Supply ZMSPC5 intelligent fire emergency lighting and evacuation system

Child wooden intelligent emergency lighting and evacuation lighting system design features of a fixed fire emergency lighting to solve the traditional problems of 1.1 evacuation direction, easy to fire workers introduced; 1.2 voltage of 220V, fire extinguishing water overflowing easy to hurt firefighters; 1.3 evacuation signs light translucent smoke in a bad state; no maintenance prompts evacuation signs lamp failure 1.4; 1.5 systems are not energy efficient. 1.6 Material fire resistance and no linkage. Advantage 2 sub-wood intelligent fire emergency lighting and evacuation systems anywhere in the building for 2.1 have evacuation plans, based on adaptive software algorithm to automatically create the best evacuation route in case of fire, according to the best path lights indicating the direction of evacuation; 2.2 Safety voltage power supply to ensure the safety of firefighters; 2.3 evacuation signs lights twinkling in the fire, good transparency; 2.4 evacuation signage lights fault system failure prompted, easy maintenance; 2.5 use LED light source, each lamp consumption Can all within 3W, system energy. 2.6 fully tempered glass lamps, high temperature. 2.7 Independent address code, fully automatic query lighting is good or bad, and have automatic monthly inspection, inspection functions. 2.8 independent ground evacuation using computer algorithms, dynamic water for 15-30 seconds, a clear evacuation. 2.9 dual battery protection features, centralized power plants within the lamp has a battery to ensure local failure after work independently. 2.10 intelligent evacuation network architecture for the serial approach to effectively avoid interference. 2.11 Control Panel IPC control, completely 5.7--17 touch screen operation, with the windows system, easy to upgrade and compatibility. 3 sub-wood design 3.1 Evacuation emergency lighting and setting area evacuation area 3.1 of the building, according to the characteristics of the building should be divided into horizontal evacuation area, regional and vertical evacuation in case of fire still work work area. 3.1.1 horizontal evacuation areas: construction (including traffic tunnels) in the evacuation corridors, evacuation route; front stairwell front room, fire elevator room and combined room; refuge floors (rooms). 3.1.2 Vertical evacuation area includes the following places: the stairwell (including open stairwells, enclosed staircase, stairwell); outdoor stairs. 3.1.3 Building work area when the fire remains fire operations include the following areas: fire control room; fire pump room; manned total distribution room, transformer substation;-owned power generator room and the fire protection system battery room. 3.2 evacuation lighting illumination requirements of the building fire emergency lighting illumination shall meet the following requirements: 3.2.1 Lighting in the region should not be below ground level of illumination centerline 1.0lx, lighting illuminance levels edges of the area should not be less than 0.5lx. 3.2.2 centerline ground level of illumination within the stairwell should not be lower than 5.0lx 3.4 4.1 System classification and selection of fire emergency lighting and evacuation system depending on the power source (battery pack) and transferred to the emergency control mode setting, divided into the following four types of systems: A type of system - own power decentralized control systems (the system may include picture-type fire emergency lighting). B class system - centralized power decentralized control systems. C class system - own power centralized control system (the system may include picture-type fire emergency lighting). D class system - centralized power centralized control system. 4.2 System Select 4.2.1 Rail Transit concourse level and platform layer, stations, terminals and airport terminals and other transportation hubs, 20000m2 more shopping malls, exhibition centers and hospital outpatient service building and other places should choose class C or D class system. 4.2.2 evacuation corridors and stairwells should not choose a non-emergency power supply voltage safe voltage of centralized power-type fire emergency lighting and evacuation system. 4.2.3 large department stores, supermarkets, large stadiums, subway tunnels and other required flow evacuation signs light guide place, select class C or D class system. 4.2.4 When a centralized power supply and line voltage drop can not meet the requirements, set up centralized power should be decentralized. 3.5 System Requirements 5.1 General provisions 5.1.1 fire evacuation instructions, should be used to fire emergency lights or fire emergency lighting sign composite lamps; non-evacuation signage lamps can be used as an auxiliary indicator. Main electrical power supply and control connections 5.1.2 Emergency lighting should ensure that when the fire broke out, fire emergency lighting all make all switched to emergency state. 5.1.3 Emergency lighting investment of time should not exceed 5s. 5.1.4 to fire emergency lighting power supply circuit (including centralized power type fire emergency lighting systems emergency power supply circuit) is strictly prohibited setting off the charge and off the lamp lighting state of emergency light switch device, sockets and other loads. 5.1.5 In normal power supply status, allows you to set the switch to control fire emergency lighting of work, but the switch should not affect the fire emergency lighting from the normal operating state into a state of emergency work. 5.2 System Design A class system - own power decentralized control systems design. 5.2.1 Set up automatic fire alarm system building, automatic fire alarm system should be able to manually or automatically controlled fire emergency lighting distribution box working condition. 5.2.2 automatic fire alarm system is not set building, all fire emergency lighting lamps should be connected to a dedicated power supply circuit, the normal lighting power interruptions, all fire emergency lighting into the emergency state. B class system - designed to focus the power of decentralized control systems set up automatic fire alarm system in the building, the system into emergency state control should be designed to meet the following requirements: 5.2.3 centralized power control unit should be set in Fire control room; 5.2.4 centralized set the system battery, centralized power control device should be able to manually control the fire emergency lighting distribution box working condition; 5.2.5 decentralized set the system battery, centralized power the control device should be able to manually control the battery pack and the operating mode changing means; 5.2.6 automatic fire alarm system should linkage control centralized power control unit and fire emergency lighting distribution box working condition. 5.2.7 not set up automatic fire alarm system construction, the system into emergency state control should be designed to meet the following requirements. 1 centralized power control unit should be set in place manned; 2 centralized power supply circuit should be connected to the special illumination. 5.4.4 In the evacuation corridors laying line junction box and fire emergency lighting should meet the requirements of protection class IP65 of. 5.4.5 centralized power supply emergency lighting to be provided at the fire control room power distribution, low voltage power distribution room or fireproof partition. 5.4.6 emergency lighting distribution box should be set separately in each fire district, distribution of electrical power distribution box should be installed within or between the shaft, the shaft should not set distribution occasionally in use waterproof fire performance distribution box. 5.4.7-rise building evacuation stairwell emergency lighting should be set separately centralized power distribution box or a separate emergency output branch. 5.4.8 Single-phase power supply single concentration should not exceed the total power 10kW, three-phase power supply single concentration should not exceed the total power of 30kW. Class C and D class system - own power and centralized power centralized control system design 5.4.9 Emergency lighting controller should be set up in the fire linkage control signal control room, and can receive automatic fire alarm system into a state of emergency The control-related fire emergency lighting into the emergency state. Class 5.4.10 C system emergency lighting controller should be able to control and display the working status of the system all the fire emergency lighting, emergency lighting, power distribution boxes and other accessories. 5.4.10 Class D system emergency lighting controller should be able to control and display the system all the fire emergency lighting, emergency lighting centralized power, emergency lighting distribution box and other accessories in working condition. 5.4.11 D class centralized power supply emergency lighting system should be designed to meet the requirements of Part B class system. Evacuation plan 5.4.12 system arranged to meet the following requirements: 1. The system should be able to receive a building fire alarm; two sites should take place according to a fire alarm signal to confirm the fire, the optimum safe escape route, evacuation route optimization; 3 The manufacturer shall provide system design logic evacuation plan; 4 main system controller does not work, you should be able to switch manually to the emergency state. 5.4.13 system power supply design should meet the following requirements: 1 controller main power supply by fire; 2 controller standby power should at least make the controller work after the main power supply is interrupted 2h. 5.4.14 evacuation route in accordance with a select portion of the fire alarm system, fire alarm controller should receive all the fire detector alarm information, and should be determined according to performance-based design evacuation plans. 5.4.15 system in the main controller does not work, you should have a manual completion of pre-evacuation plan.