RU103199U1 - TEMPERATURE REGULATOR AND COOLANT FLOW CONSUMPTION - Google Patents

Abstract

 1. The regulator of temperature and flow rate of the coolant flow in the pipeline, including a cylindrical body with inlet and outlet nozzles, while a saddle is installed in the inlet nozzle, and a regulating body is made in the body, made in the form of a hydraulic cylinder filled with a heat-sensitive fluid, a rod, one end of which is located in the hydraulic cylinder and is connected with the piston, and the second end is located in the housing and is connected with a shut-off valve mounted above the seat, characterized in that the housing is equipped with a removable cover and a second inlet th nozzle, on the outer surface of the cylinder formed or knurling or grooving, or placed wire or ribbon, shut off valve is mounted rotatably about its axis, while on the side surfaces of the check valve and the seat is provided with through holes, the total area are equal to each other. ! 2. The temperature and flow rate controller in the pipeline according to claim 1, characterized in that as a heat-sensitive fluid using a fluid with high volume expansion, such as brake fluid, freon, etc.

Description

The inventive utility model relates to instrumentation, in particular, to direct-acting controllers designed to automatically maintain the temperature and flow rate of a coolant, for example, liquid or gas, and can be applied in any field of the national economy, mainly in ventilation, cooling, heating, hot water supply, etc.

The temperature regulator is known from the prior art, comprising a housing with inlet and outlet channels, a thermowell in communication with a power cylinder mounted in the rack of the housing with a spring-loaded piston and a rod connected to a locking member, and a tuning mechanism, which is made in the form of a threaded sleeve interacting with a threaded sleeve section of the rack and resting on the power cylinder mounted with the possibility of longitudinal movement relative to the rack (see RF patent for the invention No. 2175142 "Temperature controller", filing date and May 10, 2000, published October 20, 2001, IPC (7) G05D 23/02).

The disadvantages of this design include its cumbersomeness and complexity due to the presence of a large number of components, as well as the unreliability of operation and operation, due primarily to the weak interconnection of the power (regulatory) body (cylinder) with a thermal bulb carried out using a long thin capillary , which makes it difficult to install the regulator, and with a slight change in the position of the capillary, the operating mode and conditions are violated (which often happens in practice) and therefore constant additional adjustment and readjustment.

A controller is also known, comprising a housing with inlet and outlet nozzles, a spring-loaded regulator installed in it, connected by a heat-sensitive fluid through a capillary to a sensing element of a liquid thermosystem, including a thermal bulb and a tuning bellows with a tuning screw. The tuning bellows is located in the housing coaxially with the sensitive element, the stroke of its tuning screw exceeds the distance between the bottom of the tuning bellows and the sensitive element (see description to the USSR Copyright Certificate No. 634250 “Direct-acting temperature controller”, application filing date 1977.03.04, publication date 1978.11.25).

The disadvantages of this controller include the complexity of the design due to the presence of many components in it, which reduces operational reliability, complicates installation / disassembly and adjustment, as well as the long period required for the controller to operate when the temperature of the controlled fluid changes.

The closest in technical essence is a direct-acting liquid temperature regulator containing a cylindrical body with inlet and outlet nozzles, a hydraulic cylinder installed in it with a regulating body, including a stem with a shut-off valve, connected by a heat-sensitive liquid through a channel with a sensitive element of the liquid thermosystem, while the sensitive element the liquid thermosystem is made in the form of a cylinder located in the inner part of the housing so that the outer surface the inner cylinder and the inner surface of the body form a slot cavity, while a fluid with a high volume expansion, for example, brake fluid, is selected as a heat-sensitive fluid, and the stem with a shut-off valve is equipped with a tensile spring (see application for invention No. 2005113951 “Regulator liquid temperature ”, filing date 05/11/2005, publication date of the application 11/20/2006).

The disadvantages of this design include the low speed of the regulator in the event of a change in the temperature of the controlled fluid, as well as the inability to use the regulator of the same size in pipelines with different pipe diameters.

The technical result to which the claimed utility model is aimed is to expand the functionality of the device, increase maintainability, speed of operation of the controller, the accuracy of its settings and regulation of temperature and flow rate of the coolant.

The specified technical result is achieved by the fact that the temperature and flow rate controller includes a cylindrical body with inlet and outlet nozzles, while a saddle is installed in the inlet nozzle, and a regulating body made in the form of a hydraulic cylinder filled with a thermosensitive liquid is placed in the body, one end which is located in the hydraulic cylinder and connected to the piston, and the second end is located in the housing and connected to a shut-off valve mounted above the seat, according to the utility model the whisker is equipped with a removable cover and a second inlet pipe, either knurling or grooves are made on the outer surface of the hydraulic cylinder, or a wire or tape is placed, the shut-off valve is mounted to rotate around its axis, and through holes are made on the lateral surfaces of the shut-off valve and seat, total whose areas are equal to each other.

As a heat-sensitive fluid, a fluid with a high volume expansion is used, for example, brake fluid, freon, etc.

The inventive temperature and flow rate controller is illustrated by drawings, where

figure 1 is a General view of the device in section;

figure 2 - the relative position of the valve and seat with combined holes in the section;

figure 3 - the relative position of the valve and the seat when the holes are not aligned in the section.

The inventive utility model consists of a cylindrical casing 1, containing a first inlet pipe 2 located in the lower part of the casing, and placed on the sides of the casing 1, a second inlet pipe 3 and an outlet pipe 4. In the casing 1 there is a regulating body made in the form of a hydraulic cylinder 5, filled with a heat-sensitive fluid, which is used as a fluid with high volume expansion, for example, brake fluid, freon, etc. A rod 6 is placed inside the housing 1, one end of which is located in the hydraulic cylinder 5 and connected to the control piston 7, and the second end is placed in the housing 1 and is connected to a rotary shut-off valve 8 located above the seat 9 by means of a fastener 10, for example , a screw with which to set the initial (initial) position of the shutoff valve 8 with respect to the seat 9.

To increase the rate of heat transfer from the coolant to the heat-sensitive fluid on the outer surface of the hydraulic cylinder 5, either knurling, or grooves, or an additional wire or tape (not shown) are placed. In this case, the heat-transfer surface area increases by 40%, which, in turn, allows to increase the amount of heat transferred per unit time from the pipeline with the heat carrier to the heat-sensitive fluid, and, therefore, reduce the response time of the shut-off valve 8 to the change in the temperature of the heat carrier.

A removable cover 11 is mounted on the upper part of the housing 1, mounted on the connecting element 12, rigidly connected to the housing 1 and representing, for example, a flange connection.

On the hydraulic cylinder 5, coaxial to its axis, is an adjusting nut 13 associated with the regulating piston 14.

In addition, the inlet pipes 2, 3 and the outlet pipe 4 can be further provided with removable connecting elements 15.1, 15.2 and 15.3, made, for example, in the form of couplings, or flange connections, or the like. Thanks to the connecting elements 12 and 15.1, 15.2 and 15.3, the housing is installed and fixed in ventilation, cooling, heating, hot water supply, etc. (not shown in the drawing).

Through holes are provided on the lateral surfaces of the shut-off valve 8 and the seat 9, opposite through to each other in segments from 45 ° to 135 ° from 225 ° to 315 °. When the valve 8 rotates around the axis of the regulator and sets it relative to the seat 9 in a certain (predetermined) position, the valve and seat openings overlap and / or combine, thereby forming a living section area for the coolant to pass through the first inlet pipe 2.

Due to the possibility of forming a living cross-sectional area, the accuracy of the controller settings and the accuracy of regulating the flow and temperature of the coolant are increased.

In addition, the possibility of forming the living cross-sectional area of the opening for the coolant passage allows the use of one standard size of the regulator for pipes of different diameters.

In this case, the living cross-sectional area of the holes made on the side surfaces of the shut-off valve 8 and the seat 9 is calculated using the following ratio

,

Where

F _w.s.p. - the living area of the first inlet pipe 2;

∑F _w.s.w.s. - total area of live sections of all holes of the saddle 9;

∑F _railways - total area of live sections of all valve openings 8.

The implementation of the claimed utility model is confirmed by examples of specific performance.

Example 1

When regulating the flow of coolant, for example, in ventilation, cooling, heating systems, the inventive controller operates as follows.

Using, for example, a removable flange connection 15.3, the second inlet pipe 3 is muffled. Considering the incompressibility property and the constancy of the temperature of the heat-sensitive fluid inside the sealed hydraulic cylinder, before starting work, turn the adjusting nut 13 directly connected to the control piston 14 and through the heat-sensitive fluid with the control piston 10 and rod 6, vertically set the initial (initial) position of the valve 8 with respect to the seat 9. Thus, set the living area cross-section, determined by the complete or incomplete combination of the through holes of the valve 8 and the seat 9 vertically. At the same time, the specified living cross-sectional area will determine the amount of coolant flow, for example, fluid coming from the heating system through the inlet pipe 2 to the regulator body 1, passing along the hydraulic cylinder 5 and exiting through the outlet pipe 4.

If the temperature of the coolant entering the body rises, the volume of the heat-sensitive fluid in the hydraulic cylinder increases, the control piston 10 connected to the stem 6 starts to move down, changing the position of the valve 8 relative to the seat 9, namely, reducing the distance between them. This, in turn, leads to a decrease in the living cross-sectional area due to the partial overlap of the through holes of the valve and the seat, as a result, the flow rate of the coolant entering the regulator decreases.

When the temperature of the coolant entering the regulator decreases, the volume of the heat-sensitive fluid, on the contrary, decreases, which leads to the piston 10 moving up, the distance between the valve 8 and the seat 9 increases, the living area of the openings aligned on the valve and the seat also increases. As a result, the flow of coolant entering the regulator increases.

Thus, there is a process of regulating the flow of coolant when changing its temperature.

Example 2

When regulating the temperature of the coolant, the device operates as follows. A second additional inlet pipe 3 is opened through which a coolant is supplied, the temperature of which differs from the temperature of the coolant supplied through the first inlet 2.

At the same time, a mixing zone is formed inside the regulator body, in which flows of coolants having different temperatures are mixed.

In the case when the temperature of the coolant entering through the first inlet pipe 2 differs (above or below) the temperature of the coolant supplied through the second inlet pipe 3, using the adjusting nut 13, control piston 14, control piston 10 and stem 6, the initial position of valve 8 is established in relation to the saddle 9. The formation of the living cross-sectional area occurs similarly to that described above in example 1. The living-cross-sectional area determines the volume of the hotter or colder coolant coming from the first- inlet pipe 2, and hence the temperature of the fluid in the mixing zone and downstream of the regulator.

Consider the example when a heat carrier with a higher temperature enters through the inlet pipe 2.

Upon receipt of flows of coolants with different temperatures in the cavity of the body forms a mixing zone and, accordingly, a mixed coolant.

When the temperature of the mixed coolant in the mixing zone increases, the volume of the heat-sensitive fluid in the hydraulic cylinder 5 increases, the valve 8 starts to move down, and the valve and seat openings overlap, which leads to a decrease in the living cross-sectional area, and, consequently, a decrease in the volume of incoming coolant, for example, liquid having a higher temperature. Due to this, the temperature of the mixture of two coolants coming from the inlet pipes 2 and 3 to the regulator body 1 will decrease.

When the temperature of the mixed coolant in the mixing zone decreases, the process is carried out in the reverse order.

Thus, the temperature of the mixed heat carrier in the mixing zone is regulated.

A regulator of this design can be installed in the system of inlet and / or outlet pipelines not only by means of flange connections with which the inlet and outlet pipes are equipped, but also by means of an integral connection, for example, welding, by which the inlet and outlet pipes are connected to the pipeline. In this case, the living cross-sectional area of the combined valve and seat openings should be equal to the living cross-sectional area of the pipe supplying the coolant to the inlet pipe 2, while the initial living cross-sectional area of the combined openings equal to the living cross-sectional area of the supply pipe (inlet pipe 2) is set by rotation valve 8 relative to seat 9. Regardless of how the regulator is installed in the system, it is possible to repeatedly replace or dismantle any structural element located in the housing, while simultaneously It is possible to clean the body cavity from scale and rust.

The inventive utility model is a universal device, since one type of regulator can be used as a temperature and flow rate controller in a wide range of nominal bores of heating, hot water, ventilation pipes, in particular, 15, 25, 32, 40, 50, 80, 100 mm. The required initial living area of the combined holes, equal to the living area of the inlet pipe (inlet pipe 2), is obtained by rotating the valve 8 relative to the seat 9.

The utility model has high maintainability, response speed, accuracy of setting and regulating the temperature and flow rate of the coolant.

At the time of application submission, production was launched using the claimed utility model at the production base of Komos Group LLC, Ekaterinburg.

Claims (2)

1. The regulator of temperature and flow rate of the coolant flow in the pipeline, including a cylindrical body with inlet and outlet nozzles, while a saddle is installed in the inlet nozzle, and a regulating body is made in the body, made in the form of a hydraulic cylinder filled with a heat-sensitive fluid, a rod, one end of which is located in the hydraulic cylinder and is connected with the piston, and the second end is located in the housing and is connected with a shut-off valve mounted above the seat, characterized in that the housing is equipped with a removable cover and a second inlet th nozzle, on the outer surface of the cylinder formed or knurling or grooving, or placed wire or ribbon, shut off valve is mounted rotatably about its axis, while on the side surfaces of the check valve and the seat is provided with through holes, the total area are equal to each other. 2. The temperature and flow rate controller in the pipeline according to claim 1, characterized in that as a heat-sensitive fluid using a fluid with high volume expansion, such as brake fluid, freon, etc.