JP2021173683A - Blowout panel apparatus - Google Patents

Abstract

To provide blowout panel apparatus capable of appropriately setting the speed at which steam flows out from an opening (the degree of pressure reduction per unit time).SOLUTION: A blowout panel apparatus 20 which is provided in an opening A of a wall surface of a building 100 of a nuclear reactor-related facility, comprises: a blowout panel 1 formed to have a shape that closes the opening A; an electric drive device 4 provided on the outer wall surface of the building 100 of the nuclear reactor-related facility; an arm 2 connecting the blowout panel 1 and the electric drive device 4; a damper 3 connecting the arm 2 and the outside of the wall of the building 100 of the nuclear reactor-related facility; and a pedestal 5 which is located near an arm base 2d of the arm 2, and on which the blowout panel 1 is seated. By rotation of the arm 2 about the arm base 2d as an axis, the upper and lower parts of the blowout panel 1 are pressed against the pedestal 5 when the internal pressure of the building 100 of the nuclear reactor-related facility rises, while the blowout panel 1 is electrically restored to its original state when the internal pressure of the building 100 drops.SELECTED DRAWING: Figure 2A

Description

The present invention relates to a blowout panel device.

In the building of a nuclear facility, a blowout panel has been proposed that automatically closes (closes) the opening when the opening of the building is released by a predetermined internal pressure and then the pressure inside the building drops to a certain extent.

In the blowout panel device according to Patent Document 1, a hanger arm is projected from the outdoor surface of the blowout panel, and the tip of the hanger arm is movably engaged with a rail installed on a downward slope toward an opening. Has been done. The rail is fixed to the upper inner surface of the duct that guides the steam that has flowed out when the main steam pipe ruptures. Further, a shock absorber is provided on the inner surface of the side wall of the duct so as to face the base end of the hanger arm.

Therefore, in the blowout panel device according to Patent Document 1, since the tip of the hanger arm of the blowout panel is movably engaged with the rail, blow is performed when the internal pressure of the steam flowing out when the main steam pipe ruptures acts. The out panel moves rapidly along the rails. In addition, the shock absorber receives the blowout panel to alleviate the impact acting on the blowout panel and prevent its damage.

Japanese Unexamined Patent Publication No. 3-77097

In the blowout panel device according to Patent Document 1, when the steam outflow from the building is stopped, the blowout panel returns to the opening by its own weight. However, since the blowout panel is pressed against the opening by its own weight, if the blowout panel cannot securely close the opening, it is necessary to remotely close the blowout panel. In addition, the rate at which steam flows out from the opening (degree of decompression per unit time) could not be adjusted appropriately.

The present invention has been made to solve the above-mentioned problems, and provides a blowout panel device capable of appropriately adjusting the speed at which steam flows out from an opening (degree of decompression per unit time). The purpose.

In order to achieve the above object, the blowout panel device of the present invention is a blowout panel device provided in an opening of a wall surface of a building of a nuclear reactor-related facility, and is a blowout formed in a shape to close the opening. A panel, an electric drive device provided on the outer wall surface of the reactor-related facility building, an arm connecting the blowout panel and the electric drive device, and a damper connecting the arm and the outside of the wall surface of the reactor-related facility building. , It is located near the base of the arm and is equipped with a pedestal on which the blowout panel is seated. The blowout panel is electrically restored to its original state when the internal pressure of the reactor-related facility building drops. Other aspects of the present invention will be described in embodiments described below.

According to the present invention, the speed at which steam flows out from the opening (degree of decompression per unit time) can be made appropriate.

It is explanatory drawing of the outline of the apparatus which shows the positional relationship between the opening provided in the building of the reactor-related facility which concerns on 1st Embodiment, and a blowout panel. It is a side view which shows the positional relationship between a blowout panel and a gantry in normal times which concerns on 1st Embodiment. It is a side view which shows the positional relationship between a blowout panel and a gantry at the time of reclosing which concerns on 1st Embodiment. It is a side view which shows the positional relationship between a blowout panel and a gantry which is a modification of FIG. 2A. It is a side view which shows the positional relationship between a blowout panel and a gantry while opening the opening which concerns on 1st Embodiment. It is a side view which shows the positional relationship between a blowout panel and a gantry when the blowout panel which concerns on 1st Embodiment is seated on a gantry. It is a top view which shows the positional relationship between a blowout panel and a gantry in normal times which concerns on 1st Embodiment. It is a top view which shows the positional relationship between a blowout panel and a gantry at the time of reclosing which concerns on 1st Embodiment. It is an enlarged side view of the connection part of a blowout panel and an arm which concerns on 1st Embodiment. It is a figure which looked at the connection part of the blowout panel and arm which concerns on 1st Embodiment from the X direction shown in FIG. 6A. It is a side view which shows the positional relationship between a blowout panel and a gantry at the time of opening which concerns on 2nd Embodiment. It is a side view which shows the positional relationship between a blowout panel and a gantry at the time of opening which is a modification of FIG. 7A. It is a side view which shows the positional relationship between a blowout panel and a gantry at the time of opening which concerns on 3rd Embodiment.

Embodiments for carrying out the present invention will be described in detail with reference to the drawings as appropriate.
<< First Embodiment >>
FIG. 1 is a schematic explanatory view of an apparatus showing a positional relationship between an opening A and a blowout panel 1 provided in a building of a nuclear reactor-related facility according to the first embodiment. FIG. 1 is a perspective view of the building 100 from inside the building 100 (see FIG. 2A). When steam flows out into the building 100 of the reactor-related facility and the internal pressure in the building 100 rises, the blowout panel 1 is moved by the arm 2 in order to protect the building 100. As the arm 2 rotates about the arm base 2d, the blowout panel 1 is separated from the opening A. As a result, the steam in the building 100 is released to the outside through the opening A, and the internal pressure in the building 100 decreases.

FIG. 2A is a side view showing the positional relationship between the blowout panel 1 and the gantry 5 in normal times according to the first embodiment. The right side of the paper indicates the inside of the building 100, the left side indicates the outside of the building 100, and the downward direction indicates the direction of the ground. FIG. 3 is a side view showing the positional relationship between the blowout panel 1 and the gantry 5 while the opening A according to the first embodiment is being opened. FIG. 4 is a side view showing the positional relationship between the blowout panel 1 and the gantry 5 when the blowout panel 1 according to the first embodiment is seated on the gantry 5. FIG. 2B is a side view showing the positional relationship between the blowout panel 1 and the gantry 5 at the time of reclosing according to the first embodiment. The right side of the paper shows the inside of the building 100, the left side shows the outside of the building 100, and the downward direction shows the ground side. FIG. 2C will be described later. Further, FIG. 5A is a top view showing the positional relationship between the blowout panel 1 and the gantry 5 in normal times according to the first embodiment. The upper side of the paper indicates the outside of the building 100, the lower side indicates the inside of the building 100, and the depth direction indicates the ground direction. FIG. 5B is a top view showing the positional relationship between the blowout panel 1 and the gantry 5 at the time of reclosing according to the first embodiment. The upper side of the paper indicates the outside of the building 100, the lower side indicates the inside of the building 100, and the depth direction indicates the ground direction.

Note that FIG. 2A is a diagram of a combination of the BB cross section of FIG. 5A and the arrow C, and FIG. 2B is a diagram of the combination of the BB cross section of FIG. 5B and the arrow C.

As shown in FIG. 2A, the opening A is provided on the side surface of the building 100 and so as to penetrate the inside and outside of the building 100. The opening A functions as a steam outlet when the internal pressure in the building 100 rises. In normal times, the blowout panel 1 is in a position to close the opening A. One of the arms 2 is connected to the back side of the blowout panel 1, and the other is connected to the electric drive device 4. Further, a bent portion 2a is provided in the intermediate portion of the arm 2.

The base of the damper 3 is connected to the outer wall surface of the building 100 by a bearing, and the damper 3 is configured to be rotatable in the vertical direction around the base. Further, the root portion of the damper 3 is located between the electric drive device 4 and the opening A. The tip of the damper 3 is connected to the bent portion 2a of the arm 2 by a bearing, and the damper 3 is configured to be rotatable about the bent portion 2a. This bearing can be attached to the shaft portion of the arm 2 side, the damper 3 side, or both of them, but there is no problem if only one side of the arm 2 side or the damper 3 side is used. Then, in the bent portion 2a of the arm 2, the arm 2 and the damper 3 are connected by penetrating the shaft pin 10 (see FIG. 5A).

The electric drive device 4 is fixed to the outer wall surface of the building 100 and is a device for rotationally driving the arm 2. The gear of the electric drive device 4 is a ratchet type gear, and has a mechanism that rotates freely when opened. Specifically, when the blowout panel 1 is opened, the gear of the electric drive device 4 rotates freely, so that the blowout panel 1 is opened, and when the electric drive device 4 is driven after the power is restored, the gears mesh with each other. , A mechanism for closing the opening A with the blowout panel 1.

The gantry 5 is composed of members 5a, 5b, and 5c, and is installed on the outer wall surface of the building 100 (hereinafter, referred to as the outdoor wall surface of the building). The member 5a is provided from the lower side of the electric drive device 4 in the direction perpendicular to the outdoor wall surface of the building, and the member 5b is provided upward from the tip of the member 5a (opposite side of the outdoor wall surface of the building). .. Further, the member 5c is provided in the direction perpendicular to the inside of the member 5b, and is in a position to support the blowout panel 1 when opened.

When the member 5a is viewed from above, as shown in FIG. 5A, the structure is such that three members 5a project outward from the outdoor wall surface of the building, and the members 5a are connected to each other by reinforcing members. Members 5b and 5c are also connected by reinforcing members in the same manner.

Note that FIG. 2C is a side view showing the positional relationship between the blowout panel and the gantry, which is a modification of FIG. 2A. In the example shown in FIG. 2A, the gantry 5 is provided below the opening A, but in the case of the blowout panel device 20A shown in FIG. 2C, the gantry 5 may be provided above the opening A.

Returning to FIG. 2A, the cushion 6 is composed of the cushion 6a and the cushion 6b, and the cushion 6a is provided on the member 5a. Further, the cushion 6b is provided at the tip of the member 5c. The weight 7 is provided on the outside of the building 100 of the blowout panel 1, and has a function of keeping the direction (posture) of the blowout panel 1 vertical when the blowout panel 1 moves.

A branch 8b is provided so as to protrude outward from the outdoor wall surface of the building, and a stop plate 8a is provided on the branch 8b. A plurality of stop plates 8a are provided around the opening A, and the blowout panel 1 can be fixed by projecting the stop plate 8a to a position where the stop plate 8a closes the opening A.

The packing 9 is located at the intersection 100a where the opening A penetrating the wall of the building 100 and the outdoor wall surface of the building intersect, and when the blowout panel 1 closes the opening A, the packing 9 comes into close contact with the blowout panel 1. It is provided as follows. Further, the shape of the packing 9 is inclined so as to increase in thickness from the outside of the building to the inside of the building, and can be brought into close contact with the inclinations provided on the four sides of the blowout panel 1.

FIG. 6A is an enlarged side view of the connection portion between the blowout panel 1 and the arm 2 according to the first embodiment. The blowout panel 1 is provided with a rotary shaft hole in a branch portion 1c on the back surface of the blowout panel 1. A bolt 1a is inserted into the rotating shaft hole and the tip hole 2c of the arm 2, and the arm 2 can rotate around the horizontal axis. Further, a stopper 1b protrudes from the branch 1c in the vicinity of the rotary shaft hole. A stopper hole 2b is provided in the vicinity of the tip hole 2c of the arm 2 in an arc shape, and the stopper 1b is inserted into the stopper hole 2b. The stopper 1b can limit the blowout panel 1 so that it can only rotate to a certain angle.

FIG. 6B is a view of the connection portion between the blowout panel 1 and the arm 2 according to the first embodiment as viewed from the X direction shown in FIG. 6A. As described above, the bolt 1a is inserted into the rotary shaft hole provided in the branch 1c and the tip hole 2c of the arm 2, and is screwed with the nut 1d. A washer 1e is provided between the blowout panel 1 and the arm 2.

FIG. 3 is a side view showing the positional relationship between the blowout panel 1 and the gantry 5 while the opening A is being opened. The right side of the page shows the inside of the building 100, the left side shows the outside of the building 100, and the downward direction shows the direction of the ground. Hereinafter, the same members as those in FIG. 2A are designated by the same reference numerals. When the internal pressure of the building 100 rises above a predetermined value, the stop plate 8a is damaged, and the blowout panel 1 is separated from the opening A toward the outside of the building by the pressure inside the building applied to the blowout panel 1 and the auxiliary force of the damper 3. Since the damper 3 is connected to the bent portion 2a of the arm 2, the blowout panel 1 is opened until it is fully opened by the assisting force that the damper 3 tries to extend.

FIG. 4 is a side view showing the positional relationship between the blowout panel 1 and the gantry 5 when the blowout panel 1 is seated on the gantry 5. The right side of the paper shows the inside of the building 100, the left side shows the outside of the building 100, and the downward direction shows the ground side. After the blowout panel 1 is opened, the blowout panel 1 is pressed by the cushions 6a and 6b to sit on the gantry 5. By seating the blowout panel 1 on the gantry 5 in this way, the movement of the blowout panel 1 can be restricted, and the earthquake resistance can be maintained.

Further, in the design stage of the blowout panel 1, the length of the arm 2 is related to the seating position of the blowout panel 1. That is, since the distance between the seating position of the blowout panel 1 and the opening A can be changed according to the length of the arm 2, the speed at which steam flows out from the opening A (degree of decompression per unit time) is also at the design stage. It is possible to adjust. For example, as the length of the arm 2 is increased, the blowout panel 1 is separated from the opening A when the blowout panel 1 is seated on the gantry 5, so that the speed at which steam flows out from the opening A (decompression per unit time). Degree) can be increased.

Next, a flow in which the closed blowout panel device 20 opens in the order of FIGS. 2A, 3 and 4 due to an increase in the internal pressure of the building 100 will be described.

In the blowout panel device 20 in normal times, the damper 3 is loaded in the direction of extension, while the blowout panel 1 is fixed by the stop plate 8a (see FIG. 2A). Therefore, the blowout panel 1 is fixed to the opening A. Although the electric drive device 4 is energized in normal times, no load is applied to the arm 2.

Then, when the internal pressure of the building 100 rises above a predetermined value due to steam flowing out when the main steam pipe ruptures, the stop plate 8a is damaged, and the arm 2 rotates about the arm base 2d, so that the blowout panel 1 becomes It moves away from the opening A. Further, since the damper 3 continues to apply the load in the direction of extension, the blowout panel 1 moves in the direction of descending to the gantry 5 by the auxiliary force of the damper 3 (see FIG. 3). When the blowout panel 1 moves, a weight 7 (balancer) is attached to the lower side of the blowout panel 1, so that the direction (posture) of the blowout panel 1 can be kept vertical. be.

When the damper 3 is further extended, the upper part and the lower part of the blowout panel 1 are seated on the gantry 5 via the cushions 6b and 6a, respectively (see FIG. 4). In this way, since the blowout panel 1 is seated while being pressed against the gantry 5 by the assisting force of the damper 3, the blowout panel 1 withstands earthquake motion even when an earthquake occurs when the blowout panel 1 is opened. It is possible.

In a structure without a damper 3 as in Patent Document 1, the blowout panel 1 is opened even a little when the internal pressure rises, so that the steam inside the building flows out from the gap. However, since the gap between the blowout panel 1 and the opening A is small, the pressure loss when steam flows out from the building 100 becomes large, and it takes time for the pressure inside the building to drop to an allowable value.

On the other hand, by pressing the blowout panel 1 against the gantry 5 by the auxiliary force of the damper 3 as in the present embodiment, it is possible to keep a sufficient distance between the blowout panel 1 and the opening A, and steam can be generated outdoors. It is possible to reduce the pressure loss when flowing out to.

Next, a flow in which the open blowout panel device 20 performs the closing operation in the order of FIGS. 4, 3 and 2B will be described. The upper part and the lower part of the blowout panel 1 are seated on the gantry 5 via cushions 6b and 6a, respectively (see FIG. 4).

When the opening A is closed, the electric drive device 4 lifts the blowout panel 1 with the arm 2, and the arm 2 rotates about the arm base 2d. Since the damper 3 constantly applies a load in the direction of extension, the electric drive device 4 moves the blowout panel 1 with a load that overcomes the load of the damper 3 (see FIG. 3).

Therefore, the load that presses the blowout panel 1 against the packing 9 of the opening A can be designed in advance as the power of the electric drive device 4. On the other hand, in the method of closing the opening A by the weight of the blowout panel 1 as in Patent Document 1, the load for pressing the blowout panel 1 against the opening A cannot be designed in advance, and the opening A cannot be designed. There was a possibility that the degree of sealing after closing was lower than the design value.

In the present embodiment, by designing the load for pressing the blowout panel 1 against the packing 9 of the opening A in advance, it is possible to secure the degree of sealing after closing the opening A up to the design value.

Then, the blowout panel 1 closes the opening A (see FIG. 2B). In the blowout panel device according to Patent Document 1, when the steam outflow from the building 100 is stopped, the blowout panel 1 returns to the opening A by its own weight. However, when the pressing force from the blowout panel 1 to the opening A becomes weak and the blowout panel 1 cannot securely close the opening A, the blowout panel 1 cannot be closed remotely.

According to the present embodiment, by moving the arm 2 by the electric drive device 4, the opened blowout panel 1 can be restored to the original state by a remote instruction.

<< Second Embodiment >>
FIG. 7A is a side view showing the positional relationship between the blowout panel 1 and the gantry 5A at the time of opening according to the second embodiment. The right side of the paper shows the inside of the building 100, the left side shows the outside of the building 100, and the downward direction shows the ground direction. In the case of the blowout panel device 20B of the second embodiment, since there is a margin of space downward from the opening A, the gantry 5A is provided further lower than that of the first embodiment. Then, when the blowout panel 1 is completely opened, a part of the damper 3 moves to a position where it touches the outdoor wall surface of the building. According to this embodiment, the members 5b and 5c are not required, and the member 5a of the gantry 5A can be made smaller, so that the weight of the gantry 5A can be reduced.

FIG. 7B is a side view showing the positional relationship between the blowout panel and the gantry at the time of opening, which is a modified example of FIG. 7A. In the case of the blowout panel device 20C, the position of the gantry 5A is upside down as compared with FIG. 7A. In the structure of FIG. 7B, the gantry 5A can play a role of a snow shield by locating the gantry 5A above the opening A.

<< Third Embodiment >>
FIG. 8 is a side view showing the positional relationship between the blowout panel 1 and the gantry 5C at the time of opening according to the third embodiment. The lower side of the paper indicates the inside of the building 100, the upper side indicates the outside of the building 100, and the depth direction indicates the ground direction. In the case of the blowout panel device 20D of the third embodiment, it is assumed that there is not enough space in the vertical direction of the opening A, and the difference is that the blowout panel 1 moves in the horizontal direction. In the third embodiment, the gantry 5B is composed of a plurality of members 5e. The member 5e is provided with a cushion 6b.

In the blowout panel device 20D, the arm 2 rotates around the base, so that the inner wall surface side of the blowout panel 1 is pressed by the gantry 5B when the internal pressure of the reactor-related facility building rises, and the blowout panel device 20D is used in the reactor-related facility building. When the internal pressure drops, the blowout panel 1 can be electrically restored to its original state.

According to this embodiment, the gantry 5C can be provided even when there is not enough space in the vertical direction of the opening A. In FIG. 8, the gantry 5B is provided on the left side when facing the paper, but it may be provided on the right side.

<Effect>
(1) In the blowout panel device according to Patent Document 1, when the steam outflow from the building is stopped, the blowout panel 1 returns to the opening A by its own weight. However, when the pressing force from the blowout panel 1 to the opening A becomes weak and the blowout panel 1 cannot securely close the opening A, the blowout panel cannot be closed remotely.
On the other hand, according to the present embodiment, the electric drive device 4 moves the arm 2 to close the opened blowout panel 1 by a remote instruction.
(2) When the blowout panel 1 is opened by the steam flowing out into the reactor building, the pressure loss when the steam flows out to the outside of the building can be reduced.
(3) Electric power is not used when it is open, and electric power is used when it is closed. The airtightness at the time of closing can be set by motor power. Compared with the conventional gravity closing method, the required sealing force can be arbitrarily designed.
(4) The damper 3 is used as an aid to fully open the blowout panel 1 and is pressed against the gantry 5. As a result, even if an earthquake occurs in the open state, the blowout panel 1 is fixed to the gantry 5, so that it can withstand the vibration caused by the earthquake. Further, in an emergency, even when water is injected into the furnace by discharging water from the outside, the opening A can be made free of obstacles, so that the water can be easily discharged.

1 Blowout panel 1a Bolt 1b Stopper 1c Branch 1d Nut 1e Washer 2 Arm 2a Bending part 2b Stopper hole 2c Tip hole 2d Arm base (base)
3 Damper 4 Electric drive device 5,5A, 5B Stand 5a, 5b, 5c Members 6,6a, 6b Cushion 7 Weight (balancer)
8a Stop plate 8b Branch 9 Packing 10 Axis pin 20, 20A, 20B, 20C, 20D Blowout panel device 100 Building

Claims (7)

It is a blowout panel device installed in the opening of the wall of the building of the nuclear reactor related facility.
A blowout panel molded into a shape that closes the opening, and
An electric drive device installed on the outer wall surface of the reactor-related facility building,
An arm connecting the blowout panel and the electric drive device,
A damper that connects the arm to the outside of the wall surface of the reactor-related facility building,
It is located near the base of the arm and is provided with a stand on which the blowout panel is seated.
By rotating the arm around the base, the upper and lower parts of the blowout panel are pressed against the gantry when the internal pressure of the reactor-related facility building rises, and the above-mentioned when the internal pressure of the reactor-related facility building decreases. A blowout panel device characterized in that the blowout panel is electrically restored to its original state. The blowout panel device according to claim 1.
A blowout panel device characterized in that the degree of decompression of the opening per unit time can be adjusted by the arm length. The blowout panel device according to claim 1.
A blowout panel device characterized in that the gear of the electric drive device is a ratchet type gear. The blowout panel device according to claim 1.
A blowout panel device characterized in that a stopper for restricting rotation of the blowout panel is provided on the back side of the blowout panel. The blowout panel device according to claim 1.
A blowout panel device characterized in that a weight is provided on the outer surface side of the blowout panel. The blowout panel device according to claim 1.
The damper is a blowout panel device characterized in that an extensional load is applied to the arm. It is a blowout panel device installed in the opening of the wall of the building of the nuclear reactor related facility.
A blowout panel molded into a shape that closes the opening, and
An electric drive device installed on the outer wall surface of the reactor-related facility building,
An arm connecting the blowout panel and the electric drive device,
A damper that connects the arm to the outside of the wall surface of the reactor-related facility building,
It is located near the base of the arm and is provided with a stand on which the blowout panel is seated.
By rotating the arm around the base, the inner wall surface side of the blowout panel is pressed against the gantry when the internal pressure of the building of the reactor-related facility rises, and the blow occurs when the internal pressure of the building of the reactor-related facility decreases. A blowout panel device characterized in that the outpanel is electrically restored to its original state.

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