KR101388953B1 - Flooding prevention system of water supplying equipment used in blast furnace - Google Patents

Abstract

The present invention relates to a immersion prevention system of blast furnace water supply system including a pump motor and an emergency engine located in an underground lowland.
The immersion prevention system of the blast furnace water supply system according to the present invention, the immersion detection unit is installed in the vicinity of the blast furnace water supply facility, including a plurality of water level detection sensors, for detecting whether the blast furnace water supply facility is inundated; An immersion processor for performing a series of immersion treatments by remote control when the immersion of the blast furnace water facility is detected by the immersion detector; An immersion pump installed at the lowest position of the blast furnace water supply system and forcibly discharging water to the outside during the immersion of the blast furnace water supply facility by remote control; An immersion sensing unit, an immersion processing unit, and a control unit for controlling the overall operation of the immersion pump, the immersion processing unit is composed of a immersion suction pipe for immersion suction, and a plurality of control valves for immersion suction control of the immersion suction pipe It is characterized by.
According to the immersion prevention system of the blast furnace water supply system of the present invention as described above, even if unintentional immersion in the blast furnace water facility occurs, it is possible to prevent by remote control without approaching people so as not to rise to the inundation above a certain height. .

Description

FLOODING PREVENTION SYSTEM OF WATER SUPPLYING EQUIPMENT USED IN BLAST FURNACE

The present invention relates to a immersion prevention system of the blast furnace water supply system, and more particularly to a immersion prevention system of the blast furnace water facility including a pump motor and an emergency engine located in the underground lowland.

In general, the blast furnace water supply system includes a pump motor and an emergency engine located in an underground lowland. Such blast furnace water system is highly likely to be flooded due to external factors such as rainwater inflow, tidal wave, etc. as well as internal factors such as gland packing damage, drain valve leakage, joint damage, and flooded pump failure. It is true.

In addition, steel mills are generally located in coastal lowlands due to their geographical location, and are heavily affected by heavy rains and tsunamis during typhoons and extreme weather events. For this reason, the pump room of the blast furnace facility is an unmanned facility where the shift worker performs facility inspections at regular intervals by remote operation and adjusts only when the level of the tank is required. In case of short-term loss of water, damage from flooding sometimes occurs.

Referring to FIG. 1, the cooling panel 102, the air vent 104, and the hot stove facility 110 of the blast furnace body 100 during operation are high temperature points of 1,000 degrees or more, and the blast furnace water supply facility 150 is such a high temperature point. It is a facility to prevent the damage caused by the heat loss of the device by performing a cooling operation and to perform a smooth operation.

The blast furnace water supply system 150 is composed of a low pressure pump 152, a high pressure pump 154, and a hot well pump 156, the flow rate generated by the operation of the low pressure pump 152 is located in the water tank 120 is located high After it is supplied, it is supplied to the main equipment such as the cooling plate 102 and the hot stove facility 110 of the blast furnace body 100 by gravity or the like, and the cooling water heated at a high temperature location undergoes a cooling operation in the cooling tower 130. It will cycle again.

This low pressure pump 152 is a low pressure relative to the high pressure pump 154, the operating pressure is approximately 7kg / cm ² level.

The high pressure pump 154 is a facility for cooling the tuyere 104 affected by the ultra high temperature in the high heat portion of the blast furnace 100, the working pressure reaches approximately 17kg / cm ² .

The hot well pump 156 is hot by circulating high heat points of the blast furnace body 100 and the hot stove facility 110, and pumps the hot water returned by the height difference from the hot well pond 140 to cool the cooling tower 130. Cooling is made while passing through and serves to send the cold water pond 142 somewhat higher. Here, the low capacity of the hot well ponds 140 and cold well ponds 142 is a large capacity, and typically has to maintain a fairly low water level in order to ensure that the water level surface is naturally returned from the blast furnace body 100 and the peripheral equipment. The pump room of the water supply system will be installed in the underground lowland.

In the past, a immersion pump was installed to prevent immersion caused by internal and external factors of a pump room located in an underground basin in a blast furnace water supply facility. These submersible pumps were able to adjust the number of gland packing seals and the number of minute loss of pipes to below the proper height, but they could not cope with the capacity exceeding the processing capacity such as the number of gland packing seals, damage to flange connection, damage to drain valve, damage to high pressure joint, etc. There was this. In addition, when flooding is caused by a failure of the submersion pump itself or an error in the level gauge, a situation may occur in which a vacuum device is connected to treat the inundation.

When flooding a large amount of water, the motor that starts the pumps of the blast furnace facility and the emergency engine for emergency operation may be inoperable. There is a risk of causing a major accident.

The present invention has been proposed to solve the above problems, an object of the present invention is to provide a immersion prevention system of the blast furnace water facilities that can prevent the immersion of the blast furnace water facilities, including a pump motor and an emergency engine located in the underground lowland. To provide.

In order to achieve the above object, the immersion prevention system of the blast furnace water supply system of the present invention is installed in the vicinity of the blast furnace water installation, including a plurality of water level sensor, the immersion detection unit for detecting whether the blast furnace water supply equipment Wow; An immersion processor for performing a series of immersion treatments by remote control when the immersion of the blast furnace water facility is detected by the immersion detector; An immersion pump installed at the lowest position of the blast furnace water supply system and forcibly discharging water to the outside during the immersion of the blast furnace water supply facility by remote control; An immersion sensing unit, an immersion processing unit, and a control unit for controlling the overall operation of the immersion pump, the immersion processing unit is composed of a immersion suction pipe for immersion suction, and a plurality of control valves for immersion suction control of the immersion suction pipe It is characterized by.

Preferably, the plurality of water level sensors are a high level sensor for detecting a high level of immersion, a high level sensor for detecting a high level of immersion, and a low level of immersion. Low level sensor and a low level sensor for detecting the low level (LL) level of immersion.

When the detection signal is generated from the high (H) level sensor, the immersion pump starts to operate, and when the detection signal is generated from the low (LL) level sensor, the immersion pump is stopped.

The immersion treatment unit may further include an alarm unit that generates an alarm when the immersion of the blast furnace facility is detected by the immersion detection unit.

A plurality of control valves are provided in the immersion suction pipe to control the immersion suction inlet, the vent control valve of the hotwell suction filter, and the suction control valve installed in the front of the hotwell suction filter to control the flow of water in the blast furnace facility It is configured to include.

When the immersion control valve is opened and the suction control valve is closed, the immersion water is sucked through the immersion suction pipe.

The submerged suction pipe is branched from the front end of the hot well suction filter, and preferably the submerged suction pipe is installed below the low level sensor.

According to the immersion prevention system of the blast furnace water supply system of the present invention as described above, even if unintentional immersion in the blast furnace water facility occurs, it is possible to prevent by remote control without approaching people so as not to rise to the inundation above a certain height. .

In addition, according to the present invention, by providing a four-level level meter and inlet side immersion suction function of the hot well pump and the step-by-step action function by the system, the immersion can be properly treated, and thus the pump motor and emergency engine of the blast furnace facility, etc. It is possible to prevent the damage in advance, and to prevent the large failure of the blast furnace, such as heat loss and explosion accident of the high temperature device, it is effective to contribute to stabilization of the operation of the blast furnace.

In addition, according to the present invention, it is possible to prevent the risk of electric shock accidents due to a short-circuit when a person approaches randomly for immersion measures, and does not require a separate equipment or manpower such as a vacuum device, it is possible to immediately take action.

In addition, according to the present invention, by minimizing the internal impact of the pump, such as cavitation, to achieve its own equipment protection without affecting the life of the equipment, by utilizing the cooling water circulation system is ancillary to contribute to the improvement of equipment life and cooling water It works.

1 is a system diagram relating to cooling water circulation in a blast furnace installation.
2 is a block diagram of a immersion prevention system of the blast furnace water installation according to the present invention.
Figure 3 is a flow chart illustrating a method for preventing immersion of blast furnace water equipment according to the present invention.
Figure 4 is a flow chart illustrating in detail the operation of the immersion prevention system according to the present invention.
Figure 5 is a flow chart illustrating in detail the stop of the immersion prevention system according to the present invention.

Hereinafter, the immersion prevention system of the blast furnace water supply system according to the present invention will be described in detail with reference to the accompanying drawings. In the drawings referred to in the present invention, components having substantially the same configuration and function will use the same reference numerals.

2 is a block diagram of the immersion prevention system of the blast furnace water installation according to the present invention, referring to Figure 2, the immersion prevention system of the blast furnace water equipment according to the present invention,

An immersion detector 240 installed in the vicinity of the blast furnace water facility 150 (see FIG. 1) and including a plurality of water level detection sensors to detect whether the blast furnace water facility 150 is inundated;

When the immersion of the blast furnace water supply facility 150 is detected by the immersion detection unit 240, the immersion processing unit 250 for performing a series of immersion treatment by a remote control;

An immersion pump 300 installed at the lowermost position of the blast furnace water supply facility 150 and forcibly discharging water to the outside during the immersion of the blast furnace water supply facility 150 by remote control;

Including the submersion detection unit 240, the submersion processing unit 250, and the overall control of the operation of the submersion pump 300,

Immersion processing unit 250 is characterized in that consisting of a plurality of control valves for immersion suction pipe 253, and immersion suction control of the immersion suction pipe 253 for immersion suction.

The plurality of water level detection sensors of the immersion detection unit 240 includes a high level sensor 241 for detecting a high level of HH and a high level sensor 242 for detecting a high level of immersion; And a low level sensor 243 for detecting the low (L) level of immersion, and a low low level sensor 244 for detecting the low (LL) level of immersion.

Each of the sensing sensors 241, 242, 243, and 244 of the submersion detecting unit 240 is preferably a level gauge, and is fixedly installed on the support 245 at each height corresponding to the degree of submersion, respectively. It is connected to the relay 210 of (200). When each of the detection sensors 241, 242, 243, 244 is fixed to the support 245, when using the plot type level gauge it is good to give some room to move up and down.

In one embodiment, when the detection signal is generated from the high (H) level sensor 242, the immersion pump 300 starts to operate.

In addition, when the detection signal is generated from the low-low (LL) level sensor 244, the immersion pump 300 is configured to stop operation.

Preferably, the immersion treatment unit 250 may further include an alarm unit 260 for generating an alarm when the immersion of the blast furnace facility 150 by the immersion detection unit 240 is detected.

The alarm unit 260 is installed at a well-identified area around the site and the entrance on the upper part of the pump, and this alarm unit 260 is marked to enable identification of the color and legend according to remote operation / operation / stop.

A plurality of control valves are provided. The submersion suction pipe 253 is provided with a submersion control valve 252 for controlling submersion suction, and a vent control valve 256 is installed at the hot well suction filter 156a. At the front end of the 156a, a suction control valve 254 is provided to control the flow of running water of the blast furnace water supply facility 150.

Preferably, the immersion control valve 252 is full open, the immersion is suctioned through the immersion suction pipe 253 in the state in which the suction control valve 254 is closed.

Each of the control valves 252, 254, and 256 is configured in the form of an automatic valve to enable remote operation, and is also connected to enable operation of the PLC 220.

Preferably, the submerged suction pipe 253 is branched from the front end of the hot well suction filter 156a, and it is preferable that the submerged suction pipe 253 is installed below the installation position of the low (L) level sensor 243 for smooth submerged treatment.

In detail, the submerged suction pipe 253 is collected in a natural round shape that is not abrupt in front of the hot well suction filter 53.

The control unit 200 includes a relay 210 and a PLC 220, the immersion detection unit 240 for detecting the immersion degree, the immersion processing unit 250 to measure this when immersion, and the immersion pump 300 It plays a role in controlling the operation of the overall.

Specifically, the control unit 200 receives a signal from the inundation detecting unit 240 through the relay 210 to the PLC 220, controls to display the current state on the display 230, the driver's operation The matters are calculated by the PLC 220 controlling the respective devices and connected to the alarm unit 260 and the control valves 252, 254, and 256.

The display 230 and the monitoring camera 270 are provided for the purpose of performing comprehensive monitoring and operation of the blast furnace equipment. The display 230 and the monitoring camera 270 are installed on a wall that is easy to check whether the site is flooded and operated, and, if necessary, assisted by the cab. It can be configured to monitor at any time by connecting to monitoring monitor.

Operation of the apparatus according to the present invention configured as described above will be described in detail below with reference to the accompanying drawings.

3 to 5 is a flow chart illustrating a method of preventing immersion of the blast furnace water installation according to the present invention.

First, referring to FIG. 3, the overall flow of the immersion prevention method of the blast furnace water system according to the present invention, when the actual immersion situation occurs, the respective detection sensors 241, 242, 243, of the immersion detection unit 240, The operation of the immersion pump and the immersion prevention system (S108 and S200) according to the value of 244 may be required, and if the level is lowered (on return to the normal state) due to appropriate measures, the immersion pump and the immersion prevention system are stopped S200 and S114).

Referring to FIG. 3, each of the detection sensors 241, 242, 243, and 244 of the submersion detection unit 240 detects a submersion degree (level) (S100).

If the immersion level is detected at the high level (HH) level (a signal is detected from the high level sensor 241), the alarm unit 260 will generate an alarm, and the manual on the power supply and valve in the field Warn not to operate or approach (S104). Subsequently, the immersion prevention system of the present invention is operated (S200).

When the operation routine of the immersion prevention system is implemented, an on-site alarm unit 260 indicates that the remote operation is to be performed to warn against manual operation or access to arbitrary power and valves in the field.

Although it is difficult for the worker to access itself according to the actual water level during flooding, it acts to prevent the risk of electric shock accidents caused by a short circuit which is likely to occur by random access.

At this time, the driver can check the flooding while rotating the surveillance camera 270 through the display 230 in the remote position, and in case of malfunction can determine the site and request repair of the sensor.

Next, when the immersion level is detected as the high (H) level (a signal is detected from the high level sensor 242), the immersion pump 300 starts to operate (S108).

Next, when the immersion level is detected as the low (L) level (a signal is detected from the low level sensor 243), the immersion prevention system according to the present invention stops the operation (S300).

Finally, when the immersion level is detected as the low low (LL) level (signal is detected from the low low level sensor 244), the operation of the immersion pump 300 is stopped (S114).

Figure 4 is a flow chart illustrating in detail the operation of the immersion prevention system according to the present invention.

As described above, the immersion prevention system includes a plurality of control valves, for example, a immersion control valve 252, a suction control valve 254, and a vent control valve 256.

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In addition, the opening and closing (or closing) of the vent control valve is repeated repeatedly to effectively remove residual air and bubbles.

In particular, the manipulation of the control valves is largely performed in two steps.

First, the immersion control valve 252 is slightly open (about 30%), and the suction control valve 254 is slightly closed. At this time, about 30% of the opening degree of the flow rate is realistic neutral point.

Next, after a certain flow rate, the entire remaining amount of the submersion control valve 252 is fully opened, and the suction control valve 254 is completely blocked.

In addition, the opening and locking of the vent control valve 256 is repeatedly performed in the middle of each step, which is to vent the air remaining inside, and it is sufficient to simply shut off after opening.

Here, the opening and locking of the vent control valve 256 takes about 1-2 seconds as in the manual valve operation in the field. However, the submerged control valve 252 and the suction control valve 254 is large, takes about 2-3 minutes when full adjustment.

Referring to FIG. 4, first, an active window for immersion action is displayed along with an alarm on the display 230, and operation of the immersion prevention system is started.

First, to adjust the opening degree of the immersion control valve 252 (S204), first slightly open the immersion control valve 252, that is, after opening the opening degree of the immersion control valve 252 about 30% (S206), The opening degree of the suction control valve 254 is adjusted (S210), and the suction control valve 254 is slightly closed, that is, only 30% of the opening of the suction control valve 254 is opened (S212). That is, it can be seen that the opening degree of the immersion control valve 252 and the opening degree of the suction control valve 254 maintain the relationship between the immersion control valve opening degree (30%) = the suction control valve opening degree (30%). Here, the opening and locking of the vent control valve 256 are repeated after the opening of the immersion control valve 252 and the partial blocking of the suction control valve 254, and the opening and locking of the vent control valve 256 are repeated. Effectively removes residual air and bubbles.

If the opening degree of the suction control valve 254 is not opened by 30%, the suction control valve 256 is closed (S214).

Thereafter, after the predetermined flow rate flows, the remaining amount of the immersion control valve 252 is opened, that is, the immersion control valve 252 is fully opened (S220), and the suction control valve 254 is completely closed (S224). . At this time, the immersion is sucked through the suction pipe 253. Of course, the opening and locking of the vent control valve 256 is repeated in the middle (S220), which is to vent the air remaining therein.

Finally, after this series of operations, an on-site alarm is displayed as the plant is running.

Such a series of operations may cause harmful phenomena such as cavitation to the low pressure pump 152, the high pressure pump 154, and the hot well pump 156 that are operating due to the air initially sucked in the immersion suction pipe 253 when the immersion prevention system is operated. It does not generate, but it does not generate a shock due to a sudden valve operation.

Figure 5 is a flow chart illustrating in detail the stop of the immersion prevention system according to the present invention.

Referring to FIG. 5, if the immersion prevention system operation 260 is performed, and the immersion level is detected as the low (L) level (a signal is detected from the low level sensor 243) (S110), the immersion prevention system according to the present invention. This operation is stopped (S300), this process is the step of opening the suction control valve 254 (S302), the step of blocking the flood control valve 252, and the step of turning off the alarm unit 260 of the site Proceeds.

After the immersion prevention system is stopped (S200), the immersion pump 300 operates until the residual water level of the immersion becomes a low level, that is, until the immersion level is detected as a low low (LL) level.

If the immersion level is sensed as low LL level, the operation of the immersion pump 300 is stopped.

After that, if the repair work is delayed or the flooding level is increased again due to the increase in flooding amount, the flooding prevention system is restarted to prevent flooding over a certain level.

150: blast furnace water supply facility 152: low pressure pump
154: high pressure pump 156: hot well pump
156a: hot well suction filter 200: control unit
240: immersion detection unit 241: high high level sensor
242: high level sensor 243: low level sensor
244: low level sensor 250: immersion treatment unit
252: immersion control valve 253: immersion suction pipe
254: suction control valve 256: vent control valve
260: alarm unit 300: immersion pump

Claims (9)

In blast furnace water supply system,
An immersion detection unit installed in the vicinity of the blast furnace water supply facility and including a plurality of water level detection sensors to detect whether the blast furnace water supply facility is flooded;
When the immersion of the blast furnace water equipment is detected by the immersion detection unit performs a series of immersion treatment by remote control, the immersion suction pipe for immersion suction, and the immersion provided with a plurality of control valves for the immersion suction control of the immersion suction pipe A processing unit;
An immersion pump installed at the lowest position of the blast furnace water supply system and forcibly discharging water to the outside during the immersion of the blast furnace water supply facility by remote control;
It includes a immersion detection unit, immersion processing unit, the control unit for controlling the overall operation of the immersion pump,
A plurality of control valves are provided in the immersion suction pipe to control the immersion suction inlet, the vent control valve of the hotwell suction filter, and the suction control valve installed in the front of the hotwell suction filter to control the flow of water in the blast furnace facility The immersion prevention system of the blast furnace water equipment, characterized in that it comprises a. The method of claim 1,
The plurality of water level sensors include a high level sensor that detects a high level of immersion, a high level sensor that detects a high level of immersion, and a low level that detects a low level of immersion. Immersion prevention system of the blast furnace water supply facility, characterized in that the sensor and a low-low level sensor for detecting the low-low (LL) level of immersion. 3. The method of claim 2,
The immersion prevention system of the blast furnace water supply system characterized in that the immersion pump starts operation when a detection signal is generated from the high (H) level sensor. 3. The method of claim 2,
The immersion pump system of the blast furnace water supply system, characterized in that the immersion pump is stopped when the detection signal is generated from the low-low (LL) level sensor. The method of claim 1,
The immersion treatment unit further includes an alarm unit for generating an alarm when an immersion of the blast furnace water facility is detected by the immersion detection unit. delete delete The method of claim 1,
The immersion suction pipe is a immersion prevention system of the blast furnace water supply, characterized in that is installed branched from the front end of the hot well suction filter. 3. The method according to claim 1 or 2,
The immersion suction pipe is installed below the low level sensor, the immersion prevention system of the blast furnace water equipment.

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