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NB 35047-2015: Code for seismic design of hydraulic structures of hydropower project
NB 35047-2015
NB
ENERGY INDUSTRY STANDARD OF
THE PEOPLE’S REPUBLIC OF CHINA
ICS 27.140
P 59
Registration number. J2042-2015
P NB 35047-2015
Replacing DL 5073-2000
Code for seismic design of
hydraulic structures of hydropower project
ISSUED ON. APRIL 02, 2015
IMPLEMENTED ON. SEPTEMBER 01, 2015
Issued by. National Energy Administration
Table of Contents
Foreword ... 4
1 General ... 9
2 Terms and symbols ... 11
2.1 Terms ... 11
2.2 Symbols ... 14
3 Basic requirements ... 16
4 Site, foundation and slope ... 19
4.1 Site ... 19
4.2 Foundation ... 21
4.3 Slope ... 22
5 General in earthquake action and seismic analysis ... 24
5.1 Seismic action components and its combination ... 24
5.2 Seismic action types ... 25
5.3 Design seismic acceleration and standard design response spectrum ... 25
5.4 Earthquake action and combination with other actions ... 26
5.5 Structural modeling and calculation method ... 27
5.6 Dynamic properties of concrete and foundation rock for hydraulic structures
... 29
5.7 Seismic design ultimate limit state with partial factors ... 30
5.8 Seismic calculation for subsidiary structure ... 31
5.9 Seismic earth pressure ... 32
6 Embankment dam ... 33
6.1 Seismic calculation ... 33
6.2 Seismic measure ... 36
7 Gravity dam ... 39
7.1 Seismic calculation ... 39
7.2 Seismic measure ... 43
8 Arch dam ... 44
8.1 Seismic calculation ... 44
8.2 Seismic measure ... 47
9 Sluice ... 49
9.1 Seismic calculation ... 49
9.2 Seismic measure ... 51
10 Underground hydraulic structure ... 53
10.1 Seismic calculation ... 53
10.2 Seismic measure ... 55
11 Intake tower ... 56
11.1 Seismic calculation ... 56
11.2 Seismic measure ... 61
12 Penstock of hydropower station and ground powerhouse ... 63
12.1 Penstock... 63
12.2 Ground powerhouse ... 64
13 Aqueduct ... 65
13.1 Seismic calculation ... 65
13.2 Seismic measure ... 66
14 Shiplift ... 67
14.1 Seismic calculation ... 67
14.2 Seismic measure ... 67
Appendix A Seismic stability calculation of embankment dam with quasi-static
method ... 69
Appendix B Calculation of aqueduct dynamic water pressure ... 72
Explanation of wording in the Code ... 76
List of normative standards ... 77
2 Terms and symbols
2.1 Terms
2.1.1 Seismic design
Special design for the engineering structure of the strong earthquake zone. It
generally includes two aspects. seismic calculation and seismic measure.
2.1.2 Basic intensity
Within the 50-year period, under general site conditions, it may encounter the
seismic intensity of which the exceeding probability P50 is 0.10. Generally, the
corresponding seismic intensity value is determined in accordance with the
Appendix [in GB 18306], in accordance with the seismic peak acceleration
value as indicated in GB 18306 for the site.
2.1.3 Design intensity
The seismic intensity determined as the basis for engineering fortification based
on the basic intensity.
2.1.4 Reservoir earthquake
Earthquakes associated with reservoir impoundment that generally occur within
10 km of the reservoir bank.
2.1.5 Maximum credible earthquake
Earthquakes with the greatest ground motion that may occur at sites which are
evaluated in accordance with the seismic geological conditions of the project
site.
2.1.6 Scenario earthquake
Among the potential sources that may generate peak acceleration of ground
motion at the site, the earthquake with the magnitude and epicentral distance
that is determined along the main fault location in accordance with the principle
of the maximum probability of occurrence.
2.1.7 Seismic ground motion
Geotechnical movement caused by earthquakes.
2.1.8 Seismic action
The dynamic action of ground motion on the structure.
time history.
2.1.18 Mode decomposition method
The method of firstly solving the seismic effect of the structure corresponding
to its various modes at each stage and then combining them into the structure
total seismic effect. The direct superimposing of the mode effects of each stage
obtained by time-history analytical method is called mode decomposition time-
history analytical method, whilst the combination of those obtained by reaction
spectrum is called mode decomposition reaction spectrum method.
2.1.19 Square root of the sum of the squares (SRSS) method
The mode combination method of taking the square root of the sum of squared
seismic effects of various modes as the total seismic action.
2.1.20 Complete quadratic combination (CQC) method
The mode combination method of taking the square of the seismic effect of
each mode and the square root of the sum of the coupling items of different
vibration modes as total seismic effect.
2.1.21 Seismic hydrodynamic pressure
The dynamic pressure exerted by the water body on the structure due to
seismic effect.
2.1.22 Seismic earth pressure
The dynamic pressure exerted by the soil on the structure caused by the
earthquake.
2.1.23 Quasi static method
The static analytical method of using the product of gravity action, the ratio of
design seismic acceleration to gravity acceleration, and the given dynamic
distribution factor as the designed seismic force.
2.1.24 Seismic effect reduction factor
A factor that is introduced to reduce the seismic effects due to the simplification
of the calculation method of the seismic effect.
2.1.25 Natural vibration period
The time required for the structure to complete a free vibration in accordance
with a certain mode. The natural vibration period corresponding to the first mode
is called the basic natural vibration period.
years is 0.10 for the hydraulic structures of categories other than
category A, but it shall also not be less than the corresponding
seismic horizontal acceleration divisional value in the divisional map.
3 For the hydraulic structures, of which the engineering seismic
fortification is category A, which requires specific site seismic safety
evaluation, in addition to performing seismic design based on the
design seismic peak acceleration, it shall make specific
demonstration for the safety margin of avoiding uncontrolled
drainage catastrophe of reservoir water when it is subject to the
maximum credible earthquake of the site, and propose the seismic
safety theme report it is based on, wherein. the horizontal peak
acceleration representative value of the “maximum credible
earthquake” shall be determined in accordance with the seismic
geological conditions of the site, using the deterministic method or
the result of the probability method of which the exceeding
probability P100 within 100 years is 0.01.
4 When the backwater structure is upgraded from grade 2 to grade 1 due to
dam height and seismic geological conditions, in addition to performing
seismic design based on the horizontal design seismic peak acceleration
of which the exceeding probability P50 within 50 years is 0.10, it shall also
be based on the horizontal design seismic peak acceleration of which the
exceeding probability P100 within 100 years is 0.05 to perform specific
demonstration for the safety margin of avoiding uncontrolled drainage
catastrophe of reservoir water.
5 In the special report on seismic safety, the site-related design response
spectrum should be determined in accordance with the scenario
Get QUOTATION in 1-minute: Click NB 35047-2015
Historical versions: NB 35047-2015
Preview True-PDF (Reload/Scroll if blank)
NB 35047-2015: Code for seismic design of hydraulic structures of hydropower project
NB 35047-2015
NB
ENERGY INDUSTRY STANDARD OF
THE PEOPLE’S REPUBLIC OF CHINA
ICS 27.140
P 59
Registration number. J2042-2015
P NB 35047-2015
Replacing DL 5073-2000
Code for seismic design of
hydraulic structures of hydropower project
ISSUED ON. APRIL 02, 2015
IMPLEMENTED ON. SEPTEMBER 01, 2015
Issued by. National Energy Administration
Table of Contents
Foreword ... 4
1 General ... 9
2 Terms and symbols ... 11
2.1 Terms ... 11
2.2 Symbols ... 14
3 Basic requirements ... 16
4 Site, foundation and slope ... 19
4.1 Site ... 19
4.2 Foundation ... 21
4.3 Slope ... 22
5 General in earthquake action and seismic analysis ... 24
5.1 Seismic action components and its combination ... 24
5.2 Seismic action types ... 25
5.3 Design seismic acceleration and standard design response spectrum ... 25
5.4 Earthquake action and combination with other actions ... 26
5.5 Structural modeling and calculation method ... 27
5.6 Dynamic properties of concrete and foundation rock for hydraulic structures
... 29
5.7 Seismic design ultimate limit state with partial factors ... 30
5.8 Seismic calculation for subsidiary structure ... 31
5.9 Seismic earth pressure ... 32
6 Embankment dam ... 33
6.1 Seismic calculation ... 33
6.2 Seismic measure ... 36
7 Gravity dam ... 39
7.1 Seismic calculation ... 39
7.2 Seismic measure ... 43
8 Arch dam ... 44
8.1 Seismic calculation ... 44
8.2 Seismic measure ... 47
9 Sluice ... 49
9.1 Seismic calculation ... 49
9.2 Seismic measure ... 51
10 Underground hydraulic structure ... 53
10.1 Seismic calculation ... 53
10.2 Seismic measure ... 55
11 Intake tower ... 56
11.1 Seismic calculation ... 56
11.2 Seismic measure ... 61
12 Penstock of hydropower station and ground powerhouse ... 63
12.1 Penstock... 63
12.2 Ground powerhouse ... 64
13 Aqueduct ... 65
13.1 Seismic calculation ... 65
13.2 Seismic measure ... 66
14 Shiplift ... 67
14.1 Seismic calculation ... 67
14.2 Seismic measure ... 67
Appendix A Seismic stability calculation of embankment dam with quasi-static
method ... 69
Appendix B Calculation of aqueduct dynamic water pressure ... 72
Explanation of wording in the Code ... 76
List of normative standards ... 77
2 Terms and symbols
2.1 Terms
2.1.1 Seismic design
Special design for the engineering structure of the strong earthquake zone. It
generally includes two aspects. seismic calculation and seismic measure.
2.1.2 Basic intensity
Within the 50-year period, under general site conditions, it may encounter the
seismic intensity of which the exceeding probability P50 is 0.10. Generally, the
corresponding seismic intensity value is determined in accordance with the
Appendix [in GB 18306], in accordance with the seismic peak acceleration
value as indicated in GB 18306 for the site.
2.1.3 Design intensity
The seismic intensity determined as the basis for engineering fortification based
on the basic intensity.
2.1.4 Reservoir earthquake
Earthquakes associated with reservoir impoundment that generally occur within
10 km of the reservoir bank.
2.1.5 Maximum credible earthquake
Earthquakes with the greatest ground motion that may occur at sites which are
evaluated in accordance with the seismic geological conditions of the project
site.
2.1.6 Scenario earthquake
Among the potential sources that may generate peak acceleration of ground
motion at the site, the earthquake with the magnitude and epicentral distance
that is determined along the main fault location in accordance with the principle
of the maximum probability of occurrence.
2.1.7 Seismic ground motion
Geotechnical movement caused by earthquakes.
2.1.8 Seismic action
The dynamic action of ground motion on the structure.
time history.
2.1.18 Mode decomposition method
The method of firstly solving the seismic effect of the structure corresponding
to its various modes at each stage and then combining them into the structure
total seismic effect. The direct superimposing of the mode effects of each stage
obtained by time-history analytical method is called mode decomposition time-
history analytical method, whilst the combination of those obtained by reaction
spectrum is called mode decomposition reaction spectrum method.
2.1.19 Square root of the sum of the squares (SRSS) method
The mode combination method of taking the square root of the sum of squared
seismic effects of various modes as the total seismic action.
2.1.20 Complete quadratic combination (CQC) method
The mode combination method of taking the square of the seismic effect of
each mode and the square root of the sum of the coupling items of different
vibration modes as total seismic effect.
2.1.21 Seismic hydrodynamic pressure
The dynamic pressure exerted by the water body on the structure due to
seismic effect.
2.1.22 Seismic earth pressure
The dynamic pressure exerted by the soil on the structure caused by the
earthquake.
2.1.23 Quasi static method
The static analytical method of using the product of gravity action, the ratio of
design seismic acceleration to gravity acceleration, and the given dynamic
distribution factor as the designed seismic force.
2.1.24 Seismic effect reduction factor
A factor that is introduced to reduce the seismic effects due to the simplification
of the calculation method of the seismic effect.
2.1.25 Natural vibration period
The time required for the structure to complete a free vibration in accordance
with a certain mode. The natural vibration period corresponding to the first mode
is called the basic natural vibration period.
years is 0.10 for the hydraulic structures of categories other than
category A, but it shall also not be less than the corresponding
seismic horizontal acceleration divisional value in the divisional map.
3 For the hydraulic structures, of which the engineering seismic
fortification is category A, which requires specific site seismic safety
evaluation, in addition to performing seismic design based on the
design seismic peak acceleration, it shall make specific
demonstration for the safety margin of avoiding uncontrolled
drainage catastrophe of reservoir water when it is subject to the
maximum credible earthquake of the site, and propose the seismic
safety theme report it is based on, wherein. the horizontal peak
acceleration representative value of the “maximum credible
earthquake” shall be determined in accordance with the seismic
geological conditions of the site, using the deterministic method or
the result of the probability method of which the exceeding
probability P100 within 100 years is 0.01.
4 When the backwater structure is upgraded from grade 2 to grade 1 due to
dam height and seismic geological conditions, in addition to performing
seismic design based on the horizontal design seismic peak acceleration
of which the exceeding probability P50 within 50 years is 0.10, it shall also
be based on the horizontal design seismic peak acceleration of which the
exceeding probability P100 within 100 years is 0.05 to perform specific
demonstration for the safety margin of avoiding uncontrolled drainage
catastrophe of reservoir water.
5 In the special report on seismic safety, the site-related design response
spectrum should be determined in accordance with the scenario
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