Distribution board is a safe system designed for house or building that included protective devices, isolator switches, circuit breaker and fuses to connect safely the cables and wires to the sub circuits and final sub circuits including their associated Live (Phase) Neutral and Earth conductors. Distribution board is also known as “Fuse Board“, “Panel Board” or “Consumer Unit“. following are the types of Distribution boards.
Related Wiring Tutorial: Wiring of the Distribution Board (Single Phase Supply From Utility Pole & Energy Meter to the Consumer Unit)
Types of Distribution Boards
Main Distribution Board (MDB)
Sub Distribution Board (SDB)
Final Distribution Board (FDB)
MDB = Main Distribution Board
A distribution board unit installed in the buildings which firstly receive the incoming single phase electric supply (AC low voltage (LV) (230V AC or 120V AC in US) from transformer secondary through electric pole and energy meter or the distribution company’s electric service provider outlets is known as Main Distribution Board.
Main Distribution Board (MDB) is also known as Fuse board or consumer unit where the main protective and isolation devices are installed to provide electricity in a safe range to the connected electrical appliances.
The Distribution Board which is used to distribute electrical wiring and circuits within a selected area in a building or house, i.e. floor in a multi storey building. The Sub distribution board is connected and supplied from the Main Distribution Board through different wires and cables rated according to the load requirement.
FDB = Final Distribution Board
The Distribution Board which provide electric supply to the Final and Sub Final Circuits is known as Final Distribution Board. FDB (Final Distribution Board) directly connected through SDB (Sub Distribution Board) and the final switches are used to control the connected electrical devices and appliances such as light, air-conditioner, fan etc.
Wiring Accessories for Single Phase Distribution Board
Main Distribution Board or Fuse Boards (Consumer Unit) usually contains on the following three main units to control and distribute electric supply to the different connected appliances and devices through electrical wiring cables and wires.
In this Single Phase home supply wiring diagram, the main supply (Single Phase Live (Red Wire) and Neutral (Black Wire) comes from the secondary of the transformer (3 Phase 4 Wire (Star) System) to the single phase energy meter (Note that Single Phase supply is 230V AC and 120V AC in US). These two lines (Line and Neutral) from energy meter are connected to the Double Pole MCB isolator switch. They Live Wire is connected to the RCD and then to the common busbar segment of Single Pole MCBs. The outgoing lines from MCBS (SP) are connected to the final circuits and sub final circuit and electrical devices like fan, lights, switches etc.
The Neutral are connected through Energy meter, MCB (DP), RCD and then to the Neutral Link. All the sub circuits, sub circuits can be connected to the Neutral Link. Keep in mind all the electrical devices and appliances should be connected to the Earth Link for safety which is directly connected to the earth electrode and earth plate for proper earthing and grounding.
In the following single phase electrical wiring for home supply, We used 63A MCB (DP), 63A RCD (DP) and different rating if MCBs (SP) such as 20A, 16A, 10A etc according to your need.
Below is the given wiring diagram of Single Phase Distribution Board with RCD in both NEC and IEC electrical wiring color codes. The same description and detailes can be used as mentioned for the above fig 1.
This is the main operating switch which is used to control the electric power supply in the building(s). The main switch can be used to immediately turn ON or OFF the main electric supply to the connected appliances in case of emergency like short circuits, electric shock, fire, or while working on the main board, sub circuit or final sub circuits to troubleshoot and for maintenance purposes. Multiple or separate mains switch board or fuse board may be used if more supply unites are installed in the system i.e. storage heater etc.A (RCD) Residual-Current Device, or (RCCB) Residual-Current Circuit Breaker, is an electrical wiring device or switch that disconnects or trip a circuit whenever it detects that the electric current is not balanced between the energized conductor (L) and the return neutral conductor (N). And then instantly disconnect the electricity flow in the connected circuits by operating in the safe mode automatically to avoid electric hazards.
Related Wiring Tutorial: Staircase Wiring Circuit Diagram – How to Control a Lamp from 2 Places by 2-Way Switches?
CB (SP) = Single Pole Circuit Breakers
Circuit Breaker is a device like a fuse which makes and breaks the circuit. In other words, Circuit Breaker is a device which switch ON and OFF electric sup
ply at normal and abnormal condition respectively. These are automatic protection devices in the Main Switch Board or Fuse-Box that switch off a circuit if they detect a fault. Circuit Breaker may be Single Pole (SP), DP-Double Pole (DP) and Triple Pole (TP). The size of the fuse and Circuit Breaker are similar to use, but Circuit Breaker is more safe to use as compared to fuses due to automatic operation as you can reset it again if it trips ever.
Before we start, its recommended to read the article about proper selection & different types of solar panels and photovoltaic panel for home & commercial use as well. To the point, lets know how to wire and install a solar panel system according to the proper calculation and load requirements.
Suppose, we are going to install a solar power system in our home for a total load of 800W where the required backup time of battery is 3 hours (You may use it your own as it is just for sample calculation)
If the number of batteries are given, and you want to know the Backup Time for these given batteries, then use this formula to calculate the backup hours of batteries.1200 Wh x 2 Batteries = 2400 Wh
2400 Wh / 800 W = 3 hours.
In the first scenario, we will use 12V inverter system, therefore, we will have to connect two (2) batteries (each of 12V, 100 Ah) in Parallel. But a question raised below:
Related Post: What are the Blocking Diode and Bypass Diodes in a Solar Panel Junction Box?
Series or Parallel Connection for Batteries
Why Batteries in Parallel, not in Series?
Because this is a 12V inverter System, so if we connect these batteries in series instead of parallel, then the rating of batteries become V1 + V2 = 12V + 12V = 24V while the current rating would be same i.e.100Ah.
That’s why we will connect the batteries in parallel, because the Voltage of batteries (12 V) remains same, while its Ah (Ampere Hour) rating will be increased. i.e. the system would become = 12V and 100Ah +100Ah = 200Ah.
For example, for a single 12V, 100Ah battery, The charging time would be:
T = Ah / A = 100Ah / 10A = 10 Hrs (Ideal Case)
due to some losses, (it has been noted that 40% of losses occurred during the battery charging), this way, we take 10-12 A charging current instead of 10 A, this way, the charging time required for a 12V, 100Ah battery would be:
100Ah x ( 40/100 ) = 40 (100Ah x 40% of losses)
the battery rating would be 100Ah + 40 Ah = 140 Ah (100Ah + losses)
Now the required charging current for the battery would be:
140Ah / 12A = 11.6 Hours.
Required No of Solar Panels (Series or Parallel) ?
Distribution board is a safe system designed for house or building that included protective devices, isolator switches, circuit breaker and fuses to connect safely the cables and wires to the sub circuits and final sub circuits including their associated Live (Phase) Neutral and Earth conductors. Distribution board is also known as “Fuse Board“, “Panel Board” or “Consumer Unit“. following are the types of Distribution boards.
Related Wiring Tutorial: Wiring of the Distribution Board (Single Phase Supply From Utility Pole & Energy Meter to the Consumer Unit)
Types of Distribution Boards
Main Distribution Board (MDB)
Sub Distribution Board (SDB)
Final Distribution Board (FDB)
MDB = Main Distribution Board
A distribution board unit installed in the buildings which firstly receive the incoming single phase electric supply (AC low voltage (LV) (230V AC or 120V AC in US) from transformer secondary through electric pole and energy meter or the distribution company’s electric service provider outlets is known as Main Distribution Board.
Main Distribution Board (MDB) is also known as Fuse board or consumer unit where the main protective and isolation devices are installed to provide electricity in a safe range to the connected electrical appliances.
The Distribution Board which is used to distribute electrical wiring and circuits within a selected area in a building or house, i.e. floor in a multi storey building. The Sub distribution board is connected and supplied from the Main Distribution Board through different wires and cables rated according to the load requirement.
FDB = Final Distribution Board
The Distribution Board which provide electric supply to the Final and Sub Final Circuits is known as Final Distribution Board. FDB (Final Distribution Board) directly connected through SDB (Sub Distribution Board) and the final switches are used to control the connected electrical devices and appliances such as light, air-conditioner, fan etc.
Wiring Accessories for Single Phase Distribution Board
Main Distribution Board or Fuse Boards (Consumer Unit) usually contains on the following three main units to control and distribute electric supply to the different connected appliances and devices through electrical wiring cables and wires.
In this Single Phase home supply wiring diagram, the main supply (Single Phase Live (Red Wire) and Neutral (Black Wire) comes from the secondary of the transformer (3 Phase 4 Wire (Star) System) to the single phase energy meter (Note that Single Phase supply is 230V AC and 120V AC in US). These two lines (Line and Neutral) from energy meter are connected to the Double Pole MCB isolator switch. They Live Wire is connected to the RCD and then to the common busbar segment of Single Pole MCBs. The outgoing lines from MCBS (SP) are connected to the final circuits and sub final circuit and electrical devices like fan, lights, switches etc.
The Neutral are connected through Energy meter, MCB (DP), RCD and then to the Neutral Link. All the sub circuits, sub circuits can be connected to the Neutral Link. Keep in mind all the electrical devices and appliances should be connected to the Earth Link for safety which is directly connected to the earth electrode and earth plate for proper earthing and grounding.
In the following single phase electrical wiring for home supply, We used 63A MCB (DP), 63A RCD (DP) and different rating if MCBs (SP) such as 20A, 16A, 10A etc according to your need.
Below is the given wiring diagram of Single Phase Distribution Board with RCD in both NEC and IEC electrical wiring color codes. The same description and detailes can be used as mentioned for the above fig 1.
This is the main operating switch which is used to control the electric power supply in the building(s). The main switch can be used to immediately turn ON or OFF the main electric supply to the connected appliances in case of emergency like short circuits, electric shock, fire, or while working on the main board, sub circuit or final sub circuits to troubleshoot and for maintenance purposes. Multiple or separate mains switch board or fuse board may be used if more supply unites are installed in the system i.e. storage heater etc.A (RCD) Residual-Current Device, or (RCCB) Residual-Current Circuit Breaker, is an electrical wiring device or switch that disconnects or trip a circuit whenever it detects that the electric current is not balanced between the energized conductor (L) and the return neutral conductor (N). And then instantly disconnect the electricity flow in the connected circuits by operating in the safe mode automatically to avoid electric hazards.
Related Wiring Tutorial: Staircase Wiring Circuit Diagram – How to Control a Lamp from 2 Places by 2-Way Switches?
CB (SP) = Single Pole Circuit Breakers
Circuit Breaker is a device like a fuse which makes and breaks the circuit. In other words, Circuit Breaker is a device which switch ON and OFF electric sup
ply at normal and abnormal condition respectively. These are automatic protection devices in the Main Switch Board or Fuse-Box that switch off a circuit if they detect a fault. Circuit Breaker may be Single Pole (SP), DP-Double Pole (DP) and Triple Pole (TP). The size of the fuse and Circuit Breaker are similar to use, but Circuit Breaker is more safe to use as compared to fuses due to automatic operation as you can reset it again if it trips ever.
Before we start, its recommended to read the article about proper selection & different types of solar panels and photovoltaic panel for home & commercial use as well. To the point, lets know how to wire and install a solar panel system according to the proper calculation and load requirements.
Suppose, we are going to install a solar power system in our home for a total load of 800W where the required backup time of battery is 3 hours (You may use it your own as it is just for sample calculation)
If the number of batteries are given, and you want to know the Backup Time for these given batteries, then use this formula to calculate the backup hours of batteries.1200 Wh x 2 Batteries = 2400 Wh
2400 Wh / 800 W = 3 hours.
In the first scenario, we will use 12V inverter system, therefore, we will have to connect two (2) batteries (each of 12V, 100 Ah) in Parallel. But a question raised below:
Related Post: What are the Blocking Diode and Bypass Diodes in a Solar Panel Junction Box?
Series or Parallel Connection for Batteries
Why Batteries in Parallel, not in Series?
Because this is a 12V inverter System, so if we connect these batteries in series instead of parallel, then the rating of batteries become V1 + V2 = 12V + 12V = 24V while the current rating would be same i.e.100Ah.
That’s why we will connect the batteries in parallel, because the Voltage of batteries (12 V) remains same, while its Ah (Ampere Hour) rating will be increased. i.e. the system would become = 12V and 100Ah +100Ah = 200Ah.
For example, for a single 12V, 100Ah battery, The charging time would be:
T = Ah / A = 100Ah / 10A = 10 Hrs (Ideal Case)
due to some losses, (it has been noted that 40% of losses occurred during the battery charging), this way, we take 10-12 A charging current instead of 10 A, this way, the charging time required for a 12V, 100Ah battery would be:
100Ah x ( 40/100 ) = 40 (100Ah x 40% of losses)
the battery rating would be 100Ah + 40 Ah = 140 Ah (100Ah + losses)
Now the required charging current for the battery would be:
140Ah / 12A = 11.6 Hours.
Required No of Solar Panels (Series or Parallel) ?
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