Bicol University Civil Engineering Department Course Project - PDF

Summary

This document is a course project on engineering utilities, specifically building electrical service equipment and overcurrent protection. It covers the concepts, components, and types of fuses and circuit breakers within the context of building electrical systems. The document is intended for undergraduate students in civil engineering at Bicol University.

Full Transcript

BICOL UNIVERSITY
Legazpi East Campus
College of Engineering
CIVIL ENGINEERING DEPARTMENT

COURSE PROJECT IN
ENGINEERING UTILITIES 1
Building Electrical Service Equipment and Overcurrent
Protection Devices: Fuses and Breakers

PALACIO, ANTHONY JR. P.
SY, KISSY JEIREL D.
BSCE-3C

ENGR. HANA MYKA GATON-DULAY
COURSE INSTRUCTOR
 BICOL UNIVERSITY
Legazpi East Campus
College of Engineering
CIVIL ENGINEERING DEPARTMENT

CHAPTER 2: BUILDING ELECTRICAL SERVICE EQUIPMENT AND
OVERCURRENT PROTECTION: FUSES AND CIRCUIT BREAKERS

OVERVIEW:
This module will provide an understanding about the concept and components of
building service equipment that are utilized in the electrical system of a building, and
the crucial role of overcurrent protection, such as fuses and breakers, in ensuring the
safety and efficiency of power distribution in the building.

LEARNING OBJECTIVES:
By the end of this module, the students should be able to:
Know the components of building electrical service equipment
Understand the concept of overcurrent protection and its potential hazards
Differentiate the types of fuses and circuit breakers
Apply the knowledge in real-life application such as selecting appropriate
overcurrent protection devices based on electrical requirements

INTRODUCTION:
Electrical service equipment and overcurrent protection are essential
components in any building’s electrical system. Electrical service equipment serves as
the nervous system of a building, distributing electrical energy across different parts
of the building. These are the components installed in the building to manage
distribution, control and protection of electricity from the utility supply to the various
circuits within the building.
A crucial part of this system is the overcurrent protection. It refers to the
methods and devices used to protect electrical circuits and equipment from damage
caused by excessive current flow. Additionally, this protects the building from any
potential hazards caused by overcurrent such as fire and electric shock.
 BICOL UNIVERSITY
Legazpi East Campus
College of Engineering
CIVIL ENGINEERING DEPARTMENT

BUILDING ELECTRICAL SERVICE EQUIPMENT:
Electrical Service Equipment -is considered as the nervous system of a building. It
refers to the conductors and equipment responsible for the distribution of electric
energy from the serving utility to the wiring system of the premises served.

Building electrical service equipment includes:

1. Service Entrance Conductor- refers to the conductors that carry power from
the transformer through a metering device to the building’s service disconnects.

Types of Service Entrance Conductors:
a. Overhead Service Entrance Conductors (Service Drop):
The overhead wires that bring electricity from the utility pole to a
building. These wires run from the pole to a point on the building,
usually above the roof, where they connect to the building's
electrical system.
b. Underground Service Entrance Conductors (Service Lateral):
The underground cables that bring electricity from the utility’s
underground system to a building. These cables are buried in the
ground and connect to the building's electrical system, usually at
a meter or service panel.

Photo from: https://energyknowledgebase.com/
 BICOL UNIVERSITY
Legazpi East Campus
College of Engineering
CIVIL ENGINEERING DEPARTMENT

2. Service Entrance- This refers to the location
where the service entrance conductors
connect to the building’s electrical system. It
is the starting point for all electrical power that
comes into a building. Additionally, it includes
the components that connect the utility-
supplied wiring (the service lateral or service
drop) to the service disconnect, excluding the
utility’s metering equipment.
Photo from: https://home.howstuffworks.com/

▪ Service Entrance Equipment- receives the service entrance
conductors.
▪ Service Disconnect- part of service entrance equipment that allows
electrical service from the utility company to be switched off so that power
is disconnected to the building installation. It is a set of fuses or a circuit
breaker that protects the service entrance conductors.

3. Switchboard- is considered as the nerve centers of electrical systems, acting
as the primary distribution point for electrical power. It is responsible for
receiving electricity from the main power source and distributing it to various
circuits and devices throughout a building or facility.

Photo From: https://jaricgroup.com.au/
 BICOL UNIVERSITY
Legazpi East Campus
College of Engineering
CIVIL ENGINEERING DEPARTMENT

4. Panelboard- also known as distribution board or
breaker panel, serves as secondary distribution
points within electrical systems. It receives power
from the switchboard and further distributes it to
individual circuits, accommodating the specific
electrical requirements of different areas or
equipment. Panelboards feature circuit breakers
or fuses that protect circuits from overloads and
Photo From: https://ultrasteel.com.ph/
short circuits, safeguarding both electrical
equipment and human life.

5. Building Transformer - is a device used in
transmitting and distributing power from the power
plant to a substation. It is responsible for
increasing or decreasing the incoming voltage
from the utility provider to the levels required for
the building’s electrical system.

Photo From: https://daelim-
electric.com/

OVERCURRENT PROTECTION:
Overcurrent - occurs when the current in an electrical circuit exceeds the circuit’s
capacity, leading to potential hazards like overheating, fires, or equipment damage.
Common causes of overcurrent:
1. Short circuit- occurs when electrical conductors accidentally touch,
creating a path of very low resistance, leading to a surge of current.
2. Overload- happens when a circuit carries more current than it’s
designed for, typically due to too many devices or appliances operating
simultaneously.
 BICOL UNIVERSITY
Legazpi East Campus
College of Engineering
CIVIL ENGINEERING DEPARTMENT

Overcurrent Protection is crucial for electrical safety as it prevents excessive current
from flowing through electrical circuits, which could otherwise cause overheating, fires,
or damage to equipment. By detecting conditions short circuits and overloads,
overcurrent protection devices automatically interrupt the flow of electricity, mitigating
risks and ensuring the safety operation of electrical systems.

Tripping- refers to the automatic operation of an OCP device that interrupts the flow
of electrical current in a circuit when an abnormal condition occurs.

OVERCURRENT PROTECTIVE DEVICES:

Overcurrent protective devices are designed to safeguard circuits from excessive
currents that can lead to overheating, fires, or equipment damage. These devices
detect abnormal conditions, such as short circuits and/or overloads, that automatically
interrupt the flow of electricity to prevent potential hazards.

Fuses and circuit breakers serve as automatic overcurrent protection devices. They
are designed to open a circuit if the amount of current, in amps, that flows through the
circuit exceeds the OCP device rating.

1. Fuse- a protective device designed to prevent overcurrent in electrical circuits.
It consists of metal wire or strip that melts when the current exceeds a specific
threshold, breaking the circuit and interrupting the flow of electricity. This
process, known as blowing.

Types of Fuses:

a. Plug Fuse- is a round fuse which screw into a base
in the fuse holder to complete the circuit. It is used
primarily in residential and light commercial
electrical systems with low-voltage, low-current
circuits. The operating range is usually up to 150
volts and from 0.5 ampere to 30 amperes.
 BICOL UNIVERSITY
Legazpi East Campus
College of Engineering
CIVIL ENGINEERING DEPARTMENT

b. Cartridge Fuse- operates exactly like the plug-type
fuse. In the cartridge fuse, the fuse link is enclosed in
a tube of insulating material with metal ferrules at
each end (for contact with the fuse holder).
c. Fast-acting fuse (quick-blow fuse)- is a type of
fuse designed to interrupt the electrical circuit
almost immediately when the current exceeds its
rated capacity. It provides rapid protection for
sensitive electronic components and circuits that
cannot tolerate even short-duration overcurrent
conditions.
d. Time-Delay Fuse (Slow-Blow Fuse) - is designed
to tolerate short bursts of overcurrent, such as
inrush currents, without blowing immediately. This
feature makes time-delay fuses suitable for circuits
where temporary current spikes are normal, such
as those with inductive loads.
e. Resettable Fuses/ Positive Temperature
Coefficient (PTC) Fuses - are designed to protect
electrical circuits by automatically resetting after an
overcurrent condition has cleared, offering a
reusable option compared to traditional single-use
fuses.

2. Circuit Breaker- is an electrical device that automatically interrupts the flow of
current in a circuit when an abnormal condition, such as an overload or short
circuit, is detected. They operate using an internal mechanism that senses the
fault and trips the breaker, cutting off the electrical supply to prevent damage
to the circuit and connected devices. Unlike fuses, circuit breakers can be reset
manually after tripping, allowing the circuit to return to normal operation.
 BICOL UNIVERSITY
Legazpi East Campus
College of Engineering
CIVIL ENGINEERING DEPARTMENT

Common Types of Circuit Breakers:

a. Miniature Circuit Breaker (MCB) - designed for low
voltage applications, MCBs protect against
overloads and short circuits in residential and light
commercial settings. They have a fixed trip setting,
making them suitable for consistent load conditions.
b. Molded Case Circuit Breaker (MCC)- used in
higher current applications than MCBs. MCCBs offer
adjustable trip settings and are common in industrial
environments. They provide protection against
overloads, short circuits and in some cases ground
faults.
c. Residual Current Device (RCD) / Residual
Current Circuit Breaker (RCCB) - This device
detects and disconnects circuits when it senses a
leakage current (earth fault), preventing electric
shocks. RCDs are essential in applications when
direct human contact with electrical components is
a risk.
d. Air Circuit Breaker (ACB)- Used primarily in high-
current industrial applications, ACBs operate by
interrupting the circuit using air as the arc
extinguishing medium. They are typically employed
in the main power distribution of large buildings and
industrial plants.
 BICOL UNIVERSITY
Legazpi East Campus
College of Engineering
CIVIL ENGINEERING DEPARTMENT

e. it protects electrical power stations and
distribution systems by interrupting electric
currents, when tripped by a protective relay.
SF6 (sulfur hexafluoride) gas is commonly
used as an insulating medium in high-
voltage circuit breakers and other electrical
equipment.

FACTORS TO CONSIDER WHEN SELECTING FUSE AND CIRCUIT BREAKER:

1. Current Rating- also known as ampacity or ampere rating, determines the
maximum current the fuse can handle without blowing, providing protection for
electrical components from overcurrent conditions. Overrating or underrating
the fuse or breaker can lead to either tripping or failure to protect the circuit.
2. Voltage Rating- it indicates the maximum voltage the fuse can safely interrupt
without breaking down. A fuse or circuit breaker with a voltage rating lower than
the circuit voltage may fail to open properly during a fault. The voltage rating
should be equal to or greater than the maximum voltage present in the circuit.
3. Interrupting Capacity- also known as breaking capacity is the maximum
current which the fuse can safely break or interrupt at rated voltage. It is
essential to ensure that the fuse's breaking capacity is higher than the potential
short-circuit current of the circuit.
4. Operating Environment- when selecting an OCP device, it is important to
consider the operating environment, such as temperature, humidity, corrosive
atmospheres, and potential exposure to chemicals or dust. Certain fuses and
breakers are designed for specific environmental conditions.
5. Response Time- is the time it takes to blow and interrupt the current once an
overcurrent condition occurs. Fuses come in various types, such as fast-acting
(quick-blow) and time-delay (slow-blow). The selection depends on the
sensitivity of the circuit and the nature of the load. Fast-acting fuses protect
 BICOL UNIVERSITY
Legazpi East Campus
College of Engineering
CIVIL ENGINEERING DEPARTMENT

6. sensitive components, while time-delay fuses handle inrush currents without
blowing.
7. Standards and Approvals- The fuse should meet the required safety
standards and approvals (e.g. Philippine Electrical Code (PEC) and
International Electrical Code (IEC) for the application and region in which it will
be used.
8. Types of Loads- different types of electrical loads have unique characteristics
that affect how current flows through a circuit. Understanding the type of load
helps in choosing the appropriate protective devices that provide effective
protection.
Resistive Loads: These loads, such as incandescent lighting and
heating elements, have a consistent current draw without significant
inrush. For these loads, standard fuses or circuit breakers with
appropriate current ratings can be used.
Inductive Loads: Loads like motors, transformers, and inductors draw
higher currents when first energized, known as inrush current, which can
be 5 to 10 times the normal operating current. Time-delay fuses or
breakers are often required to handle the inrush without tripping
unnecessarily.
Capacitive Loads: These loads, such as power factor correction
capacitors and certain electronic devices, may also exhibit inrush
currents, though their characteristics differ from inductive loads.
 BICOL UNIVERSITY
Legazpi East Campus
College of Engineering
CIVIL ENGINEERING DEPARTMENT

References:
What are Overcurrent Protection Devices? (2021, February 10). Retrieved September
3, 2024, from https://eepower.com/technical-articles/what-are-overcurrent-protection-
devices/
Service conductor · Energy KnowledgeBase. (n.d.).
https://energyknowledgebase.com/topics/service-conductor.asp

Different Types of Fuses and their Applications. (n.d.). Components101.
https://components101.com/articles/different-types-of-fuses-and-their-applications

AllumiaX LLC. (2020b, October 2). How to select the right fuse for power systems
protection. https://www.allumiax.com/blog/how-to-select-the-right-fuse-for-power-
systems-protection

Limited, C. E. (2023, September 20). Circuit Breaker Types and Applications - C&S
Electric. C&S Electric Blog. https://cselectric.co.in/blog/everything-need-know-circuit-
breakers-introduction-applications-types/

PLUG-TYPE FUSE. (n.d.). https://electriciantraining.tpub.com/14175/css/Plug-Type-
Fuse-92.htm