RU160998U1 - HEATING FLOW REGULATOR - Google Patents

Abstract

A coolant flow regulator containing a normally open solenoid valve and a safety valve connected by fittings inlet to input and output to output, characterized in that it further comprises three shut-off and control modules, and the combined inputs of a normally open solenoid valve and a safety valve are connected by fittings to the output of the first locking-regulating module, the combined outputs of a normally open solenoid valve and a safety valve are connected by fittings to the course of the second locking and regulating module, and the input of the first locking and regulating module is connected by fittings to the input of the third locking and regulating module, connected by fittings to the output of the second locking and regulating module, while the input of the regulator is the combined inputs of the first and third locking and regulating modules, and the output of the regulator is the combined outputs of the second and third locking and regulating modules.

Description

The utility model relates to instrumentation, in particular, to means for regulating the heat consumption of buildings and structures, and can be used in industry and housing and communal services.

A known coolant flow controller (RF Patent for utility model No. 140284, IPC G05D 7/00, 2013) containing a normally open solenoid valve and a safety valve connected by an input to the input of a normally open solenoid valve, while the output of the safety valve is connected to the output normally open solenoid valve.

The disadvantage of this utility model is its low reliability, which is associated with the possibility of airing the channel parallel to the normally-open solenoid valve, which leads to a decrease in the efficiency of eliminating hydraulic shocks and complicating the processes of setting the flow rate regulator of the coolant and crimping its design.

Closest to the claimed utility model is the "Flow Rate Regulator" (RF Patent for Utility Model No. 150892, IPC G05D 7/00, 2014), adopted as a prototype and containing a normally open solenoid valve and a safety valve connected by fittings and / or branch pipes input to input and output to output.

The disadvantage of this coolant flow controller is determined by its lack of reliability and low maintainability due to the need to interrupt for a long time the coolant is supplied to the heat consumer in the event of emergency, repair and / or preventive work on a normally open solenoid valve and / or safety valve.

The technical result of the claimed utility model is to increase reliability and improve maintainability of the flow rate controller by providing an additional parallel to the normally open solenoid valve heat transfer channel for the heat consumer.

The technical result is achieved by the fact that the coolant flow controller contains a normally open solenoid valve and a safety valve connected by fittings and / or nozzles to the input to the input and output to the output, and additionally contains three shut-off and control modules, the combined inputs of a normally open solenoid valve and the safety valve is connected by fittings and / or nozzles to the output of the first locking-regulating module, the combined outputs of a normally open electromagnetic the valve and the safety valve are connected by fittings and / or nozzles to the input of the second locking and regulating module, and the input of the first locking and regulating module is connected by fittings and / or pipes to the input of the third locking and regulating module, connected by fittings and / or pipes to the output of the second locking -regulating module, while the input of the regulator is the combined inputs of the first and third locking-regulating modules, and the output of the regulator are the combined outputs of the second and third locking-regulating modules.

In FIG. 1 is a drawing of the proposed flow rate controller.

The coolant flow controller contains a normally-open solenoid valve 1, a safety valve 2, a first shut-off and control module 3, a second shut-off and control module 4, a third shut-off and control module 5 and pipelines with fittings and / or nozzles 6-13.

The inputs of the normally-open solenoid valve 1 and the safety valve 2 are connected by a pipeline with fittings and / or nozzles 6 and connected through a pipeline with fittings and / or nozzles 7, the first shut-off and control module 3 and pipelines with fittings and / or nozzles 8 and 9 with the input of the third locking and regulating module 5.

The outputs of the normally-open solenoid valve 1 and the safety valve 2 are connected by a pipeline with fittings and / or nozzles 10 and connected through a pipeline with fittings and / or nozzles 11, a second locking and regulating module 4 and pipelines with fittings and / or nozzles 12 and 13 with the output of the third locking and regulating module 5.

The input of the coolant flow regulator is the inputs of the first locking and regulating module 3 and the third locking and regulating module 5 connected by pipelines with fittings and / or pipes 8 and 9, and the outputs of the second are the outputs of the coolant flow regulator combined by pipelines with fittings and / or pipes 12 and 13 locking regulatory module 4 and the third locking regulatory module 5.

The conditional passage of the third locking and regulating module 5, as well as the conditional passageways of the pipelines with fittings and / or nozzles 9 and 13 must correspond to the conditional passage of the pipeline section into which the flow rate regulator is installed in order to maintain the existing value of the hydraulic resistance of this pipeline section.

The flow rate controller operates as follows.

In the initial state, the first locking and regulating module 3 and the second locking and regulating module 4 are open, and the third locking and regulating module 5 is closed. In this case, the coolant through pipelines with fittings and / or nozzles 9 and 8, the first shut-off and control module 3, the pipeline with fittings and / or nozzles 7, a normally-open solenoid valve 1, the pipeline with fittings and / or nozzles 11, the second shut-off control module 4 and pipelines with fittings and / or nozzles 12 and 13, is supplied to the consumer with a maximum flow rate.

The control unit (not shown in the drawing) sets the period for regulating the coolant flow rate and, during the specified control period, determines the required duration (i.e. pulse duty) of the coolant supply to the heating system of the heat consumer through a normally open solenoid valve 1 and generates a shutdown command -open solenoid valve 1 after the pulse duration.

In this case, the closing of a normally-open solenoid valve 1 is performed when a supply voltage is applied to its coil, and the opening of a normally-open solenoid valve 1 is restored when a voltage is removed from its coil.

Closing a normally-open solenoid valve 1 is accompanied by an abrupt increase in the coolant pressure (water hammer) in pipelines with fittings and / or nozzles 6-9 and in the first shut-off-control module 3, i.e. at the inlet of the coolant flow controller.

The coolant pressure surge is leveled as a result of the short-term opening (actuation) of the safety valve 2, and the portion of the coolant is not dumped in a traditional way (i.e., into a separate external vessel), but into the heat consumer’s pipeline, bypassing the already closed normally-open electromagnetic valve 1 through the pipeline with fittings and / or nozzles 6, a safety valve 2, pipelines with fittings and / or nozzles 10 and 11, a second locking and regulating module 4 and pipelines 12 and 13.

As a result, the pressure of the coolant at the inlet of the coolant flow regulator is restored to the previous level, after which the safety valve 2 closes, and the flow of coolant into the heat consumer’s pipeline stops.

The presence of an air vent 14 in the pipeline with fittings and / or nozzles 10 eliminates the possibility of airing the flow rate controller, which ensures the effectiveness of eliminating hydraulic shocks that occur when the normally-open solenoid valve 1 closes, and also simplifies the preliminary adjustment of the flow rate controller and crimping its design .

The use of a normally-open solenoid valve 1 eliminates the interruption of the coolant in the heating system of the heat consumer in emergency situations, for example, during an emergency disconnection from the power supply network.

In the event of an emergency and / or the need for repair and maintenance work on a normally open solenoid valve 1 and / or safety valve 2, the third locking and regulating module 5 opens, and the first locking and regulating module 3 and the second locking and regulating module 4 are closed, which interrupts the operation of the coolant flow controller, but the heat consumer is supplied with the maximum flow for the time of emergency and / or repair work.

In addition, this makes it possible to minimize the duration of interruption in the flow of heat carrier into the heating system of the heat consumer during installation of the flow rate controller and subsequent commissioning.

In other words, the design of the coolant flow controller allows not only to automate the heat management process of buildings and structures, but also to maintain the integrity and performance of the original heat consumer heat supply scheme.

Moreover, various locking and regulating modules (both with a manual actuator and with an electric actuator, etc.) can be used in the circuit, for example, valves, butterfly valves, gate valves, electromagnetic valves, etc.

The pulsed (portioned) supply of the heat carrier to the heat consumer makes it possible to provide the average value for the period of regulation of the heat carrier flow in an extremely wide range, i.e. from zero to the maximum value while eliminating unwanted acoustic noise and maintaining the maximum coolant flow both in the generated coolant pulse and in emergency situations, which is confirmed experimentally by testing and the introduction of prototypes of the coolant flow controller.

Thus, the implementation of the proposed coolant flow controller allows for high reliability by completely eliminating the interruption of the coolant supply to the heat consumer and significantly improve its maintainability.

Claims (1)

A coolant flow regulator containing a normally open solenoid valve and a safety valve connected by fittings inlet to input and output to output, characterized in that it further comprises three shut-off and control modules, and the combined inputs of a normally open solenoid valve and a safety valve are connected by fittings to the output of the first locking-regulating module, the combined outputs of a normally open solenoid valve and a safety valve are connected by fittings to the course of the second locking and regulating module, and the input of the first locking and regulating module is connected by fittings to the input of the third locking and regulating module, connected by fittings to the output of the second locking and regulating module, while the input of the regulator is the combined inputs of the first and third locking and regulating modules, and the output of the regulator is the combined outputs of the second and third locking and regulating modules.

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