RU140779U1 - HEAT SUPPLY SYSTEM - Google Patents

Abstract

A heat supply system containing a coolant and circulating pumps connected by pipelines with shut-off and control valves, equipment for heating the coolant, expansion tanks, tanks for draining and supplying a coolant, pumps for replenishing and issuing a coolant, as well as distribution and return collectors, characterized in that the system is multi-circuit, including the primary and secondary circuits, and at the inlet to each secondary circuit of the system, a lowering heat exchanger is installed, and coolants with various physical and chemical properties are used in the circuits of the system.

Description

The inventive utility model relates to the field of heat engineering, and more specifically to heat supply systems and can be used in the design of heat supply systems for industrial enterprises and offshore drilling platforms.

A well-known heat supply system containing a coolant, connecting pipelines with fittings, a circulation pump, heating medium heating equipment — a boiler, an expansion tank and a distribution riser (see the training manual - Yu. D. Sibikin “Heating, ventilation and air conditioning”, M .: Publishing House Center "Academy", 2008, p. 87)

The disadvantage of this known system is a significant limitation on the application. The presence of risers allows for uninterrupted heat supply in the premises of a typical configuration, mainly of a multi-level layout, for example, in multi-storey residential buildings. The coolant in this system is water. As a result of the above, the system is ineffective for supplying heat to industrial facilities, where it is necessary to ensure large temperature differences and high heating temperatures.

A well-known heat supply system containing circulating pumps, heating medium equipment, expansion tank, drain and reserve tanks, replenishment and delivery pumps, as well as distribution and return manifolds (see Technical handbook - Walter Wagner), containing a heat carrier and circulating pumps connected by pipelines with shutoff and control valves; “Heat Transfer Technique with Organic Media, Germany, Dr. Ingo Resch GmbH, 1997, p. 506 - prototype of the claimed utility model).

Taken as a prototype of the specified well-known system is used for heating industrial enterprises. Various specialized environments, for example, thermal oil, can be used as a heat carrier in this system.

The disadvantage of the prototype is that this system is built on a single-circuit principle, while in the circuit the entire circulation cycle (heat delivery to the consumer) is carried out using one type of coolant. This limits the range of application of this system, in particular, it cannot be used for simultaneous heat supply of industrial and residential premises, the heat supply requirements of which differ significantly, for example, on an offshore drilling platform.

The objective of the claimed utility model is the creation of a unified heat supply system that provides the most efficient and safe supply of thermal energy to both production facilities, technological equipment, as well as administrative and residential premises. And also the creation of conditions for the application of the most compact layout of system elements.

The technical result of the claimed utility model is to expand the operational capabilities of the system while improving reliability and reducing the dimensions of system elements.

This is achieved in a heat supply system containing a coolant and pipelines with shut-off and control valves, circulation pumps, heating medium heating equipment, expansion tanks, coolant drain and supply tanks, coolant replenishment and delivery pumps, as well as distribution and return collectors, a degasser so that the system is multi-circuit, including primary and secondary circuits, with a step-down heat exchanger installed at the entrance to each secondary circuit of the system, and coolants with various physicochemical properties were used in the system circuits.

A significant advantage of organizing a multi-circuit system is the possibility of using different types of coolants for each circuit, which makes it possible to improve the operational and technical characteristics of the system: reduce weight and dimensions, increase the reliability and durability of the heat supply system.

A multi-circuit diagram of the heat supply system with various coolants in the circuits allows you to protect the system equipment from mechanical and chemical wear while observing environmental and sanitary standards.

Factors that increase the reliability of the system are:

- no risk of defrosting the system at low temperatures;

- the ability to maintain high temperature, which, at low costs, allows more efficient transfer of thermal energy and reduce the area of heat-transferring surfaces, i.e. overall dimensions of equipment and systems;

- the ability to maintain relatively low pressures, since the temperature ranges for the use of the coolant are selected below its boiling point. This factor also has a positive effect on reducing overall dimensions (equipment dimensions, wall thickness of pipelines, etc.) and the reliability of the system.

In addition, many coolants have properties that reduce hydrodynamic resistance and improve the working conditions of pumps and valves.

The figure 1 shows an example diagram of the inventive heat supply system - heat supply system of a self-propelled floating drilling rig.

To expand the operational capabilities of the system while increasing the reliability and reducing the dimensions of its elements by providing a higher temperature difference, the system is multi-circuit, including primary 1 and secondary 2 pipelines 3 and 4. Inside the circuit 1, coolant 5 circulates - thermal oil, and inside the circuit 2 - heat carrier 6 - propylene glycol.

The primary circuit 1 includes circulation pumps 9 connected by a network of pipelines 3 with shutoff 7 and control valves 8, equipment 10 for heating the coolant 5, an expansion tank 11, a drain tank 12 and a reserve tank 13 for the coolant 5, pumps 14 for replenishing and discharging the coolant 5, and also distribution 15 and return 16 collectors and a degasser 17. At the entrance to the secondary circuit 2 of the system, a step-down heat exchanger 18 is installed.

The secondary circuit 2 includes circulating pumps 21 connected by a network of pipelines 4 with shutoff 19 and control valves 20, heating medium heating equipment 6 — a reducing heat exchanger 18, expansion tank 22, drain tank 23 and reserve tank 24 of heating medium 6, replenishment and delivery pumps 25 6, as well as distribution 26 and return 27 collectors and degasser 28.

To ensure constant pressure in the above-described coolant tanks 5 and 6 and to prevent contact of the coolant 5 and 6 with air, the circuit of the inventive heat supply system is equipped with a nitrogen supply system 29 of the primary circuit 1 and a nitrogen supply system 30 of the secondary circuit 2.

To control the main parameters of the coolant 5 and 6 (flow, temperature, pressure); instrumentation (not shown)

The inventive heat supply system is designed to provide thermal energy to consumers of thermal energy 31 of the primary circuit 1 and consumers of thermal energy 32 of the secondary circuit 2.

The inventive heat supply system of a self-elevating floating drilling rig works as follows: circulation pumps 9 of the coolant 5 of the primary circuit 1 through pipelines 3 send the coolant 5 to the equipment 10 for heating the coolant 5. Heated to the working temperature of the coolant 5 is supplied to the distribution manifold 15 of the primary circuit 1. From the collector 15 the heat carrier 5 is distributed to the step-down heat exchanger 18 of the secondary circuit 2 and to consumers 32, for the maintenance of which heat is required carrier with increased temperature characteristics (for example, to equipment for heating fuel gas (not shown). Having generated thermal energy in a step-down heat exchanger 18 and consumers 31, heat carrier 5 enters the return manifold 16. Distribution 15 and return 16 of the primary circuit collector 1 are interconnected via control valves 8, which allows you to maintain a constant flow rate of coolant 5 in circuit 1 by bypassing part of the coolant 5 from the distribution 15 to the return manifold 16 while reducing progress on consumers 31.

After the return manifold 16, the entire coolant 5 passes through the degasser 17 to remove the gaseous component. Then, the coolant 5 enters the inlet of the circulation pumps 9, closing the primary circuit 1 of the circulation.

The filling of the primary circuit 1 is carried out by the pumps 14 replenishment and the issuance of coolant 5. Pumps 14 direct the coolant 5 from the tank stock 13 to the expansion tank 11.

The coolant 5 is drained through the piping system 3 to the drain tank 12. The principle of the coolant 5 draining is gravity, “gravity”.

The main function of the primary circuit 1 is the transfer of heat to consumers, including a lowering heat exchanger 18 of the secondary circuit. 2. Due to the design features of the known heat exchangers, including a lowering heat exchanger 18, the primary coolant heat carrier 5 carries out a flow inside the heat exchanger housing (not shown), where heat is transferred through the heating medium to the secondary coolant 6 2. Heat carriers 5 and 6 moving in countercurrent through the channels (not shown) of the heat exchanger 18, they exchange heat from the primary circuit 1 with a higher temperature to the secondary circuit 2 with a lower temperature and, thus, lower The heat exchanger 18 is a heat source for the secondary circuit 2 of the inventive heat supply system.

The secondary circuit 2 has a similar structure to circuit 1. Pumps 21 are responsible for the circulation, which supply the heat carrier 6 to the heat exchanger 18, from which the heated heat carrier 6 is supplied to the distribution manifold 26 of the secondary circuit 2, from where it is supplied to the consumers 32 of the secondary circuit 2. The heat carrier 6 from consumers 32 is collected in the return manifold 27, from where through the degasser 28 of the secondary circuit 2 enters the input of the circulation pumps 21 of the secondary circuit 2. Distribution 26 and the return 27 of the collector of the secondary circuit 2 also interconnected via control valves 20.

The filling of the secondary circuit 2 is carried out by means of the replenishment pumps 25, which take the coolant 6 from the reserve tank 24 and direct it to the expansion tank 22.

The coolant 6 is drained through a network of pipelines 4 to the drain tank 23. The principle of draining the coolant 6 is gravity, “gravity”.

All heat-generating equipment of the claimed heat supply system, pumps, heat exchangers have individual piping for uniform distribution of heat carriers in the system, as well as for the possibility of cutting off the heat carrier flow through each of the elements of the system separately (without loss of operability of the system as a whole). If necessary, the system may contain several secondary circuits.

The technical and economic advantages of the claimed utility model are the creation of a unified heat supply system that provides the most efficient and safe supply of thermal energy to both production facilities, technological equipment, and administrative and residential premises using the most compact layout of system elements. This is achieved by expanding the operational capabilities of the system while increasing reliability and reducing the dimensions of its elements.

Claims (1)

A heat supply system, containing a coolant and circulation pumps connected to pipelines with shutoff and control valves, heating medium heating equipment, expansion tanks, coolant drain and supply tanks, coolant replenishment and delivery pumps, as well as distribution and return manifolds, characterized in that the system is multi-circuit including primary and secondary circuits, and at the entrance to each secondary circuit of the system there is a step-down heat exchanger, and in the circuits of the system emy used coolants with different physico-chemical properties.

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