KR102012128B1 - Apparatus for draining condenssation water - Google Patents

Abstract

The present invention relates to a device for discharging a condensate water comprising: a condensate water inlet pipe connected to a lower side of a transferring pipe such that the condensate water is introduced from the transferring pipe for transferring a byproduct gas; a condensate water chamber connected to the condensate water inlet pipe to store the condensate water and to maintain the pressure in the transferring pipe at a set pressure; a condensate water discharge pipe connected to an upper side of the condensate water chamber so as to allow the condensate water which exceeds a capacity of the condensate water chamber to reach a set height; an overflow pipe connected to a part corresponding to the set height of the condensate water discharge pipe to discharge the condensate water exceeding a capacity of the condensate water chamber to a collection pit, and an opening hole formed such that a pipe blockage can be observed; and an opening and closing door installed in the overflow pipe so as to open and close the opening hole. Therefore, the present invention is capable of preventing pipe blockage.

Description

Condensate Discharge Device {APPARATUS FOR DRAINING CONDENSSATION WATER}

The present invention relates to a condensate discharge device, and more particularly, to prevent the blockage of the pipe of the overflow pipe for discharging the condensate contained in the by-product gas, it is possible to monitor the internal environment of the overflow pipe, The present invention relates to a condensate discharge device that can prevent freezing.

In general, by-product gases such as blast furnace gas (BGF), linz-Donawitz gas (LDG) and coke oven gas (COG) generated from steel mills are mainly used in power plants, cold rolling mills and hot rolling mills. It is used as an energy source.

Since the by-product gas contains moisture, condensate is generated inside the transfer pipe for transferring the by-product gas, and a condensate discharge device is installed in the transfer pipe to discharge the condensate inside the transfer pipe.

Background art of the present invention is disclosed in Korean Patent Laid-Open No. 2001-0057461 (published on July 4, 2001, title of the invention: a device for preventing gas leakage of a seal port).

An embodiment of the present invention can prevent the blockage of the pipe of the overflow pipe to discharge the condensate contained in the by-product gas, can monitor the internal environment of the overflow pipe, condensate can prevent the freezing of condensate in winter To provide a discharge device.

The condensate discharge device according to the present invention includes: a condensate inlet pipe connected to the lower side of the transfer pipe so that condensate flows from the transfer pipe for transporting by-product gas, and is connected to the condensate inlet pipe to store the condensate, and the pressure of the transfer pipe is set. A condensate chamber to maintain pressure, a condensate outlet tube connected to the upper side of the condensate chamber to allow condensate exceeding the capacity of the condensate chamber to reach a set height, and a condensate chamber connected to a portion corresponding to the set height of the condensate outlet tube. A condensate exceeding a capacity of the discharge pipe to the collecting pit, an overflow pipe having an opening formed therein so that the pipe blockage can be observed, and an opening / closing door installed in the overflow pipe so as to open and close the opening. It is done.

In addition, the opening and closing door is characterized in that the pressure sensor for measuring the pressure inside the overflow pipe is installed.

In addition, the opening and closing door is characterized in that the temperature sensor for measuring the temperature inside the overflow tube is installed.

In addition, a condensate discharge channel is installed inside the overflow pipe, and a load sensor is installed between the condensate discharge channel and the overflow tube to determine the amount of solid deposit accumulated in the condensate discharge channel.

In addition, a heating member is installed between the condensate discharge channel and the overflow tube to prevent freezing of the condensate inside the overflow tube.

The apparatus may further include a controller connected to the pressure sensor, the temperature sensor, the load sensor, and the heating member, wherein the controller generates a pressure abnormal signal when the pressure inside the overflow tube is greater than or equal to the set pressure. If the internal temperature is below the set temperature, generate an abnormal temperature signal, generate the heating member operation signal for the heating member to operate, and if the solid deposit accumulated in the condensate drain channel inside the overflow pipe is above the set amount, And generating a signal.

The apparatus may further include a data indicator connected to a controller to display data measured by the pressure sensor, the temperature sensor, and the load sensor.

The apparatus may further include an alarm sound generator connected to the controller to generate a pressure abnormal alarm sound, a temperature abnormal alarm sound, and a pipe occlusion warning sound.

The condensate discharge device according to the present invention can prevent the blockage of the pipe by forming an open hole in the overflow pipe for discharging the condensate contained in the by-product gas.

Moreover, by providing various sensors and monitoring devices, the internal environment of the overflow pipe can be monitored.

In addition, by providing the heating member, freezing of the condensed water in winter can be prevented.

1 is a view showing a schematic installation state of the condensate discharge device according to an embodiment of the present invention.
2 is a view showing the components applied to the condensate discharge device according to an embodiment of the present invention.
3 is a view showing the installation structure of the condensate discharge channel applied to the condensate discharge device according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the condensate discharge device according to the present invention. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or convention. Therefore, definitions of these terms should be made based on the contents throughout the specification.

1 is a view showing a schematic installation state of the condensate discharge device according to an embodiment of the present invention, Figure 2 is a view showing the configuration applied to the condensate discharge device according to an embodiment of the present invention, Figure 3 2 is a view illustrating an installation structure of a condensate discharge channel applied to a condensate discharge device according to an embodiment of the present invention.

1 to 3, the condensate discharge device according to an embodiment of the present invention, as shown in Figure 1, is connected to the transfer pipe 10 for transferring the by-product gas, is generated in the transfer pipe 10 The condensate (W) is safely discharged to the water collecting pit 20 installed underground. The condensate W collected in the water collecting pit 20 is transferred to a condensate treatment apparatus (not shown) through the delivery pipe 30.

Condensate discharge device according to an embodiment of the present invention includes a condensate inlet pipe 100, the condensate chamber 200, the condensate discharge pipe 300, the overflow pipe 400, the opening and closing door 500 .

The condensate inlet pipe 100 is connected to the lower side of the transfer pipe so that the condensed water (W) is introduced from the transfer pipe 10 for transferring the by-product gas is formed extending in the downward direction.

The condensate inlet pipe 100 is provided with a first valve 110 and a second valve 120 capable of blocking the inflow of the condensate W from the transfer pipe 10.

The condensate chamber 200 is connected to the lower end of the condensate inlet pipe to store the condensate (W), to accommodate the condensate (W) full inside to maintain the pressure of the transport pipe at the set pressure.

The condensate discharge pipe 300 is connected to the upper side of the condensate chamber 200 and extends upward. The condensate discharge pipe 300 is installed to allow the condensate (W) that exceeds the capacity of the condensate chamber 200 to rise to the set height.

Since the condensate (W) is filled up to the set height of the condensate discharge pipe 300, and the condensate (W) is also temporarily accommodated in the condensate chamber 200, the by-product gas inside the transfer pipe (10) is an overflow pipe (to be described later) 400) may not be introduced.

The overflow pipe 400 is connected to a portion corresponding to a set height at which the condensate (W) is filled in the condensate discharge pipe 300 to discharge the condensate exceeding the capacity of the condensate chamber 200 to the water collecting pit 20. do.

The overflow pipe 400 is installed to be inclined in the vicinity of the condensate discharge pipe 300, it is installed to be horizontal in the vicinity of the water collecting pit (20).

The overflow pipe 400 may be formed with a plurality of open holes (H) so that the blockage of the pipe due to the solid precipitate (S) can be observed. The opening hole (H) is preferably formed in a sufficiently large size so that a tool for removing the solid deposits (S) accumulated in the pipe can be inserted, for example, may be formed in a substantially rectangular shape.

Opening and closing door 500 is installed on the upper side of the overflow pipe 400 to open and close the opening hole (H) formed in the overflow pipe 400, a transparent material to observe the inside of the overflow pipe 400 It is preferable to comprise a.

The opening and closing door 500 may be provided with a pressure sensor 510 for measuring the pressure inside the overflow pipe 400, the pressure sensor 510 is provided with a display for displaying the measured pressure.

Therefore, the operator can check the internal pressure of the overflow pipe 400 before opening and closing the opening and closing door 500 for removing or depositing the solid deposit (S), and can safely open and close the opening and closing door 500.

In addition, the opening and closing door 500 may be provided with a temperature sensor 520 for measuring the temperature inside the overflow tube 400, the temperature sensor 520 is provided with a display for displaying the measured temperature.

Therefore, the operator can check the internal temperature of the overflow tube 400 separately from the data indicator 950 which will be described later, and can predict the occurrence of the abnormal temperature in the overflow tube 400 in advance.

As illustrated in FIGS. 2 and 3, a separate condensate discharge channel 600 may be installed inside the overflow pipe 400.

In addition, as shown in Figure 2, between the condensate discharge channel 600 and the overflow pipe 400, there is a plurality of load sensors 700 to determine the amount of solid deposits (S) accumulated in the condensate discharge channel 600 Can be installed.

In addition, a heating member 800 may be installed between the condensed water discharge channel 600 and the overflow pipe 400 to prevent freezing of the condensed water W inside the overflow pipe 400.

In addition, the condensate discharge device according to an embodiment of the present invention further comprises a pressure sensor 510, a temperature sensor 520, a load sensor 700, and a controller 900 connected to the heating member 800, respectively. The controller 900 may further include a pressure sensor 510, a temperature sensor 520, and a data indicator 950 for displaying data measured by the load sensor 700.

Therefore, the data information displayed on the data indicator 950 by the operator can be periodically checked, thereby enabling a preventive check, thereby preventing the blockage of the pipe of the overflow pipe 400 in advance.

The controller 900 generates a pressure abnormal signal when the pressure inside the overflow pipe 400 measured by the pressure sensor 510 is equal to or higher than the set pressure.

In addition, when the temperature inside the overflow pipe 400 measured by the temperature sensor 520 is lower than or equal to the set temperature, the controller 900 generates a temperature abnormal signal, and in addition, the heating member 800 operates. Generate an activation signal.

In addition, when the controller 900 determines that the solid sediment (S) accumulated in the condensate discharge channel 600 inside the overflow pipe 400 through the load measured by the load sensor 700 is greater than or equal to the set amount, the pipe Generate an occlusion attention signal.

The controller 900 may be further connected with an alarm sound generator 1000 for generating a pressure abnormal alarm sound, a temperature abnormal alarm sound, and a pipe closing caution alarm sound. The controller 900 may generate a pressure abnormal signal and a temperature abnormal signal. , When at least one signal of the pipe occlusion warning signal is generated, the alarm sound generator 1000 immediately sounds an alarm sound, and the operator can immediately check and respond to it.

As described above, according to the present invention, by forming an opening in the overflow pipe for discharging the condensed water contained in the by-product gas, it is possible to prevent the blockage of the pipe. Moreover, by providing various sensors and monitoring devices, the internal environment of the overflow pipe can be monitored. In addition, by providing the heating member, freezing of the condensed water in winter can be prevented.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and those skilled in the art to which the art belongs can make various modifications and other equivalent embodiments therefrom. Will understand. Therefore, the true technical protection scope of the present invention will be defined by the claims below.

10: conveying piping 20: catchment feet
30: delivery pipe 100: condensate inlet pipe
110: first valve 120: second valve
200: condensate chamber 300: condensate discharge pipe
400: overflow pipe H: opening hole
500: opening and closing door 510: pressure sensor
520: temperature sensor 600: condensate discharge channel
700: load sensor 800: heating member
900: controller 950: data indicator
1000: alarm sound generator

Claims (8)

A condensate inlet pipe connected to the lower side of the conveying pipe so that condensed water is introduced from the conveying pipe for conveying by-product gas;
A condensate chamber connected to the condensate inlet pipe to store the condensate and maintain the pressure in the transfer pipe at a set pressure;
A condensate discharge pipe connected to an upper side of the condensate chamber to allow condensate exceeding a capacity of the condensate chamber to rise to a set height;
An overflow pipe connected to a portion corresponding to the set height of the condensate discharge pipe to discharge condensate exceeding the capacity of the condensate chamber to a collecting pit, and having an opening formed therein so that a pipe blockage can be observed; And
And an opening / closing door installed in the overflow pipe so as to open and close the opening hole.
The opening and closing door is provided with a pressure sensor for measuring the pressure inside the overflow tube, and a temperature sensor for measuring the temperature inside the overflow tube,
A condensate discharge channel is installed inside the overflow pipe, and a load sensor is installed between the condensate discharge channel and the overflow pipe to detect an amount of solid deposit accumulated in the condensate discharge channel. .
delete delete delete The method of claim 1,
And a heating member disposed between the condensate discharge channel and the overflow pipe to prevent freezing of the condensate inside the overflow pipe.
The method of claim 5,
And a controller connected to the pressure sensor, the temperature sensor, the load sensor, and the heating member, respectively.
The controller,
When the pressure inside the overflow pipe is greater than or equal to the set pressure, generates a pressure abnormal signal,
When the temperature inside the overflow tube is less than the set temperature, generates a temperature abnormal signal, and generates a heating member operation signal to operate the heating member,
And when the solid deposit accumulated in the condensate discharge channel inside the overflow pipe is greater than or equal to a predetermined amount, generating a pipe occlusion caution signal.
The method of claim 6,
And a data indicator connected to the controller for displaying the data measured by the pressure sensor, the temperature sensor, and the load sensor.
The method of claim 7, wherein
And an alarm sound generator connected to the controller for generating a pressure alarm, a temperature alarm, and a pipe occlusion warning sound.

Images