RU32867U1 - Gas-water heat exchanger with protection against low-temperature corrosion on the gas side and deep power control - Google Patents

Abstract

A gas-water heat exchanger containing a heat exchange surface, a cold water supply pipe to the heat exchanger, a recirculation pipe with a pump for heating cold water at the inlet of the heated water in the heat exchanger, a control valve for controlling the temperature of the water at the inlet to the heat exchanger and a control valve for controlling the temperature of the outlet water from a heat exchanger, characterized in that the heat exchange surface is divided into at least two sections, the surface of each subsequent section exceeding n the surface of the previous section is not less than 20%, the heat exchanger is additionally equipped with a cold water bypass pipe connected to by-pass pipes with all sections except the first and a heated water pipe at the outlet of the heat exchanger, a throttle device is installed in each branch pipe to the heat exchanger sections, which controls a valve for controlling the temperature of the water at the inlet to the heat exchanger is installed on the cold water supply pipe to the first section, a control valve for regulating the rate water at the outlet of the heat exchanger - at the outlet of the bypass pipe to the heated water pipe at the outlet of the heat exchanger, and between the outlet of the last section and the mixing point with the bypass pipe, an additional control valve is installed.

Description

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 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 of water vapor contained in flue gases at a cold heat exchange surface, at rated power, and also to provide a given law for changing the temperature of water at the outlet of the heat exchanger with a decrease in its thermal power.

The gas-water heat exchanger closest in purpose and achieved result to the proposed utility model is known, comprising a heat exchange surface, a supply pipe to a cold water heat exchanger, a recirculation pipe with a pump for heating cold water at the inlet of the heated water in the heat exchanger, a control valve for controlling the temperature water at the inlet to the heat exchanger and a control valve for regulating the temperature of the water at the outlet of the heat exchanger 1. The specified heat exchanger is a a pre-heating boiler equipped with an economizer included in an additional recirculation circuit, the recirculation pipe of the water heated in the boiler is connected to the inlet of the water economizer, and a control valve for controlling the water temperature at the inlet to the heat exchanger is installed on the recirculation pipe.

The disadvantages of the known heat exchanger 1 are the need for a larger pump, 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, which is aggravated by a decrease in the temperature difference between cold and heated water in the economizer, as well as the need regulation of the flow of recirculated water to maintain a predetermined temperature at the entrance to the boiler.

The achieved result of the utility model is the reduction of capital costs for equipment, the reduction of energy consumption for the drive of the recirculation pump, as well as the ability to maintain the set temperature of the water heated in the heat exchanger or the set law of the temperature change of the water heated in the heat exchanger with a more significant decrease in the heat capacity of the heat exchanger.

Obtaining the indicated result is ensured by the fact that in the gas-water heat exchanger containing the test surface, the cold water supply pipe to the heat exchanger, a recirculation pipe with a pump for heating cold water at the inlet to the heat exchanger with heated water therein, a control valve for controlling the temperature of the water at the inlet to the heat exchanger and control valve for controlling the temperature of the water leaving the heat exchanger, according to the invention, the heat exchange surface is divided into at least two sections and, moreover, the surface of each subsequent section exceeds the surface of the previous section by at least 20%,%, the heat exchanger is additionally equipped with a bypass cold water pipe connected by drain pipes to all sections except the first and to the heated water pipe at the outlet of the heat exchanger, in each a throttle device, a control valve for regulating the water temperature at the inlet to the heat exchanger is installed on the cold water supply pipe, is installed to the sections of the heat exchanger We are in the first section, the control valve for regulating the temperature of the water at the outlet of the heat exchanger - at the bypass pipe outlet to the heated water pipeline at the heat exchanger outlet, and an additional control valve is additionally installed between the outlet of the last section and the mixing point with the bypass pipeline.

The drawing as an example shows a diagram of the inclusion of a gas-water heat exchanger according to a utility model on the heated side (water). The heat exchanger in the particular case contains four pipe.

sections 1.1, 1.2, 1.3, 1.4, each section has an input collector 2.1, 2.2, 2.3, 2.4, respectively, and an output collector 3.1, 3.2, 3.3, 3.4, respectively. Each output manifold 3.1, 3.2, 3.3 of the previous pipe section is connected to the input collector 2.2, 2.3, 2.4 of the subsequent pipe section, respectively, bypass pipes 4.1, 4.2, 4.3. All pipe sections 1.1-1.4 are blown by a common stream of flue gases (not shown in the drawing). The sections are connected to a common cold water supply pipe 5, equipped with a 5.1 pump and having bends 6.1, 6.2, 6.3, 6.4, 6.5. Moreover, branch 6.1 is connected to the inlet manifold 3.1 of the first pipe section, branches 6.2-6.4 to the intersection bypass pipes 4.1-4.3, and branch 6.5 to the outlet pipe 7 of heated water, equipped with a check valve 7.1 and connected to the outlet manifold 3.4 of the latter running water of the pipe section 1.4. On the inlet branch 6.1 and the final branch 6.5 of cold water, a control valve 8.1 is installed, respectively, for regulating the water temperature at the inlet to the heat exchanger and a control valve 8.5 for regulating the water temperature at the outlet of the heat exchanger, and on the intermediate branches 6.2-6.4, throttle devices 9.2, 9.3 , 9.4. The outlet pipe of the heated water is connected to the cold water outlet 6.1 to the first pipe section 1.1 by a recirculation pipe 10 equipped with a pump 10.1.

The heat exchanger is as follows. Pump 5.1 cold water is pumped into the supply pipe 5. Through the drain 6.1 a small amount of cold water enters the first section 1.1 of the heat exchanger, preheating to a safe temperature (60 ° C) under conditions of low-temperature corrosion due to mixing with recirculated heated water, which is pumped by the pump 10.1 constant

performance. The water temperature at the inlet to the section is maintained within the specified limits by the control valve 8.1 installed on the cold water outlet 6.1 in the first section 1.1 From the section 1.1 water bypass

the new pipeline 4.1 enters section 1.2, pre-cooled by mixing with cold water coming from branch 6.2. Further, in a similar way, water is transferred sequentially through all sections of the heat exchanger, pre-cooled at the beginning of each section 1.2-1.4 with a portion of the initial cold water coming from the outlets 6.2-6.4. Since in each subsequent section 1.1-1.4, compared with the previous one, more water is supplied for heating, the heat exchange surface of each subsequent pipe section is increased by the value determined in each case by thermal calculation. According to a utility model, the surface of each subsequent section exceeds the surface of the previous section by at least 20%.

At maximum power of the heat exchanger, the backup control valve 7.1. fully open, control valve 8.5 is fully closed, control valve 8.1 maintains the minimum allowable water temperature at the inlet to the first section, the set water temperature behind the heat exchanger is ensured by the appropriate choice of the heating surface of the heat exchanger. If necessary, reduce the heat capacity of the heat exchanger, in

including regardless of the temperature and gas flow rate at the inlet to the heat exchanger, the water flow rate at the inlet to the heat exchanger is reduced. Wherein:

- valve 7.1. it maintains a preset value of the pressure drop between the inlet and outlet of the heat exchanger, which makes it possible to control the water temperature at the outlet of the heat exchanger with a valve 8.5, as well as the stability of the flow rate generated by the recirculation pump.

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1

-valve 8.1, depending on the ratio of the amount of heat entering the heat exchanger with the heating gases and the required heat capacity of the heat exchanger, implements the specified law of changing the temperature of the water entering the first section. In this case, the value of the water temperature at the inlet to the first section should always be between the minimum and max.

acceptable values.

-valve 8.5 regulates the temperature of the water leaving the heat exchanger.

Deep regulation of the heat exchanger power is ensured by the fact that the power is reduced by reducing the temperature head both at the outlet of the heat exchanger (valve 8.5) and at the inlet to the heat exchanger (valve 8.1). If the saturation temperature at the water pressure at the outlet of the heat exchanger is higher than the temperature of the heating gases, the heat capacity of the heat exchanger can be reduced to zero, while the heat exchanger remains ready for immediate heat release.

Throttle devices on bends 6.2-6.4 provide such (unregulated) costs at which the temperatures at the inlets in sections 1.2-1.4 are maintained at a level not lower than 60 ° C. In the calculated operating mode (the mode with the maximum water flow through the heat exchanger), the inlet temperature to the first section 1.1 is maintained at 60 ° C by

changes in the flow of cold water in the tap 6.1. If the total water flow through the heat exchanger decreases, compared with the calculated value, the outlet temperature of the heated water is ensured provided that the temperature at the inlet to the first section increases above 60 ° C, which in this case slightly affects the efficiency of the heat exchanger.

The advantage of a gas-water heat exchanger according to a utility model is that for heating cold water in front of the first section of the heat exchanger, a minimum consumption of recirculated heated water is required, which significantly increases the cost-effectiveness of this heat exchanger, according to

Compared to the prototype. Another advantage of the gas-water heat exchanger according to the utility model is the reduction of the minimum load,

at which the required water temperature is provided at the outlet of the heat exchanger.

Sources of information 1. The author's certificate of the USSR, No. 1390489, 4 F24H 1/00, 1986.

Claims (1)

A gas-water heat exchanger containing a heat exchange surface, a cold water supply pipe to the heat exchanger, a recirculation pipe with a pump for heating cold water at the inlet of the heated water in the heat exchanger, a control valve for controlling the temperature of the water at the inlet to the heat exchanger and a control valve for controlling the temperature of the outlet water from a heat exchanger, characterized in that the heat exchange surface is divided into at least two sections, the surface of each subsequent section exceeding n the surface of the previous section is not less than 20%, the heat exchanger is additionally equipped with a cold water bypass pipe connected to by-pass pipelines with all sections except the first and a heated water pipe at the outlet of the heat exchanger, a throttle device is installed in each by-pass pipe to the heat exchanger sections, which regulates a valve for controlling the temperature of the water at the inlet to the heat exchanger is installed on the cold water supply pipe to the first section, a control valve for regulating the rate water at the outlet of the heat exchanger - at the outlet of the bypass pipe to the heated water pipe at the outlet of the heat exchanger, and between the outlet of the last section and the mixing point with the bypass pipe, an additional control valve is installed.