RU2072465C1 - Heat supply system temperature controller - Google Patents

Abstract

FIELD: heating systems; water radiators. SUBSTANCE: temperature controller has journalled cock and thermostat connected with cock by means of union nut. Cock has spring-loaded stem with shutoff member engaging with seat. Thermostat has temperature converter in form of bellows fitted by one end in thin-walled housing and forming a ring space with the housing. Ring space is filled with vapor-and-liquid working medium. Other end of bellows is made blind. Bellows accommodate compression spring resting on cover of thermostat housing and relieving the bellows from pressure. Pressure stem is mounted in central hole of cover for reciprocating. Thickness of compression spring coils and their pitch are selected to provide mechanical stop preventing closing of bellows goffers. EFFECT: improved reliability of operation. 2 cl, 2 dwg

Description

 The invention relates to temperature controllers for a heating heat supply system, in particular to bellows-type temperature controllers installed on water heating radiators.

 Known temperature regulator for the heating system (ed. St. USSR N 1104475), comprising a housing, heat-sensitive bellows and valve. The body of the device is made with a partition dividing it into chambers, a heat-sensitive bellows is installed in the first chamber, which is connected to a valve installed in the second chamber above the seat made in the partition, each of the chambers is equipped with an inlet pipe, each of which is connected through a corresponding pipeline to a control valve with a direct pipe of the heating system from the heating network, the first chamber being equipped with an outlet pipe connected to a direct pipe of the heating system for connecting tion to the consumer.

The disadvantages of the device include:
thermosensitive bellows measures the temperature of the water directly;
unsuccessful housing design possible leaks.

 Another temperature regulator for the heating system (ed. St. USSR N 1596192) is also known, consisting of two chambers, two pipes from the hot water supply line and to the return heating network are suitable for the first chamber, the second camera is connected to the direct heating network, between the first and the second chambers have a regulating body made in the form of a nozzle and a throttle needle connected to a thermo bellows connected to an adjusting element, a thermo bellows is placed in a third chamber, the input of which is connected to a pipe connected to the feed water supply, and exit with the first camera.

 The disadvantage of this regulator is that the thermosilphon measures directly the water temperature.

 Closest to the proposed one is a thermostat for a heating heating system, a description of which is given in the brochure of the Danish company Danfoss (Technical Description VD.53.P3.SO Danfoss 7/93, Moscow, 1993, p. 9, 13).

 This thermostat contains a valve valve and a thermostat connected to it by means of a union nut, while the valve valve has a spring-loaded stem with a valve in contact with a seat located inside the valve cavity, and the thermostat has a thermal converter installed in its body, which includes a thin-walled valve sealed from one end bellows housing, forming together with the housing an annular cavity filled with a vapor-liquid working fluid and having a blind bottom on the other hand, a pressure rod for axial stress from the bottom of the bellows arising from the varying pressure on the bellows of the vapor-liquid working fluid, and the transfer of forces to the spring-loaded stem of the valve cock and the compression spring that unloads the bellows and spans the rod. In this design, the spring is compressed when the valve overlaps the opening to an increasing degree, which prevents the overlap. To prevent damage to the bellows at high temperatures, a special mechanical stop has been introduced, which complicates the design of the thermostat and increases its volume, and the valve stem stroke is relatively small, which allows the use of a thermostat in heating heating systems with lower heat carrier (water) consumption and a high degree of purification.

 All this in general reduces the reliability of the use of such temperature controllers under unstable operating pressure in heat supply systems and water of different composition and quality.

 The aim of the invention is to increase the reliability of the use of temperature controllers under conditions of unstable working pressure in heat supply systems and water of different composition and quality, to prevent the probability of bellows breakage due to abnormal temperature increases, pollution and a possible reduction in valve valve capacity.

 The goal is achieved in that the thermostat contains a valve and a thermostat connected to it by means of a union nut, while the valve has a spring-loaded stem with a shut-off element in contact with a seat located inside the valve cavity, and the thermostat has a thermal converter installed in its body, including a hermetically sealed from one end into a thin-walled housing, a bellows, forming together with the housing an annular cavity filled with a vapor-liquid working fluid and having a blind bottom on the other hand, is pressurized a rod for perceiving axial forces from the bottom of the bellows arising from the varying pressure on the bellows of the vapor-liquid working fluid, and transferring these forces to the spring-loaded stem of the valve cock and the compression spring unloading the bellows and covering the rod; according to the invention, the compression spring unloading the bellows is located inside the latter and is locked by means of a cover connected to the thermostat housing, while the compression spring unloading the bellows is supported by the cover and the thickness of the spring turns and their pitch are selected so that it is fully compressed forms a mechanical stop preventing the bellows corrugation from being folded, the lid having a central hole, and the pressure rod mounted with the possibility of reciprocating movement in the lid opening.

 A rotary nozzle sealed with rubber rings is installed coaxially with the stem with a locking member, the end part of which is a cylindrical sleeve, at the end of which there is a recess with a helical surface located opposite the cavity for the coolant to exit the valve, and the locking member is located inside the sleeve , and the maximum height of the latter is selected from the condition of ensuring free movement of the valve inside the sleeve with free and fully compressed states of the compression spring, zhayuschey bellows.

 In FIG. 1 shows a temperature controller; in FIG. 2 the same, without a thermostat (temporarily removed for replacement or diagnostics).

 The temperature controller for the heating heat supply system (Fig. 1) comprises a valve tap 1 and a thermostat 2 connected by a union nut 3. The thermostat 2 is fixed relative to the valve tap 1 in the circumferential direction by means of a notch 4 made on the corresponding mating surfaces of the valve tap 1 and thermostat 2. Valve 1 includes a housing 5, which is a tee with nozzles for input 6, output 7 of the coolant (hot water) and the placement of the regulatory body 8. Pipes for input 6 and the coolant outlet 7 is located coaxially and separated by a partition 9 located at the level of the common axis of the input 6 and output 7. The partition 9 forms a hole 10. The regulating body 8 consists of a rotary nozzle 11, in the axial hole of which there is a rod 12 and a locking element 13 fixed thereon .

 The hole 10 is made coaxially with the thermostat 2 and, at the contact with the locking member 13, forms a saddle under the locking member 13. The rod 12 is axially spring loaded with a compression spring 14 resting on the support washer 15. The support washer 15 is held on the rod 12 by means of a spring retaining ring 16. The rod 12 and the nozzle 11 itself are sealed with round rubber o-rings 17, 18. The sealing ring 18 at the junction of the rod 12 and the nozzle 11 is sealed in the nozzle 11 along its inner cylindrical surface with a washer 19, which in turn is fixed The nozzle 11 is designed to pre-control the flow of coolant through the outlet pipe 7 of the valve cock 5. The end part 21 of the rotary nozzle 11 is a cylindrical sleeve at the end of which a recess is made with a helical surface 22. End 23 rod 12 is made in the form of a sphere to prevent mashing and distortions on the part of the moving organs of the thermostat 2. Duza 11 is fixed in the housing 5 of the valve valve 1 with the washer 24 and ruzyne split ring 25. At the end of the nozzle 11 facing outwardly from the closure member 13 is applied radial needle (not shown) indicating the direction of rotation for regulation of the passage opening. A nozzle 26 is put on the nozzle 11, rigidly fixed inside the cavity of the valve valve 1, designed to accommodate the regulating body 8. A circular arrow (not shown) is applied to the outer end of the sleeve 26, showing the direction of rotation of the nozzle 11 to change the flow rate of the coolant.

 The thermostat 2 consists of a housing 27, a handle 28 and a thermal converter 29. The housing 27 is a hollow cylinder with a thread 30 on the inner surface. To connect with parts of the valve tap, the body 27 of the thermostat 2 has an annular base, at the end of which a gear notch 4 is made, corresponding to the notch of the valve tap. By placing the teeth of the notches of the thermostat 2 in the cavities between the teeth of the notches of the valve valve 1 and, conversely, by tightening with the union nut 3, the valve valve body is reliably connected to the thermostat. An annular gap 31 of the housing serves to accommodate and freely move the skirt 32 of the handle 28. An axial hole is provided in the housing 27 to center and freely move the sleeve 33. The handle 28 is used to set the desired operating mode by moving the movable elements relative to the seat of the locking member 13. The handle 28 represents a hollow cylindrical part with a thread 30, providing movement relative to the housing 27 in the axial direction, and a skirt 32 on which a scale is applied (not shown). The combination of the scale of the skirt 32 with the limb on the body 27 (not shown) determines the position of the movable elements of the thermostat 34 relative to the seat 35 of the locking member 13. The skirt 32 is fixed on the handle 28 with a screw 36 in a position that provides the initial position of the scale with the valve fully closed. To improve heat transfer with the environment, the handle 28 has longitudinal slit-like cutouts 37. In the cavity of the handle, the heat transfer 29 is installed in the shoulder 38 through the washer 39. Its fixation in the cavity of the handle 28 is made using the cover 40 and the washer 41. The cover 40 is moved and fastened in the handle on the thread 42. The temperature transducer 29 is used to move the movable elements 34 of the thermostat depending on the ambient temperature. The temperature transducer 29 consists of a thin-walled case 43, in which a corrugated bellows 44 with tips 45 and 46 is installed, while the tip 45 is rigidly fixed (welded) relative to the case 43, and the tip 46 has the ability to move relative to the case 43 in the axial direction.

 The cavity formed by the outer surface of the bellows 44 with the inner surface of the housing 43 is filled with a vapor-liquid working fluid (PRT) 47. The tip 46 is rigidly connected (welded) with a threaded sleeve 50, which has a threaded hole 48 for fixing the pressure rod 49. The rod 49 is mounted on it threaded sleeve 33 acts on the stem 12 of the valve valve. A compression spring 52 is placed and fixed inside the bellows by the cover 51. The cover 51 has a central opening relative to which the pressure rod 49 moves. The spring 52 compensates for the lack of rigidity of the bellows 44 and prevents it from “folding” at high operating pressure levels of PRT 47. PRT 47 is hydrocarbon compound, the state of aggregation of which is determined by the presence of both liquid and its vapor. The amount of matter of each state of aggregation is determined by the equilibrium of the processes of evaporation and condensation and is in a strictly defined dependence on the heating temperature PRT 47.

 The temperature controller for the heating system can be disassembled to replace the thermostat 2. In this case (Fig. 2), a cover 53 is temporarily installed in place of the thermostat 2, having a mating thread on the inner surface. The cover 53 allows manual control by moving the rod 12 when the spherical tip 23 is in contact with the counter-protrusion 54 inside the cover 53. By screwing or unscrewing the cover 53, manual control can be performed before replacing the thermostat 2.

 The temperature controller for the heating heating system works as follows (figure 1).

 Desiring to set a certain temperature in the room, the consumer rotates the handle 28 of the thermostat 2, thereby setting the desired scale division relative to the body limb 27. Thereby, a certain position of the locking member 13 relative to the seat 35 is set, adjusting the temperature regulator and the size of the valve cross-section and, accordingly, flow rate coolant.

 In this tuned state, the thermoconverter, when exposed to ambient air, changes its temperature, as a result of which the vapor pressure of the PRT changes and the movable elements of the thermostat, and therefore the regulating body 8, move relative to the seat 35. The flow cross section of the valve valve of the thermostat that changes at the same time determines a new flow heat carrier through the heating device and means its temperature.

 A change in the heat transfer of the heater affects the air temperature in the room, the latter on the temperature of the PRT 47 of the thermocouple, which leads to a new return movement of the shut-off member 13. The cycle is repeated again.

 Thanks to such reciprocating movements of the locking member 13, a certain equilibrium is established between the temperature in the room and the position of the locking member 13 relative to the seat 35. As a result, such a position is established relative to the seat 35, in which the heat transfer mode set by the consumer is ensured by setting the thermostat handle to the required position. To fill the PRT thermoconverter, a small diameter 55 non-ferrous soft metal tube was used, which is bent and sealed after filling to the required pressure.

 The principle of operation of the thermostat is as follows. The consumer sets the rotation of the handle 28 to the desired thermal conditions in the room. The rotation of the handle 28 causes its axial movement and lowering (or raising) of the heat transducer 29. Through the rod 49, the threaded sleeve 50 and the rod 12 of the valve valve 1, the movement is transmitted to the locking element 13. As it approaches the seat 35 of the hole 10, the force on the movable elements ( 12, 13, 33, 49, 50) the thermostat increases, the flow rate of the coolant through the hole 10 drops and vice versa. In the selected position of the handle 28 of the thermostat, with the corresponding values of the acting forces, their static equilibrium is achieved by establishing a certain pressure difference on the shut-off element 13, certain spring compressive forces 14 and 52, and PRT 47 pressure forces. When the ambient temperature rises above a predetermined consumer, heating and pressure increase PRT 47. The bellows 44 is compressed, moving the threaded sleeve 50, the rod 49, the threaded sleeve 33, the rod 12 and the locking element 13 in the direction of overlapping the bore Version 10. The flow rate of the coolant decreases, which after some time will lead to a decrease in the temperature in the room to the one set by the consumer. If the temperature in the room becomes lower than set by the consumer, the pressure PRT 47 will drop. The bellows 44 will expand and under the action of the spring 14, the system of moving elements (12, 13, 33, 49, 50) will move in the direction of increasing the bore of the opening 10. The flow rate of the coolant will increase, and after a while the temperature in the room will increase to the desired temperature.

 The design of the nodes of the thermostat provides high reliability. The spring 52 is locked in the housing of the thermocouple 29 using the cover 51, attached to the housing by screws. This determines the predetermined compression of the spring 52 during compression of the bellows, setting the design force to close the hole 10 by the locking member 13.

 The length of the spring 52, the thickness of its coils and the pitch of the coils are selected in such a way that at the maximum allowable compression of the bellows, the coils of the spring come into contact and a mechanical stop is formed, which prevents further compression of the bellows.

 The locking member is located inside the hollow cylinder, and the maximum height of the latter is selected from the condition of ensuring the free movement of the locking member inside the hollow cylinder when the compression spring unloading the bellows is free and fully compressed.

 Due to this, the stroke of the locking element has a reserve of movement, which allows the use of standardized designs for heat supply systems with different pipe diameters (from 1/4 to 1 inch). It also provides a high degree of protection against unauthorized growth of water pressure in the heating system due to the stock movement of the rod.

Claims (2)

 1. Thermostat for a heating heat supply system, comprising a valve and a thermostat connected to it by means of a union nut, while the valve contains a spring-loaded stem with a shut-off element that interacts with a seat located in the cavity of the valve body, equipped with coolant inlet and outlet nozzles, and a thermostat contains a thermoconverter installed in its housing, including a bellows sealed at one end into a thin-walled housing, which forms filled pairs with the thermostat housing with a fluid working medium, an annular cavity and made with a blind bottom from the other end, a pressure rod interacting with a spring-loaded valve valve stem, and a compression spring unloading the bellows and covering the rod, characterized in that the compression spring is installed inside the bellows and the thermostat housing is provided with a cover, forming a support for the compression spring, while the spring is made with a thickness of turns and a step, providing the possibility of the formation in a fully compressed state of the mechanical stop, preventing the folding of corrugations fona, wherein the cover has a central hole and a push rod mounted for reciprocating movement in the bore of the cover.  2. The temperature regulator according to claim 1, characterized in that the valve tap is equipped with a coaxially mounted rod with a locking element and a rotary nozzle sealed with rubber rings, a part of which is facing the saddle, made in the form of a cylindrical sleeve with a screw recess on the end side from the side facing the coolant outlet pipe, while the locking member is placed inside the cylindrical sleeve, made with a maximum height, providing free movement of the locking member in the sleeve with free and fully compressed state of the spring with Atia discharged bellows.

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