JP6517050B2 - Flight protection equipment - Google Patents

Description

  In particular, the present invention relates to an airborne object protection facility that prevents airborne objects from reaching an object to be protected in a nuclear facility.

  Nuclear facilities are provided with mechanisms to ensure the safety of the facilities. For example, a mechanism for protecting various devices from airborne objects is described in Patent Document 1 below. The reactor building described in this patent document 1 houses a safety system equipment and system, and has a building structure constructed to have a wall thickness resistant to an impact from an aircraft collision as an external flying object, and the building structure And a roof structure constructed above, the building structure and the roof structure being configured to be separated from each other, and to have foundation structures independent of each other.

JP 2011-252800 A

  Here, as flying objects, there are objects flying toward the equipment to be protected by gusts or strong winds. If such a flying object collides with the device to be protected, it may cause damage or failure. Furthermore, in Japan, safety facilities are to be protected from damage from external impacts under Article 6 of the Regulations on the Position, Structure, and Facilities of Nuclear Power Generation Reactors and their Associated Facilities, as defined by the Nuclear Regulatory Commission. It is stipulated that the safety function should not be impaired even when the assumed natural phenomenon occurs. The influence of tornado is mentioned as one of the natural phenomena assumed based on the natural environment around this site. For this reason, it is required that the design of the reactor facility does not impair the safety of the reactor facility due to a tornado as a natural phenomenon that causes gusts and strong winds that occur extremely rarely during operation of the reactor facility and its accompanying events. ing. Specifically, based on the “Natural power plant tornado impact assessment guide”, set the design tornado and design load (design tornado load and other combined load), investigate the flying object in the power plant, and fly Take preventive measures, evaluate the structural soundness of the tornado protective facility against the design load to be considered, etc., take measures corresponding to the result, and maintain the safety function.

  In the conventional reactor building described above, since the roof structure is constructed so as to cover the upper side of the building structure and has a steel structure, the roof structure becomes heavy. Then, the insufficient strength of the roof structure which is a heavy load is considered, and the earthquake resistance at the time of the occurrence of the earthquake is not sufficient. In particular, when sufficient sites can not be secured around existing facilities or when structural reinforcement is not possible, the earthquake resistance at the time of an earthquake may be insufficient.

  An object of the present invention is to solve the problems described above, and it is an object of the present invention to provide an airborne object protection facility capable of suitably protecting an object to be protected and securing sufficient earthquake resistance.

  An airborne object protection facility according to the present invention for achieving the above object is an airborne object protection facility for protecting an object to be protected installed on the ground from the outside, and the aforementioned object is covered so as to cover the periphery of the object to be protected. A side wall erected on the ground with a predetermined gap from the object to be protected, an upper wall connected to an upper portion of the side wall to cover the upper side of the object to be protected, and a horizontal direction in the side wall And a vibration reduction mechanism for reducing the vibration of the vehicle.

  Therefore, since the outside of the object to be protected is covered with the side wall portion and the upper wall portion, even if the flying object flies toward the object to be protected due to gusts or strong winds when the tornado or the like is generated, the airborne object can be By colliding with the upper wall, it is possible to prevent a collision with the object to be protected. Further, by providing the vibration reduction mechanism in the side wall portion and the upper wall portion, it is possible to reduce the vibration acting in the horizontal direction with respect to the side wall portion or the upper wall portion by the vibration reduction mechanism when an earthquake or the like occurs. As a result, an object to be protected can be suitably protected, and sufficient earthquake resistance can be secured.

  In the missile protection system of the present invention, the vibration reduction mechanism is characterized by having a seismic isolation mechanism.

  Therefore, by using the vibration reduction mechanism as the seismic isolation mechanism, the side wall portion and the upper wall portion can be easily constructed even for the existing equipment. In this case, the vibration of the side wall portion and the upper wall portion can be reduced by a simple configuration called a seismic isolation mechanism, and the configuration of the side wall portion and the upper wall portion can be simplified.

  In the missile protection system of the present invention, the ground is provided with a recess in the periphery of the object to be protected, a base plate is provided in the recess, and the support of the side wall portion is provided on the base plate via the seismic isolation mechanism. It is characterized in that a member is installed.

  Therefore, the base plate is provided in the recess provided on the ground, and the support member of the side wall portion is installed on the base plate via the seismic isolation mechanism, so that the sidewall portion and the seismic isolation mechanism can be easily installed.

  In the missile protection system of the present invention, the vibration reduction mechanism has a damper mechanism, and is disposed between the support member and the base plate in parallel with the seismic isolation mechanism.

  Therefore, by providing the seismic isolation mechanism and the damper mechanism as the vibration reduction mechanism, and arranging the seismic isolation mechanism and the damper mechanism in parallel between the support member and the base plate, the vibration of the side wall portion and the upper wall portion by the seismic isolation mechanism. Can be reduced, and the vibration generated by the damper mechanism can be attenuated early.

  In the missile protection system of the present invention, the damper mechanism is disposed along the horizontal direction.

  Therefore, by disposing the damper mechanism in the horizontal direction, horizontal vibrations in the side wall portion and the upper wall portion can be attenuated early.

  In the missile protection system of the present invention, the height of the upper surface of the support member and the height of the ground are set to the same height.

  Therefore, by making the height of the upper surface of the support member and the height of the ground the same height, the vibration reduction mechanism is not exposed, and it is possible to prevent the impact of flying objects on the vibration reduction mechanism as well. It is possible to improve the quality.

  In the airborne object protection facility of the present invention, the vibration reduction mechanism has a damper mechanism, and the damper mechanism is disposed between the side wall portion and a structure adjacent to the side wall portion. .

  Therefore, by using the vibration reduction mechanism as the damper mechanism and arranging it between the side wall portion and the adjacent structure, the vibration of the side wall portion and the upper wall portion can be properly reduced and damped, and the vibration reduction is also possible. The installation of the mechanism can be facilitated to reduce the operation cost.

  In the missile protection system of the present invention, the side wall portion and the upper wall portion are characterized in that a protective net is fixed to a frame structure.

  Therefore, by using the side wall portion and the upper wall portion as the frame structure, sufficient strength can be secured even if it is lightweight, and the protection net is protected by fixing the protection net to the frame structure. It is possible to effectively prevent the impact of flying objects on the object.

  In the airborne object protection facility of the present invention, the upper wall portion has a first upper wall portion disposed on the upper stage side and a second upper wall portion disposed on the lower stage side, and the second upper wall portion Is characterized in that the protective net is fixed.

  Therefore, by providing the first upper wall on the upper side and the second upper wall on the lower side as the upper wall, the strength around the upper wall can be increased, and protection is provided to the second upper wall on the lower side. By fixing the net, it is possible to prevent the collision of flying objects and to improve the durability of the upper wall portion.

  In the airborne object protection facility of the present invention, the side wall portion is provided with an inlet / outlet opening, and has a larger area than the inlet / outlet opening, facing the inside or the outside of the inlet / outlet opening with a predetermined gap. It is characterized in that a closing member is erected.

  Therefore, by erecting the closing member at the entrance opening, the passage can be easily secured for maintenance of the protection target, and protection is provided while preventing collision of flying objects against the protection target. Maintainability of the object can be secured.

  According to the flying object protection facility of the present invention, the vibration reducing mechanism for reducing the horizontal vibration in the side wall portion is provided, so that the object to be protected can be suitably protected, and sufficient earthquake resistance can be secured. it can.

FIG. 1 is a front view showing the airborne object protection facility of the first embodiment. FIG. 2 is a longitudinal sectional view showing an airborne object protection facility. FIG. 3 is a plan view showing an airborne object protection facility. FIG. 4 is a horizontal cross section (IV-IV cross section of FIG. 1) showing an airborne object protection facility. FIG. 5 is a schematic view showing a protective net. FIG. 6 is a schematic view showing a covering unit. FIG. 7 is a longitudinal sectional view showing a seismic isolation mechanism. FIG. 8 is a front view showing another seismic isolation mechanism. FIG. 9 is a top view showing an entrance / exit part. FIG. 10 is a side view showing an entrance / exit part. FIG. 11 is a plan view showing the airborne object protection equipment of the second embodiment. FIG. 12 is a longitudinal sectional view showing an airborne object protection facility. FIG. 13 is a front view showing the airborne object protection facility of the third embodiment.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that the present invention is not limited by the embodiments, and in the case where there are a plurality of embodiments, the present invention also includes those configured by combining the respective embodiments.

First Embodiment
FIG. 1 is a front view showing the airborne object protection facility of the first embodiment, FIG. 2 is a longitudinal sectional view showing the airborne object protection facility, FIG. 3 is a plan view showing the airborne object protection facility, FIG. It is a horizontal cross section (IV-IV cross section of FIG. 1) showing an object protection installation.

  In the first embodiment, as shown in FIGS. 1 and 2, the facility is a nuclear power plant, and the protection target is, for example, a condensate tank T. The nuclear power plant is provided with a missile protection system 10 for protecting the condensate tank T for various safety measures.

  The airborne object protection facility 10 protects the condensate tank (object to be protected) T installed on the ground G from the outside. The airborne object protection facility 10 includes a side wall 11, an upper wall 12, and a vibration reduction mechanism 13.

  The condensate tank T is a circular tank and is erected on a foundation 21 placed on the ground G. The ground G is provided with a recess 22 around the condensate tank T. The recess 22 is formed by digging the ground G, and has a rectangular ring shape in plan view. The base plate 23 is provided inside the recess 22. The base plate 23 has a ring shape that is rectangular in plan view, like the recess 22.

  A plurality of vibration reduction mechanisms 13 are provided on the base plate 23 at predetermined intervals along the longitudinal direction. The vibration reduction mechanism 13 reduces horizontal vibration in the side wall portion 11. And each support member 24 is installed in the upper part of each vibration reduction mechanism 13, respectively. The support member 24 is a heavy load, for example, a counterweight.

  The side wall portion 11 is in the form of a square tube that covers the condensate tank T from all sides. The side wall portion 11 is erected on the ground G with a predetermined gap from the side surface of the condensate tank T so as to cover the periphery of the condensate tank T. The side wall portion 11 is a frame structure, and includes a plurality of columns 31 extending in the vertical direction and beams 32 extending in the horizontal direction so as to connect the columns 31. In this case, a reinforcing member (truss) may be provided to diagonally reinforce the space portion formed by the columns 31 and the beams 32. The protective net 33 is fixed to the entire surface of the side wall portion 11.

  The lower end portions of the columns 31 are installed and fixed on the support members 24 in the side wall portion 11. In this case, the height of the upper surface of the support member 24 and the height of the ground G are set to the same height.

  Further, the upper wall portion 12 is connected to the upper portion of the side wall portion 11 so as to cover the upper side of the condensate tank T. The upper wall portion 12 has a square plate shape that covers the condensate tank T from above. The upper wall portion 12 is fixed to the upper portion of the side wall portion 11 with a predetermined gap from the upper surface of the condensate tank T so as to cover the upper side of the condensate tank T.

  The upper wall portion 12 is configured of a first upper wall portion 41 disposed on the upper stage side and a second upper wall portion 42 disposed on the lower stage side. As shown in FIG. 3, the first upper wall portion 41 is a frame structure, and includes a plurality of longitudinal beams 43 and a plurality of transverse beams 44 connected so as to cross each other along the horizontal direction. . And the reinforcement member (truss) 45 which diagonally reinforces the space part formed of each longitudinal beam 43 and each cross beam 44 is connected. Further, as shown in FIG. 4, the second upper wall portion 42 is a frame structure, and includes a plurality of longitudinal beams 46 and a plurality of lateral beams 47 connected so as to cross each other along the horizontal direction. ing. In this case, reinforcing members (truss) may be provided to diagonally reinforce the space portions formed by the vertical beams 46 and the horizontal beams 47. The protective net 48 is fixed to the entire surface of the second upper wall portion 42.

  In this case, the first upper wall 41 is disposed at the upper end of the side wall 11, and the second upper wall 42 is disposed below the first upper wall 41 by a predetermined distance. Therefore, not only the rigidity of the side wall portion 11 but also the rigidity of the second upper wall portion 42 can be increased by providing not only the columns 31 and the beams 32 but also the reinforcing members (truss) as the side wall portion 11. it can.

  FIG. 5 is a schematic view showing a protective net. As shown in FIG. 5, the protective net 48 provided on the second upper wall portion 42 is fixed to the opening formed by the longitudinal beam 46 and the transverse beam 47. The protective net 48 is composed of a net body 48a made of a wire mesh and a string-like connecting member 48b provided around the net body 48a. The vertical beam 46 has a locking pin 49 fixed to the cross connection portion with the cross beam 47, and the protective net 48 is locked to the respective locking pin 49 by the connecting member 48b. It is fixed to Although the protection net 48 provided on the upper wall portion 12 has been described here, the protection net 33 provided on the side wall portion 11 also has substantially the same configuration.

  The structure of the protective net 48 (33) is not limited to the one described above. FIG. 6 is a schematic view showing a covering unit. As shown in FIG. 6, the covering unit 51 is manufactured, for example, in a factory or on the ground to form a unit, and is attached to the side wall portion 11 or the upper wall portion 12 as the covering unit 51. In the covering unit 51, the connecting piece 53 is fixed to the longitudinal middle portion of the rectangular frame 52 and the two reinforcing pieces 54 are fixed in a truss shape, and the net 55 is covered so as to cover the front surface. Is attached and configured. The frame 52 is integrally formed with a plurality of mounting portions 52a around the periphery, and fixes the covering unit 51 at a predetermined position on the side wall portion 11 or the upper wall portion 12 by using the mounting portions 52a with bolts not shown. . The workability of the side wall portion 11 and the upper wall portion 12 is improved by sequentially fixing the plurality of covering units 51 later.

  Here, although the vibration reduction mechanism 13 is demonstrated, two types of vibration reduction mechanisms 13A and 13B are demonstrated below. FIG. 7 is a longitudinal sectional view showing a seismic isolation mechanism, and FIG. 8 is a front view showing another seismic isolation mechanism.

  As shown in FIG. 7, the vibration reduction mechanism 13 </ b> A is configured by the seismic isolation mechanism 61. The seismic isolation mechanism 61 is provided between the upper surface of the base plate 23 and the lower surface of the support member 24. The seismic isolation mechanism 61 is a seismic isolation structure (rubber support) 62, and for example, a lower pedestal 63 fixed to the upper surface of the base plate 23 and an upper pedestal 64 fixed to the lower surface of the support member 24. The pillars 65 connecting the lower pedestal 63 and the central portion of the upper pedestal 64, and between the lower pedestal 63 and the upper pedestal 64 have a plurality of stacked disc shapes disposed around the struts 65. And a support plate 66. The support plate 66 is a laminate of a plurality of rubber plates or a laminate of a plurality of rubber plates and a plurality of steel plates alternately.

  Also, as shown in FIG. 8, the vibration reduction mechanism 13 B is configured by the seismic isolation mechanism 71 and the damper mechanism 72, and the seismic isolation mechanism 71 and the damper mechanism 72 are between the base version 23 and the support member 24. It is arranged in parallel. Moreover, the damper mechanism 72 is arrange | positioned along the horizontal direction. That is, the seismic isolation mechanism 71 is the seismic isolation structure 73, and may be, for example, the seismic isolation structure 62 described above, or a simple laminate of a plurality of rubber plates or a plurality of rubber plates and a plurality of steel plates It may be a laminate of The damper mechanism 72 is a hydraulic damper 74, which is disposed along the horizontal direction, has one end connected to the side surface of the support member 24, and the other end connected to the concrete structure 75 erected from the base plate 23. It is connected.

  Therefore, when a load in the horizontal direction acts on the side wall portion 11 and the upper portion 12 at the time of occurrence of an earthquake or the like, the side wall portion 11 and the upper wall portion 12 swing in the horizontal direction by this load. However, since the side wall portion 11 is supported by the vibration reduction mechanism 13 (13A, 13B), the load in the horizontal direction acting on the side wall portion 11 and the upper wall portion 12 has an inertial force and the vibration reduction mechanism 13 Act on. Then, the natural frequency of the side wall portion 11 and the upper wall portion 12 deviates from the predominant period of the acceleration response spectrum, the response acceleration of the side wall portion 11 and the upper wall portion 12 is reduced, and the side wall portion 11 and the upper wall portion The horizontal swing of 12 is reduced.

  In the airborne object protection facility 10, a side wall 11 is provided with a port for maintenance. FIG. 9 is a top view showing the inlet / outlet portion, and FIG. 10 is a side view showing the inlet / outlet portion.

  The side wall portion 11 is assembled such that the plurality of columns 31 and the plurality of beams 32 are orthogonal to each other, and the plurality of protection nets 33 are fixed. Is provided. A closing member 81 is provided upright on the inner side of the side wall portion 11 from the inlet / outlet opening 80. Similar to the side wall portion 11, the closing member 81 is configured such that the plurality of columns 82 and the plurality of beams 83 are orthogonal to each other, and the plurality of protective nets 84 are fixed. The closing member 81 has an area larger than that of the inlet / outlet opening 80, and is erected inside the inlet / outlet opening 80 with a predetermined gap 85, 86 therebetween. Therefore, the maintenance passage 87 is provided by the inlet / outlet opening 80 and the predetermined gaps 85 and 86.

  Thus, in the airborne object protection facility of the first embodiment, a side wall is provided upright on the ground G with a predetermined gap from the condensate tank T so as to cover the periphery of the condensate tank T as the object to be protected. A portion 11, an upper wall portion 12 connected to an upper portion of the side wall portion 11 so as to cover the upper side of the condensate tank T, and a vibration reduction mechanism 13 for reducing horizontal vibration in the side wall portion 11 are provided.

  Therefore, since the outer side of the condensate tank T is covered with the side wall portion 11 and the upper wall portion 12, even when the flying object flies toward the protection target due to gusts or strong winds when the tornado or the like occurs, this flying object is The collision with the side wall portion 11 and the upper wall portion 12 can prevent the collision with the condensate tank T. Further, the vibration reducing mechanism 13 is provided on the side wall portion 11 and the upper wall portion 12 so that the vibration acting on the side wall portion 11 or the upper wall portion 12 in the horizontal direction by the vibration reducing mechanism 13 when an earthquake or the like occurs. It can be reduced. As a result, the condensate tank T can be suitably protected, and sufficient earthquake resistance can be secured.

  In this case, it is possible to provide equipment for protecting the falling of flying objects while reducing the influence on the existing condensate tank T. Further, by providing the impact protection system 10 with less influence on the condensate tank T, reinforcement required for the condensate tank T can be reduced. In addition, since the force acting on the incident protection system 10 can be reduced, the strength required for the incident protection system 10 can also be reduced.

  In the missile protection system of the first embodiment, the vibration reduction mechanism 13A is used as the seismic isolation mechanism 61. Therefore, the side wall 11 and the upper wall 12 can be easily constructed even for the existing equipment. In this case, the vibration of the side wall portion 11 and the upper wall portion 12 can be reduced by the simple configuration of the seismic isolation mechanism 61, and the structures of the side wall portion 11 and the upper wall portion 12 can be simplified.

  In the flying object protection facility of the first embodiment, a recess 22 is provided in the ground G around the condensate tank T, a base plate 23 is provided in the recess 22, and a sidewall is provided on the base plate 23 via the seismic isolation mechanism 61. The support member 24 of the part 11 is installed. Therefore, the side wall 11 and the seismic isolation mechanism 61 can be easily installed around the condensate tank T.

  In the missile protection system of the first embodiment, the seismic isolation mechanism 71 and the damper mechanism 72 are provided as the vibration reduction mechanism 13B, and the seismic isolation mechanism 71 and the damper mechanism 72 are arranged in parallel between the support member 24 and the base plate 23. doing. Therefore, the vibration of the side wall portion 11 and the upper wall portion 12 can be reduced by the vibration isolation mechanism 71, and the vibration generated by the damper mechanism 72 can be attenuated early.

  In the missile protection system of the first embodiment, the damper mechanism 72 is disposed along the horizontal direction. Therefore, horizontal vibration in the side wall portion 11 and the upper wall portion 12 can be attenuated early.

  In the missile protection system of the first embodiment, the height of the upper surface of the support member 24 and the height of the ground G are set to the same height. Therefore, the vibration reduction mechanism 13 is not exposed, and the collision of the flying object can be prevented also with respect to the vibration reduction mechanism 13, and the safety can be improved.

  In the missile protection system of the first embodiment, the side wall portion 11 and the upper wall portion 12 are configured by fixing the protective nets 33 and 48 to the frame structure. Therefore, sufficient strength can be secured even if it is lightweight, and by fixing the protective nets 33 and 48 to this frame structure, the protective nets 33 and 48 cause collision of flying objects to the condensate tank T. Can be effectively prevented. And while maintaining air circulation possible by the protection nets 33 and 48, it is possible to protect the falling of flying objects. Thereby, heat radiation from the inside of the flying object protection facility 10 can be suitably performed, and a temperature rise can be suppressed. In addition, the protective nets 33 and 48 are separated by a distance that does not contact the condensate tank T even if the protective nets 33 and 48 are bent when a steel pipe or a steel material assumed to be an airborne object flies. It is preferable to arrange.

  In the airborne object protection facility of the first embodiment, a first upper wall portion 41 disposed on the upper stage side as the upper wall portion 12 and a second upper wall portion 42 disposed on the lower stage side are provided. The protective net 48 is fixed to the part 42. Therefore, the strength around the upper wall portion 12 can be increased, and by fixing the protective net 48 to the second upper wall portion 42 on the lower side, collision of flying objects can be prevented, and the durability of the upper wall portion 12 can be improved. It is possible to improve the quality. That is, by providing the reinforcing member (truss) up to the upper portion of the side wall portion 11, the rigidity of the second upper wall portion 42 to which the protective net 48 is fixed can be improved.

  In the airborne object protection facility according to the first embodiment, the side wall 11 is provided with the inlet / outlet opening 80 and has a larger area than the inlet / outlet opening 80 and a predetermined gap 85, 86 inside (or outside) the inlet / outlet opening 80. And a closing member 81 is erected to face each other. Therefore, the maintenance passage 87 can be secured to easily maintain the condensate tank T, and the maintainability of the condensate tank T can be secured while preventing collision of flying objects to the condensate tank T. it can.

Second Embodiment
FIG. 11 is a plan view showing an airborne object protection installation according to a second embodiment, and FIG. 12 is a longitudinal sectional view showing an airborne object protection installation. The members having the same functions as those in the above-described embodiment are denoted by the same reference numerals, and detailed descriptions thereof will be omitted.

  In the second embodiment, as shown in FIG. 11 and FIG. 12, the incident protective equipment 90 protects the condensate tank (protection object) T installed on the ground G from the outside. The airborne object protection facility 90 includes a side wall 11, an upper wall 12, an adjacent structure 91, and a vibration reduction mechanism 92.

  The ground G is provided with a recess 22 around the condensate tank T, and the recess 22 is provided with a base plate 23 inside. A plurality of vibration reducing mechanisms 13 are provided on the base plate 23 at predetermined intervals along the longitudinal direction, and the support members 24 are respectively installed on the upper portions thereof. The side wall portion 11 is a frame structure and is installed and fixed on each support member 24. The upper wall portion 12 is fixed to the upper portion of the side wall portion 11 with a predetermined gap from the upper surface of the condensate tank T so as to cover the upper side of the condensate tank T.

  The ground G is provided with a recess 93 around the condensate tank T. The recess 93 is formed by digging the ground G, and has a rectangular ring shape in plan view. The recess 93 has a base plate 94 provided therein. Like the recess 93, the base plate 94 has a ring shape having a rectangular plan view.

  A plurality of vibration reducing mechanisms 96 are provided on the base plate 94 at predetermined intervals along the longitudinal direction. The vibration reduction mechanism 96 is to reduce horizontal vibration in the adjacent structure body 91. And each support member 95 is installed in the upper part of each vibration reduction mechanism 96, respectively. The adjacent structural body 91 is a frame structure and is erected at a predetermined distance from the side wall portion 11, and is configured by connecting a plurality of columns and a plurality of beams.

  A vibration reduction mechanism 92 is provided between the upper portion of the side wall portion 11 and the adjacent structure body 91. The vibration reduction mechanism 92 is a damper mechanism, and is constituted by a plurality of hydraulic dampers 97. The plurality of hydraulic dampers 97 are interposed between the upper portion of the side wall portion 11 and the upper portion of the adjacent structural body 91, and are arranged in parallel along the horizontal direction and at predetermined intervals in the horizontal direction.

  In the second embodiment, the vibration reduction mechanisms 13 and 96 may be eliminated. That is, since it is difficult to provide a large base plate 23 when there is not a sufficient space outside the side wall portion 11, a small base plate 23 is provided on the outside of the side wall portion 11, and Alternatively, the side wall 11 may be installed via the support member 24.

  Thus, in the airborne object protection facility of the second embodiment, the side wall 11 and the upper wall 12 covering the condensate tank T are provided, and the adjacent structure 91 is erected adjacent to the side wall 11. A hydraulic damper (damper mechanism) 97 as a vibration reduction mechanism 92 is disposed between the side wall portion 11 and the adjacent structure 91.

  Therefore, since the outer side of the condensate tank T is covered with the side wall portion 11 and the upper wall portion 12, even when the flying object flies toward the protection target due to gusts or strong winds when the tornado or the like occurs, this flying object is The collision with the side wall portion 11 and the upper wall portion 12 can prevent the collision with the condensate tank T. Further, by providing a hydraulic damper (damper mechanism) 97 between the side wall portion 11 and the adjacent structure 91, the hydraulic damper 97 can be made horizontal to the side wall portion 11 or the upper wall portion 12 when an earthquake or the like occurs. The acting vibration can be reduced. As a result, the condensate tank T can be suitably protected, and sufficient earthquake resistance can be secured.

  Further, by disposing the vibration reduction mechanism 92 between the side wall portion 11 and the adjacent structure 91, the vibration of the side wall portion 11 or the upper wall portion 12 can be properly reduced and attenuated, and the vibration reduction is also possible. The mounting of the mechanism 92 can be facilitated to reduce the operation cost.

Third Embodiment
FIG. 13 is a front view showing the airborne object protection facility of the third embodiment.

  In the third embodiment, as shown in FIG. 13, the airborne object protection facility 100 protects a condensate tank (not shown) installed on the ground G from the outside. The airborne object protection facility 100 includes a side wall portion 101, an upper wall portion 102, a vibration reduction mechanism 103, and a reinforcing portion 104.

  The ground G is provided with a recess 111 around the condensate tank, and the recess 111 is provided with a base plate 112 inside. A plurality of vibration reduction mechanisms 103 are provided on the base plate 112 at predetermined intervals along the longitudinal direction, and the support members 113 are respectively installed on the upper portions thereof. The side wall portion 101 is a frame structure, and is installed and fixed on each support member 113. The upper wall portion 102 is fixed to the upper portion of the side wall portion 101 with a predetermined gap from the upper surface of the condensate tank so as to cover the upper side of the condensate tank.

  The flying object protection facility 100 has a polyhedral shape in its upper portion by the side wall portion 101 and the upper wall portion 102, and the inclined reinforcing portion 104 is integrally connected to the corner portion of the upper wall portion 102. In this case, in the side wall portion 101 and the upper wall portion 102, a protection net is fixed to the front as in the first embodiment. On the other hand, the reinforcing portion 104 is configured to be reinforced by a protective net or downhill.

  As described above, in the airborne object protection facility of the third embodiment, the side wall portion 101 and the upper wall portion 102 covering the condensate tank are provided, and the reinforcing portion 104 is provided between the side wall portion 101 and the upper wall portion 102. Also, the vibration reduction mechanism 103 is provided at the lower part of the side wall portion 101.

  Therefore, since the outer side of the condensate tank is covered with the side wall portion 101 and the upper wall portion 102, even if the flying object flies toward the protection target due to gusts or strong winds when the tornado or the like occurs, the flying object is the side wall The collision with the portion 101 and the upper wall portion 102 can prevent the collision with the condensate tank. At this time, since the reinforcing portion 104 is provided between the side wall portion 101 and the upper wall portion 102, the rigidity of the side wall portion 101 and the upper wall portion 102 can be enhanced. Further, by providing the vibration reduction mechanism 103 in the lower part of the side wall portion 101, it is possible to reduce the vibration acting horizontally on the side wall portion 101 and the upper wall portion 102 by the vibration reduction mechanism 103 when an earthquake or the like occurs. it can. As a result, the condensate tank can be suitably protected, and sufficient earthquake resistance can be secured.

  In the embodiment described above, the exterior shape of the flying object protection facility is a cube, but it may be a rectangular parallelepiped, a polyhedron, a hemisphere, or the like.

  Moreover, in the embodiment mentioned above, although the protection object was made into the condensate tank T, it is not limited to this, For example, another water storage tank, cooling installation, piping etc. may be sufficient.

10, 90, 100 Airborne object protection equipment 11, 101 Side wall 12, 102 Upper wall 13, 13B, 96, 103 Vibration reduction mechanism 22, 93, 111 Recess 23, 94, 112 Base version 24, 95, 113 Support member 33, 48 protection net 41 first upper wall 42 second upper wall 51 covering unit 61, 71 seismic isolation mechanism 62, 73 seismic isolation structure 72 damper mechanism 74, 97 hydraulic damper 80 entrance opening 81 closing member 85, 86 Clearance 87 Maintenance passage 91 Adjacent structure 104 Reinforcement section T Condenser tank (protected object)

Claims (8)

An airborne object protection facility that protects a protected object installed on the ground from the outside,
A side wall portion erected on the ground with a predetermined gap from the protection object so as to cover the periphery of the protection object;
An upper wall connected to an upper portion of the side wall so as to cover the upper side of the object to be protected;
A vibration reduction mechanism for reducing horizontal vibration in the side wall portion;
Bei to give a,
A protective net is fixed to the frame structure on the side wall portion and the upper wall portion,
The upper wall portion has a first upper wall portion disposed on the upper stage side, and a second upper wall portion disposed on the lower stage side, and the protective net is fixed to the second upper wall portion.
An airborne object protection facility characterized by An airborne object protection facility that protects a protected object installed on the ground from the outside,
A side wall portion erected on the ground with a predetermined gap from the protection object so as to cover the periphery of the protection object;
An upper wall connected to an upper portion of the side wall so as to cover the upper side of the object to be protected;
A vibration reduction mechanism for reducing horizontal vibration in the side wall portion;
Bei to give a,
The side wall portion is provided with an inlet / outlet opening, and has a larger area than the inlet / outlet opening, and a closing member is erected opposite the inside or outside of the inlet / outlet opening with a predetermined gap.
An airborne object protection facility characterized by The said vibration reduction mechanism has a seismic isolation mechanism, The airborne object protection installation of Claim 1 or Claim 2 characterized by the above-mentioned. A recess is provided in the ground around the object to be protected, a base plate is provided in the recess, and a support member for the side wall portion is installed on the base plate via the seismic isolation mechanism. An airborne object protection facility according to claim 3 . The said vibration reduction mechanism has a damper mechanism, and is arrange | positioned in parallel with the seismic isolation mechanism between the said support member and the said base version, The airborne object protection installation of Claim 4 characterized by the above-mentioned. The said damper mechanism is arrange | positioned along a horizontal direction, The airborne object protection installation of Claim 5 characterized by the above-mentioned. The height of the upper surface of the said support member and the height of the said ground are set to the same height, The airborne object protection installation as described in any one of the Claims 4-6 characterized by the above-mentioned. The vibration reduction mechanism includes a damper mechanism, the damper mechanism is any of claims 1 to 7, characterized in that arranged between the structures adjacent to the side wall and the side wall portion The airborne object protection facility according to claim 1 or 2.

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