A power plant anti-terrorism prevention device and system
The power plant anti-terrorism and control device, composed of conical fixing blocks and support rods, combined with a TCP/IP communication system, solves the problems of long installation time and failure to locate intrusions in a timely manner, achieving rapid installation and strong anti-terrorism protection, and improving the security of the power plant.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- HUANENG LANCANG RIVER HYDROPOWER CO LTD
- Filing Date
- 2023-11-30
- Publication Date
- 2026-06-09
AI Technical Summary
The existing power plant fences are time-consuming to install and dismantle, and cannot be located in time during illegal intrusions, lacking conspicuous anti-terrorism protection measures.
The power plant anti-terrorism and control device, composed of a conical fixing block, drive shaft, support rod and metal wire, combined with a TCP/IP communication anti-terrorism protection system, including an alarm module and control center, enables rapid installation, location of intrusion, and deterrence and anti-terrorism protection.
It simplifies the installation process, improves installation efficiency, enables timely location of intrusions and provides a strong deterrent, thereby enhancing power plant security.
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Figure CN117967124B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of counter-terrorism protection technology, and in particular to a counter-terrorism prevention and control device and system for power plants. Background Technology
[0002] As a specialized workplace, power plants contain numerous and valuable pieces of specialized equipment. To enhance security and prevent unauthorized intrusion, entry is prohibited for non-technical personnel and unauthorized individuals. Current technology often involves constructing a closed perimeter wall around the power plant and installing electronic security fencing to isolate the plant from the outside world.
[0003] In existing technologies, electronic fences are mostly fixed to the wall using screws and rivets. However, disassembling or installing them requires specific tools or skills, thus taking considerable time and effort. Furthermore, drilling holes or riveting is necessary when installing screws and rivets, which can damage the wall surface. Replacing or repairing the electronic fence may require repairing or replacing parts of the wall or performing other maintenance work. Additionally, the security measures of electronic fences are insufficient to promptly and effectively highlight and locate the intrusion site in the event of unauthorized intrusion, and lack conspicuous and compelling measures to alert security personnel to take counter-terrorism precautions. Therefore, we propose a power plant counter-terrorism control device and system to address these problems. Summary of the Invention
[0004] In view of the problems existing in the prior art, the present invention is proposed.
[0005] Therefore, the purpose of this invention is to provide a power plant anti-terrorism and control device and system, the purpose of which is to provide a simple and reliable fixing measure for installation and disassembly, as well as an anti-terrorism protection measure that can deter and counter-terrorism and can promptly and conspicuously locate the intrusion location in the event of illegal intrusion.
[0006] To solve the above-mentioned technical problems, the present invention provides the following technical solution: a power plant anti-terrorism and control device, comprising: an installation unit including a fixing component located on a wall and a driving component disposed above the fixing component; a support unit including a connecting rod located above the driving component, a support assembly disposed above the connecting rod, and multiple sets of series components evenly distributed on the support assembly; a fixing unit including an adjusting component located inside the fixing component, a first adjusting assembly and a second adjusting assembly alternately distributed around the outside of the adjusting component, a sleeve component located on the support assembly, and a reinforcing assembly disposed between the sleeve component and the first adjusting assembly; and a metal wire connected in series between the support units.
[0007] As a preferred embodiment of the power plant anti-terrorism and control device of the present invention, the fixing component includes a fixing block with a conical structure, a fixing frame disposed below the fixing block, and a connecting cylinder disposed above the fixing block.
[0008] As a preferred embodiment of the power plant anti-terrorism and control device of the present invention, the driving component includes a driving shaft located inside the connecting cylinder, a connecting shaft disposed above the driving shaft, and an auxiliary rod disposed on the side of the driving shaft.
[0009] As a preferred embodiment of the power plant anti-terrorism and control device of the present invention, the support component includes a support rod located at the top of the connecting rod, multiple sets of slots formed on the support rod, and a fixing groove also formed on the support rod and located below the slots.
[0010] As a preferred embodiment of the power plant anti-terrorism and control device of the present invention, the series component includes an installation component located in the slot, and a fixing bolt disposed below the installation component and extending into the fixing slot.
[0011] As a preferred embodiment of the power plant anti-terrorism and control device of the present invention, the adjusting component includes an adjusting plate located between the fixing block and the fixing frame, a hexagonal shaft disposed above the adjusting plate, and a limiting block disposed at the top of the hexagonal shaft.
[0012] To solve the above-mentioned technical problems, the present invention also includes: a power plant anti-terrorism protection system, comprising a switching module, an alarm module, a warning module, and a control center, wherein the switching module, the alarm module, and the control center communicate bidirectionally via TCP / IP.
[0013] As a preferred embodiment of the power plant anti-terrorism protection system of the present invention, the alarm module includes sound, light and vibration modes to provide early warning from three aspects: hearing, vision and touch. The alarm module is fixedly installed on the top of the support unit.
[0014] As a preferred embodiment of the power plant anti-terrorism protection system of the present invention, the switching module includes a pulse host and an alarm host, the pulse host is directly connected to a metal wire, and the alarm host is connected to an alarm module.
[0015] As a preferred embodiment of the power plant anti-terrorism protection system of the present invention, the control center includes an electronic map and a monitoring unit, and the control center directly controls the transfer module.
[0016] The beneficial effects of this invention are: it enables quick and rapid installation and positioning, saves installation and setup time, improves work efficiency, and has strong stability, ensuring the stability of the device after it is set up. Through isolation, it can effectively prevent unauthorized entry and illegal intrusion, improve the security of the surrounding environment, and can promptly stop and clearly display the intrusion location in the event of illegal intrusion, making it convenient for security personnel to carry out security protection work in a timely manner. Attached Figure Description
[0017] To more clearly illustrate the technical solutions of the embodiments of the present invention, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort. Wherein:
[0018] Figure 1 This is a schematic diagram of the overall structure of a power plant anti-terrorism and control device and system according to the present invention.
[0019] Figure 2 This is a schematic diagram of the installation unit structure of a power plant anti-terrorism and prevention device according to the present invention.
[0020] Figure 3 This is a schematic diagram of the fixed component structure of a power plant anti-terrorism and control device according to the present invention.
[0021] Figure 4 This is a schematic diagram of the fixed component of a power plant anti-terrorism and control device from an upward perspective, according to the present invention.
[0022] Figure 5 This is a schematic diagram of the support unit structure of a power plant anti-terrorism and control device according to the present invention.
[0023] Figure 6 This is a schematic diagram of the overall internal structure of a power plant anti-terrorism and control device according to the present invention.
[0024] Figure 7 This is a schematic diagram of the fixed unit structure of a power plant anti-terrorism and control device according to the present invention.
[0025] Figure 8 This is a schematic diagram of the fixed unit structure of a power plant anti-terrorism and control device from an upward angle, according to the present invention.
[0026] Figure 9 This is a schematic diagram of the structure of the first and second adjustment components of a power plant anti-terrorism and control device according to the present invention.
[0027] Figure 10 This is a schematic diagram of the process of a power plant anti-terrorism protection system according to the present invention. Detailed Implementation
[0028] To make the above-mentioned objects, features and advantages of the present invention more apparent and understandable, the specific embodiments of the present invention will be described in detail below with reference to the accompanying drawings.
[0029] Many specific details are set forth in the following description in order to provide a full understanding of the invention. However, the invention may also be practiced in other ways different from those described herein, and those skilled in the art can make similar extensions without departing from the spirit of the invention. Therefore, the invention is not limited to the specific embodiments disclosed below.
[0030] Secondly, the term "one embodiment" or "embodiment" as used herein refers to a specific feature, structure, or characteristic that may be included in at least one implementation of the present invention. The phrase "in one embodiment" appearing in different places in this specification does not necessarily refer to the same embodiment, nor is it a single or selective embodiment that is mutually exclusive with other embodiments.
[0031] Secondly, the present invention is described in detail with reference to the schematic diagrams. When detailing the embodiments of the present invention, for ease of explanation, the cross-sectional views illustrating the device structure may be partially enlarged, not according to the usual scale. Furthermore, the schematic diagrams are merely examples and should not limit the scope of protection of the present invention. In addition, actual fabrication should include three-dimensional spatial dimensions of length, width, and depth.
[0032] Example 1
[0033] Reference Figures 1-6 The first embodiment of the present invention provides a power plant anti-terrorism and control device, including an installation unit 100, including a fixing component 101 located on the wall and a driving component 102 disposed above the fixing component 101. The fixing component 101 has a conical structure and is fixed on the wall. The driving component 102 is vertically threaded to the center position of the fixing component 101.
[0034] The support unit 200 includes a connecting rod 201 located above the driving component 102, a support assembly 202 disposed above the connecting rod 201, and multiple sets of series components 203 evenly distributed on the support assembly 202. The connecting rod 201 is rotatably connected to the top end of the driving component 102, the support assembly 202 is fixedly connected above the connecting rod 201, and the series components 203 are inserted into the support assembly 202.
[0035] The fixing unit 300 includes an adjusting component 301 located inside the fixing component 101, a first adjusting assembly 302 and a second adjusting assembly 303 alternately distributed around the outside of the adjusting component 301, a sleeve component 304 located on the support component 202, and a reinforcing assembly 305 disposed between the sleeve component 304 and the first adjusting assembly 302. The adjusting component 301 is rotatably connected to the fixing component 101. There are four sets of first adjusting assemblies 302 and second adjusting assemblies 303 in total. The body is divided into two sets of first adjustment components 302 and two sets of second adjustment components 303. The two sets of first adjustment components 302 are located on both sides of the wall and are used for clamping and fixing. Both the first adjustment components 302 and the second adjustment components 303 are slidably connected around the fixing component 101. The sleeve component 304 is slidably sleeved on the connecting rod 201. The reinforcing component 305 is not only connected between the first adjustment component 302 and the sleeve component 304, but also between the second adjustment component 303 and the sleeve component 304.
[0036] The metal wire 400 is connected in series between the support units 200. The device as a whole includes multiple sets of support units 200, and the metal wire 400 is connected in series and fixed between multiple sets of support units 200 to form a mesh-like isolation strip. The metal wire 400 as a whole carries a high voltage pulse, which can play the role of protection, isolation and electric shock repulsion.
[0037] During use, the installation unit 100 is erected on the wall. The rotating drive component 102 drives the adjusting component 301 to rotate. The rotating adjusting component 301 pushes the first adjusting assembly 302 and the second adjusting assembly 303 connected below to move and adjust accordingly. Rotating the adjusting component 301 forward expands the first adjusting assembly 302 and the second adjusting assembly 303 outward, thus adjusting the fixing range according to the wall size. Rotating the adjusting component 301 in the reverse direction moves the first adjusting assembly 302 inward, ultimately clamping and fixing the entire device to the wall. This clamping fixing method avoids damage to the wall that can occur with traditional fixing devices. While overcoming the disadvantages of other methods, the installation and fixing method is simple and quick, and it is also more time-saving and labor-saving when disassembling and adjusting. At the same time, the moving first adjustment component 302 and second adjustment component 303 will drive the reinforcing component 305 to move synchronously. Finally, the reinforcing component 305, the first adjustment component 302 and the second adjustment component 303 cooperate with each other to form a support frame structure, thereby ensuring and improving the stability of the device. Repeat the above operation to install multiple sets of devices on the wall. Then, the metal wires 400 are connected and fixed between multiple sets of support units 200 through the series component 203 to form a protective isolation belt. On the basis of the wall, the protection height is further increased and the safety protection effect is improved.
[0038] Example 2
[0039] Reference Figures 6-9 This is the second embodiment of the present invention, which differs from the first embodiment in that it provides an effective measure to fix the metal wire 400 and avoid the occurrence of extra work.
[0040] Compared to Embodiment 1, the fixing component 101 further includes a conical fixing block 101a, a fixing frame 101b disposed below the fixing block 101a, and a connecting cylinder 101c disposed above the fixing block 101a. The fixing block 101a has a conical structure, the fixing frame 101b is fixedly connected to the lower part of the fixing block 101a and distributed in a cross shape, the connecting cylinder 101c is fixedly connected to the center position of the fixing block 101a, and the driving component 102 is threadedly connected to the connecting cylinder 101c.
[0041] Furthermore, the fixed block 101a has four sets of limiting grooves 101a-1 for limiting, and the first adjusting component 302 and the second adjusting component 303 are slidably limited connected in the limiting grooves 101a-1. The connecting cylinder 101c has a threaded groove 101c-1, and the driving component 102 is threadedly connected in the threaded groove 101c-1.
[0042] The driving component 102 includes a driving shaft 102a located inside the connecting cylinder 101c, a connecting shaft 102b disposed above the driving shaft 102a, and an auxiliary rod 102c disposed on the side of the driving shaft 102a. The driving shaft 102a is threadedly connected to the connecting cylinder 101c. When the driving shaft 102a rotates, it can extend and retract vertically within the connecting cylinder 101c through the engagement of the threads. The connecting shaft 102b is fixedly connected to the top end of the driving shaft 102a and extends into the connecting rod 201. The auxiliary rod 102c is rotatably connected to the side of the driving shaft 102a and can only rotate within a 90-degree range on the side of the driving shaft 102a. The folded-out auxiliary rod 102c can provide an external force point when rotating the driving component 102, thereby facilitating the overall rotation of the driving component 102.
[0043] Furthermore, a storage groove 102a-1 is provided on the side of the drive shaft 102a, and the auxiliary rod 102c is rotated and stored in the storage groove 102a-1. An auxiliary groove 102a-2 is provided on the upper half of the drive shaft 102a. The auxiliary groove 102a-2 can provide an additional way to rotate the drive shaft 102a. A rectangular wrench can be inserted into it to assist in the rotation operation. A movable groove 102a-3 is provided inside the drive shaft 102a. The upper half of the adjusting component 301 extends into the movable groove 102a-3. A sliding groove 102a-4 is provided below the movable groove 102a-3. The edge of the sliding groove 102a-4 is rectangular. A limiter 102b-2 is provided at the top of the connecting shaft 102b.
[0044] The support assembly 202 includes a support rod 202a located at the top of the connecting rod 201, multiple sets of slots 202b formed on the support rod 202a, and a fixing slot 202c formed on the support rod 202a and located below the slots 202b. The support rod 202a is fixedly connected to the top of the connecting rod 201. The slots 202b are used to accommodate the serial components 203 and have a semi-circular opening. The fixing slot 202c is used to fix the serial components 203.
[0045] The series component 203 includes a mounting component 203a located in the slot 202b and a fixing bolt 203b disposed below the mounting component 203a and extending into the fixing groove 202c. The mounting component 203a is housed in the support rod 202a, and the fixing bolt 203b is threadedly connected to the fixing groove 202c. The outer end of the mounting component 203a is limited and connected to the fixing bolt 203b, and moves accordingly with the movement of the fixing bolt 203b.
[0046] Furthermore, the mounting assembly 203a includes a semi-circular fixing plate 203a-1, a wiring groove 203a-2 formed on the fixing plate 203a-1, and a connecting ear 203a-3 disposed at the outer end of the fixing plate 203a-1. The wiring groove 203a-2 is used for the metal wire 400 to pass through it, and the connecting ear 203a-3 is sleeved on the fixing bolt 203b and is limited by the fixing bolt 203b.
[0047] During use, rotating the fixing bolt 203b causes it to connect with the support rod 202a via a thread. This pulls the fixing plate 203a-1 out of the slot 202b through the connecting lug 203a-3. The pulled-out mounting assembly 203a is limited by the slot 202b and moves in a parallel manner. Then, the metal wire 400 to be fixed is placed into the wiring trough 203a-2. Rotating the fixing bolt 203b in the opposite direction causes it to move the mounting assembly 203a-1 with the metal wire 400 installed. 03a returns to the slot 202b. The mounting component 203a, which is completely overlapped in the slot 202b, will fix and limit the metal wire 400 on the support component 202. By integrating the serial component 203 with the support component 202, it is convenient for installers to simply insert the metal wire 400 into the corresponding serial component 203 and then fix it when installing the electronic fence. This simplifies the installation steps and avoids the workload of installing additional fixing measures after the support unit 200 is installed, thus improving installation efficiency.
[0048] Example 3
[0049] Reference Figure 1 This is the third embodiment of the present invention. The difference between this embodiment and the first embodiment is that the entire installation device is assembled by clamping, which improves the assembly efficiency and increases the stability of the device after installation.
[0050] The adjusting component 301 includes an adjusting disk 301a located between the fixing block 101a and the fixing frame 101b, a hexagonal shaft 301b disposed above the adjusting disk 301a, and a limiting block 301c disposed at the top of the hexagonal shaft 301b. The adjusting disk 301a is rotatably connected to the fixing component 101. The hexagonal shaft 301b above the fixing component 101 passes through the connecting cylinder 101c and extends to the sliding groove 102a-4. Its outer edge is connected to the sliding groove 102a-4. The matching ensures that the adjusting component 301 and the driving component 102 are mutually limited in the horizontal direction, preventing either one from rotating in a single circular motion. Both can rotate simultaneously, but they can slide relative to each other in a vertical direction. That is, the hexagonal shaft 301b can move telescopically within the sliding groove 102a-4, and the limiting block 301c also extends into the driving shaft 102a. The adjusting component 301 is limited below the driving component 102 by the limiting block 301c, preventing accidental detachment.
[0051] Furthermore, four sets of first adjustment grooves 301a-1 are provided on the adjustment disk 301a. Below the first adjustment grooves 301a-1, there are second adjustment grooves 301a-2 with the same curvature but slightly larger size. The inner ends of the first adjustment component 302 and the second adjustment component 303 extend into the first adjustment grooves 301a-1. One end of the first adjustment groove 301a-1 is close to the center of the adjustment disk 301a, and the other end is close to the edge of the adjustment disk 301a.
[0052] Furthermore, the first adjusting component 302 includes a first sliding block 302a located within the limiting groove 101a-1, a first reinforcing block 302b disposed below the outer end of the first sliding block 302a, a first rotating shaft 302c disposed above the outer end of the first sliding block 302a, and a first limiting component 302d disposed at the inner end of the first sliding block 302a. The first sliding block 302a is slidably connected within the limiting groove 101a-1 and is limited by the limiting groove 101a-1, only able to move within the limiting groove 101a-1. The sliding component 302b slides in the opening direction of the first sliding block 302a but cannot rotate in a circle. The first reinforcing block 302b is vertically positioned below the outer end of the first sliding block 302a. The first rotating shaft 302c is located above the first reinforcing block 302b. The bottom end of the reinforcing component 305 is rotatably connected to the first rotating shaft 302c. The first limiting component 302d extends into the first adjusting groove 301a-1 and is limited by the first adjusting groove 301a-1, so it can only slide within the arc range of the first adjusting groove 301a-1.
[0053] Furthermore, the first limiting component 302d includes a limiting rod 302d-1 extending into the first adjusting groove 301a-1, and a second limiting piece 302d-2 located at the end of the limiting rod 302d-1 and extending into the second adjusting groove 301a-2. The second limiting piece 302d-2 is used to limit the first limiting component 302d to prevent the first limiting component 302d from accidentally sliding out of the first adjusting groove 301a-1. The second adjusting groove 301a-2 provides space for the second limiting piece 302d-2 to slide.
[0054] Furthermore, the second adjustment component 303 includes a second sliding block 303a located within the limiting groove 101a-1, a second reinforcing block 303b disposed below the outer end of the second sliding block 303a, a second rotating shaft 303c disposed above the outer end of the second sliding block 303a, and a second limiting component 303d disposed within the inner end of the second sliding block 303a. The overall structure of the second adjustment component 303 is the same as that of the first adjustment component 302. The two are symmetrically distributed and connected to the fixed block 101a, respectively, within the symmetrically positioned limiting groove 101a-1. Here, the first adjustment component 302 is located within the fixed block 101a. The directions on block 101a are named front and back sides. The directions of the second adjustment component 303 on the fixed block 101a are left and right sides. Both the first adjustment component 302 and the second adjustment component 303 are snapped onto the outside of the fixed component 101. The difference is that the length of the first limiting component 302d extending downward is greater than that of the second limiting component 303d. The lower part of the first limiting component 302d extends to the outside of the bottom surface of the fixed component 101 to clamp the walls on both sides below the fixed component 101. The lower part of the second limiting component 303d is flush with the bottom surface of the fixed component 101, which is to support the stability of the device on the top surface of the wall.
[0055] During use, rotating the drive component 102 causes the adjustment component 301 to rotate via the hexagonal shaft 301b. The adjustment disc 301a rotates synchronously at this time. During this rotation, the position of the first adjustment groove 301a-1 changes. The first limiting component 302d, located within the first adjustment groove 301a-1, moves synchronously with it. However, the first adjustment component 302 is limited by the limiting groove 101a-1 and cannot rotate with it. Nevertheless, the force exerted by the first adjustment groove 301a-1 on the first limiting component 302d does not disappear. Therefore, when the position of the first adjustment groove 301a-1 changes, this displacement force is converted into a force that pushes the first limiting component 302d along its curved edge, causing the first adjustment component 302 to move along the limiting groove. The sliding thrust of the slot 101a-1 enables the first adjusting component 302 to expand outward or clamp inward. Similarly, the second adjusting component 303 moves on the left and right sides of the fixing block 101a in the same way. By clamping the device, the problem of damaging the wall surface caused by drilling holes or riveting in the wall in the traditional technology can be avoided. At the same time, the installation, fixing and disassembly of the device can be completed by simply adjusting the direction of rotation of the driving component 102, which greatly improves the work efficiency of device construction and disassembly, and makes it easier to carry out subsequent maintenance work. Furthermore, by adjusting the number of rotations of the driving component 102, the clamping and fixing range of the device can be adjusted according to the size of the wall, which can further enhance the application range of the device and greatly improve the flexibility of the device.
[0056] Furthermore, the sleeve component 304 includes a collar 304a sleeved on the connecting rod 201, and multiple sets of fixing ears 304b disposed on the outside of the collar 304a. The collar 304a is slidably sleeved on the connecting rod 201, the fixing ears 304b are fixedly connected to the outside of the collar 304a, and the top end of the reinforcing component 305 is rotatably connected to the fixing ears 304b.
[0057] Furthermore, the reinforcing component 305 includes a reinforcing rod 305a located between the first adjusting component 302 and the sleeve component 304, a first connecting block 305b disposed at the end of the reinforcing rod 305a, and a second connecting block 305c disposed at the top of the reinforcing rod 305a. The first connecting block 305b is rotatably connected to the first rotating shaft 302c, and the second connecting block 305c is rotatably connected to the fixing ear 304b.
[0058] During use, the top of the reinforcing component 305 is connected to the fixing ear 304b, while the bottom is connected to the first rotating shaft 302c and the second rotating shaft 303c. The fixing ear 304b is closer to the support unit 200 than the first rotating shaft 302c and the second rotating shaft 303c. Therefore, the reinforcing component 305 is set at an inclined angle between the sleeve part 304 and the first adjusting component 302 and the second adjusting component 303. The four sets of reinforcing components 305 are set in the same way, forming an upwardly converging support frame structure. When the first adjusting component 302 and the second adjusting component 303 are fixed... When component 101 moves around, the first adjusting component 302 moves to the front and rear sides of the device, and the second adjusting component 303 moves to the left and right sides of the wall. Both of them will simultaneously drive the reinforcing component 305 to move, thereby simultaneously adjusting the support angle of the reinforcing component 305. This allows the four sets of reinforcing components 305 to provide auxiliary support from the four sides of the device, dispersing the pressure and load under the support unit 200. This helps to reduce stress concentration near the support rod, provides additional support for the area under the device, reduces the risk of collapse or collapse, and thus improves the safety of the entire device.
[0059] The remaining structure is the same as that in Example 2.
[0060] Example 4
[0061] Reference Figure 1 and Figure 10The fourth embodiment of the present invention provides a power plant anti-terrorism protection system, including a transfer module 500, an alarm module 600, a warning module 700, and a control center. The transfer module 500, the alarm module 600, and the control center communicate bidirectionally via TCP / IP. The control center can control the start, stop, and close of all devices. The control center is generally located in the main security control room, where on-duty personnel observe and monitor.
[0062] Furthermore, the warning module 700 is a bright yellow warning sign with the warning slogan "High Voltage Danger, Do Not Climb". One warning module 700 is installed at every other end of the metal wire 400 to warn potential intruders, instill fear in them, and deter them from intrusion. The warning module 700 also has a night light function, which also serves as a warning and deterrent, further enhancing the anti-terrorism protection effect.
[0063] The alarm module 600 includes sound, light, and vibration alarms, providing early warning from three aspects: hearing, vision, and touch. The alarm module 600 is fixedly installed on the top of the support unit 200. By emitting sound and light alarms, the alarm module 600 can help security personnel determine the location of the intrusion, thereby enabling them to carry out counter-terrorism protection work more quickly.
[0064] The adapter module 500 includes a pulse host and an alarm host. The pulse host is directly connected to the metal wire 400, and the alarm host is connected to the alarm module 600. The pulse host sends current pulses to the metal wire 400 to provide an electric shock warning. The alarm host sends alarm information to activate the alarm module 600, which provides an alarm through auditory and visual means.
[0065] Furthermore, the adapter module 500 and the metal wire 400 are interconnected. When an unauthorized intruder performs improper operations on the metal wire 400, a pulse electric shock will be triggered, and an alarm will be triggered simultaneously. Improper operations include: 1. When an animal or human directly touches or touches any of the metal wires 400 through a metal conductor, the animal or human will be shocked by a pulse electric shock, creating a sense of intimidation, and the system alarm will be triggered at the same time; 2. When the metal wire 400 is short-circuited horizontally or vertically, an alarm will be triggered immediately, and an alarm sound will be provided; 3. Touching any of the metal wires 400 will result in a pulse electric shock, and touching two metal wires 400 at the same time will result in an electric shock, making the prevention very tight. An alarm will be triggered if an intruder attempts to cut the metal wire 400 to force entry. In other words, the pulse voltage running on the metal wire 400 is between 5000V and 10000V, and the alarm voltage values are 3000V and 10000V. When external disturbances or damage cause voltage leakage in the fence, if the leakage drops below 3000V or the voltage rises above 10000V, an alarm will be triggered.
[0066] During use, the power plant's anti-terrorism and control device is installed on the original wall, increasing the height of the original wall, making it more difficult to climb over, and providing initial blocking and protection. At the same time, the high-voltage pulse transmitted by the adapter module 500 on the metal wire 400 can provide a safe electric shock to the climber. This voltage is safe and reliable and does not directly harm the human body, forcing the climber to abandon the idea of intrusion, thus achieving a protective effect. Combined with the audible and visual alarm of the alarm module 600, it can effectively play a role in anti-terrorism protection.
[0067] The control center includes an electronic map and a monitoring unit. The control center directly controls the transfer module 500. When an intrusion occurs, the control center can use the monitoring unit and the electronic map to visually locate and mark the illegal intrusion information and location, making it convenient for security personnel to quickly carry out counter-terrorism and protection work.
[0068] During use, when someone illegally climbs over or damages the power plant's anti-terrorism and security devices, the transfer module 500 will be triggered. Its internal pulse host will emit a pulse current to shock and warn the unauthorized personnel, and simultaneously transmit the alarm information to the control center. After receiving the signal, the control center will send the alarm information to the alarm host. The alarm host will control the alarm module 600 to activate the audible and visual alarm, and simultaneously display the monitoring screen of the intrusion area. The screen will also reflect the location of the alarm on the electronic map. At this time, the on-duty personnel at the center will notify the security personnel on patrol to rush to the scene immediately to handle the situation, thereby quickly carrying out anti-terrorism and security work. After the security personnel have finished handling the situation on the scene, they can restore the alarm status of the control center and the pulse host.
[0069] The remaining structure is the same as that in Example 3.
[0070] It is important to note that the constructions and arrangements of this application shown in several different exemplary embodiments are merely illustrative. Although only a few embodiments are described in detail in this disclosure, those who consult this disclosure will readily understand that many modifications are possible (e.g., changes in the size, dimensions, structure, shape, and proportions of various elements, as well as parameter values (e.g., temperature, pressure, etc.), mounting arrangements, use of materials, color, orientation, etc.) without substantially departing from the novel teachings and advantages of the subject matter described in this application). For example, an element shown as integrally formed may be composed of multiple parts or elements, the position of elements may be inverted or otherwise altered, and the nature or number or position of discrete elements may be changed or altered. Therefore, all such modifications are intended to be included within the scope of the invention. The order or sequence of any process or method steps may be changed or rearranged according to alternative embodiments. In the claims, any "device plus function" clause is intended to cover the structure described herein that performs the function, and not only structurally equivalent but also equivalent in structure. Other substitutions, modifications, alterations, and omissions may be made in the design, operation, and arrangement of the exemplary embodiments without departing from the scope of the invention. Therefore, the present invention is not limited to the specific embodiments, but extends to various modifications that still fall within the scope of the appended claims.
[0071] Furthermore, in order to provide a concise description of exemplary embodiments, not all features of actual embodiments (i.e., those features that are not relevant to the currently considered best mode for carrying out the invention, or those features that are not relevant to implementing the invention) may be omitted.
[0072] It should be noted that the above embodiments are only used to illustrate the technical solutions of the present invention and are not intended to limit it. Although the present invention has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and all such modifications or substitutions should be covered within the scope of the claims of the present invention.
Claims
1. A power plant anti-terrorism and control device, characterized in that: include, The installation unit (100) includes a fixing component (101) located on the wall and a driving component (102) disposed above the fixing component (101). The support unit (200) includes a connecting rod (201) located above the drive component (102), a support assembly (202) disposed above the connecting rod (201), and multiple sets of serial components (203) evenly distributed on the support assembly (202). The fixing unit (300) includes an adjusting component (301) located inside the fixing component (101), a first adjusting assembly (302) and a second adjusting assembly (303) alternately distributed around the outside of the adjusting component (301), a sleeve component (304) located on the support assembly (202), and a reinforcing assembly (305) disposed between the sleeve component (304) and the first adjusting assembly (302); and a metal wire (400) connected in series between the support units (200); The fixing component (101) includes a tapered fixing block (101a), a fixing frame (101b) disposed below the fixing block (101a), and a connecting cylinder (101c) disposed above the fixing block (101a); the fixing block (101a) is provided with four sets of limiting grooves (101a-1) for limiting, the first adjusting component (302) and the second adjusting component (303) are both slidably limited and connected in the limiting grooves (101a-1), the connecting cylinder (101c) is provided with a threaded groove (101c-1), and the driving component (102) is threadedly connected in the threaded groove (101c-1); The adjusting component (301) includes an adjusting plate (301a) located between the fixing block (101a) and the fixing frame (101b), a hexagonal shaft (301b) disposed above the adjusting plate (301a), and a limiting block (301c) disposed at the top of the hexagonal shaft (301b). The adjustment plate (301a) has four sets of first adjustment slots (301a-1), and a second adjustment slot (301a-2) with the same curvature but slightly larger size is provided below the first adjustment slots (301a-1).
2. The power plant anti-terrorism and control device according to claim 1, characterized in that: The drive component (102) includes a drive shaft (102a) located inside the connecting cylinder (101c), a connecting shaft (102b) disposed above the drive shaft (102a), and an auxiliary rod (102c) disposed on the side of the drive shaft (102a).
3. The power plant anti-terrorism and control device according to claim 2, characterized in that: The support assembly (202) includes a support rod (202a) located at the top of the connecting rod (201), multiple sets of slots (202b) formed on the support rod (202a), and a fixing slot (202c) also formed on the support rod (202a) and located below the slots (202b).
4. The power plant anti-terrorism and control device according to claim 3, characterized in that: The tandem component (203) includes a mounting assembly (203a) located within the slot (202b) and a fixing bolt (203b) disposed below the mounting assembly (203a) and extending into the fixing slot (202c).
5. A power plant anti-terrorism protection system comprising the control device described in any one of claims 1 to 4, characterized in that: It also includes a switching module (500), an alarm module (600), a warning module (700), and a control center. The switching module (500), the alarm module (600), and the control center communicate bidirectionally via TCP / IP.
6. The power plant anti-terrorism protection system according to claim 5, characterized in that: The alarm module (600) includes sound, light and vibration forms, and provides early warning from three aspects: hearing, vision and touch. The alarm module (600) is fixedly installed on the top of the support unit (200).
7. The power plant anti-terrorism protection system according to claim 6, characterized in that: The adapter module (500) includes a pulse host and an alarm host. The pulse host is directly connected to a metal wire (400), and the alarm host is connected to an alarm module (600).
8. The power plant anti-terrorism protection system according to claim 7, characterized in that: The control center includes an electronic map and a monitoring unit, and the control center directly controls the transfer module (500).