RU2537658C1 - Three-way valve - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: valve has the housing 1 with input 3, output 4 and offtake branch pipes 5. Between internal hollow of the housing 1 and output 4 and offtake branch pipes 5 the seats 6, 7 are located. The housing 1 has a valve block with the valve trays 8, 9, installed on a rotary lever 10 with a possibility of contact of the tray 8 with the seat 6 in one extreme angular position of the rotary lever 10 and the tray 9 with the seat 7 in the other extreme angular position of the rotary lever 10. The axis 11 of the lever 10 is located between output 4 and offtake branch pipes 5 perpendicularly to the plain with the axes of these branch pipes. On the housing 1 fitting is installed, through which in parallel to axis 11 a movable rod of the valve block moving device passes The named facilities also contain the motion booster in the form of double-shoulder lever. The named rod from one end interacts with a heat head thruster, and from another one - with the smaller shoulder of the double-shoulder lever. The greater shoulder of the double-shoulder lever passes through a sealing element. The double-shoulder lever is spring-bias towards the side of pressing of the valve tray 8 to seat 6, adjacent to the output branch pipe 4.

EFFECT: improvement of accuracy of temperature regulation, lowering of hydraulic resistance to the heat carrier flow and improvement of convenience of valve operation.

5 cl, 3 dwg

Description

The invention relates to control valves, in particular to three-way valves for connecting water heating appliances with the possibility of controlling the degree of their heating.

A multi-way thermostatic valve is known from RU 96220 U1 for a single pipe heating system with heating devices (radiators or convectors) supplying and discharging coolant from heating devices by pipelines. This valve contains a housing with inlet and two outlet pipes, a locking element, a partition with a saddle of the locking element, dividing the passage channel of the housing into two cavities, one of which is made with an adjustable cross section of the coolant passage, and the other cavity is made full passage as when placing the locking element on the saddle , and when it is raised with the possibility of providing a constant unobstructed communication of this cavity with a bypass and with a pipe that removes the coolant from the heater through PTO of the second outlet pipe.

The known valve has a simple design and has a low hydraulic resistance, which does not require the presence of a circulation pump in the heating system.

However, such a valve is intended for installation in heating systems of houses with a storey of more than 8. This is due to the fact that in high-rise buildings the total flow rate of the coolant in the system is quite large, and the ratio of the costs “heater / bypass” specified in RU 96220 U1 (20- 25 / 80-75) ensures the passage through the heater of the amount of coolant that does not allow its excessive “cooling” at reasonable values of the area of the radiating surface of the heater.

In low-rise buildings, the total coolant flow in heating systems is much lower. For example, in a 4-storey building it is 6 times smaller than in a 24-storey building with the same layout. In a low-rise building, 20-25% of the coolant passing through the heater is not enough to heat the room (even with a significantly increased area of the heater) and maintain the temperature of the "return" to the temperature schedule regulated by SNiP. Although the document RU 96220 U1 indicates the possibility of changing the ratio of costs by changing the internal dimensions of the valve, however, such a change is limited to 15-35 / 85-65 (see V.N. Karpov "Water heating systems of multi-storey buildings. Technical design recommendations" , M., ABOK-PRESS, 2010, chapter 2). Essentially, the only internal size of the valve that can be changed is the area of the bore, since the pipeline supplying the coolant to the heater has a standard section, and the internal volume of the valve itself has practically no effect on the flow ratio. Theoretically, this ratio can vary in the range of 0-35 / 100-65. The 0/100 ratio corresponds to a fully closed thermal valve, when the entire flow goes through the bypass, which, in turn, imposes restrictions on its throughput both from above and from below, because the amount of working coolant flow for each building is strictly regulated.

From the document RU 118007 U1, a three-way valve for connecting a water heating device is known, comprising a housing with an inlet, outlet, outlet and valve nozzles, as well as a controllable valve block with a sleeve, a stem and a valve disc. The inlet and outlet pipes are located on the same axis and are separated by a solid partition, the axis of the outlet pipe is located at right angles to the axis of the inlet and outlet pipes and communicates with the cavity of the inlet pipe, and the axis of the valve pipe is perpendicular to the plane of the axes of the inlet, outlet and outlet pipes, and its the cavity communicates through an opening located along the axis of this cavity with the cavity of the inlet pipe, and also through the channel with the cavity of the outlet pipe. On the surface of the inlet pipe inside the cavity of the valve pipe around the hole in the cavity of the inlet pipe, a valve seat is made to fit the valve plate, and the stem of the controlled valve block is mounted in its sleeve with the possibility of reciprocating movement with the protrusion of one end on one side of the sleeve and with the protrusion of the second end on the other hand, on which the valve disc is fixed, the rod being spring-loaded in the sleeve in the direction of pushing the first end out of the sleeve. At the same time, the sleeve of the controlled valve block is rigidly fixed in the valve pipe of the housing with the possibility of contact of the valve plate with the valve seat when moving the rod into the housing and is made with an external thread section for fixing the valve control element.

The design of the known valve will allow it to be connected to a single-pipe heating system with the formation of a bypass section and has sufficient reliability both during operation and at the commissioning stage, while ensuring accuracy of adjustment with a minimum variation in adjustment parameters between products of the same series.

However, such a valve has the same drawbacks as described above. The inability to provide an inflow coefficient (the ratio of the amount of coolant passing through the heater to the total flow through the branch of the heating system) of more than 35% is characteristic of all single-valve valves (see the book by V.N. Karpov mentioned above), which limits the scope of their application.

In addition, due to the large number of turns and brakes of the coolant flow in a valve of this design, a significant pressure loss occurs on it, which further reduces the coefficient of coolant leakage into the heating device and, as a result, leads to the need for an excessive increase in the area of the radiating surface of the heating devices and excessive cooling of the "return".

Closest to the valve according to the present invention is a three-way valve company HERZ ARMATUREN GmbH (Austria) Herz CALIS-TS-RD DN25, 776140 (http://herz-armaturen.ru/three-way-valves/l-7761-39/7sphrase id = 32835).

This valve comprises a housing with an internal cavity and with inlet, outlet and outlet pipes, a first seat located between the internal cavity of the housing and the outlet pipe, a second seat located between the internal cavity of the housing and the outlet pipe, a valve block including the first and second valve plates mounted on the movable element with the possibility of contact of the first plate with the first saddle in one extreme position of the movable element and the second plate with the second saddle in the other extreme position of the movable element, means of moving the valve block and means of sealing the internal cavity of the housing. In this case, the valve block is spring-loaded in the direction of pressing the second plate to the second saddle, and the means for moving the valve block include a movable stem emerging from the housing, which is configured to interact with the control element.

When using this valve in its initial position, the entire coolant flow through the first seat goes to the outlet pipe connected to the convector. When the temperature in the room rises, the control element acts on the rod, moving it down, thereby covering the flow through the first saddle to the outlet pipe and opening the flow through the second saddle to the outlet pipe. With a significant increase in temperature, the first plate completely covers the first saddle, and the entire flow of coolant flows through the second saddle to the outlet pipe. As the convector cools down, the room temperature decreases, the pusher of the control element ceases to act on the rod, and under the action of the spring, the movable element carrying the plates returns to its original state, as a result of which the coolant again enters the outlet pipe, heating the convector, etc.

This valve allows you to ensure the flow of heat through the heater and bypass in the ratio of 0-100 / 100-0, which makes it possible to use it in low-rise construction. However, due to the limited travel of the control element of thermostatic heads of any type (0.22-0.36 mm / ° C), the movement of the movable element of the valve block, and therefore the valve plates, is also very small. Thus, even in a fully open state (the valve block is in one of the extreme positions), the hydraulic resistance of the valve is very significant. Numerous braking and rotation of the coolant flow also contribute to an increase in hydraulic resistance.

All this leads to large pressure losses in the branches of the heating system and the very likely need for a circulation pump in the system.

In addition, in all the examined valves, the magnitude of the static pressure of the coolant has a significant impact on their operation due to the direct influence of the working medium on the valve stem.

Also, all these designs require periodic replacement of the sealing element due to its abrasion due to the translational movement of the rod. In this case, wear of the sealing element can lead to leakage of the coolant.

The objective of the invention is to remedy these disadvantages, in particular the creation of a simple and reliable valve design, providing increased accuracy of temperature control, reducing hydraulic resistance to the flow of coolant and ease of operation.

This problem is solved in a three-way valve containing a housing with an internal cavity and with inlet, outlet and outlet pipes; a first saddle located between the inner cavity of the housing and the outlet pipe; a second saddle located between the internal cavity of the housing and the outlet pipe; a valve block including first and second valve plates mounted on the movable element with the possibility of contact of the first plate with the first seat in one extreme position of the movable element and the second plate with the second seat in the other extreme position of the movable element, the valve block being spring loaded in the pressure direction a second plate to the second saddle; means for moving the valve block, including a movable stem emerging from the housing, configured to interact with a control element; and means for sealing the internal cavity of the housing.

According to the invention, the movable element of the valve block is made in the form of a pivot arm mounted in the housing with the possibility of rotation around an axis located between the outlet and outlet branch pipes perpendicular to the plane in which the axes of the outlet and outlet branch pipe lie; valve plates are installed on both sides of the lever relative to its longitudinal axis; the movable rod of the valve block moving means is located substantially parallel to the axis of rotation of the lever and passes through a fitting mounted on the valve body; and the means of moving the valve block contain a power amplifier in the form of a two-shoulder lever mounted on an axis located in the non-fluid cavity essentially parallel to the longitudinal axis of the lever in its middle position, the larger shoulder of the two-shoulder lever is passed through the sealing element into the internal cavity of the housing and is kinematically connected with its end to by a rotary lever, and the smaller shoulder of the two-shouldered lever contacts the movable stem, while the valve block is spring-loaded by means of a spring installed in a non-liquid and interacting with a two-arm lever.

The implementation of the valve according to the invention, providing a ratio of the flow rate of the coolant through the heater and the bypass 0-100 / 100-0, allows to reduce the hydraulic resistance to the flow of the coolant due to the reduction in the number of turns and braking flow, as well as significantly reduce the effect of static pressure on the operation of the valve due to the execution element of the valve block in the form of a rotary lever passing into the internal cavity of the housing through the sealing element. In addition, this design of the movable element eliminates the need for periodic maintenance of the valve during operation due to the lack of translational movement of the movable element of the valve block relative to the sealing element and abrasion of the latter, while ensuring reliable separation of the liquid and non-liquid cavities.

Preferably, the inlet and outlet nozzles are located along one axis, and the axis of the outlet nozzle is perpendicular to the axis of the inlet and outlet nozzles, which minimizes hydraulic resistance to the flow of the coolant.

The sealing element can be made in the form of a corrugated membrane or bellows, which allows you to reliably seal the non-liquid cavity of the valve with minimal efforts to counter the movement of the means of moving the valve block.

The kinematic connection of the larger shoulder of the two shoulders of the lever with the pivot arm can be carried out by means of a fork formed at the end of the specified shoulder, covering the pivot arm.

The invention is illustrated by drawings.

Figure 1 shows a three-way valve according to the invention, a sectional view;

figure 2 is a section along aa in figure 1;

figure 3 is a section along BB in figure 1.

The three-way valve contains a housing 1 with an internal cavity 2 and with inlet, outlet and outlet pipes 3, 4 and 5, respectively. The inlet and outlet nozzles 3 and 4 are located along one axis, and the axis of the outlet nozzle 5 is perpendicular to the axis of the inlet and outlet nozzles 3 and 4. In the housing 1, between the inner cavity 2 of the housing and the outlet nozzle 4 there is a first seat 6, and between the inner cavity 2 the second saddle 7 is located in the housing and the branch pipe 5. In addition, a valve block is installed in the housing 1, which includes the first and second valve plates 8 and 9 mounted on the movable element in the form of a rotary lever 10. The lever 10 is installed in the housing 1 with zmozhnostyu rotation about an axis 11 situated between the outlet and the branch pipes 4 and 5 perpendicular to the plane in which lie the axes of these nozzles. Valve plates 8 and 9 are installed on both sides of the lever 10 relative to its longitudinal axis, so that in one extreme position of the lever 10, the first plate 8 is in contact with the first seat 6, and in the other extreme position of the lever 10, the second plate 9 is in contact with the second seat 7.

The three-way valve also contains means for moving the valve block, including a movable stem 12 and a power amplifier in the form of a two-shouldered lever 13 mounted on an axis 14 located essentially parallel to the longitudinal axis of the lever 10 in its middle position. The larger shoulder 15 of the two shoulders of the lever 13 through the sealing element 16 is passed into the inner cavity 2 of the housing 1 and contains at its end a fork 17 covering the pivot arm 10, thereby providing kinematic communication with the pivot arm 10. The smaller shoulder 18 of the two shoulders of the arm 13 is in contact with the rod 12 which is installed in the fitting 19, mounted on the housing 1, with the possibility of longitudinal movement essentially parallel to the axis 11 of rotation of the lever 10. The two-arm lever 13 is spring-loaded in the direction of pressing of the second plate 9 to the second seat 7, for example er by a helical spring 20 compression. The sealing element 16, made in the form of a corrugated membrane or bellows, separates the non-liquid cavity from the inner cavity 2 of the valve so that the axis 14 on which the two-arm lever 13 is mounted is located in the non-liquid cavity.

On the fitting 19 is also installed a control element in the form of a thermostatic head 21, the pusher of which is in contact with the rod 12.

The three-way valve operates as follows.

In the position shown in FIG. 1, the three-way valve is in an intermediate state, and the coolant flow supplied to the inlet pipe 3 is distributed between the convector and the bypass, passing through the outlet and outlet pipes 4 and 5.

With increasing temperature, the thermostatic head 21 acts with its pusher on the movable rod 12 (Fig.2), moving it in the direction shown by arrow c. The rod 12, interacting with the smaller shoulder 18 of the two shoulders of the lever 13, transfers the movement of the pusher of the thermostatic head 21 to the larger shoulder 15 of the two shoulders of the lever 13, providing movement of the plug 17 in the direction shown by the arrow g (Fig.1, 2). The fork 17, interacting with the pivoting arm 10, rotates it, thereby bringing the first valve disc 8 closer to the first seat 6 and moving the second valve disc 9 away from the second saddle 7. In this case, the flow rate of the coolant through the convector decreases, and through the bypass increases. As a result, the convector cools down, the temperature in the room drops, the working fluid in the thermal head 21 decreases in volume, and its pusher stops pressing on the movable rod 12. Under the action of the spring 20, the two-arm lever 13 moves in the direction shown in Fig. 2 by the arrow ∂, bringing the second valve plate 9 to the second saddle 7 and moving the first valve disc 8 away from the first saddle 6. This increases the flow rate of the coolant through the convector, which leads to its heating and, as a result, to an increase in room temperature. The process proceeds cyclically and continuously, ensuring that the temperature in the room is maintained in accordance with the set value determined by the selected position of the control element of the thermostatic head.

Although the operation of a three-way valve is described in its interaction with a thermostatic head, the valve according to the invention can also be used in combination with other control elements, for example with a thermoelectric actuator or with a control element in the form of a manually operated handle.

Claims (5)

1. Three-way valve containing a housing with an internal cavity and with inlet, outlet and outlet pipes; a first saddle located between the inner cavity of the housing and the outlet pipe; a second saddle located between the internal cavity of the housing and the outlet pipe; a valve block including first and second valve plates mounted on the movable element with the possibility of contact of the first plate with the first seat in one extreme position of the movable element and the second plate with the second seat in the other extreme position of the movable element, the valve block being spring loaded in the pressure direction a second plate to the second saddle; means for moving the valve block, including a movable stem emerging from the housing, configured to interact with a control element; and means for sealing the internal cavity of the housing, characterized in that the movable element of the valve block is made in the form of a pivot arm mounted in the housing with the possibility of rotation around an axis located between the outlet and outlet branch pipes perpendicular to the plane in which the axes of the outlet and outlet branch pipe lie; valve plates are installed on both sides of the lever relative to its longitudinal axis; the movable rod of the valve block moving means is located substantially parallel to the axis of rotation of the lever and passes through a fitting mounted on the valve body; and the means of moving the valve block contain a power amplifier in the form of a two-shoulder lever mounted on an axis located in the non-fluid cavity essentially parallel to the longitudinal axis of the lever in its middle position, the larger shoulder of the two-shoulder lever is passed through the sealing element into the internal cavity of the housing and is kinematically connected with its end to by a rotary lever, and the smaller shoulder of the two-shouldered lever contacts the movable stem, while the valve block is spring-loaded by means of a spring installed in a non-liquid and interacting with a two-arm lever. 2. The valve according to claim 1, characterized in that the inlet and outlet nozzles are located along one axis, and the axis of the outlet nozzle is perpendicular to the axis of the inlet and outlet nozzles. 3. The valve according to claim 1, characterized in that the sealing element is made in the form of a corrugated membrane. 4. The valve according to claim 1, characterized in that the sealing element is made in the form of a bellows. 5. The valve according to claim 1, characterized in that the kinematic connection of the larger shoulder of the two shoulders of the lever with a rotary lever is a fork formed at the end of the specified shoulder, covering the rotary lever.

Images