RU213988U1 - DEVICE FOR REGULATION OF THE HEAT CARRIER PARAMETERS AND ACCOUNTING OF HEAT AMOUNT - Google Patents

Abstract

The utility model relates to the field of public utilities, in particular to devices for metering and controlling the amount of heat, flow and other parameters of the coolant in heat supply systems. The device for regulating the parameters of the coolant and accounting for the amount of heat includes a housing (10) and a coolant supply pipeline and a coolant discharge pipeline located in it. The first shut-off valve (1), the first air vent (2.1), the filter for cleaning the coolant from mechanical impurities (3), the heat meter (4), the valve (5) for adjusting the pressure and flow of the coolant and the second shut-off valve (7) are installed in series on the coolant supply pipeline . The heat meter (4) is configured to connect sensors to it, in particular a temperature sensor (9). A second air vent (2.2) and a third shut-off valve (6) equipped with fittings are installed in series on the coolant outlet pipeline. An impulse communication line (8) and a temperature sensor (9) are connected to the fittings of the third stopcock (6). Through the impulse line (8) the third shut-off valve (6) is connected to the valve (5). The temperature sensor (9) is also connected to the heat meter (4). The technical result is an increase in the compactness of the device for accounting for the amount of heat with a simultaneous decrease in the number of threaded connections, which also affects the increase in the reliability of the assembly and the convenience of its assembly.

Description

The utility model relates to the field of public utilities, in particular to devices for metering and controlling the amount of heat, flow and other parameters of the coolant in heat supply systems.

Known from the prior art is a unit for accounting for the amount of heat disclosed in the utility model patent RU 158848, published on January 20, 2016, IPC G01K17/00, F24D19/00. The well-known metering unit includes a housing in which pipelines for supplying and discharging coolant are placed. On the pipeline for supplying the heat carrier, the first shut-off valve, the filter for removing mechanical impurities, the first balancing valve, the vane counter of the amount of heat, the air valve and the second shut-off valve are installed in series. A third shut-off valve, a second balancing valve and a fourth shut-off valve are installed in series on the pipeline for removing the coolant. The balancing valves are interconnected by an impulse tube for adjusting the pressure drop and the coolant flow.

The disadvantages of the well-known metering unit for the amount of heat is the placement on the return pipeline of the heat meter partner valve installed on the supply pipeline, while the partner valve is installed with two additional ball valves to turn it off. This design significantly increases the number of threaded connections, which, together with a large number of structural elements, increases the total number of points of probable failure. The noted shortcomings affect the overall reliability of the assembly, the convenience of its assembly, as well as its overall dimensions.

The technical problem to be solved by the present utility model is to create a highly reliable device for regulating the parameters of the coolant and accounting for the amount of heat with increased ease of assembly and installation.

The technical result achieved in solving the technical problem is to increase the compactness of the heat metering device while reducing the number of threaded connections, which also affects the ease of assembly.

The technical problem is solved, and the technical result is achieved due to the fact that the device for regulating the parameters of the coolant and accounting for the amount of heat includes a coolant supply pipeline and a coolant discharge pipeline. The first shut-off valve, the first air vent, the filter for cleaning the coolant from mechanical impurities, the heat meter, the valve for regulating the pressure and flow of the coolant and the second shut-off valve are installed in series on the coolant supply pipeline. A second air vent and a third shut-off valve equipped with fittings are installed in series on the coolant outlet pipeline. An impulse communication line and a temperature sensor are connected to the fittings of the third stopcock. The third stopcock is connected to the valve by means of an impulse communication line, and the temperature sensor is also connected to the heat meter.

The technical problem is solved, and the technical result is also achieved in the following particular embodiment of the device for controlling the parameters of the coolant and accounting for the amount of heat.

The device for regulating the parameters of the coolant and accounting for the amount of heat can be equipped with a housing, inside which the coolant supply pipeline and the coolant discharge pipeline can be placed. The case provides protection of the components placed in it from mechanical and environmental influences, which improves the overall reliability of the device. In addition, the presence of a single housing speeds up and simplifies the installation of the device.

The pipelines for supplying the coolant and removing the coolant provide, respectively, the supply and removal of the coolant to the heat supply system. Shut-off valves allow you to block the flow of the coolant if necessary. The filter for cleaning the coolant from mechanical impurities ensures the purification of the coolant from contaminants and impurities that could damage the components of the device. Air vents clean the coolant from gas impurities, which affects both the accuracy of the device and the elimination of air blockages in the pipeline. The pressure and flow control valve regulates the pressure and flow of the heating medium in the heating system. The temperature sensor connected to the heat meter, located on the supply branch of the pipeline, and the third shut-off valve, located on the return branch of the pipeline, makes it possible to ensure a uniform temperature background of the room. The impulse communication line connecting the third shut-off valve and the valve transmits the influence of the coolant from the third shut-off valve to the pressure and flow control valve to control and control the pressure and flow of the coolant.

The proposed version of the device allows, while maintaining the functionality, to reduce the outlet branch of the pipeline to one shut-off valve with a connected impulse communication line from the control valve and a temperature sensor from the heat meter. In other words, the device includes a smaller number of structural elements compared to the closest analogue, which requires fewer connections (including threaded ones), and, consequently, the compactness of the heat metering device is ensured while increasing ease of assembly. Thus, high reliability of the device for regulating the parameters of the coolant and accounting for the amount of heat is achieved, and its assembly and installation is facilitated.

Further, the present utility model is illustrated by a drawing (figure 1), which shows a general structural diagram of the device for regulating the parameters of the coolant and accounting for the amount of heat.

The device for regulating the parameters of the coolant and accounting for the amount of heat includes a housing (10) and a coolant supply pipeline and a coolant discharge pipeline located in it. The first shut-off valve (1), the first air vent (2.1), the filter for cleaning the coolant from mechanical impurities (3), the heat meter (4), the valve (5) for adjusting the pressure and flow of the coolant and the second shut-off valve (7) are installed in series on the coolant supply pipeline . The heat meter (4) is configured to connect sensors to it, in particular a temperature sensor (9). A second air vent (2.2) and a third shut-off valve (6) equipped with fittings are installed in series on the coolant outlet pipeline. An impulse communication line (8) and a temperature sensor (9) are connected to the fittings of the third stopcock (6). Through the impulse line (8) the third shut-off valve (6) is connected to the valve (5). The temperature sensor (9) is also connected to the heat meter (4). As structural elements of the proposed device, any known to a specialist in this field of technology can be selected. For example, a mesh filter can be taken as a filter for cleaning the coolant from mechanical impurities (3). Ball valves can be used as stop valves (1), (6) and (7).

The housing (10) provides protection of the nodes placed in it from mechanical influences, and also simplifies the installation of the proposed device at the place of operation.

The device for regulating the parameters of the coolant and accounting for the amount of heat works as follows.

The claimed device is mounted on the pipeline of the heating system of the room. The heat carrier supply pipeline is connected to the heat supply system pipeline supplying the heat carrier, and the heat carrier outlet pipeline, respectively, to the heat supply system pipeline discharging the heat carrier. Shut-off valves (1) and (7) block, if necessary, the flow of heat carrier through the pipeline for supplying the heat carrier of the device. The coolant, having entered the supply pipeline, passes through the first shut-off valve (1), after which it is cleaned of contaminants and impurities that could damage the device components by means of the first air vent (2.1) and the filter for cleaning the coolant from mechanical impurities (3). Further, the heat meter (4) measures the thermal parameters of the heat carrier, taking into account the data of the temperature sensor (9), and the valve (5) for regulating the pressure and flow of the heat carrier controls the pressure and flow of the heat carrier in the heat supply system based on the received data on the heat carrier and the impact transmitted via the impulse communication line ( eight). The coolant passes through the second shut-off valve (7) and enters the heat supply system of the room, at the exit from which it enters the coolant outlet pipeline of the device, where the third shut-off valve (6) passes, on which the temperature is measured by a temperature sensor (9) and pressure is measured by means of a pulse communication lines (8).

The claimed device for regulating the parameters of the coolant and accounting for the amount of heat eliminates the need to lengthen (for example, using additional pipe sections, couplings, nuts, etc., connected by threaded connections) the coolant outlet pipeline to align its length with the coolant supply pipeline. Also, the coolant outlet pipeline of the claimed device is reduced to only one shut-off valve, to which the impulse communication line from the control valve and the temperature sensor from the heat meter are connected, in other words, the device includes a smaller number of structural elements compared to known solutions, which also requires fewer connections (including number of threaded). Thus, both a reduction in the overall dimensions of the device and an increase in protection against leaks, and, consequently, an increase in reliability, are provided. In addition, the assembly of both the device itself and its installation in the heat supply system is simplified.

Claims (2)

1. A device for regulating the parameters of the coolant and accounting for the amount of heat, including a coolant supply pipeline and a coolant outlet pipeline, and the following are installed in series on the coolant supply pipeline: the first shut-off valve (1), the first air vent (2.1), the filter for cleaning the coolant from mechanical impurities (3) , heat meter (4), valve (5) for adjusting the pressure and flow of the coolant and the second shut-off valve (7), and on the coolant outlet pipeline are installed in series: the second air vent (2.2) and the third shut-off valve (6), equipped with fittings, while to an impulse communication line (8) and a temperature sensor (9) are connected to the fittings of the third stopcock (6), and the third stopcock (6) is connected to the valve (5) via an impulse communication line (8), and the temperature sensor (9) is also connected to the heat meter (four). 2. The device according to claim. 1, characterized in that the coolant supply pipeline and the coolant outlet pipeline are placed in the housing (10).

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