RU2327080C2 - Heat water supply system (variants) - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: invention relates to heat-power engineering, heat water supply systems and hot-water supply systems for residential buildings and industrial enterprises. Heat water supply system comprises a steam source, direct and return pipelines, consumer heat-water supply network, jet pump with nozzle for active fluid feed, nozzle for passive fluid feed, and outlet branch pipe. Jet pump works as a heat exchanging and circulating equipment. Nozzle for active fluid feed of the jet pump is connected (via pipeline) to the steam source; nozzle for passive fluid feed - to the return pipeline, outlet branch pipe - to the straight pipeline of heat water supply system. The return pipeline has a coolant buffer tank equipped with system of additional heating of coolant coming through the mentioned buffer tank. Also variants of heat water supply system are described.

EFFECT: possibility to control temperature and/or flow rate of heat power, transferred to consumers.

12 cl, 6 dwg

Description

The invention relates to a power system, heating systems and hot water supply of residential and industrial enterprises.

Technical solutions are known in which injectors or jet pumps are used as circulation pumps. Such systems include the following inventions.

A.S. 1762080, F24D 3/08, prior. 04.17.86, “Heat supply system” contains a heat exchanger, jet pump, direct and return heating network piping, the first of which is connected to the hot water supply line and to the outlet pipe of the two-stage injector, and the second to the mixing chamber of the first injector stage. In this system, the heat source is geothermal wells with brine, therefore, the system design contains a separator and devices as a steam generator, which allow to separate the coolant in the primary circuit (brine) and the coolant of the secondary circuit - water. The circulation of coolants is provided by jet pumps, which allows, as in the present invention, not to supply additional energy, providing circulation of the coolant in the primary circuit. However, the jet pump in this design does not perform the function of a heat exchanger.

The well-known "Method of heat supply to the consumer from the steam network" according to patent SU 1210670, class. F24D 9/082, prior. 06/19/80, in which steam is generated in a central source, steam is transported through the steam network at an overpressure, and steam is condensed in a heat exchanger. The condensation of steam in the heat exchanger is carried out at an overpressure by the return water of the heating system. The steam condensate is sent to the working nozzle of the heating system jet pump, and the return water of the heating system heated in the heat exchanger is supplied to its receiving chamber. In this invention, the jet pump does not use water as the active medium, but water; it does not perform the functions of a heat exchanger and an additional water supply device.

In the invention RU No. 2140043 “Heat supply system” F24D 9/02, publication 20.10.1999, the system comprises a central steam source, direct and return pipelines, a consumer heat supply network, a jet pump having a nozzle for supplying an active medium and a nozzle for supplying a passive medium, and outlet pipe.

According to the invention, the jet pump, as a heat exchange device and circulation means, is connected through a pipe to a steam source through a nozzle for supplying an active medium. The jet pump nozzle for supplying a passive medium is connected to a return pipe, the input of the device for additional supply of a passive medium is connected to a water supply tank or a water supply source. The outlet nozzle of the jet pump is connected to a direct pipeline of the heat supply system.

In this invention, a jet pump performs several functions: it circulates the coolant in the consumer network and serves as a device for heat transfer, transferring steam energy to the water circulating in the network. In addition, it provides the function of additional replenishment of the coolant, especially for systems with high consumption of hot water.

However, this system does not allow controlling either the temperature or the flow rate of the coolant supplied to the consumers ’heat supply network. This is due to the peculiarity of the jet pump. Its characteristic is the same as that of volumetric pumps - the flow rate through the jet pump does not depend on back pressure (of course, while back pressure does not exceed the pressure of the jet pump.) The flow rate through the jet pump and its injection coefficient (ratio of water flow to steam flow) depend on the temperature of the water entering its inlet. The injection pump injection determines the heating of the water in the jet pump.

Thus, the temperature of the water entering the inlet of the jet pump determines the flow of water and the heating of water in it, and therefore the power supplied to consumers. Moreover, when the temperature of the water in the return pipe decreases, the flow rate through the jet pump increases, and when the temperature of the water rises, it decreases. While the heat supply system requires just the opposite.

The technical result achieved in the claimed inventions consists in the fact that in each embodiment of the system, it becomes possible to regulate the heat power transmitted to consumers by temperature and / or flow rate.

This result in the first embodiment is achieved by the fact that the heat supply system contains a steam source, direct and return pipelines, a heat supply network of consumers, a jet pump having a nozzle for supplying an active medium and a nozzle for supplying a passive medium and an outlet pipe. The jet pump as a heat exchange device and circulation means, a nozzle for supplying an active medium is connected through a pipeline to a steam source, a nozzle for supplying a passive medium is connected to a return pipe and an outlet pipe is connected to a direct pipeline of the heat supply network. The difference lies in the fact that the buffer tank of the coolant is included in the return pipe, equipped with a system for additional heating of the coolant passing through the buffer tank.

The inclusion of the buffer tank for the coolant in the return pipe, with an additional heating system for the coolant in this buffer tank, allows you to adjust the temperature of the coolant at the inlet of the nozzle for supplying a passive medium of the main jet pump. In this case, by adjusting the temperature at the inlet of the passive nozzle of the main jet pump, it is possible to regulate the flow through the jet pump, and hence the heat power transmitted to consumers.

The system for additional heating of the coolant can be performed on the basis of any of the known systems for heating the liquid coolant.

In addition, the aforementioned system for additional heating of the coolant can be made in the form of an additional jet pump having a nozzle for supplying an active medium and a nozzle for supplying a passive medium and an outlet pipe, while the jet pump with a nozzle for supplying an active medium is connected through a pipe to a steam source, a nozzle for supplying a passive medium - to the output of the said buffer tank, and the output pipe is connected to the input of the said buffer tank, while on said pipeline connecting the source of steam and a nozzle for supplying the active medium of an additional jet pump, a control valve is installed.

In this case, an additional jet pump is used, supplied from the same source of steam. The temperature in the buffer tank is controlled by the amount of steam supplied to this additional jet pump. This amount of steam is determined by the control valve.

The capacity of the water supply or the source of water supply through the make-up valve can be connected to the return pipe, which allows you to replenish the loss of coolant.

At the inlet of the direct pipeline, after the jet pump, a valve can be installed to discharge excess coolant.

In the second embodiment, the heat supply system contains a steam source, direct and return pipelines, a heat supply network for consumers, a jet pump having a nozzle for supplying an active medium and a nozzle for supplying a passive medium and an outlet pipe, while the jet pump as a heat exchange device and means of circulation , a nozzle for supplying an active medium is connected through a pipeline to a steam source, a nozzle for supplying a passive medium is connected to a return pipe and an outlet pipe is connected to a direct pipeline of the lovodosnabzheniya. The buffer tank of the coolant, equipped with a system of additional heating of the coolant passing through the said buffer tank, is included in a direct pipeline. In this option, if necessary, the water entering the direct pipeline is heated, which leads to an increase in the thermal power of the coolant entering the consumers.

As in the first embodiment, the aforementioned system for additional heating of the coolant can be made in the form of an additional jet pump having a nozzle for supplying an active medium and a nozzle for supplying a passive medium and an outlet pipe, while the jet pump with a nozzle for supplying an active medium is connected through a pipeline to a source steam, a nozzle for supplying a passive medium to the outlet of the said buffer tank, and the outlet pipe is connected to the inlet of the said buffer tank, while on the said pipe connecting steam source and nozzle for supplying the active medium of an additional jet pump; a control valve is installed.

In this case, an additional jet pump is used, supplied from the same source of steam. The temperature in the buffer tank is controlled by the amount of steam supplied to this additional jet pump. This amount of steam is determined by the control valve.

In the third embodiment, the heat supply system also contains a steam source, direct and return pipelines, a heat supply network for consumers, a jet pump having a nozzle for supplying an active medium and a nozzle for supplying a passive medium and an outlet pipe, while the jet pump, as a heat exchange device and means of circulation , a nozzle for supplying an active medium is connected through a pipeline to a steam source, a nozzle for supplying a passive medium is connected to a return pipe and an outlet pipe is connected to a direct pipeline heat supply, The difference is that in the direct pipeline and in the return pipe are included buffer tanks of the coolant, equipped with a system of additional heating of the coolant passing through the mentioned buffer tanks.

As in the first and second versions, each of the aforementioned systems for additional heating of the coolant in the forward and reverse pipelines can be made in the form of an additional jet pump having a nozzle for supplying an active medium and a nozzle for supplying a passive medium and an outlet pipe, while the jet pump a nozzle for supplying an active medium is connected through a pipeline to a steam source, a nozzle for supplying a passive medium is connected to the output of the said buffer tank, and an output pipe is connected to the input of the mentioned buffer tank STI, wherein on said line connecting the steam source and a nozzle for supplying additional active medium of the jet pump, the control valve is installed.

In this case, an additional jet pump is used, supplied from the same source of steam. The temperature in the buffer tank is controlled by the amount of steam supplied to this additional jet pump. This amount of steam is determined by the control valve.

In the third version, it becomes possible to regulate not only the heat power supplied to consumers through the coolant, but also the average temperature of the coolant, as required by the heating system located at the consumers.

The invention is illustrated by drawings. Figure 1 shows a diagram of a heat supply system according to the first embodiment, Figure 2 - the same diagram with an additional jet pump, Figure 3 shows a diagram of a jet pump, Figure 4 - a diagram of a heat supply system according to a second embodiment, Figure 5 - the same diagram with an additional jet pump, Fig.6 is a diagram of a heat supply system according to the third embodiment with additional jet pumps.

The heat supply system according to the first embodiment (FIG. 1) contains a steam source 1, a straight pipe 2, a return pipe 3, a consumer heat supply network 4, a jet pump 5. The jet pump 5 (FIG. 1-2) has a nozzle 6 for supplying an active medium and a nozzle 7 for supplying a passive medium and an outlet pipe 8. The jet pump 5 is used as a heat exchange device and circulating means and the nozzle 6 is connected through a pipe to a steam source 1, by a nozzle 7 for supplying a passive medium to a return pipe 3, and an outlet pipe 8 to straight pipe rovodu 2.

In the return pipe 3 (FIG. 1), a buffer tank 9 of the coolant is included, equipped with a system 10 for additional heating of the coolant.

In this case, the most efficient additional heating system is based on a jet pump, although any other heating system can be used.

The system 10 for additional heating of the coolant (Figure 2) is made in the form of an additional jet pump 11 having a nozzle 12 for supplying an active medium and a nozzle 13 for supplying a passive medium and an outlet pipe 14, while the jet pump with a nozzle 12 for supplying an active medium is connected through a control a valve 15 to a steam source 1, a nozzle 13 for supplying a passive medium to the outlet of said buffer tank 9 and an outlet pipe 14 to the inlet of said buffer tank 9.

A water supply tank or a water supply source (not shown) is connected to a return pipe 3 through a make-up valve 16. At the inlet of the direct pipe 2, after the jet pump 5, a valve 17 is installed to discharge excess coolant.

As the jet pumps 5 and 11, in particular, the jet pump described in patent RU No. 2116522, publication 1998.07.27 can be used. As a rule, the additional jet pump 11 is a pump of lower power than the main jet pump 5.

The heat supply system operates as follows.

The Central source of steam 1 (Fig.1-2), for example a steam boiler, delivers steam through a pipe to the nozzle 6 for supplying the active medium of the jet pump 5. Through the return pipe 3 from the heat supply network 4, cooled water enters the nozzle 7 for supplying a passive medium, of the same jet pump 5. The steam entering the nozzle for supplying an active medium 6 of the jet pump 5 (Fig. 3) is accelerated, mixed in the mixing chamber with water entering through the nozzle 7 for supplying a passive medium. In the mixing chamber of the jet pump 5, flow acceleration and heat exchange processes between steam and water occur. Next, hot water through a direct pipe 2 is supplied to the heat supply network 4, and the chilled water returns from the network to the jet pump 5 through the return pipe 3.

The coolant from the return pipe 3 through the buffer tank 9 enters a nozzle 7 for supplying a passive medium of the main jet pump 5. An additional jet pump 11 (Figure 2) pumps the coolant through the tank 9. Since steam enters the jet pump 11, it heats the coolant. Therefore, the temperature of the coolant behind the buffer tank 9 is slightly higher than in the return pipe before the buffer tank 9.

If the temperature of the coolant in the return line 3 was accidentally reduced, this would cause an immediate change in the flow rate through the jet pump 5. But in this scheme, the temperature in the buffer tank 9 will decrease. In accordance with the properties of the jet pump, this will cause an increase in water flow through the additional jet pump 11. At the same time, the steam flow to the jet pump 11 will increase, and accordingly, the heating medium in the tank 9. As a result, the decrease in the temperature of the heat medium behind the tank 9 will be less than in the return pipe . If the temperature in the return pipe is accidentally increased, the picture will be reversed. Thus, the tank 9 with an additional jet pump 11 ensure that the flow rate of the coolant in the system is maintained.

The control valve 15 allows you to change the steam pressure in front of the steam nozzle of the additional jet pump 11. In accordance with the properties of the jet pump, increasing the steam pressure in front of the nozzle 12 to supply the active medium of the additional jet pump 11 causes an increase in water flow through the jet pump and a decrease in its injection coefficient. As a result, the heating of the coolant in the tank 9 will increase. Thus, the tank 9 with an additional jet pump 11 and a control valve 15 provide control of the coolant flow in the system.

The jet pump 5 constantly introduces into the heat supply system a flow equal to the steam flow. If the steam flow rate to the jet pump 5 is greater than the flow rate for hot water supply, then the heat carrier must be removed from the circuit, which is carried out through valve 17. If the steam flow rate to the jet pump 5 is lower than the flow rate to hot water supply, the heat transfer medium must be introduced into the heat supply system, which is carried out through valve 16. Almost the first takes place at night, when the flow rate for hot water supply is almost absent, the second - during the day.

The additional heating system 10 with other variants of its execution performs the same function and acts on the main jet pump 5 of the heat supply system in the same way.

The heat supply system according to the second embodiment (Fig. 4-5) contains a steam source 1, a straight pipe 2, a return pipe 3, a consumer heat supply network 4, a jet pump 5. The jet pump 5 is used as a heat exchange device and circulation means, and the nozzle 6 is connected through a pipeline to the steam source 1, nozzle 7 for supplying a passive medium to the return pipe 3, and the outlet pipe 8 to the direct pipe 2.

In the direct pipeline 2 (Figure 4), a buffer tank 18 of the coolant is included, equipped with a system 19 for additional heating of the coolant.

The system 19 for additional heating of the coolant (Figure 5) is made in the form of an additional jet pump 20 having a nozzle 21 for supplying an active medium and a nozzle 22 for supplying a passive medium and an outlet pipe 23, while the jet pump with a nozzle 21 for supplying an active medium is connected through a control a valve 24 to a steam source 1, a nozzle 22 for supplying a passive medium to the outlet of said buffer tank 18 and an outlet pipe 23 to an inlet of said buffer tank 18.

The heat supply system according to the second embodiment (Figure 5) works as follows.

The jet pump 5 delivers the coolant into the direct pipeline through the buffer tank 18. An additional jet pump 20 pumps the coolant through the tank 18. Since steam enters the jet pump 20, it heats the coolant. Therefore, the temperature of the coolant behind the tank 18 is slightly higher than after the jet pump 5.

If the temperature drops accidentally behind the jet pump 5, the temperature in the tank 18 will decrease. In accordance with the properties of jet pumps, this will increase the flow rate of water through the additional jet pump 20. At the same time, the steam flow rate to the jet pump 20 will increase, and, accordingly, the heating medium in the vessel 18. As a result, the decrease in the temperature of the medium behind the vessel 18 will be less than after the jet pump 5. If the temperature rises behind the jet pump 5, the picture will be reversed. Thus, the tank 18 with an additional jet pump 20 maintain the temperature of the coolant in the direct pipe.

The heat supply system according to the third embodiment includes buffer tanks 9 and 18, as well as systems 10 and 19 for additional heating of the coolant.

The system contains a steam source 1, a straight pipe 2, a return pipe 3, a consumer heat supply network 4, a jet pump 5. The jet pump 5 is connected by a nozzle 6 through a pipe to a steam source 1, by a nozzle 7 for supplying a passive medium to a return pipe 3, and an output pipe 8 to the direct pipe 2.

In the direct pipeline 2 (FIG. 6), the buffer tank 18 of the coolant is equipped with a system 19 for additional heating of the coolant, and in the return pipe, the buffer tank 9 of the coolant equipped with system 10 for additional heating of the coolant.

Systems 10 and 19 for additional heating of the coolant (Fig. 6) are made in the form of additional jet pumps 11 and 20 having nozzles 12 and 21 for supplying an active medium and nozzles 13 and 22 for supplying a passive medium and outlet pipes 14 and 23, while the jet the pump nozzle for supplying an active medium is connected through the corresponding control valve 15 or 24 to the steam source 1.

The operation of the heat supply system according to the third option combines the capabilities of the first and second options and provides an additional opportunity to control the modes of supplying the consumer with a coolant more widely and more flexibly.

Claims (12)

1. A heat supply system containing a steam source, direct and return pipelines, a heat supply network for consumers, a jet pump having a nozzle for supplying an active medium and a nozzle for supplying a passive medium and an outlet pipe, the jet pump being a heat exchange device and a circulation means, a nozzle for supplying an active medium is connected through a pipeline to a steam source, a nozzle for supplying a passive medium is connected to a return pipe and an outlet pipe is connected to a direct pipeline of the heat supply network I, characterized in that the return line is enabled coolant buffer capacity, equipped with an additional heating system coolant flowing through said buffer tank. 2. The heat supply system according to claim 1, characterized in that the aforementioned system for additional heating of the coolant is made in the form of an additional jet pump having a nozzle for supplying an active medium and a nozzle for supplying a passive medium and an outlet pipe, while the jet pump is a nozzle for supplying an active medium connected through a pipeline to a steam source, a nozzle for supplying a passive medium to the outlet of said buffer tank and an outlet pipe connected to the inlet of said buffer tank, while on said pipes to the wire connecting the steam source and the nozzle for supplying the active medium of the additional jet pump, a control valve is installed. 3. The heat supply system according to claim 1, characterized in that the capacity of the water supply or the water supply through the make-up valve is connected or connected to the return pipe. 4. The heat supply system according to claim 1, characterized in that a valve is installed at the inlet of the direct pipeline to discharge excess coolant. 5. A heat supply system containing a steam source, direct and return pipelines, a heat supply network for consumers, a jet pump having a nozzle for supplying an active medium and a nozzle for supplying a passive medium and an outlet pipe, while the jet pump as a heat exchange device and means of circulation, a nozzle for supplying an active medium is connected through a pipeline to a steam source, a nozzle for supplying a passive medium is connected to a return pipe and an outlet pipe is connected to a direct pipeline of the heat supply network I, characterized in that the straight line is included coolant buffer capacity, equipped with an additional heating system coolant flowing through said buffer tank. 6. The heat supply system according to claim 5, characterized in that the aforementioned system for additional heating of the coolant is made in the form of an additional jet pump having a nozzle for supplying an active medium and a nozzle for supplying a passive medium and an outlet pipe, while the jet pump is a nozzle for supplying an active medium connected through a pipeline to a steam source, a nozzle for supplying a passive medium to the outlet of said buffer tank and an outlet pipe connected to the inlet of said buffer tank, while on said pipes to the wire connecting the steam source and the nozzle for supplying the active medium of the additional jet pump, a control valve is installed. 7. The heat supply system according to claim 5, characterized in that the water supply capacity or the water supply source through the make-up valve is connected to a return pipe. 8. The heat supply system according to claim 5, characterized in that a valve is installed at the inlet of the direct pipeline to discharge excess coolant. 9. A heat supply system comprising a steam source, direct and return pipelines, a consumer heat supply network, a jet pump having a nozzle for supplying an active medium and a nozzle for supplying a passive medium and an outlet pipe, the jet pump being a heat exchange device and a circulation means, a nozzle for supplying an active medium is connected through a pipeline to a steam source, a nozzle for supplying a passive medium is connected to a return pipe and an outlet pipe is connected to a direct pipeline of the heat supply network I, characterized in that the straight conduit and the return conduit include buffering coolant vessel equipped with an additional heating system coolant flowing through said buffer tanks. 10. The heat supply system according to claim 9, characterized in that said additional coolant heating systems are made in the form of an additional jet pump having a nozzle for supplying an active medium and a nozzle for supplying a passive medium and an outlet pipe, while the jet pump is a nozzle for supplying an active medium connected through a pipeline to a steam source, a nozzle for supplying a passive medium - to the outlet of said buffer tank and an outlet pipe connected to the inlet of said buffer tank, while on said pipe oprovode connecting the steam source and a nozzle for supplying additional active medium of the jet pump, the control valve is installed. 11. The heat supply system according to claim 9, characterized in that the capacity of the water supply or the source of water supply through the make-up valve is connected to the return pipe. 12. The heat supply system according to claim 9, characterized in that a valve is installed at the inlet of the direct pipeline to discharge excess coolant.

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