KR101504620B1 - Variable reverse-flow ventilation method and system at the fire of main control room in a nuclear power plant - Google Patents

Abstract

The present invention relates to a method for controlling air supply and air exhaust by a fire air-conditioning controller when a fire breaks out in a main control board (MCB) inside a main control room or inside a compartment in a nuclear power plant. The fire air-conditioning controller controls in a normal operation mode (Phase-1) to control a main control room air-conditioning and ventilating method in a lower air supply and upper air exhaust method in a normal state, and in a main control room fire operation mode (Phase-2) to apply a lower air supply and upper air exhaust method which is the identical ventilation method to that in the normal state when a fire breaks out in the main control room where an operator resides, and in a MCB or lower double-bottom sealed compartment fire operation mode (Phase-3) to apply a lower naturally air supply and upper forcibly air exhaust method when a fire breaks out inside a MCB or in a sealed compartment.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for controlling a variable backflow ventilation during a fire in a nuclear power plant,

[0001] The present invention relates to a ventilation control method in case of a fire in a main room of a nuclear power plant, more specifically, a main control room controls air inflow to the lower part and air exhaust to the upper part, By controlling the flow direction of gas such as air and heat smoke in the fire by controlling the ventilation by the method of opening the air inlet on both sides and opening the air outlet on the lower side for forced exhaust, The present invention relates to a variable backwash ventilation control method for a fire in a nuclear power mains room so as to improve time extension and safety stop margin.

In the case of a fire in the main room of a nuclear power plant, there is a procedure to extinguish the fire by using a manual fire extinguishing system such as an automatic fire extinguisher or a fire extinguisher. However, when a fire occurs inside a control cabinet (called a main control room) installed in the main control room or in an enclosed place such as under a double bottom, it is difficult to find a fire source due to difficulty in detecting the fire.

Fire in the main control room where the reactor safety stop multi-system (A and B series) are installed at the same time has an influence of heat smoke on control cable, measuring equipment, electric switch and electronic device. Which can lead to failure of the reactor safety stop function. In addition, the heat and smoke generated in the fire should be evacuated from the main room residents due to health medical adverse effects on the operator of the main room. If fire is unavoidable, the operator must evacuate the main control functions of the main control room after switching to the second control room or remote shutdown panel (RSP).

  The main control room is equipped with an air conditioner to control the environment of the driver 's residence and the temperature and humidity of the control facility. In the steady state, the ventilation system of the air conditioner adopts the first type ventilation system which is the forced air supply and the forced air discharge system. However, in case of fire, the third type ventilation system of natural air supply and forced air discharge is usually applied. Such a third type smoke ventilation system is suitable for the purpose of removing the smoke generated in a fire area, but the operator residing in the room is also not suitable for the purpose of protecting the safety stop related equipment and facilities in the main room.

According to the conventional design method of the HVAC system, the supply diffuser / grill / opening and the return diffuser are partially distributed on the ceiling of the main control room. The circulation pattern of air in the air conditioner is such that the fresh outside air is supplied to the lower part from the air supply device at the upper part of the ceiling, circulated inside the room, and then the contaminated room air is discharged to the air outlet provided at the upper part of the ceiling.

One of the contents of the present invention is to convert the air flow inside the main chamber to the lower air supply and the upper air exhaust system in the upper air supply and the upper air supply system in the normal state or in the fire state. In other words, unlike the existing pattern where the air circulates from the upper part to the lower part when a fire occurs in the main control room, the pattern is changed to a pattern of circulating air from the lower part to the upper part. In case of a fire inside the main room, open the air supply unit connected to the outside air (air) to supply fresh air in a natural circulation manner, and the air including the heat and smoke in the room is forced out by the smoke exhaust fan do.

○ Ventilation mode of the main room of the normal state of the existing design method (Type 1 ventilation system)

1 is a schematic view of a steady state main chamber ventilation system (first type ventilation system).

As shown in FIG. 1, the current air conditioning system is supplied with the air supply (conditioned air) whose temperature and humidity are adjusted by the air supply fan in the area above the main control room. The conditioned air flows to the lower area and provides the necessary conditions for the occupants and equipment in the room (cables, electrical appliances, electronic equipment, measuring instruments, indicators and displays, computers, etc.). The indoor air, which is in a condition of poor temperature and humidity, is discharged to the outside through the exhaust port located above the main control room by the ventilation fan. Normally, the pressure inside the main chamber maintains a very high positive pressure higher than the atmospheric pressure.

In this situation, when a fire occurs in the main room, an alarm is sent to the main room operator by fire alarm to manually stop the main room air conditioner and start the smoke exhaust system.

○ Main design of existing design method Ventilation mode in case of fire (type 3 ventilation system)

Fig. 2 is a schematic view of a ventilation system (third type ventilation system) in a main room of a conventional design method.

The difference from FIG. 1 is that air is naturally introduced into the air inlet in case of fire, and the exhaust system is forced to discharge heat and smoke by using an evacuator in the same manner as a steady state fluid flow.

In the main room of the nuclear power plant where the operator resides 24 hours, if the fire occurs in the vicinity of the operator, the fire is manually suppressed by using a fire extinguisher. However, when a fire occurs in the lower part of the main control board (MCB) or the lower floor of the resilience floor, an alarm is generated by the fire detector, but it is difficult to accurately determine the fire source. Therefore, when a fire occurs in the main room, the operator operates the fire extinguishing system irrespective of the location of the fire source, type of fire, and the size of the fire. Accordingly, when a fire occurs, the circulation mode of heat and smoke caused by the existing flue gas system causes the hot flue to move from the lower part to the upper part, thereby damaging the operator. At the same time, the fire generated in the lower compartment Lt; / RTI >

In the case of the recently designed nuclear power plant or the main room where facilities are improved, a self-extinguishing system using a clean fire extinguishing agent is installed in the plenum under the raised floor of the room where the operator resides, . As shown in FIG. 2, the smoke exhaust system is a natural air supply system by opening the damper of the supply duct connected to the outside air by the third type ventilation system, and the heat and smoke in the room are forcibly discharged by a pumping machine.

However, the present smoke exhaust system using the upper air supply and the upper air exhaust system has various problems as follows.

In the case where a fire is generated in the space where the operator resides, if the upper air supply is performed, the flame may spread by stimulating the fire source. In addition, when a fire occurs in a space occupied by the operator, the upper flushing system diffuses the air including the hot flushes to the upper area, which adversely affects the operator.

In addition, although it is easy to identify the fire by the driver, the fire spreads according to the air flow caused by the smoke exhaust system, which may result in difficulty in extinguishing the fire.

Also, when a fire occurs inside the main control room or the enclosed space, the upper air supply and the upper flue gas system have difficulties in grasping the fire source by spreading the heat smoke.

Also, when the hot flue is sucked into the upper region by the upper flue gas, the fire inside the main control flame diffuses and the function of the safety stop facility and the measuring instrument is lost.

In addition, the upper flushing system diffuses the hot flue in the closed space into the residence space of the operator, thereby hindering the dwelling of the operator.

Therefore, the current flushing system can shorten the time for the operator to stay in the main control room when a fire occurs in the main control room, to make it poorer in residence, and promote the spread of heat smoke inside the main control room or the closed space, Gt; of the < / RTI >

In particular, when calculating the LFR, which is the frequency of core damage (CDF) or external release of radioactive material, which may cause reactor damage due to fire in the event of a fire in the main room made up of one fire zone, The impact of the impact on the environment is very high.

Korean Patent Publication No. 2009-0032383 (2009.04.01)

Accordingly, in the present invention, by designing the air conditioning or ventilation system of the main control room of the nuclear power plant by the variable backflow ventilation system, it is possible to extend the residence of the operator when the main control room is fired and reduce the adverse effect on the control equipment and devices caused by the fire, The present invention provides a variable backflow control method for a nuclear power plant mainframe in a fire.

According to the present invention,

The main control room (MCR) is provided with an air supply fan or a free inflow opening, and an exhaust fan is installed on the upper side. The main control unit (MCB) has a grill- An air inlet (air conditioning dampers 1 and 2) capable of automatic opening and closing, and an exhaust fan capable of removing heat and smoke from the inside of the main control unit are installed in the lower part. The main control room and the main control room And a fire and air conditioning controller for receiving the fire occurrence information and controlling the flow direction of heat and smoke by the air supply and exhaust means and the method when the fire occurs,

The fire and air conditioning controller includes:

A normal operation mode (Phase-1) in which the main control room air conditioning and ventilation mode is controlled by a forced air supply from the lower part and a forced air discharge from the upper area;

A main control room fire operation mode (Phase-2) in which the lower natural supply and the upper exhaust are applied in the same flow pattern mode as the normal state in the main room where the operator resides;

In case of a fire in a main compartment or in a closed compartment, the main compartment is controlled by a closed compartment fire mode (Phase-3) under the main compartment or under the double compartment .

The main control mode (Phase-1), the main control room internal fire operation mode (Phase-2), the main control unit or the main floor of the double floor or the closed compartment fire operation mode (Phase- Or when a fire is detected by a fire detector of the system, it can be controlled automatically or manually by controlling the controller (variable type).

In the present invention, the flow direction of the air flowed into or out of the main control room is designed to be controlled by a lower supply and an upper discharge (reverse flow) system different from the conventional system, and a control system is operated.

Further, the present invention is characterized in that the flow direction of the fluid in the main control room fire operation mode (Phase-2) and the main control room of the main floor or the double bottom floor or the closed compartment fire operation mode (Phase-3) And the variable flow rate control system is applied so as to minimize the fire risk by controlling the area of the air supply and exhaust air.

In the case of ventilation of the main control room of the nuclear power plant, the main air supply system is ventilated in the steady state and the main room in case of fire in the lower air supply and the upper air exhaust system, By controlling the exhaust system, it is possible to extend the residence time of the operator when the fire is generated and prolong the time to cope with the fire.

The present invention can maintain a pleasant and ergonomic indoor environment by utilizing the lower air supply and the upper air exhaust during normal operation, and can control the air supply amount and the upper exhaust air amount As a result, it is possible to increase the residence time of the operator and improve the livability.

In addition, it is possible to extend the evacuation time of the main control room by preventing the heat and smoke from being discharged into the main control room by the upper natural supply and the lower forced exhaust in the closed space of the main control room or the double bottom floor, The survivability can be enhanced.

In addition, it is possible to minimize the fire risk of the main control room by using the variable position control system or the variable flow control system, to reduce the frequency of core damage or the mass early release frequency caused by fire in the main control room, It is possible to automatically control the main control room ventilation and smoke control system by combining the facility and the variable backflow type ventilation system.

FIG. 1 is an outline view of a ventilation system of a normal state main control room (a first type ventilation) of an existing design method. FIG.
FIG. 2 is an outline view of the ventilation system (third type ventilation) in the case of the main design room of the conventional design method.
FIG. 3 is a schematic view of a ventilator system of a variable backflow type in the case of a fire main control unit and a double bottom floor compartment according to the present invention. FIG.
4 is a configuration diagram showing an application example according to the present invention.
5 is an explanatory view of air conditioning control in the normal operation mode (Phase-1) of the main control room according to the present invention.
FIG. 6 is an explanatory view of air conditioning control in the operation mode (Phase-2) in the main control room fire according to the present invention. FIG.
FIG. 7 is an explanatory diagram of a fire operation mode (Phase-3) air conditioning control of a main compartment or a double bottomed enclosed compartment according to the present invention.
8 (a) and 8 (b) are diagrams showing changes in the concentration of smoke in the main control room due to changes in ventilation position.

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

FIG. 3 is a view illustrating a configuration of a ventilation system of a variable backflow type at the time of a fire in a nuclear power main control room according to the present invention.

The main control unit 20 having the upper exhaust fan 110 and the lower air supply fan 120 installed in the main control room 10 and the main control room 10 enclosed in the main control room 10 is provided with an upper duct damper 1 A fire monitoring system 30 for detecting a fire from a plurality of fire detectors 31 installed at a plurality of positions in the main control unit 20 and the main control room 10, The main control room is controlled by the main air supply unit under the upper exhaust and the fire control unit 100 is controlled by the upper air supply unit and the lower air discharge unit in case of main control fire.

The fire and air conditioning controller (100)

A normal operation mode (Phase-1) in which the main control room air conditioning and ventilation system is controlled by the lower air supply and the upper exhaust system in the normal state;

A main room fire operation mode (Phase-2) in which the main air room where the operator resides and the lower air supply and the upper exhaust system are applied in the same ventilation mode as the normal state in the interior fire;

And a closed compartment fire operation mode (Phase-3) in which the main natural gas supply and the lower forced exhaust gas are applied when a fire occurs in the main control unit or in the closed compartment.

Here, the upper and lower supply means and the exhaust means of the main control room and the main control unit are not limited to those shown in FIG. 1, but an air supply fan or a free inflow opening is provided in the lower portion of the main control room (MCR) The main control unit (MCB) is equipped with an air inlet (air conditioning dampers 1 and 2) capable of manual or automatic opening in the form of a grill in which air can freely flow into the upper side, The main control room, and the main room or the indoor room from the fire detection device or the system, receives the fire occurrence information from the main control room or the closed room, detects the flow direction of the heat and smoke by the supply and exhaust means and the method A fire and air conditioning controller is installed.

FIG. 4 is a view showing an application example according to the present invention. In the air duct in which the upper exhaust fan 110 is installed, the upper exhaust damper 111 and the lower air supply fan 120 are installed, The damper 121 is further provided and the opening amount of the exhaust damper and the air supply damper is adjusted so that the amount of air supplied and exhausted is controlled according to the fire occurrence position and the fire range.

3 and 4, the air supply fan and the exhaust fan are shown for explaining the present invention. However, a plurality of air supply means and exhaust means are installed at the upper and lower positions, respectively. In the present invention, The main control room is controlled by the upper air supply upper exhaust, and the main control unit is controlled by the upper open lower exhaust.

In the normal operation mode (Phase-1), the main room fire operation mode (Phase-2), the main compartment floor or the closed compartment fire operation mode (Phase-3) under the double floor, It can be controlled automatically or manually by the controller.

In the present invention, the flow direction of the air flowed into or out of the main control room is designed to be controlled by a lower supply and an upper discharge (reverse flow) system different from the conventional system, and a control system is operated.

The flow direction of the fluid is designed to be controlled according to the location of the fire in the main control room fire operation mode (Phase-2) and the closed compartment fire operation mode (Phase-3) Variable flow rate control system is applied to minimize fire risk by controlling area.

Therefore, the fire and air conditioning controller 100 according to the present invention receives the fire occurrence position information from the fire detection system 30 and empirically sets the air supply position and the exhaust position according to the fire occurrence position, The corresponding supply and exhaust positions are set and the air supply position and the exhaust position are selectively controlled according to the fire occurrence position. The fire detectors 31 are installed at a plurality of locations and are used to identify the fire detector location information, and the fire detection system provides the fire occurrence location information together with the fire occurrence information to the air conditioning controller.

In addition, the present invention is configured to further include an air supply and exhaust position selection unit that can manually select an air supply position and an air exhaust position by a driver in the fire and air conditioning controller 100, Manual selection and control.

In the present invention, the air supply means and the exhaust means provided at a plurality of upper and lower positions are respectively configured to adjust the supply and exhaust flow rates by adjusting the amount of opening of the damper by providing dampers. The supply and exhaust amount control is further provided with a manual operation means so as to be adjustable by manual selection. In the method of automatically controlling the supply and exhaust amount of the plurality of fire detectors, the larger the number of fire detectors to detect by fire, the wider the fire range According to the fire size, the air supply and exhaust amount are controlled. Experimentally, the air supply amount and the exhaust amount control amount according to the fire position and the fire size are obtained in advance and the supply amount and the exhaust amount are automatically controlled by using this.

5 is an explanatory diagram of air conditioning control in the normal operation mode (Phase-1) of the main control room according to the present invention.

In the steady state operation mode (Phase-1), the air conditioning and ventilation system in the steady state main control room (10) adopts the first type ventilation system, but controls the lower air supply and the upper exhaust system. That is, the fire and air conditioning controller 100 drives the lower air supply fan 120 in a steady state so that the lower air supply is performed, and the upper exhaust fan 110 is driven to perform the upper exhaust. Air is forcedly supplied from the lower portion of the main control room 10 to supply fresh air to the main control room 10 and the main control unit 20 to realize the optimum environment condition. The air is forcedly discharged from the upper region of the main control room 10 to discharge the poor indoor air into the main control room 10 without affecting the residents or facilities.

6 is an explanatory diagram of air conditioning control in the main operation room fire operation mode (Phase-2) according to the present invention.

In the main operation room fire operation mode (Phase-2), the third type ventilation system of the lower natural supply and the upper forced exhaust is applied in the main control room (10), and the main control unit In case of fire in room (10), the same flow pattern as steady state mode is applied to reduce human error. If necessary, it is possible to reduce the supply air supply, increase the top exhaust, prevent fire diffusion by reducing the static pressure in the room, and minimize the heat smoke flow. As shown in FIG. 4, the amount of air supplied and the amount of air discharged are adjusted to conditionally adjust the opening amount of the lower air supply damper 121 and the upper air exhaust damper 111 to induce a decrease in the indoor static pressure.

FIG. 7 is an explanatory diagram of a closed compartment fire operation mode (Phase-3) air conditioning control of the main control unit or the lower floor according to the present invention.

The compartment fire operation mode (Phase-3) is operated in the main control unit (20) or in the third ventilation mode of the upper natural gas supply and the lower forced gas fire in the closed compartment fire. It is to prevent the spread of heat smoke to the operator resident area by the natural supply irrespective of the location such as the upper or lower part of the main control room.

It is possible to minimize the influence of the occupant's residence area due to the fire by forced exhaust from the lower part of the main room or the lower part of the main control room, and it is possible to minimize the influence of fire due to the negative pressure inside the main control room, It induces the fire suppression effect by the temperature decrease of the zone.

Therefore, it is possible to maximize the effect of suppressing the natural fire by adjusting the supply and exhaust amount, and it is possible to extend the residence time of the operator in the main control room as much as possible.

8 (a) and 8 (b) are diagrams of a change in the smoke concentration in the main control room due to a change in the ventilation hole position, by a fire dynamics simulator (FDS).

The proposed contents were analyzed by fire modeling (FDS version 4.7) on the main subject room of domestic standard nuclear power plant. 8 (a) shows the smoke stay (t = 67 sec) at the time of the upper air supply upper exhaust, (b) shows the smoke stay (t = 67 sec) at the time of lower air supply lower exhaust, As a result of comparing the smoke concentration by adjusting, it can be seen that when changing to the lower exhausting method compared to the existing air circulation method, the smoke concentration in the room is drastically reduced. As a result, the temperature, the heat velocity, and the smoke concentration of the main room were significantly improved compared to the conventional system.

Therefore, when the operation mode is changed to the operation modes (Phase-1, 2, 3) of the present invention as compared with the existing air circulation mode, the smoke concentration in the room is further reduced and the real time of the operator can be greatly extended. We can see that the result is much better than the existing method.

As a result of comparing the indoor heat flux by adjusting the ventilation hole position and the air inflow area, it was found that when the position of the ventilation hole is changed or the area of the air inlet is changed, the heat flux in the main panel increases slightly and the heat flux in the space where the operator resides decreases And it is proved that the residence time of the main room can be greatly increased by reducing the heat flux of the space where the operator resides.

Therefore, when adjusting the location and area of the outdoor air inlet and the ventilation outlet, the temperature, the heat velocity and the smoke concentration are variable according to the location and the size of the area where the fire occurs. Accordingly, the air supply and exhaust directions, It is possible to perform more effective control by variable control according to the size of fire or the like.

10: The main room 20: The main room
30: Fire detection system 31: Fire detector
100: fire and air conditioning controller 110: upper exhaust fan
111: upper exhaust damper 120: lower air supply fan
121: lower supply duct 130, 140: upper duct damper
150: Lower supply fan

Claims (7)

A method of controlling supply and exhaust by a fire control unit (100) in a main control room inside a main control room of a nuclear power plant or a fire inside a compartment,
The fire and air conditioning controller (100)
A normal operation mode (Phase-1) for controlling the main control room air conditioning and ventilation mode by the lower air supply and the upper air exhaustion mode in a steady state;
A main room fire operation mode (Phase-2) in which the main air room where the operator resides and the lower air supply and the upper exhaust system are applied in the same ventilation mode as the normal state in the interior fire;
(3) a closed compartment fire operation mode (Phase-3) in which the main natural gas supply and the lower forced exhaust gas are applied when a fire occurs in the main compartment or in a closed compartment, Variable Reverse Flow Ventilation Control Method in Failure. The method according to claim 1,
The main control room normal operation mode (Phase-1), the main control room fire operation mode (Phase-2), the main control room or the closed compartment fire control operation mode (Phase-3) Is controlled by automatic or manual selection of the air conditioner controller (10). The method of claim 1, wherein the main control room normal operation mode (Phase-1), the main control room fire operation mode (Phase-2), the main control room,
Wherein the control means is controlled by a variable control method that can be selectively controlled according to a fire position, a fire size, and a suppression method. 2. The method according to claim 1, wherein the main control room normal operation mode (Phase-1) and the main control room fire operation mode (Phase-2)
Wherein a variable position control method is adopted to apply the reversed flow type of the lower supply and the upper exhaust while selecting the positions of the supply and exhaust. The method according to claim 1, wherein the main control room fire operation mode (Phase-2) and the main control room or the compartment fire operation mode (Phase-3) control the flow direction of the fluid according to the fire occurrence position, Wherein the variable flow rate control is performed so as to minimize the fire risk by controlling the area of the main flow. 6. The method of claim 5,
Wherein the flow rate is controlled by using a variable damper system capable of controlling the area of the air supply and the air exhaust. [6] The method of claim 5, wherein the variable flow rate control is performed automatically or manually.

Images