KR20180072097A - CMCP steam condensation water recycling system - Google Patents

Abstract

Disclosed is a CMCP steam condensate recycling system with a new structure to recycle steam condensate discharged from a CMCP drier. The CMCP steam condensate recycling system according to the present invention can automatically supply condensate to a white water tank according to temperature and conductivity of the condensate transferred through a condensate transfer line or discharges the condensate through a bypass line so as to select and recycle only condensate with temperature and conductivity suitable for recycling. Therefore, the CMCP steam condensate recycling system can minimize increase of costs in disuse of the condensate and production of pure water, and prevent malfunction of a boiler, a turbine or a CMCP drier caused by recycling of inadequate condensate since automatically disusing condensate with temperature and conductivity, which do not meet the standards. The CMCP steam condensate recycling system comprises: a water reservoir tank for storing condensate discharged from a CMCP drier; a white water tank for storing pure water manufactured in a pure water manufacturing facility; condensate transfer lines for connecting the water reservoir tank and the white water tank with each other; a bypass line connected to an intermediate part of the condensate transfer lines to partition the condensate transfer lines into a supply part of the front and a discharge part of the rear; a thermometer and a conductivity analyzer disposed in the supply part to measure temperature and conductivity of the condensate flowing through the supply part; and a control means, which makes the condensate transferred to one among the bypass line and the discharge part according to signals of the thermometer and the conductivity analyzer.

Description

[0002] CMCP steam condensation water recycling system [0003]

The present invention relates to a CMCP steam condensate recycling system of a new structure capable of recycling the steam condensate discharged from the CMCP dryer.

Generally, as shown in FIG. 1, the CMCP dryer used for drying the coke making coke oven at a water content of about 5 to 6% has a boiler installed in a CDQ (Coke Dry Quenching) Pressure steam generated in the boiler 1 is used as a heat source.

At this time, steam of high temperature and high pressure (105 kg / cm 3, 545 ° C) is generated in the boiler 1 of the CDQ facility, and the steam of high temperature and high pressure thus generated is supplied to the generator turbine 2 through the first pipe 1 a (13.2 kg / cm 3, 210 ° C), and the steam having the lowered temperature and pressure passing through the generator turbine 2 is supplied through the second pipe 2a CMCP dryers (3), and Hwasung, acupuncture points, and steel mills.

The steam supplied to the CMCP dryer (3) is supplied to the CMCP dryer (3), and the steam supplied to the CMCP dryer (3) is supplied to the CMCP dryer (3) And the condensed water thus discharged is discharged through the discharge pipe 3a and discarded.

Here, the water used for generating the steam in the boiler 1 of the CDQ plant uses pure water specially prepared in the pure water production facility.

Therefore, when the steam passing through the CMCP drier 3 is discarded, the amount of pure water used is increased, and accordingly, a larger amount of pure water must be produced. Therefore, the amount of raw water used for producing pure water, The use amount of the water is increased, which causes an increase in energy loss and pure water production cost.

In addition, there is a problem that the purification treatment cost for purifying the discarded pure water also increases.

Therefore, there is a need for a new method to solve such a problem.

Korean Patent No. 10-0862865 Korean Patent No. 10-0737112

SUMMARY OF THE INVENTION It is an object of the present invention to provide a CMCP steam condensed water recycling system having a new structure capable of recycling steam condensed water discharged from a CMCP dryer.

To achieve the above object, the present invention provides a CMCP steam condensed water recycling system for recycling steam condensed water discharged from a CMCP dryer, comprising: a water storage tank for storing condensed water discharged from the CMCP dryer; A white water tank for storing pure water manufactured in a pure water manufacturing facility; A condensate transfer line connecting the water storage tank and the white water tank; A bypass line connected to an intermediate portion of the condensate transfer line for partitioning the condensate transfer line into a forward supply portion and a rear discharge portion; A temperature measuring unit and a conductivity measuring unit provided in the supplying unit to measure the temperature and the conductivity of the condensed water flowing through the supplying unit; And control means for allowing the condensed water to be transferred to either the bypass line or the discharge portion in accordance with the signals of the temperature meter and the conductivity meter.

The CMCP steam condensed water recycling system according to the present invention includes a condensate pump provided in the supply unit to transfer condensate stored in the reservoir tank to the discharge unit or the bypass line; And a cooler connected to a supply unit behind the condensed water pump to cool the condensed water passing through the supply unit.

The CMCP steam condensed water recycling system according to the present invention may further include a bypass control valve and a discharge portion control valve provided in the bypass line and the discharge unit such that the bypass line and the discharge unit are opened or closed, Wherein the control means controls the bypass control valve and the discharge portion control valve so that the valve is opened or closed inversely to each other according to the temperature and the conductivity of the condensed water, Tank, or discharged through the bypass line to be discarded.

Wherein the control means opens the bypass control valve and closes the discharge control valve when the temperature of the condensed water received from the temperature meter and the conductivity meter is 90 DEG C and the conductivity is 5 mu s / Line, and when the temperature of the condensate received from the temperature meter and the conductivity meter is lower than 90 占 폚 and 5 占 / / cm3, the discharge control valve is opened and the bypass control valve is closed, May be supplied to the white water tank through the discharge portion.

The cooler comprising: a primary cooling line connected to the supply and passing through a natural circulation pond; And a secondary cooling line connected to the supply to be located behind the primary cooling line and passing through the heat exchanger.

The CMCP steam condensate recycling system according to the present invention comprises a pair of first gate valves provided at both ends of the primary cooling line; A second gate valve provided at an intermediate portion of the supply unit such that the first cooling line is located between the connection portions, and a pair of third gate valves provided at both ends of the second cooling line; And a fourth gate valve disposed in the middle of the supply unit such that the first to fourth gate valves are selectively opened and closed so that the first to fourth gate valves are opened and closed, And the flow of condensate through the secondary cooling line.

In the CMCP steam condensate recycling system according to the present invention, depending on the temperature and conductivity of the condensed water conveyed through the condensate transfer line, the condensate is automatically supplied to the white water tank or discharged through the bypass line, whereby the temperature and the conductivity are recycled Only suitable condensate can be selected and recycled.

Therefore, it is possible to minimize the increase in cost due to the manufacture and disposal of pure water due to the disposal of the condensed water, as well as the automatic discarding of the condensate whose temperature and conductivity do not meet the standard, thereby reusing the improper condensate, It is possible to prevent a problem from occurring in a dryer or the like.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing the flow of steam supplied to a general CMCP dryer. FIG.
FIG. 2 is a view showing a CMCP steam condensed water recycling system according to the present invention. FIG.
3 to 5 are reference views showing the operation of the CMCP steam condensate recycling system according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 to 5 are views showing a CMCP steam condensed water recycling system according to the present invention. In the CMCP steam condensed water recycling system according to the present invention, the steam condensed water discharged from the CMCP dryer 3 is recycled, Thereby reducing the increase in cost.

The CMCP steam condensing water recycling system according to the present invention includes a water storage tank 10 connected to the CMCP dryer 3 for storing condensed water discharged from the CMCP dryer 3, And a condensate transfer line 31 and 32 connecting the reservoir tank 10 and the whitewater tank 20 to each other.

In addition, the CMCP steam condensate recycling system according to the present invention is connected to the middle part of the condensate transfer lines 31 and 32 to supply the condensed water transfer lines 31 and 32 to the front supply part 31 and the rear discharge part 32 And a condensate pump 50 provided in the supply unit 31 to transfer the condensed water stored in the reservoir tank 10 to the discharge unit 32 or the bypass line 40 .

In addition, the CMCP steam condensate recycling system according to the present invention includes a cooler 60 connected to a feeder 31 to cool condensate passing through a feeder 31 and a cooler 60 to be positioned behind the cooler 60 in the feeder 31. [ A temperature measuring device 70 and a conductivity measuring device 80 which measure the temperature and the conductivity of the condensed water flowing through the supply part 31, respectively.

In the CMCP steam condensate recycling system according to the present invention, the bypass line 40 and the discharge unit 32 are respectively provided with a bypass line 40 and a discharge unit 32, The control unit 110 includes a control valve 90 and a discharge control valve 100. The control unit 110 is connected to the temperature meter 70 and the conductivity meter 80 to control the bypass control valve 90 and the discharge control valve 100 are controlled.

In the CMCP steam condensed water recycling system according to the present invention, the water storage tank 10 is connected to the CMCP dryer 3 through the connection pipe 11, and the steam supplied to the dryer 3 is condensed and generated And is configured to store condensate.

The white water tank 20 is connected to the pure water production facility 4 through a water supply pipe 21 and stores pure water supplied from the pure water production facility 4. The pure water is supplied to the boiler 1 The pure water produced in the pure water production facility 4 and the condensed water supplied through the condensate transfer lines 31 and 32 as described later are stored in the boiler 1 of the CDQ facility, As shown in FIG.

The bypass line 40 is connected to a separately provided pit 41 for discharging the condensed water supplied through the supply unit 31 to the waste water pit 41 and disposing it.

The cooler 60 includes a primary cooling line 61 connected to the supply unit 31 and passing through a natural circulation pond 61a and a second cooling line 61 connected to the supply unit 31 at a position behind the primary cooling line 61 A second cooling line 62 passing through the heat exchanger 62a and a pair of first gate valves 63 provided at both ends of the primary cooling line 61, A second gate valve 64 provided at an intermediate portion of the supply part 31 so as to be positioned between the connecting parts connected to the second cooling line 62, And a fourth gate valve 66 provided in the middle of the supply part 31 so as to be positioned between the valve 65 and the connection part to which the secondary cooling line 62 is connected.

Accordingly, the first to fourth gate valves 63, 64, 65 and 66 are selectively opened and closed to control the flow of the condensed water flowing into the primary cooling line 61 and the secondary cooling line 62 can do.

3 and 4, when the first gate valve 63 and the third gate valve 65 are opened and the second gate valve 64 and the fourth gate valve 66 are closed, The condensed water that is pressurized by the condensate pump 50 and flows through the supply unit 31 is cooled in two stages while passing through the primary cooling line 61 and the secondary cooling line 62. [

When the second gate valve 64 and the fourth gate valve 66 are opened and the first gate valve 63 and the third gate valve 65 are closed, The condensed water is directly conveyed rearward without passing through the primary cooling line 61 and the secondary cooling line 62. [

Various types of the temperature measuring instrument 70 and the conductivity measuring instrument 80 have been developed and widely used, and a detailed description thereof will be omitted.

The bypass control valve 90 and the discharge portion control valve 100 are provided with a motor that is operated in accordance with an electric signal of the control means 110 to control the operation of the motor, .

The control unit 110 receives the signals of the temperature meter 70 and the conductivity meter 80 and controls the bypass control valve 90 and the outlet control valve 100 according to the temperature and the conductivity of the condensed water. So that the condensed water is supplied to the whitewater tank 20 through the discharge portion 32 or the condensed water is discharged through the bypass line 40 and discarded.

3, the control means 110 controls the discharge control valve 100 to open the discharge control valve 100, and when the condensed water is at a temperature of 90 ° C. and 5 μs / The bypass control valve 90 is closed so that the condensed water is supplied to the white water tank 20 through the discharge portion 32. [

On the contrary, if the condensed water is 90 ° C and 5 μs / cm 3 or more, the control means 110 opens the bypass control valve 90 and closes the discharge control valve 100 as shown in FIG. So that the condensed water is discharged to the waste water pit 41 through the bypass line 40 and discarded.

The CMCP steam condensate recycling system thus configured can automatically supply the condensed water to the white water tank 20 or the bypass line 40 according to the temperature and the conductivity of the condensed water transferred through the condensate transfer lines 31 and 32 , It is possible to select and recycle only the condensed water suitable for recycling the temperature and the conductivity.

Accordingly, it is possible to minimize the increase in cost due to the manufacture and disposal of pure water due to the disposal of the condensed water, as well as to automatically discard the condensate whose temperature and conductivity do not meet the criteria, The turbine 2, the CMCP dryer 3, and the like can be prevented.

The cooler 60 includes a primary cooling line 61 connected to the supply unit 31 and passing through a natural circulation pond 61a and a cooling fan 61 connected to the supply unit 31, And a secondary cooling line 62 passing through the heat exchanger 62a so as to cool the condensed water passing through the supply unit 31 to a proper temperature by using the minimum energy.

Particularly, the cooler 60 is provided with a pair of first gate valves 63 provided at both ends of the primary cooling line 61 and a connecting portion connected to the primary cooling line 61, A second gate valve 64 provided at an intermediate portion of the supply unit 31, a pair of third gate valves 65 provided at both ends of the secondary cooling line 62, The first to fourth gate valves 63, 64, 65, and 66 are selectively provided in the middle of the supply part 31 so that the first to fourth gate valves 63, 64, So that the flow of the condensed water flowing into the primary cooling line 61 and the secondary cooling line 62 can be controlled.

Therefore, when the cooler 60 is maintained, the first to fourth gate valves 63, 64, 65 and 66 are operated so that condensed water flows through the primary cooling line 61 and the secondary cooling line 62 Although the present embodiment has been described in detail with reference to the drawings, the scope of the present invention is not limited to the above-described drawings and descriptions.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Accordingly, it is intended that the present invention cover modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, To those skilled in the art. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

10. Reservoir tank 20. Multiple tank
31,32. Condensate transfer line 40. Bypass line
50. Condensate pump 60. Cooler
70. Temperature measuring instrument 80. Conductivity measuring instrument
90. Bypass control valve 100. Discharge control valve
110. Control means

Claims (6)

A CMCP steam condensate recycling system for recycling the steam condensate discharged from the CMCP dryer (3)
A water storage tank (10) for storing condensed water discharged from the CMCP dryer (3);
A white water tank 20 for storing pure water produced in the pure water manufacturing facility 4;
A condensate transfer line (31, 32) connecting the water storage tank (10) and the whitewater tank (20);
A bypass line 40 connected to an intermediate portion of the condensate transfer lines 31 and 32 to divide the condensed water transfer lines 31 and 32 into a front supply portion 31 and a rear discharge portion 32;
A temperature measuring unit 70 and a conductivity measuring unit 80 provided in the supplying unit 31 to measure the temperature and the conductivity of the condensed water flowing through the supplying unit 31; And
Control means (110) for causing condensate to be delivered to either the bypass line (40) or the discharge portion (32) according to signals from the temperature meter (70) and the conductivity meter (80);
Wherein the CMCP steam condensate recycling system comprises: The method according to claim 1,
A condensate pump 50 provided in the supply unit 31 to transfer the condensed water stored in the water storage tank 10 to the discharge unit 32 or the bypass line 40; And
A cooler (60) connected to a supply part (31) behind the condensate pump (50) to cool the condensate passing through the supply part (31);
Further comprising a CMCP steam condensate recycling system. The method according to claim 1,
A bypass control valve 90 and a discharge control valve (not shown) provided in the bypass line 40 and the discharge unit 32 to allow the bypass line 40 and the discharge unit 32 to open or close, 100)
The control unit 110 receives signals from the temperature meter 70 and the conductivity meter 80 and controls the bypass control valve 90 and the outlet control valve 100 according to the temperature and the conductivity of the condensed water And the condensed water is supplied to the whitewater tank (20) through the discharge part (32) or discharged through the bypass line (40) and is discarded. The method of claim 3,
The control means (110)
The bypass control valve 90 is opened and the discharge control valve 100 is opened when the temperature of the condensed water received from the temperature meter 70 and the conductivity meter 80 is 90 ° C. and the conductivity is 5 μs / The condensate is discharged through the bypass line 40 and discarded,
When the temperature of the condensed water received from the temperature meter 70 and the conductivity meter 80 is lower than 90 ° C. and 5 μs / cm 3, the discharge control valve 100 is opened and the bypass control valve 90 is opened And the condensed water is supplied to the whitewater tank (20) through the discharge part (32). The method according to claim 1,
The cooler (60)
A primary cooling line 61 connected to the supply unit 31 and passing through the natural circulation pond 61a; And
A secondary cooling line (62) connected to the supply part (31) so as to be located behind the primary cooling line (61) and passing through the heat exchanger (62a);
Wherein the CMCP steam condensate recycling system comprises: 6. The method of claim 5,
A pair of first gate valves (63) provided at both ends of the primary cooling line (61);
A second gate valve (64) provided at a middle portion of the supply part (31) so that the first cooling line (61) is located between the connected parts;
A pair of third gate valves (65) provided at both ends of the secondary cooling line (62); And
A fourth gate valve (66) provided in the middle of the supply part (31) so that the second cooling line (62) is located between the connected parts;
Further comprising:
The first to fourth gate valves 63, 64, 65 and 66 are selectively opened and closed to control the flow of the condensed water flowing into the primary cooling line 61 and the secondary cooling line 62 Wherein the CMCP steam condensate recycling system is a CMCP steam condensate recycling system.

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