Description
1 Preparation Principles and Application Scope
1.1 Preparation principles
This Atlas is a revision of original 86SD566. Considering the successive revision of the national standard GBJ 57-83 Design Code for Protection of Structures against Lightning and other relevant standards in 1990s, the International Electrotechnical Commission and other countries successively published new standards. This Atlas is prepared based on the standards.
1.2 Application scope
This Atlas applies to Class II and Class III lightning protection buildings. The foundation earth lead also applies to earth lead required to be arranged for buildings other than Class I, Class II and Class III lightning protection buildings.
2 Preparation bases
In terms of standards of the People's Republic of China
GB 50057-94 Design Code for Protection of Structures against Lightning (2000 Edition)
GBJ 65-83 Specifications for the Design of Grounding (Earthing) of Industrial and Civil Electric System (Trial)
2.2 National building standard design atlas
97J103-1 Aluminum Alloy Glass Curtain Wall
96SJ301 Waterproof Construction of Underground Construction
94G316 Ⅱ-Shaped Reinforced Concrete Skylight Truss
97G329 Anti-seismic Building Structure Details
92G410 1.5m×6.0m Prestressed Concrete Roof Slab
96G353 Reinforced Concrete Roof Beam
98G363 Seismic Joint Drawing for Reinforced Concrete Structural Column of Multi-Story Masonary Building
95G314 Reinforced Concrete Broken-Line Roof Truss
95G315 Prestressed Concrete Broken-Line Roof Truss
96G433 Prestressed Concrete Broken-Line and Triangle Bracket
3 The close cooperation of constructors in the disciples of civil work and electric system is very important to reach the technical purpose of this Atlas. It is recommended that: the construction in building and structural components be carried out by the constructors of civil work discipline while that out of building and structural components be carried out by constructors of electric system or lighting protection disciple. The constructors of civil work discipline may be also responsible for the construction out of building and structural components which is less in construction amount.
4 The exposed steel parts over the ground shall be painted with one pass of minium oil and two passes of anticorrosive paint.
5 Exposed lightning protection device over the ground shall be installed as detailed in the relevant standards and atlases.
6 Earthing device applied into the soil under the ground shall be installed as detailed in the relevant standards and atlases.
7 Most of building metals and embedded parts are concealed into the concrete, so it is impossible to remedy on completion of construction. It is recommended that the constructors and supervisors for electric system and lightning protection devices actively learn about and check whether the civil construction being carried out meets the relevant design requirements and timely make a correction.
8 Supplemental instruction to legends:
... ...
.. ...
9 The practice of this Atlas can provide the following advantages: safety, reliability, long service life, the least maintenance work, without using galvanized steel and without interfering with facade decoration of buildings.
As a complete or most of the devices are buried in the buildings and structural members or using metal brake of the building and structure, the service life can last a long term, even as long as that of the buildings. Sometimes the construction may be complicated, but after the completion, less maintenance is needed during the service of the buildings;in most cases, there is no need to maintain the devices. On the contrary, the exposed special lightning protection device and artificial earth lead buried in the soil shall be replaced for several times due to corrosion, etc. during the service life of buildings, supposed to be 50-100 years.Therefore, when the building metals are used as the devices, the construction expenses of the first time may be expensive (in most cases, it is not necessarily expensive), but from the point of service life of buildings, the expenses are economic, moreover, the steels for special device may not be needed in most cases.
Name of figure page Name of figure page
Contents 1
Description 3
Cast-in-situ frame joint connection for multilayer and high-rise buildings
Lightning protection measures for aluminum alloy glass curtain wall 9
Artificial earth lead in strip foundation 11
Artificial earth lead applied in concrete cushion under rubber or plastic waterproof layer
Artificial earth lead applied in concrete cushion under steel plate waterproof layer
Connection of steel column with reinforced concrete foundation
Connection of cup mouth type reinforced concrete foundation
Connection of cup mouth type reinforced concrete foundation
Practice of embedding connecting plate in reinforced concrete of multi-storey and high-rise buildings
Connection of embedded parts of precast reinforced concrete column at high-low span joint of single-storey factory building
Connection of embedded parts of precast reinforced concrete column at high span joint of single-storey factory building
Electric system connection diagram formed by reinforced concrete roof slab, eaves fascia and panel of single-storey factory building 23
Connection of steel bar within parapet wall coping ring beam used as lightning arrester and fire ladder
Lightning protection connection between parapet wall coping and vertical reinforcement
Lightning protection connection of fire ladder at roof riser and cornice without parapet wall in industrial factory building
Lightning protection connection of steel ladder at reinforced concrete skylight truss end wall
Column top jumper wire at reinforced concrete column expansion joint
Embedded parts of special treatment according to lightning protection requirements at single-slope reinforced concrete roof beam
Embedded parts of special treatment according to lightning protection requirements at double-slope reinforced concrete roof beam
Embedded parts for special lightning protection for reinforced concrete segmental roof truss of 6m-span skylight truss 32
Embedded parts for special lightning protection for reinforced concrete segmental roof truss of 9m-span skylight truss 34
Embedded parts for special lightning protection for reinforced concrete open web roof truss 36
Embedded parts for special lightning protection for prestressed concrete bracket
Connection between steel door/window and building metal
Connection between aluminum alloy door/window and building metal
Connection between full-length aluminium alloy window and building metal
Using steel bar of water tower as a part of lightning protection system
Example of direct lightning protection measures for workshop building
Workshop foundation serving as the earthing device of electric installation
Connection with steel bars in concrete
Welded steel mesh in reinforced concrete ground serving as signal reference network
Equipment base serving as signal reference network
High frequency signal reference network composed of thin copper strips
Design example of mixed equipotential bonding in building
Example of equipotential bonding with steel bar in building
Design examples of office building shielding, equipotential bonding and earthing
Design example of lightning protection system of reinforced concrete building
Lightning protection measures for multi-storey building
Lightning protection measures for high-rise building
Equipotential bonding of low-voltage distribution system and electronic system at building access 55
Using metal roof, steel roof truss and steel column as the lightning protection system
Basic method of functional equipotential bonding of information system
Combination of functional equipotential bonding methods of information system
Constitution of earthing, equipotential bonding and common earthing system of building
Equipotential bonding between electrical equipment of single-storey factory building and lightning protection system, current path when lightning strikes the plant
Method for measuring metal resistance of constructed building
Calculation of power frequency earthing resistance of natural foundation earth lead 63
Standard
03D501-3 Installation of lightning protection and earthing devices made from building metals (English Version)
Standard No.
03D501-3
Status
superseded
Language
English
File Format
PDF
Word Count
28000 words
Price(USD)
600.0
Implemented on
2003-2-1
Delivery
via email in 1 business day
Detail of 03D501-3
Standard No.
03D501-3
English Name
Installation of lightning protection and earthing devices made from building metals
Description
1 Preparation Principles and Application Scope
1.1 Preparation principles
This Atlas is a revision of original 86SD566. Considering the successive revision of the national standard GBJ 57-83 Design Code for Protection of Structures against Lightning and other relevant standards in 1990s, the International Electrotechnical Commission and other countries successively published new standards. This Atlas is prepared based on the standards.
1.2 Application scope
This Atlas applies to Class II and Class III lightning protection buildings. The foundation earth lead also applies to earth lead required to be arranged for buildings other than Class I, Class II and Class III lightning protection buildings.
2 Preparation bases
In terms of standards of the People's Republic of China
GB 50057-94 Design Code for Protection of Structures against Lightning (2000 Edition)
GBJ 65-83 Specifications for the Design of Grounding (Earthing) of Industrial and Civil Electric System (Trial)
2.2 National building standard design atlas
97J103-1 Aluminum Alloy Glass Curtain Wall
96SJ301 Waterproof Construction of Underground Construction
94G316 Ⅱ-Shaped Reinforced Concrete Skylight Truss
97G329 Anti-seismic Building Structure Details
92G410 1.5m×6.0m Prestressed Concrete Roof Slab
96G353 Reinforced Concrete Roof Beam
98G363 Seismic Joint Drawing for Reinforced Concrete Structural Column of Multi-Story Masonary Building
95G314 Reinforced Concrete Broken-Line Roof Truss
95G315 Prestressed Concrete Broken-Line Roof Truss
96G433 Prestressed Concrete Broken-Line and Triangle Bracket
3 The close cooperation of constructors in the disciples of civil work and electric system is very important to reach the technical purpose of this Atlas. It is recommended that: the construction in building and structural components be carried out by the constructors of civil work discipline while that out of building and structural components be carried out by constructors of electric system or lighting protection disciple. The constructors of civil work discipline may be also responsible for the construction out of building and structural components which is less in construction amount.
4 The exposed steel parts over the ground shall be painted with one pass of minium oil and two passes of anticorrosive paint.
5 Exposed lightning protection device over the ground shall be installed as detailed in the relevant standards and atlases.
6 Earthing device applied into the soil under the ground shall be installed as detailed in the relevant standards and atlases.
7 Most of building metals and embedded parts are concealed into the concrete, so it is impossible to remedy on completion of construction. It is recommended that the constructors and supervisors for electric system and lightning protection devices actively learn about and check whether the civil construction being carried out meets the relevant design requirements and timely make a correction.
8 Supplemental instruction to legends:
... ...
.. ...
9 The practice of this Atlas can provide the following advantages: safety, reliability, long service life, the least maintenance work, without using galvanized steel and without interfering with facade decoration of buildings.
As a complete or most of the devices are buried in the buildings and structural members or using metal brake of the building and structure, the service life can last a long term, even as long as that of the buildings. Sometimes the construction may be complicated, but after the completion, less maintenance is needed during the service of the buildings;in most cases, there is no need to maintain the devices. On the contrary, the exposed special lightning protection device and artificial earth lead buried in the soil shall be replaced for several times due to corrosion, etc. during the service life of buildings, supposed to be 50-100 years.Therefore, when the building metals are used as the devices, the construction expenses of the first time may be expensive (in most cases, it is not necessarily expensive), but from the point of service life of buildings, the expenses are economic, moreover, the steels for special device may not be needed in most cases.
Contents of 03D501-3
Name of figure page Name of figure page
Contents 1
Description 3
Cast-in-situ frame joint connection for multilayer and high-rise buildings
Lightning protection measures for aluminum alloy glass curtain wall 9
Artificial earth lead in strip foundation 11
Artificial earth lead applied in concrete cushion under rubber or plastic waterproof layer
Artificial earth lead applied in concrete cushion under steel plate waterproof layer
Connection of steel column with reinforced concrete foundation
Connection of cup mouth type reinforced concrete foundation
Connection of cup mouth type reinforced concrete foundation
Practice of embedding connecting plate in reinforced concrete of multi-storey and high-rise buildings
Connection of embedded parts of precast reinforced concrete column at high-low span joint of single-storey factory building
Connection of embedded parts of precast reinforced concrete column at high span joint of single-storey factory building
Electric system connection diagram formed by reinforced concrete roof slab, eaves fascia and panel of single-storey factory building 23
Connection of steel bar within parapet wall coping ring beam used as lightning arrester and fire ladder
Lightning protection connection between parapet wall coping and vertical reinforcement
Lightning protection connection of fire ladder at roof riser and cornice without parapet wall in industrial factory building
Lightning protection connection of steel ladder at reinforced concrete skylight truss end wall
Column top jumper wire at reinforced concrete column expansion joint
Embedded parts of special treatment according to lightning protection requirements at single-slope reinforced concrete roof beam
Embedded parts of special treatment according to lightning protection requirements at double-slope reinforced concrete roof beam
Embedded parts for special lightning protection for reinforced concrete segmental roof truss of 6m-span skylight truss 32
Embedded parts for special lightning protection for reinforced concrete segmental roof truss of 9m-span skylight truss 34
Embedded parts for special lightning protection for reinforced concrete open web roof truss 36
Embedded parts for special lightning protection for prestressed concrete bracket
Connection between steel door/window and building metal
Connection between aluminum alloy door/window and building metal
Connection between full-length aluminium alloy window and building metal
Using steel bar of water tower as a part of lightning protection system
Example of direct lightning protection measures for workshop building
Workshop foundation serving as the earthing device of electric installation
Connection with steel bars in concrete
Welded steel mesh in reinforced concrete ground serving as signal reference network
Equipment base serving as signal reference network
High frequency signal reference network composed of thin copper strips
Design example of mixed equipotential bonding in building
Example of equipotential bonding with steel bar in building
Design examples of office building shielding, equipotential bonding and earthing
Design example of lightning protection system of reinforced concrete building
Lightning protection measures for multi-storey building
Lightning protection measures for high-rise building
Equipotential bonding of low-voltage distribution system and electronic system at building access 55
Using metal roof, steel roof truss and steel column as the lightning protection system
Basic method of functional equipotential bonding of information system
Combination of functional equipotential bonding methods of information system
Constitution of earthing, equipotential bonding and common earthing system of building
Equipotential bonding between electrical equipment of single-storey factory building and lightning protection system, current path when lightning strikes the plant
Method for measuring metal resistance of constructed building
Calculation of power frequency earthing resistance of natural foundation earth lead 63
