RU184672U1 - All-mode gas-water heater with protection against low-temperature corrosion on the gas side, designed to heat the working fluid of the cycle and network water of the heating network - Google Patents

Abstract

The utility model relates to heat exchange technology and can be used in hot water boilers, industrial hot water recovery boilers, gas condensate heaters, network and make-up water of waste heat boilers installed behind gas turbines and diesel engines, etc. to protect gas-water heat exchangers from low-temperature corrosion on the gas side, resulting from condensation of water vapor contained in flue gases at a cold heat exchange surface, at rated power, as well as for heating network water of the heating network. The gas-water heat exchanger comprises a heat exchange surface, a cold condensate pipe, a hot condensate pipe, a cold condensate bypass pipe, a common bypass pipe, and a water / water heat exchanger. The heat exchange surface is divided into three sections connected in series through the water. The cold condensate bypass line is designed to control the heat load of the upstream water heater. The common bypass pipe is designed to adjust the temperature of the condensate in the outlet pipe. The water-to-water heat exchanger is designed to transfer thermal energy of the working fluid of the cycle to the network water. The utility model provides a corrosion-free mode of operation of the heating surface under all operational loads, heating the water of the cycle, as well as heating the network water in the range of 95-150 ° C by transferring part of the thermal energy of the water of the cycle of the network water in the water-to-water heat exchanger.

Description

The utility model relates to heat exchange technology and can be used in hot water boilers, industrial hot water heat recovery boilers, gas condensate heaters, network and make-up water of heat recovery boilers installed behind gas turbines and diesel engines, etc. to protect gas-water heat exchangers from low-temperature corrosion on the gas side resulting from condensation on the cold heat exchange surface of water vapor contained in the flue gases, in all operational uzkah, as well as for heating-system water district heating network.

Known gas-water heat exchanger containing a heat exchange surface, a supply pipe to the cold water heat exchanger and a means of increasing the temperature of cold water at the inlet of the heat exchanger to a value exceeding the dew point of water vapor in the heating gases [1] is an analogue. The means for raising the temperature of cold water at the inlet to the heat exchanger according to [1] is made in the form of a recirculation pipe equipped with a pump connecting the hot water outlet of the heat exchanger with a cold water pipe. The heat exchanger is a water boiler equipped with an economizer included in the recirculation loop, and the recirculation pipe of the water heated in the boiler is connected to the input of the water economizer.

The disadvantages of the known heat exchanger [1] are the necessity of using a recirculation pump of greater productivity, significant energy costs for creating the recirculation flow necessary to heat the water entering the boiler to a temperature safe under conditions of low-temperature corrosion.

A gas-water heat exchanger is known, comprising a heat exchange surface divided into at least two sections connected in series by water, a cold water supply pipe to the first section, a bypass pipe for mixing cold water in a cascade scheme into all other sections, and means for raising the temperature of cold water by the entrance to the first of the mentioned sections to a value exceeding the dew point of water vapor in the heating gases [2] is a prototype. The means for raising the temperature of cold water according to [2], as in [1], is a recirculation pipe equipped with a pump. By reducing the amount of recirculated water as a result of mixing cold water into all sections of the heat exchange surface, the technical solution [2] allows to reduce the energy consumption for recirculation, but cannot completely eliminate the need for a recirculation pump.

The disadvantages of the known heat exchanger [2] are the need to use a recirculation pump, which is an energy consumer to create the recirculation flow necessary to heat the water entering the boiler to a temperature safe under conditions of low temperature corrosion.

A gas-water heat exchanger is known, comprising a heat exchange surface divided into at least two sections connected in series through water, a cold water supply pipe to the first section, a bypass pipe for mixing cold water in a cascade circuit to all other sections, and means for raising the temperature of cold water at the entrance to the first of the mentioned sections to a value exceeding the dew point of water vapor in the heating gases [3], the said means is made in the form of an aqueous-cold water pre-heater, p CONNECTIONS of heating medium to the outlet of hot water from the last section of the heat exchange surface.

The disadvantages of the known heat exchanger [3] are the inability to transfer part of the thermal energy of the working fluid of the cycle network water to the heating network.

The gas-water heat exchanger closest in designation and effect is known, comprising a heat exchange surface divided into three sections connected in series through water, a cold condensate pipeline, a hot condensate pipeline, a water-water heat exchanger designed to transfer heat energy of the working fluid of the cycle to network water [4].

The disadvantages of the known heat exchanger [4] is the inability to heat network water to a temperature of more than 110 ° C.

The achievable result of the utility model is the expansion of the control range of the water-to-water heat exchanger designed to heat the network water, which allows heating the network water to a temperature of 150 ° C inclusive, thereby ensuring the fulfillment of the temperature schedule of the heating network at low ambient temperatures, while increasing the thermal the load of the heater in question, which leads to a deeper cooling of the flue gases at the outlet.

Obtaining this result is ensured by the fact that in a gas-water heat exchanger containing a heat exchange surface divided into three sections connected in series by water, a cold condensate pipe, a cold condensate bypass pipe for regulating the heat load of an upstream water heater, a hot condensate pipe, a common bypass pipe for adjusting the condensate temperature in the outlet pipe, condensate recirculation pump, water-to-water heat exchanger, intended started to transfer thermal energy of the working fluid of the cycle to the network water, a part of the working medium of the cycle intended for heating the network water is taken condensate with high potential from the pipeline of hot condensate.

The drawing shows, by way of example, a circuit for switching on a gas-water heater (gas condensate heater) according to a utility model for the heated side (water) and the heating side (flue gas).

The heater in a particular case contains three pipe sections 1.1, 1.2, 1.3, a heat exchange surface located in the gas duct 2 and connected in series through water by lines 3 of the main flow of the working fluid (condensate) and washed by a flow of 4 flue gases, a cold water supply pipe 5 to the upstream water heater 6, three-way valve 7 for redistributing cold condensate between the bypass pipeline of cold condensate 8 and the upstream water heater 6, the pipeline of hot condensate 9, common bypass pipe a wire 10 with a control valve 11 installed on it to adjust the temperature of the condensate in the outlet pipe 12, a condensate recirculation pump 13, which supplies the heated working fluid of the cycle to the water-to-water heat exchanger 14, designed to transfer the thermal energy of the working fluid of the cycle to the network water, the control valve 15 to regulate the heat load of the water-water heat exchanger 10, respectively, and the temperature of the network water in the range of 95-150 ° C.

The operation of the gas-water heater according to the utility model is as follows. Cold condensate enters the gas-water heater, parallel to the inlet pipe 4, an upstream water heater 6 is included, in which the condensate is heated to safe from the point of view of low-temperature corrosion at the entrance to the pipe section 1.1. The thermal load of the upstream water heater 6 is equal to the amount of energy needed to heat the entire amount of the working fluid before supplying to the pipe section 1.1 to a temperature of at least 60 ° C. The heat load of the upstream water heater 6 is regulated using a three-way valve 7 by redistributing cold water between the cold condensate bypass pipe 8 and the upstream water heater 6. In the pipe section 1.1, the working fluid is heated to a temperature of 80 -110 ° C, then the working fluid is sent to the upstream water heater 6, where the working fluid entering the gas-water heater is heated before being fed into the pipe section 1.1. Having given part of the thermal energy in the pre-heater 6, the working fluid is sent to the pipe section 1.2 for heating to a temperature of 80-110 ° C. For the final heating, the working fluid is sent to the pipe section 1.3 and then to the hot condensate pipeline 9. From the hot condensate pipeline 9 the selection of the working fluid by means of a condensate recirculation pump 13, which is sent to the water-to-water heat exchanger 14. In the water-to-water heat exchanger 14, the heating water is heated in the range 95-150 ° C in accordance with schedule-temperature district heating network. Regulation of the heat load of the water-water heat exchanger 14, respectively, and the temperature of the supply water, is carried out using the valve 15. Regulation of the heat load of the gas-water heater, respectively, and the correction of the temperature of the condensate in the outlet pipe 12 is carried out by supplying part of the condensate, bypassing the pipe sections 1.1, 1.2, 1.3, through a common bypass pipe 10, flow control through a common bypass pipe 10 is carried out using the control valve 11.

Information sources:

1. USSR copyright certificate No. 1390489, 4 F24H 1/00, 1986.

2. Application No. 2003111636 of 04.25.2003 for the grant of a patent of the Russian Federation for a utility model

3. Application No. 2003123377 of 08/05/2003 for the grant of a patent of the Russian Federation for a utility model

4. Patent of the Russian Federation for utility model 180217, publ. 06/06/2018, bull. Number 16

Claims (1)

A gas-water heat exchanger containing a heat exchange surface divided into three sections connected in series by water, a cold condensate pipe, a cold condensate bypass pipe for regulating the heat load of an upstream water heater, a hot condensate pipe, a common bypass pipe for adjusting the condensate temperature in the outlet pipe, a condensate recirculation pump, water-to-water heat exchanger designed to transfer thermal energy of the working fluid of the cycle network water

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