of the spring-loaded rod provides movement of the disk of the rod with force, this ensures reliable fixation of the spring-loaded rod, and, consequently, the adjustment piston, in the initial position, and ensures smooth emergency response.

In addition, due to the fact that in the upper part of the adjusting piston an open axial cavity is made in the form of a cup facing the bottom towards the pressure chamber of the piston, and communicating with the pressure chamber of the piston through a through axial channel made therein, tightly closed by a plug from the side of the upper axial cavity , it is possible to refuel or refill the bulb with working fluid through the piston of the pressure regulator (the plug is removed).

When using an adjusting piston with a safety valve, the initial installation of the adjusting piston is performed by means of a nut made in the form of a cylindrical cap, on the inner side surface of which a thread is made. The nut is screwed on top of the master cylinder. At the same time, the possibility of moving the adjusting rod axially by the required value is provided due to the execution of the lateral surface of the nut cylindrical with thread on the inner side surface. As a result, it is possible to fix the initial position of the adjusting piston by moving it along the axial turning of the nut. The length of the forming nut limits the movement of the adjusting piston in the ram.

To accommodate the safety valve with the possibility of interaction with the adjusting piston, inside the upper part of the adjusting piston axially a cavity is made in the form of a body of revolution having a cone in the lower part communicating with the discharge cavity of the piston through the through axial channel made in the adjusting piston. In this case, the valve consists of upper and lower parts with a lateral surface congruent with each part of the lateral cylindrical surface of the cavity, and the upper and lower parts of the valve are interconnected at a distance from each other along the axial piston by a spring. In addition, the upper part of the valve abuts against a nut screwed on top of the master cylinder. In this case, the initial compression force of the spring corresponds to the nominal pressure of the working fluid in the bulb. The execution of the lower part of the valve in the form of a cone, the apex of which overlaps the through axial channel of the piston, prevents the output of the working medium from the injection cavity under the piston into the cavity to accommodate the valve in normal operation of the device. As a result, when there is a sharp drop in the pressure of the working fluid in the bulb, the valve is pressed upward under pressure in the through axial bore of the piston of the excess working fluid and it seeps into the internal piston capacity. As a result, an emergency situation is worked out.

After reducing the pressure in the bulb, excess working fluid gradually seeps into the discharge cavity under the adjustment piston, the valve goes down and closes the through axial hole in it.

In addition, the proposed design of the location of the safety valve provides the ability to refuel or refuel the bulb with working fluid through the adjustment piston, for which the safety valve is removed from the cavity of the control rod.

Thus, from the foregoing, it follows that the proposed temperature controller during implementation ensures the achievement of a technical result consisting in increasing reliability due to the possibility of preventing failure due to a sharp increase in pressure in the thermoset of the temperature controller, as well as in improving operating conditions.

The figures depict the claimed temperature controller in four versions, namely: FIG. 1 shows an embodiment of a temperature controller with one inlet flange for hot water and one outlet flange for water drainage, while the pressure regulator for the working fluid is mounted directly on the device body; in FIG. 2 shows an embodiment of a temperature controller with an inlet flange for hot water, with an inlet flange for the "return" and one outlet flange for water drainage, while the working fluid pressure regulator is mounted directly on the device body; in FIG. 3 shows a pressure regulator of a working fluid with a spring-loaded rod of an adjusting piston; in FIG. 4 shows a pressure regulator of a working fluid with a safety valve; in FIG. Figure 5 shows the connection option of the working fluid pressure regulator for the implementation of a temperature regulator with an inlet flange for hot water, with an inlet flange for the "return" and one outlet flange for water drainage, in which the blocking block and the thermal system are allocated into independent nodes, while the outlet pipeline is away from the locking block; in FIG. Figure 6 shows the connection option of the working fluid pressure regulator for the implementation of a temperature regulator with an inlet flange for hot water, and one outlet flange for water drainage, which is located at a distance from the shut-off unit, while the shut-off unit and the thermal system are allocated as separate units.

The claimed temperature controller contains a housing 1 with pipelines for supplying 2, 3 and 4 water outlet; a cylinder 5 located in the housing 1 with a piston 6 of a locking device, at the lower end of which a locking body is fixed, which is a valve in the form of a disk 7, the diameter of which exceeds the diameter of the seat 8 integrated in the housing 1 and which is a continuation of the pipeline 2 for supplying hot water; thermal bulb 9 with a working fluid 10, communicated over the piston 6 of the locking device 7 through the channel 11 with its discharge cavity and interacting with a controlled flow of water; installed outside the housing 1, the pressure regulator 12 of the working fluid 10.

The pressure regulator 12 of the working fluid 10 comprises a power cylinder 13 with an adjustment piston 14 provided with a mechanism for its extension. The injection cavity 15 under the adjusting piston 14 is in communication with the thermowell 9 through the channel 16. The pressure regulator 12 of the working fluid 10 is configured to depress the adjusting piston 14 when the pressure of the working fluid 10 rises.

Moreover, the pressure regulator 12 may include a spring-loaded rod 17 interacting with the adjustment piston 14, the end of which interacting with the piston is made in the form of a disk 18, the diameter of which exceeds the diameter of the piston 14. In addition, the spring rod 17 together with the spring worn on it 19 is placed in a hollow cylindrical body 20, the inner diameter of which provides movement of the disk 18 of the rod 17 with effort. In addition, the housing 20 of the rod 17 in the lower part is threaded and wound externally onto the power cylinder 13. The upper part of the housing 20 is covered with a cover 21 in the form of a cylinder, the side walls of which are supported by a stepped circular recess made along the outer circumference of the housing 20. In the middle part of the cover 21, an axial hole is made with a thread for fixing the free end of the rod, which is locked with a nut 22. In addition, an open axial cavity 23 is made in the upper part of the piston 14 of the power cylinder 13 in the form of a cup facing the bottom towards the pressure the cavity 15 of the adjusting piston 13, and communicating with the discharge cavity 15 of the piston 14 through the through axial channel 24 formed therein, tightly closed by a plug 25 from the side of the upper axial cavity 23.

In addition, the pressure regulator 12 can be made in such a way that inside the upper part of the adjusting piston 14, an axial cavity 25 is made in the form of a body of revolution having a cone in the lower part that communicates with the discharge cavity 15 of the piston 14 through a through axial channel 26 made in piston 14. In the cavity 25, a safety valve 27 is installed, consisting of upper and lower parts, with a side surface congruent to each part of the side cylindrical surface of the cavity 25. The upper and lower parts of the valve 27, each other at a distance from each other along the axial adjusting piston 14 by the spring 28. The lower part of the valve 27 has the shape of a cone, the top of which overlaps the through axial channel 26 of the piston 14, and the upper part of the valve 27 abuts against the nut 29 screwed on top of the power cylinder 13. The nut 29 is made in the form of a cylindrical cover, on the inner side surface of which a thread is made.

The pressure gauge 30 is in communication with a thermal bulb 9 and controls the pressure of the working fluid 10.

In addition, the upper end 31 of the rod 9 of the piston 6 of the locking device 7 is brought out from the temperature controller housing 1 through the casing 3 by a length equal to the maximum gap between the seat 8 and valve 7, which makes it possible to visually control the size of this gap after setting the temperature controller to set temperature.

In the connection options of FIG. 5 and FIG. 6 pressure regulators 12 of the working fluid are allocated into independent units locking block and a thermal system.

The locking block comprises a housing 1 with pipelines 2 and 3 for supplying hot water and a "return", respectively, a cylinder 5 located in the housing 1 with a piston 6 of a locking device, at the lower end of which a locking body is fixed, which is a valve in the form of a disk 7, the diameter of which exceeds the diameter of the seat 8, built into the housing 1 and is a continuation of the pipeline 2 for supplying hot water.

The thermal system contains a thermocylinder 9 with a working fluid 10 and a pressure regulator 12 of a working fluid 10 connected with it. A thermocylinder 9 is placed in a passage tank 36 through which heated water enters the outlet pipe 4.

To withdraw the heated water to the passage tank 36, the locking block and the thermal system are connected through an intermediate pipe 35 (Fig. 5) or connected by flanges of the pipelines 40 and 41 for the output and supply of heated water, respectively (Fig. 6).

The pressure regulator 12 is connected above the piston of the locking device with its discharge cavity through the channel 11 in the housing 1 of the temperature regulator by a direct capillary tube 34 (Fig. 5) or a capillary tube in the form of a coil (Fig. 6). The latter allows one to minimize the influence of the ambient temperature on the change in the volume of the working medium in the capillary tube and maintain the required accuracy of the temperature of water heating.

The pressure gauge 30, the casing 32 of the upper end 31 of the rod of the locking device, are mounted on the cover 44 of the housing 1 of the temperature controller. Channel 16 is made in the housing cover, connecting the thermal system as a whole.

The housing 1 of the temperature controller is performed with a pipeline for supplying hot water 2, return 3 and water 4. The saddle 8 is built into the housing 1 and is a continuation of the pipeline 2 for supplying hot water.

When performing the fluid pressure regulator in accordance with FIG. 3, after filling the thermal system, close the axial bore through the plug 25 and screw the housing 20 with the spring-loaded piston of FIG. 3.

When performing the fluid pressure regulator in accordance with FIG. 4, after filling the thermal system, a spring-loaded safety valve 27 is inserted into the piston cavity 14, closing the through hole 26 in the piston 14 tightly with its cone. Then, the spring is inserted, and then the nut 29 is screwed on top of the adjustment cylinder 13 of the adjustment piston 14.

The claimed temperature controller operates as follows.

The claimed temperature controller regulates and stabilizes the water temperature at its outlet by changing the water flow between the seat 8 and valve 7. Let us consider the operation of the device using the temperature controller shown in FIG. one.

By means of the adjusting nut 29 of FIG. 4 set the position of the piston 6 with the valve 7 relative to the seat 8, i.e. set the gap between the valve 7 and the seat 8, corresponding to a given temperature. In this case, when loosening the nut 29 of FIG. 4, the piston 6, under the action of the return spring 43, leaves the cylinder 5, and when screwed in, it enters the cylinder.

Then set the bulb 9 to maintain a given temperature and a certain pressure drop of the controlled environment. To do this, the adjusting piston 14 in the device 12 for regulating the pressure of the working medium is moved by a screw mechanism. In this case, under the action of the adjusting piston 14, the working fluid from the bulb is supplied through the channel 11 into the discharge cavity above the piston 6 of the locking device. The piston 6 is installed in the final position corresponding to the formation of the required bore between the valve 7 and the seat 8. The adjusting piston 14 is in a constant position when the temperature controller is in normal operation, keeping the volume of fluid in its discharge cavity 15 unchanged.

The controlled flow of water enters the temperature controller through the inlet channel 2, then throttles through the passage gap between the valve 7 and the seat 8 and is discharged through the pipe 3. The thermal bulb 9 is washed by the water stream. When the temperature of the supplied water increases, the thermosensitive liquid (working fluid) in the thermowell 4 expands, passes through the channel 11 into the injection cavity on the piston 6 and moves it down, reducing the gap between the valve 7 and the seat 8, and, therefore, reducing the flow of hot water.

When lowering the temperature of the hot water supplied, the working fluid in the bulb 9 is compressed and the system works out in the opposite direction.

Thus, in the normal mode during the temperature control, the volume of the heat-sensitive liquid 10 in the injection cavity 15 of the power cylinder 13 under the adjustment piston 14 remains constant, and in the cavity of the thermowell 9 changes depending on the temperature of the controlled medium.

While the pressure regulator 12 operates as follows. In both versions of the adjustment device 12, changing the position of the adjusting piston 14 is performed by the compression force of the spring 19 (28): either by means of a spring-loaded rod 17 (FIG. 3) or by means of a spring-loaded valve 27 (FIG. 4). In this case, the compression force of the spring 19 (28) after installing the adjusting piston 14 in the initial state provides the pressure of the working fluid 10 corresponding to the standard one.

When using a spring-loaded rod 17, the adjustment piston 14 is set to its original position by screwing the lower part of the housing 20 outside onto the power cylinder 13. As a result, the pressing force of the disk 18 of the spring rod 17 against the adjustment piston 14 is adjusted.

When using a spring-loaded safety valve 27 (Fig. 4), the adjusting piston 14 is set to its original position by screwing the nut 29 on top of the power cylinder 13. As a result, the pressure of the valve 27 against the piston 14 is adjusted.

In case of a sudden pressure jump in the thermowell 9, for example, due to overheating of the working fluid, the safety valve 27 is wrung out (Fig. 4) and opens a through axial hole 26 in the adjustment piston 14, in communication with the internal cavity made in the piston 14. As a result, it increases the volume of the injection cavity 15 of the piston 14, into which the excess working fluid from the bulb 9, resulting from a pressure surge, enters.

The movement of the safety valve 27 in the piston 14 is possible due to the fact that the valve 27 consists of upper and lower parts, which are interconnected at a distance from each other along the axial piston 14 by a spring 28. In this case, the upper part of the valve 27 abuts against the nut 29 screwed on top to the power cylinder 13. When the spring 28 is compressed under the action of excessive pressure of the working fluid 10, the parts of the valve 27 come together, opening a through axial hole 26 in the piston 14 for the working fluid 10 to pass through it into the cavity made in the upper part piston 14.

The adjustment piston 14 with a spring-loaded stem 17 works similarly. When the pressure jump in the thermowell 9, the rod 17 is pressed by the adjusting piston 14, which increases the volume of the discharge cavity 15 under the adjusting piston 14, into which the excess working fluid from the thermowell 9, resulting from the jump pressure. The movement of the spring-loaded piston 17 in the housing 20 under the action of the spring 19 is possible due to the fact that the upper part of the housing 20 is covered with a cover 21 in the form of a cylinder, the side walls of which are supported by a stepped circular recess made along the outer circumference of the housing 20, and in the middle part of the cover 21 along the axial hole is made with a thread for fixing the free end of the rod 17, which is locked with a nut 22.

Claims (4)

1. The temperature controller, comprising a housing with pipelines for supplying and discharging water, a cylinder located in the housing with a piston of a locking device, which lower end is connected to the locking body; a saddle integrated in the housing and a continuation of the pipeline for supplying hot water; a thermal bulb with a working fluid communicated over the piston of the locking device with its discharge cavity and interacting with a controlled flow of water; an external fluid pressure regulator installed outside the housing, comprising a power cylinder with an adjusting piston equipped with a mechanism for its extension, while the discharge cavity under the adjusting piston is in communication with a thermowell, characterized in that the working fluid pressure regulator is capable of depressing the adjusting piston upward during a pressure jump the working fluid in the bulb, in addition, the locking device is a valve in the form of a disk, the diameter of which exceeds the diameter of the seat, fixed minutes at the lower end of the piston of the locking device, the upper end of the rod is withdrawn out of the temperature regulator body to a length equal to the maximum value of the gap between the valve seat and the valve. 2. The temperature regulator according to claim 1, characterized in that a spring-loaded rod interacting with the adjustment piston is inserted into the pressure regulator of the working fluid, the end of which interacts with the piston in the form of a disk whose diameter exceeds the diameter of the adjustment piston, in addition, spring-loaded the rod is placed in a hollow cylindrical body, the inner diameter of which provides movement of the rod disk with force, in addition, the rod body in the lower part is threaded and wound externally onto the power cylinder, when m upper casing cover is covered in a cylindrical shape, the side walls of which are supported on a stepped circular recess formed on the outer circumference of the housing at a middle portion of the cover formed on an axial threaded hole for fixing the free end of the rod which nut is doubled. 3. The temperature controller according to claim 2, characterized in that in the upper part of the adjusting piston an open axial cavity is made in the form of a cup facing the bottom towards the discharge cavity of the adjusting piston and communicating with its discharge cavity through the through axial channel made in the piston closed with a plug on the side of the upper axial cavity. 4. The temperature regulator according to claim 1, characterized in that in the pressure regulator inside the upper part of the adjustment piston, an axial cavity is made in the form of a body of revolution having a cone in the lower part that communicates with the injection cavity of the adjustment piston through the through axial channel made in it, a safety valve is installed in the cavity, consisting of the upper and lower parts, with a side surface congruent to each side of the cylindrical surface of the cavity, the upper and lower parts of the valve are connected each other at a distance from each other along the axial adjusting piston by a spring, while the lower part of the valve has the shape of a cone, the apex of which overlaps the through axial channel of the adjusting piston, and the upper part of the valve abuts against a nut screwed onto the power cylinder from above, and the nut is made in the form of a cylindrical cover, on the inner side surface of which a thread is made.