RU99118U1 - SCHEME OF INCLUSION OF A HEATER BOILER IN THE HEAT SUPPLY SYSTEM - Google Patents

Abstract

 The scheme for incorporating a hot water boiler into a heat supply system, including a hot water boiler connected via a direct pipeline with a network pump installed on it with a heat exchanger, a return pipe and shutoff valves, characterized in that a pressure regulator is installed on the return pipe behind the heat exchanger.

Description

The utility model relates to the field of power engineering and can be used in heating boiler rooms.

There is a known scheme of heat supply with open water, the most common in areas of old buildings, when the heat carrier for the needs of hot water is supplied to the consumer directly from the heating network. Consumers - heating and ventilation and hot water supply - are connected directly through hot water boilers, and the main pumps for moving water through the boiler and pipelines of the heat supply system are network pumps. Such schemes are cheaper due to the lack of additional heat exchangers, pumps and valves (Yu.L. Gusev. Basics of the design of boiler plants. - M.: Literature on construction, 1967. S.191-192).

The disadvantage of this scheme is the operation of boilers under pressure exceeding the resistance of the entire heat supply system, as well as the introduction of pollution from internal consumer systems and heating networks to boilers.

A known heat supply scheme, including a hot water boiler, a network pump, a heat exchanger and shut-off valves with independent connection of consumers - heating and ventilation and hot water supply - through heat exchangers, while the heat exchangers can be placed both directly in the boiler room and outside it (E.L. Paley, Design of boiler houses in the housing and communal services sector, St. Petersburg, Gas Club Publishing House, 2006. pp. 21-27).

By the totality of the features, this known technical solution is the closest to the claimed one and is taken as a prototype.

The disadvantage of the device adopted for the prototype, as well as the reason that impedes the achievement of the desired technical result, is the significant working pressure in the boiler, equal to the sum of the hydraulic resistance of the boiler, heat network and heat exchanger.

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources containing information about analogues of the claimed utility model, allows us to establish that the applicant has not found a technical solution characterized by features identical or equivalent to the proposed one, while the proposed solution does not appear obvious for specialist manner of the prior art and determined by the applicant.

The determination from the list of identified analogues of the prototype as the closest technical solution for the totality of features made it possible to identify in the claimed device a combination of significant distinguishing features with respect to the technical result perceived by the applicant, as set forth in the utility model listed below.

The claimed technical solution allows to significantly reduce the working pressure in the boiler, which leads to a simplification of the circuit and a reduction in metal consumption, and, therefore, to increase the reliability and efficiency of the entire heat supply system. The proposed scheme can find application in heat supply systems with both open and closed water intake.

A scheme is proposed for incorporating a hot water boiler into a heat supply system, including a hot water boiler connected via a direct pipeline with a network pump installed on it with a heat exchanger, a return pipe and stop valves, and a pressure regulator is installed on the return pipe behind the heat exchanger.

The utility model is illustrated in the drawing.

The proposed scheme with a closed water intake consists of a boiler 1, a direct pipe 2 connected to a heat exchanger of the heating system 3 and hot water supply 4. On the pipeline 2, shutoff valves 5 are installed at the outlet and inlet of the boiler 1 and the inlet and outlet of the corresponding heat exchangers 3 and 4. Behind the shutoff the fittings 5 on the pipeline 2, behind the boiler 1, a network pump 6 is installed, behind which there is a check valve 7 and a second shut-off valve 5. On the direct pipe 2 there are three-way control valves 8 connecting straight 2 minutes and the return pipes 9. An expansion tank 10 is installed in the direct pipe 2, and the return pipe 9 is connected to the make-up pipe 11 with its own valve 12 with a unit for binding oxygen dissolved in water 13. Relief valves 14 are located on the direct pipe 2. On the return pipe 9, behind the heat exchanger 3, in front of the boiler 1, a pressure regulator 15 is installed. It is possible to install a pressure regulator 15 on a straight pipe 2 in front of the mains pump 6.

The proposed scheme works as follows. Water from the return pipe 9 enters the boiler 1, where it is heated to the required temperature and through the direct pipe 2 by the network pump 6 is supplied to the heat exchanger 3 of the heating system and the heat exchanger 4 of hot water supply. From the heat exchangers 3 and 4, the chilled water is returned via the return pipe 9 to the boiler 1. The primary filling of the water system (boiler, pipelines) and emergency recharge is made from the pipe 11. Compensation of thermal expansions in the direct pipe 2 is carried out in expansion tanks 10. Relief pressure in the direct pipe 2 is carried out by safety valves 14. The temperature in the return pipe 9 at a predetermined level is maintained by three-way control valves 8. When installing pressure regulator 15 on the return pipe 9, the regulator maintains the pressure behind it behind the boiler 1. When installing the pressure regulator 15 on the direct pipeline 2, the regulator maintains the pressure in front of it behind the boiler 1. The installed pressure regulator maintains the pressure at the outlet of the boiler 1 at the minimum possible according to the conditions of boiling water, that is, for a temperature graph of 70-95 ° C - 1.4 kgf / cm ² , for a temperature graph of 70-115 ° C - 3.3 kgf / cm ² . The boiler 1 can be designed instead of the recommended design pressures, respectively 7 kgf / cm ² and 9 kgf / cm ² for 2 kgf / cm ² and 4 kgf / cm ² .

Claims (1)

A circuit for incorporating a hot water boiler into a heat supply system, including a hot water boiler connected via a direct pipeline with a network pump installed on it with a heat exchanger, a return pipe and shutoff valves, characterized in that a pressure regulator is installed on the return pipe behind the heat exchanger.