UA14745U - Temperature controller proposed by bozhok a.m. - Google Patents

Abstract

The proposed temperature controller is distinctive by that the temperature detector in the controller contains two bellows that are coupled with each other by a common movable flange and two bellows that are coupled with each other by a common fixed flange. The fourth bellow contains a fixed flange, which is coupled, via links, with the common movable flange of the first and the second bellows.

Description

Description of the invention

The useful model refers to the means of hydropneumatic automation and can be used in systems 2 of automatic regulation and control of energy systems and installations, objects of light, chemical, food, processing and other types of industry, as well as in ventilation installations, microclimate, test stands and in other in cases where it is necessary to automatically maintain the specified thermal level of the working environment.

A well-known vapor-liquid regulator of direct action of the remote type with a remote connection between the sensitive element 70 and the regulating body - type RTPD - 80 | see book Andrezen V.A. and others. Automation of ship, deenergizing installations and systems. L.: Shipbuilding, 1973, 320p. Fig. 114, p. 207-208). The sensitive element of this regulator is a thermal balloon. To reduce inertia and increase the surface of contact with the regulated environment, a tube is wound around the cylinder and connected to the thermal cylinder. A bellows chamber, a capillary and a thermoballoon are filled with filler, and a vapor space is left in the latter. The change in the vapor pressure of the filler 72 when the temperature changes is transmitted from the measuring element by a capillary to the bellows of the regulating body, ensuring the movement of the regulating valves. To adjust the regulator, a clutch is used, which changes the spring tension, and to change the degree of unevenness, a sleeve is used, which changes the working number of spring turns.

Manual control is performed by a handwheel connected to the control valves.

However, the disadvantage of the known thermoregulator is its low dynamic performance due to inertial thermal delay and the regulation principle embedded in it - according to the deviation of the regulated parameter.

Thus, the known thermostat has low dynamic accuracy and a limited scope of application. Therefore, in order to increase the dynamic accuracy of the regulation and expand the field of application, 22 improvements are proposed, the essential features of which are that the design of the thermostat includes additional links, which at the output form a regulatory signal proportional not only to the deviation of the regulated parameter, but also proportional speed (first derivative) and acceleration (second derivative) of the deviation of the regulated parameter and sum them up with the regulating signal proportional to the deviation of the regulated parameter, that is, the output movement of the regulating body of the thermostat in this case o will consist of the sum of three movements - the movement proportional to the change in the temperature "I (thermal) state of the working medium, displacement proportional to speed and displacement proportional to the acceleration of its change. -

The task is solved by the fact that in the proposed thermostat, two "I" links connected in series are additionally installed. At the same time, the first link forms a control signal proportional to the deviation and

The speed of temperature deviation, and the second link is a control signal proportional to the acceleration of the deviation -- the temperature of the working environment and summarizes the output signals.

The first link contains a second bellows, placed inside the first bellows, separated from each other by a medium, the coefficient of thermal conductivity of which is lower than the coefficient of thermal conductivity of the material of the walls of the bellows, while one end of the first and second bellows is rigidly connected to a fixed flange, and the other ends are connected to a common with a movable bellows flange with a bypass throttle opening for direct and reverse bypass of the working fluid from the cavity of the second bellows to the third.

From" To summarize the control signals proportional to the deviation of the temperature and the speed of its deviation, a fourth bellows is installed, placed inside the third, and one end of the third and fourth bellows is connected to a fixed flange, and the second end of the third bellows is directly connected to a common movable flange, and the second end of the third bellows - through the draft. The input of the first link is the deviation of the temperature of the regulated medium, and the output is the deviation of the pressure of the working fluid in the cavities of its "" second and third bellows.

The second link contains the fifth bellows, movable and fixed flanges hermetically connected to the ends of the fifth 7 bellows, the cylindrical guide of the movable flange rigidly connected to the fixed flange, the sixth bellows, one end of which is connected with a movable flange, and the second end - from the movable flange 4, to which the third bellows 5 is connected from the second end. The second end of the bellows 5 is connected to the fixed flange 6, to which the fourth bellows 7 is connected by one end, placed inside the third bellows 5 , the second end of the bellows 7 is connected to the movable flange 8. The flange 8 is connected to the axial point of the movable flange 4 by the axial point of the rod 9. 29 Cavity "a" formed by the first 2 and the second With bellows, as well as the fixed 1 and with movable 4 flanges is filled with a medium (for example, air or another substance), the coefficient of thermal conductivity of which is lower than the coefficient of thermal conductivity of the material of the bellows walls.

Cavity "c", formed by the second bellows 3, fixed 1 and movable 4 flanges, as well as cavity "c", formed by movable 4, 8 and fixed b flanges, third 5 and fourth 7 bellows are filled with a low-boiling bo liquid.

In order to bypass the easily boiling liquid from the cavity "c" to the cavity "c", which is necessary to ensure the disappearance of the component of the control signal at a certain speed in a steady thermal state, proportional to the speed of change in the temperature of the working medium, a bypass hole with an adjustable throttle 10 is made in the movable flange 4. Cavity "c" with capillaries 11, 12 connects directly with cavity "e", and with cavity "a" -

capillaries 11, 13 and adjustable throttle 14.

Cavity "a" is formed by a fixed flange 15 connected to one end, the fifth bellows 16 and a movable flange 17, to which the opposite end of the fifth bellows 16 is connected, and cavity "is" is formed by a movable flange 17, connected connected to it by one end, the sixth bellows 18, the fixed flange 19 and the guide 20, in which the flange 19 is installed. The movable flange 17 moves in the guide 21, which is rigidly connected to the fixed flange 15 and the guide 20, in which the seventh bellows 22 is placed , connected at one end to the movable flange 23, and at the other end to the fixed flange 19. Inside the seventh bellows 22, an output rod 24 is installed, with one end of which a spring 25 is connected, ensuring the interaction of the rod with the 7/0 fixed flange 19. The second end of the spring 25 rests in the sleeve 26, changing the degree of unevenness of the adjustable parameter by changing the working number of its turns, and the clutch 27 of the thermostat setting.

Manual control of the thermostat is carried out by the handwheel 28, mounted on the rod 24, which moves in the guide 29, rigidly connected to the guide 20.

The rod 24 output from the seventh bellows 22 is connected to the middle part of the summing lever 30, one 7/5 end of which is connected to the movable flange 17 by a rod Z1, and the other end to the control valve 32.

The principle of operation of the proposed temperature regulator will be considered for the two most characteristic modes of operation of power plants: a) with a sharp change in the temperature of the regulated environment; b) when the temperature of the regulated environment slowly changes.

In the first case, with a sharp increase in the temperature of the regulated medium, due to the presence of thermal resistance of the medium in cavity "a", heating of the easily boiling liquid, and accordingly, its pressure in the second bellows C will increase more slowly than in the third bellows 5. As a result of the increase in temperature in the bellows 5, the low-boiling liquid from the cavity "c" through the capillaries 11, 12, as well as through the capillaries 11, 13 and through the throttle 14 will flow, respectively, into the cavities "a" and "e" in an amount proportional to the change in the temperature of the regulated medium. At the same time, due to the low pressure of the low-boiling liquid in the second bellows C, the movable flange 4 will move up more slowly, holding the movable flange 8 connected to it by the traction 9, thus increasing the pressure of the low-boiling liquid in the third bellows 5 by an additional value, providing an additional amount of low-boiling liquid from the cavity "c" into the capillary 11, which will be proportional to the rate of increase in the temperature of the regulated medium. Thus, in the transient process of increasing the temperature of the regulated medium, the pressure of the low-boiling liquid, and therefore, its quantity entering from the cavity "c" into the capillary 11 will consist of two pressures, i.e. "the output signal from the cavity "c" consists of from the pressure caused by the temperature increase of the regulated medium M (from the proportional heating and pressure increase of the low-boiling liquid in the cavity "c") and the pressure caused by the rate of temperature increase of the regulated medium (from the movement of the movable flange - 8, caused by the delayed heating of the low-boiling liquid in the second bellows 3, and additional, "- proportional to the rate of increase in the temperature of the regulated medium, the increase in pressure in the cavity "c").

The amount of low-boiling liquid entering from the cavity "c" into the capillary 11 under a common pressure proportional to the increase in the temperature of the regulated medium and the rate of its increase, further through the capillary "12 enters the cavity "Te" directly, and through the capillary 13 and the adjustable throttle 14th cavity "a", with c, increasing the pressure in them. However, due to the presence of the throttle 14, the pressure of the low-boiling liquid in the cavity "a" will increase more slowly compared to its pressure in the cavity "te", and therefore, it will move more slowly;" movable flange 17 in relation to flange 23. As a result, overcoming the forces of the spring 25, the movable flange 23 and the rod 24 interacting with it will move, simultaneously moving the middle part of the summing lever 30 and together with it, connected to its second end, regulating valves 32. This movement of valves 32 will be proportional to the change in the temperature of the regulated environment and the rate of its change.

In addition, due to the delay from the slow movement of the movable flange 17, through the rod 31 and the opposite end of the summing lever 30, the control valves 32 will receive an additional movement, which will be proportional to the acceleration of the temperature change of the regulated medium.

Thus, the resulting movement of the control valves in the transition process will consist of three component movements: the first movement, proportional to the change in temperature; the second sp displacement, proportional to the speed (first derivative) of temperature change; of the third movement, proportional to the acceleration (second derivative) of changing the temperature of the regulated medium.

As the temperature of the low-boiling liquid stabilizes (during the stabilization of the temperature of the regulated medium and its flow through the regulated throttle 10), and therefore its pressure in the cavities "b" and "c", the distance between the movable 4 and stationary b flanges will decrease. As a result, both the lower movable 4 and the movable flange 8, connected to it by a rod 9, will rise, increasing the volume of the cavity "c", and at the same time lowering the pressure of the low-boiling liquid in it by an amount proportional to component of the temperature rise rate of the regulated environment. And as the pressures in the cavities "v" and "c" equalize, as well as because the pressures of the low-boiling liquid in the cavities "a" and "c" connected to them are equalized and a steady thermal state is reached, the summing lever 30, due to the movement of the movable flange 17 and thrust 31, will take its horizontal position, thereby ensuring the disappearance of the second and third components of the movement of the control valves 32, proportional to the speed and acceleration of the change in the temperature of the regulated medium, and the valves will be in a position corresponding to the movement proportional only to the increase in the temperature of Her b5.

In case of a sharp decrease in the temperature of the regulated environment, the proposed thermostat will work similarly, but with the only difference that the initial movements of its moving parts will be directed in the opposite direction. | as the temperature of the low-boiling liquid stabilizes (when the lower temperature of the regulated medium is stabilized) and the pressure in the cavities "v", "c", a" and Te", the second and third components of the movement of the control valves will also disappear, but already proportional to the speed and acceleration of the lowering of the temperature of the regulated medium and finally the valves will be in a position corresponding to the movement proportional only to the lowering of its temperature.

In the second case, when the temperature of the regulated medium rises slowly, then the low-boiling liquid M in the cavities "b" and "c" heats up slowly, the result is the pressure of the low-boiling liquid in /0 of these cavities and cavities "a and te" will also increase with the same degree of slowness, which will cause a parallel movement of the summing lever, In this case, the proposed thermoregulator will work like a known thermoregulator, that is, its control valves will move proportionally only to the increase in the temperature of the regulated medium.

In the case of a slow decrease in the temperature of the regulated medium, the proposed thermostat /5 will also work similarly, ensuring the movement of the regulating valves in the reverse direction according to signals proportional only to the decrease in temperature of the regulated medium, that is, it will work like a known thermostat.

The degree of influence of the control signals on the speed and acceleration of the change in the temperature of the regulated medium can be adjusted by throttles 10, 14, respectively.

The use of the proposed thermoregulator, in comparison with the already known ones, will make it possible to: - reduce the time of the transition process and thereby reduce the time of stabilization of the thermal state of the regulated medium when it is transferred from one temperature level to another; - increase the speed of operation of the control valves and thereby increase the accuracy of automatic maintenance of the set temperature regime of the regulated environment; - to reduce the degree of non-uniformity of the temperature of the regulated environment, thanks to which it is more effective to protect power and other thermal installations from both hypothermia and overheating, as well as to improve the flow of technological processes; - to increase the initial technical and economic indicators of energy and other thermal installations due to the automatic maintenance of the optimal thermal state of their regulated environment in all user-loading and high-speed modes of operation; - to increase the reliability and durability of thermal power plants and technological equipment due to - increasing the dynamic accuracy of regulating their thermal state and thus expanding the scope of application of the proposed thermoregulator M. "

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Claims (1)

The formula of the invention -- A temperature regulator containing a temperature sensor with a capillary, a bellows of an output rod with fixed and movable flanges, connected to a capillary with a temperature sensor, a regulating body with an adjustment mechanism, interacting with " 0 The ear flange of the bellows, which differs in that the thermal sensor is made in the form of the first and second bellows with a common movable flange, connected to a fixed flange, which forms a cavity filled with a medium with a lower coefficient of thermal conductivity than the coefficient of thermal conductivity of the material :from the walls of the bellows, the third and fourth bellows, connected by one end to a common fixed flange, and the fourth bellows is connected by the second end to the movable flange, which is connected by traction together with the third bellows to the opposite end of the common movable flange of the first and of the second bellows, and he - additionally equipped with a fifth bellows, movable and fixed flanges rigidly connected to the ends of the fifth bellows, a cylindrical guide for the movable flange rigidly connected to the fixed flange, a sixth bellows, one end of which is connected to the movable flange, and the other end - with a cylindrical guide, - a rod, a summing lever, the middle part of which is connected to the output rod, one arm is connected by a rod to the 5r ear flange of the fifth and sixth bellows, and the other arm - to the regulating body , as well as the first and second ve regulating throttles, and the cavity of the second and third bellows is connected through the first regulating throttle, and the cavity of the third bellows - through the capillary with the cavity of the sixth bellows directly, and with the cavity of the fifth bellows - through the capillary and the second regulating throttle . p. 60 b5