IT system - Fault protection: Difference between revisions

From Electrical Installation Guide
(Cleanup_2016_while rechecking)
m (Text replacement - "\[\[ru:[^]]*\]\][ \r\n]*" to "")
 
(17 intermediate revisions by 3 users not shown)
Line 1: Line 1:
{{Menu_Protection_against_electric_shocks}}
{{Menu_Protection_against_electric_shocks}}
== First fault situation ==
In IT system, the first fault to earth should not cause any disconnection.


In this type of system:
The earth-fault current which flows under a first-fault condition is measured in mA.
 
*The installation is isolated from earth, or the neutral point of its power-supply source is connected to earth through a high impedance
*All exposed and extraneous-conductive-parts are earthed via an installation earth electrode.


== First fault situation ==
Two different examples of earth-fault current calculation are presented below .


{{Highlightbox|
=== Example 1 ===
In IT system the first fault to earth should not cause any disconnection}}
In the simplified circuit presented on {{FigRef|F32}}, the neutral point of the power-supply source is connected to earth through a 1500 Ω resistance. The current through the earthing resistor will be 153 mA in case of a fault (on a 230/400 V 3-phase system). The fault voltage with respect to earth due to this current is the product of this current and the resistance of the PE conductor plus earthing resistor (from the faulted component to the electrode), which is negligible.


On the occurrence of a true fault to earth, referred to as a “first fault”, the fault current is very low, such that the rule Id x R<sub>A</sub> ≤ 50 V (see [[Automatic disconnection for TT system]]) is fulfilled and no dangerous fault voltages can occur.
{{FigImage|DB431014|svg|F32|Simplified circuit}}


In practice the current Id is low, a condition that is neither dangerous to personnel, nor harmful to the installation.
=== Example 2 ===
For a network formed of 1 km of conductors as represented on {{FigRef|F33}}, the leakage impedance to earth (≈ 1 μF / km) is represented by the capacitors C<sub>1</sub> to C<sub>N</sub>. The capacitive impedance Z<sub>C</sub> is in the order of 3500 Ω per phase. In normal operation, the capacitive current{{fn|1}} to earth is therefore:


However, in this system:
<math>I_c= \frac{U_0}{Z_c}= \frac{230}{3500}=66\ mA</math> per phase.
*A permanent monitoring of the insulation to earth must be provided, coupled with an alarm signal (audio and/or flashing lights, etc.) operating in the event of a first earth fault (see {{FigRef|F16}})


{{FigImage|PB116742|jpg|F16|Phases to earth insulation monitoring device obligatory in IT system}}
{{FigImage|DB431015|svg|F33|Fault current path for a first fault in IT system}}


*The location and repair of a first fault is imperative if the full benefits of the IT system are to be realised. Continuity of service is the great advantage afforded by the system. As continuity of service is provided, it is not mandatory to repair the fault immediately avoiding to operate under stress and urgency.
During a fault between phase 1 and earth as in {{FigRef|F33}}, the voltage and current vectors can be represented as shown on {{FigRef|F34}}.


For a network formed from 1 km of new conductors, the leakage (capacitive) impedance to earth Zf is of the order of 3,500 Ω per phase.
The fault current passing through the electrode resistance R<sub>A</sub> is the vector sum of the currents:
* Capacitive currents in the two healthy phases I<sub>C2</sub> and I<sub>C3</sub>,
* Capacitive current in the neutral I<sub>CN</sub>,
* Current in the neutral impedance, I<sub>d1</sub>.


In normal operation, the capacitive current{{fn|1}} to earth is therefore:
{{FigImage|DB431016|svg|F34|Vector representation of voltages and currents  in case of fault between phase 1 and earth}}


<math>\frac{Uo}{Zf}= \frac{230}{3,500}=66\ mA</math> per phase.  
The voltages of the healthy phases have (because of the fault) increased to √3 times the normal phase voltage, so that the capacitive currents increase by the same amount: I<sub>C2</sub> = I<sub>C3</sub> = I<sub>C</sub>.√3 = 66 x √3 = 114 mA


During a phase to earth fault, as indicated in {{FigureRef|F17}},the current passing through the electrode resistance RnA is the vector sum of the capacitive currents in the two healthy phases. The voltages of the healthy phases have (because of the fault) increased to <math>\sqrt3</math> the normal phase voltage, so that the capacitive currents increase by the same amount. These currents are displaced, one from the other by 60°, so that when added vectorially, this amounts to 3 x 66 mA = 198 mA, in the present example.
The neutral voltage is 230V, so the capacitive neutral current is: I<sub>CN</sub> = I<sub>C</sub> = 66 mA


The fault voltage Uf is therefore equal to 198 x 5 x 10<sup>-3</sup> = 0.99 V, which is obviously harmless.
These currents are displaced one from the other by 30°, so that the total vector addition I<sub>d2</sub> amounts to:


The current through the short-circuit to earth is given by the vector sum of the neutral-resistor current Id1 (=153 mA) and the capacitive current Id2 (198 mA).
<math>2(I_c.\sqrt{3}).\frac{\sqrt{3}}{2} + I_c = 3.I_c + I_c = 4. I_c = 4 \times 66 = 264 mA</math>


{{FigImage|DB422229_EN|svg|F17|Fault current path for a first fault in IT system}}
e.g. for 3L+N circuits, the capacitive current to earth value increases by a factor of 4 during phase-to-earth fault, compared to its value in normal operation I<sub>C</sub>


Since the exposed-conductive-parts of the installation are connected directly to earth, the neutral impedance Zct plays practically no part in the production of touch voltages to earth.
The current Id1 through the neutral resistance is 153 mA (see simplified example above)


== Second fault situation  ==
The current through the fault to earth is given by the vector sum of the neutral resistor current I<sub>d1</sub> (= 153 mA) and the capacitive current I<sub>d2</sub> (= 264 mA).


{{Highlightbox|
It is then equal to:
The simultaneous existence of two earth faults (if not both on the same phase) is dangerous, and rapid clearance by fuses or automatic circuit-breaker tripping depends on the type of earth-bonding scheme, and whether separate earthing electrodes are used or not, in the installation concerned }}


On the appearance of a second fault, on a different phase, or on a neutral conductor, a rapid disconnection becomes imperative. Fault clearance is carried out differently in each of the following cases:
<math> \sqrt {153^2 + 263^2} = 304mA </math>


=== 1<sup>st</sup> case ===
Considering for example an earthing resistance R<sub>A</sub> equal to 50 Ω, the fault voltage U<sub>f</sub> is therefore equal to: 50 x 304 x 10<sup>-3</sup> = 15.2 V, which is obviously harmless.
It concerns an installation in which all exposed conductive parts are bonded to a common PE conductor, as shown in {{FigureRef|F18}}.


{{FigImage|DB422230_EN|svg|F18|Circuit breaker tripping on double fault situation when exposed-conductive-parts are connected to a common protective conductor}}
=== Recommendation ===


In this case no earth electrodes are included in the fault current path, so that a high level of fault current is assured, and conventional overcurrent protective devices are used, i.e. circuit-breakers and fuses.
To take full benefit of the continuity of service on first-fault condition provided by the IT system:
* A permanent monitoring of the insulation to earth must be provided, coupled with an alarm signal (audio and/or flashing lights, etc.) operating in the event of a first earth fault (see {{FigRef|F35}})
* The location and repair of a first fault is imperative if the full benefits of the IT system are to be realized. Continuity of service is the great advantage afforded by the system. As continuity of service is provided, it is not mandatory to repair the fault immediately, avoiding to operate under stress and urgency.


The first fault could occur at the end of a circuit in a remote part of the installation, while the second fault could feasibly be located at the opposite end of the installation.
{{FigImage|PB116742|jpg|F35|Example of phase-to-earth Insulation Monitoring Device used in IT system}}


For this reason, it is conventional to double the loop impedance of a circuit, when calculating the anticipated fault setting level for its overcurrent protective device(s).
== Second fault situation ==


Where the system includes a neutral conductor in addition to the 3 phase conductors, the lowest short-circuit fault currents will occur if one of the (two) faults is from the neutral conductor to earth (all four conductors are insulated from earth in an IT scheme). In four-wire IT installations, therefore, the phase-to-neutral voltage must be used to calculate short-circuit protective levels i.e
The second fault results in a short-circuit between active conductors (phases or neutral) through the earth and/or through PE bonding conductors (unless occurring on the same conductor as the first fault). Overcurrent protective devices (fuses or circuit breakers) would normally operate an automatic fault clearance.


<math>0.8\frac{Uo}{2Zc}\ge Ia </math>{{fn|2}}
Particularities and limitations specific to IT system are given in [[IT system - Implementation of protections]].


where
Fault clearance is carried out differently in each of the following cases (see {{FigRef|F36}}):


{{def|Uo| phase to neutral voltage}}
{{FigImage|DB422231_EN|svg|F36|Two different situations to be considered}}


{{def|Zc| impedance of the circuit fault-current loop (see [[Automatic disconnection for TN systems]])}}
=== 1<sup>st</sup> case ===


{{def|Ia| current level for trip setting }}
It concerns an installation in which all exposed conductive parts are bonded to a common PE conductor, as shown in {{FigRef|F37}}.


If no neutral conductor is distributed, then the voltage to use for the fault-current calculation is the phase-to-phase value, i.e.
{{FigImage|DB422230_EN|svg|F37|Circuit breaker tripping on double fault situation when exposed-conductive-parts are connected to a common protective conductor}}


<math>0.8\frac{\sqrt{3}Uo}{2Zc}\ge Ia</math>{{fn|2}}
In this case, no earth electrodes are included in the fault current path, so that a high level of fault current is assured, and conventional overcurrent protective devices are used, i.e. circuit breakers and fuses.


* Maximum tripping times
To adjust the protective devices, the short-circuit current must be calculated, using one of the different methods applicable to TN system, as already presented in [[TN system - Earth-fault current calculation]]
Disconnecting times for IT system depends on how the different installation and substation earth electrodes are interconnected.
* Methods of impedance
* Method of composition
* Conventional method


For final circuits supplying electrical equipment with a rated current not exceeding 32 A and having their exposed-conductive-parts bonded with the substation earth electrode, the maximum tripping time is given in table F8. For the other circuits within the same group of interconnected exposed-conductive-parts, the maximum disconnecting time is 5s. This is due to the fact that any double fault situation within this group will result in a short-circuit current as in TN system.
The first fault could occur at the end of a circuit in a remote part of the installation, while the second fault could feasibly be located at the opposite end of the installation.


For final circuits supplying electrical equipment with a rated current not exceeding 32 A and having their exposed-conductive-parts connected to an independent earth electrode electrically separated from the substation earth electrode, the maximum tripping time is given in {{FigureRef|F13}}. For the other circuits within the same group of non interconnected exposed-conductive-parts, the maximum disconnecting time is 1s. This is due to the fact that any double fault situation resulting from one insulation fault within this group and another insulation fault from another group will generate a fault current limited by the different earth electrode resistances as in TT system.  
For this reason, it is conventional to double the loop impedance of a circuit, when calculating the anticipated fault setting level for its overcurrent protective device(s).


*Protection by circuit-breaker
Where the system includes a neutral conductor in addition to the 3 phase conductors, the lowest short-circuit fault currents will occur if one of the (two) faults is from the neutral conductor to earth (all four conductors are insulated from earth in an IT scheme). In four-wire IT installations, therefore, the phase-to-neutral voltage must be used to calculate short-circuit protective levels i.e. :
In the case shown in {{FigureRef|F18}}, the adjustments of instantaneous and short-time delay overcurrent trip unit must be decided. The times recommended here above can be readily complied with. The short-circuit protection provided by the NSX160 circuit-breaker is suitable to clear a phase to phase short-circuit occurring at the load ends of the circuits concerned.


Reminder: In an IT system, the two circuits involved in a phase to phase short-circuit are assumed to be of equal length, with the same cross sectional area conductors, the PE conductors being the same cross sectional area as the phase conductors. In such a case, the impedance of the circuit loop when using the [[TN system - Protection against indirect contact#Conventional method|Conventional method ]] will be twice that calculated for one of the circuits in the TN case, shown in Chapter [[Protection against electric shocks and electric fires]]
<math>0.8\,\frac{U_0}{2\,Z_c}\ge I_a </math>{{fn|2}}


The resistance of circuit loop <math>FGHJ = 2R_{JH}= 2\rho\frac{L}{a}</math> where:
where


{{def|ρ| resistance of copper rod 1 meter long of cross sectional area 1 mm<sup>2</sup>, in mΩ}}
{{def
|U<sub>0</sub>| phase to neutral voltage
|Z<sub>c</sub>| impedance of the circuit fault-current loop (see [[TN system - Principle]])
|I<sub>a</sub>| current level for trip setting }}


{{def|L| length of the circuit in meters}}
If no neutral conductor is distributed, then the voltage to use for the fault-current calculation is the phase-to-phase value, i.e.


{{def|a| cross sectional area of the conductor in mm<sup>2</sup> }}
<math>0.8\,\frac{\sqrt{3}\,U_0}{2\,Z_c}\ge I_a</math>{{fn|2}}


FGHJ = 2 x 23.7 x 50/35 = 67.7 mΩ and the loop resistance B, C, D, E, F, G, H, J will be 2 x 67.7 = 135 mΩ.
The settings of overcurrent tripping relays and the ratings of fuses are the basic parameters that decide the maximum practical length of circuit that can be satisfactorily protected, as discussed in [[TN system - Earth-fault current calculation]].


The fault current will therefore be <math>0.8\times \sqrt 3 \times 230 \times 10^3/135 = 2361 A</math>.  
'''Note:''' In normal circumstances, the fault current path is through common PE conductors, bonding all exposed conductive parts of an installation, and so the fault loop impedance is sufficiently low to ensure an adequate level of fault current.


*Protection by fuses
=== 2<sup>nd </sup> case ===
The current I<sub>a</sub> for which fuse operation must be assured in a time specified according to here above can be found from fuse operating curves, as described in {{FigureRef|F15}}.


The current indicated should be significantly lower than the fault currents calculated for the circuit concerned.  
It concerns '''exposed conductive parts which are earthed either individually''' (each part having its own earth electrode) '''or in separate groups''' (one electrode for each group). If all exposed conductive parts are not bonded to a common electrode system, then it is possible for the second earth fault to occur in a different group or in a separately earthed individual apparatus.


*Protection by Residual current circuit-breakers (RCCBs)
Rules of TT system apply.
For low values of short-circuit current, RCCBs are necessary. Protection against indirect contact hazards can be achieved then by using one RCCB for each circuit.  


=== 2<sup>nd</sup> case ===
Additional protection to that described above for case 1, is required, and consists of a RCD associated to the circuit breaker controlling each group and each individually-earthed apparatus.


*It concerns exposed conductive parts which are earthed either individually (each part having its own earth electrode) or in separate groups (one electrode for each group).
The reason for this requirement is that the separate-group electrodes are “bonded” through the earth so that the phase to phase short-circuit current will generally be limited when passing through the earth bond by the electrode contact resistances with the earth, thereby making protection by overcurrent devices unreliable.
If all exposed conductive parts are not bonded to a common electrode system, then it is possible for the second earth fault to occur in a different group or in a separately earthed individual apparatus. Additional protection to that described above for case 1, is required, and consists of a RCD placed at the circuit-breaker controlling each group and each individually-earthed apparatus.


The reason for this requirement is that the separate-group electrodes are “bonded” through the earth so that the phase to phase short-circuit current will generally be limited when passing through the earth bond by the electrode contact resistances with the earth, thereby making protection by overcurrent devices unreliable. The more sensitive RCDs are therefore necessary, but the operating current of the RCDs must evidently exceed that which occurs for a first fault (see {{FigRef|F19}}).
The more sensitive RCDs are therefore necessary, but the operating current of the RCDs must evidently exceed that which occurs for a first fault (see {{FigRef|F38}}).


{{TableStart|Tab1154|2col}}
{{tb-start|id=Tab1154|num=F38|title=Correspondence between the earth leakage capacitance and the first fault current|cols=2}}
{| class="wikitable"
|-
|-
! Leakage capacitance (µF)  
! Leakage capacitance (µF)  
Line 124: Line 128:
| 30  
| 30  
| 2.17
| 2.17
|-
|}
{{TableEnd|Tab1154|F19|Correspondence between the earth leakage capacitance and the first fault current
{{tb-notes
|| Note: 1 µF is the 1 km typical leakage capacitance for 4-conductor cable. }}
|txn1= Note: 1 µF is the 1 km typical leakage capacitance for 4-conductor cable. }}
 
For a second fault occurring within a group having a common earth-electrode system, the overcurrent protection operates, as described above for case 1.
 
'''Note 1''': See also [[Protection of the neutral conductor]].


'''Note 2''': In 3-phase 4-wire installations, protection against overcurrent in the neutral conductor is sometimes more conveniently achieved by using a ring-type current transformer over the single-core neutral conductor (see {{FigRef|F20}}).
'''Note 1:''' See also: [[Protection of the neutral conductor]].


{{FigImage|DB422231_EN|svg|F20|Application of RCDs when exposed-conductive-parts are earthed individually or by group on IT system}}
'''Note 2:''' In 3-phase 4-wire installations, protection against overcurrent in the neutral conductor is sometimes more conveniently achieved by using a ring-type current transformer over the single-core neutral conductor (see [[#Second fault situation|{{FigRef|F36}}]]).


{{footnotes}}
{{footnotes}}
Line 142: Line 142:
</references>
</references>


[[ru:Автоматическое отключение питания при втором замыкании в системе IT]]
[[fr:Protection contre les chocs et incendies électriques]]
[[zh:IT 系统内发生第二次故障时的自动切断电源]]
[[de:Schutz gegen elektrischen Schlag]]

Latest revision as of 09:49, 22 June 2022

First fault situation

In IT system, the first fault to earth should not cause any disconnection.

The earth-fault current which flows under a first-fault condition is measured in mA.

Two different examples of earth-fault current calculation are presented below .

Example 1

In the simplified circuit presented on Fig. F32, the neutral point of the power-supply source is connected to earth through a 1500 Ω resistance. The current through the earthing resistor will be 153 mA in case of a fault (on a 230/400 V 3-phase system). The fault voltage with respect to earth due to this current is the product of this current and the resistance of the PE conductor plus earthing resistor (from the faulted component to the electrode), which is negligible.

Fig. F32 – Simplified circuit

Example 2

For a network formed of 1 km of conductors as represented on Fig. F33, the leakage impedance to earth (≈ 1 μF / km) is represented by the capacitors C1 to CN. The capacitive impedance ZC is in the order of 3500 Ω per phase. In normal operation, the capacitive current[1] to earth is therefore:

[math]\displaystyle{ I_c= \frac{U_0}{Z_c}= \frac{230}{3500}=66\ mA }[/math] per phase.

Fig. F33 – Fault current path for a first fault in IT system

During a fault between phase 1 and earth as in Fig. F33, the voltage and current vectors can be represented as shown on Fig. F34.

The fault current passing through the electrode resistance RA is the vector sum of the currents:

  • Capacitive currents in the two healthy phases IC2 and IC3,
  • Capacitive current in the neutral ICN,
  • Current in the neutral impedance, Id1.
Fig. F34 – Vector representation of voltages and currents in case of fault between phase 1 and earth

The voltages of the healthy phases have (because of the fault) increased to √3 times the normal phase voltage, so that the capacitive currents increase by the same amount: IC2 = IC3 = IC.√3 = 66 x √3 = 114 mA

The neutral voltage is 230V, so the capacitive neutral current is: ICN = IC = 66 mA

These currents are displaced one from the other by 30°, so that the total vector addition Id2 amounts to:

[math]\displaystyle{ 2(I_c.\sqrt{3}).\frac{\sqrt{3}}{2} + I_c = 3.I_c + I_c = 4. I_c = 4 \times 66 = 264 mA }[/math]

e.g. for 3L+N circuits, the capacitive current to earth value increases by a factor of 4 during phase-to-earth fault, compared to its value in normal operation IC

The current Id1 through the neutral resistance is 153 mA (see simplified example above)

The current through the fault to earth is given by the vector sum of the neutral resistor current Id1 (= 153 mA) and the capacitive current Id2 (= 264 mA).

It is then equal to:

[math]\displaystyle{ \sqrt {153^2 + 263^2} = 304mA }[/math]

Considering for example an earthing resistance RA equal to 50 Ω, the fault voltage Uf is therefore equal to: 50 x 304 x 10-3 = 15.2 V, which is obviously harmless.

Recommendation

To take full benefit of the continuity of service on first-fault condition provided by the IT system:

  • A permanent monitoring of the insulation to earth must be provided, coupled with an alarm signal (audio and/or flashing lights, etc.) operating in the event of a first earth fault (see Fig. F35)
  • The location and repair of a first fault is imperative if the full benefits of the IT system are to be realized. Continuity of service is the great advantage afforded by the system. As continuity of service is provided, it is not mandatory to repair the fault immediately, avoiding to operate under stress and urgency.
Fig. F35 – Example of phase-to-earth Insulation Monitoring Device used in IT system

Second fault situation

The second fault results in a short-circuit between active conductors (phases or neutral) through the earth and/or through PE bonding conductors (unless occurring on the same conductor as the first fault). Overcurrent protective devices (fuses or circuit breakers) would normally operate an automatic fault clearance.

Particularities and limitations specific to IT system are given in IT system - Implementation of protections.

Fault clearance is carried out differently in each of the following cases (see Fig. F36):

Fig. F36 – Two different situations to be considered

1st case

It concerns an installation in which all exposed conductive parts are bonded to a common PE conductor, as shown in Fig. F37.

Fig. F37 – Circuit breaker tripping on double fault situation when exposed-conductive-parts are connected to a common protective conductor

In this case, no earth electrodes are included in the fault current path, so that a high level of fault current is assured, and conventional overcurrent protective devices are used, i.e. circuit breakers and fuses.

To adjust the protective devices, the short-circuit current must be calculated, using one of the different methods applicable to TN system, as already presented in TN system - Earth-fault current calculation

  • Methods of impedance
  • Method of composition
  • Conventional method

The first fault could occur at the end of a circuit in a remote part of the installation, while the second fault could feasibly be located at the opposite end of the installation.

For this reason, it is conventional to double the loop impedance of a circuit, when calculating the anticipated fault setting level for its overcurrent protective device(s).

Where the system includes a neutral conductor in addition to the 3 phase conductors, the lowest short-circuit fault currents will occur if one of the (two) faults is from the neutral conductor to earth (all four conductors are insulated from earth in an IT scheme). In four-wire IT installations, therefore, the phase-to-neutral voltage must be used to calculate short-circuit protective levels i.e. :

[math]\displaystyle{ 0.8\,\frac{U_0}{2\,Z_c}\ge I_a }[/math][2]

where

U0 = phase to neutral voltage
Zc = impedance of the circuit fault-current loop (see TN system - Principle)
Ia = current level for trip setting

If no neutral conductor is distributed, then the voltage to use for the fault-current calculation is the phase-to-phase value, i.e.

[math]\displaystyle{ 0.8\,\frac{\sqrt{3}\,U_0}{2\,Z_c}\ge I_a }[/math][2]

The settings of overcurrent tripping relays and the ratings of fuses are the basic parameters that decide the maximum practical length of circuit that can be satisfactorily protected, as discussed in TN system - Earth-fault current calculation.

Note: In normal circumstances, the fault current path is through common PE conductors, bonding all exposed conductive parts of an installation, and so the fault loop impedance is sufficiently low to ensure an adequate level of fault current.

2nd case

It concerns exposed conductive parts which are earthed either individually (each part having its own earth electrode) or in separate groups (one electrode for each group). If all exposed conductive parts are not bonded to a common electrode system, then it is possible for the second earth fault to occur in a different group or in a separately earthed individual apparatus.

Rules of TT system apply.

Additional protection to that described above for case 1, is required, and consists of a RCD associated to the circuit breaker controlling each group and each individually-earthed apparatus.

The reason for this requirement is that the separate-group electrodes are “bonded” through the earth so that the phase to phase short-circuit current will generally be limited when passing through the earth bond by the electrode contact resistances with the earth, thereby making protection by overcurrent devices unreliable.

The more sensitive RCDs are therefore necessary, but the operating current of the RCDs must evidently exceed that which occurs for a first fault (see Fig. F38).

Fig. F38 – Correspondence between the earth leakage capacitance and the first fault current
Leakage capacitance (µF) First fault current (A)
1 0.07
5 0.36
30 2.17
  • Note: 1 µF is the 1 km typical leakage capacitance for 4-conductor cable.

Note 1: See also: Protection of the neutral conductor.

Note 2: In 3-phase 4-wire installations, protection against overcurrent in the neutral conductor is sometimes more conveniently achieved by using a ring-type current transformer over the single-core neutral conductor (see Fig. F36).

Notes

  1. ^ Resistive leakage current to earth through the insulation is assumed to be negligibly small in the example.
  2. ^ 1 2 Based on the “conventional method” noted in the first example of section Conventional method
Share