Texas Administrative Code
Title 19 - EDUCATION
Part 2 - TEXAS EDUCATION AGENCY
Chapter 130 - TEXAS ESSENTIAL KNOWLEDGE AND SKILLS FOR CAREER AND TECHNICAL EDUCATION
Subchapter B - ARCHITECTURE AND CONSTRUCTION
Section 130.58 - Electrical Technology II (Two Credits)
Universal Citation: 19 TX Admin Code ยง 130.58
Current through Reg. 49, No. 38; September 20, 2024
(a) General requirements. This course is recommended for students in Grades 11 and 12. Prerequisite: Electrical Technology I. Recommended prerequisite: Principles of Architecture or Principles of Construction. Students shall be awarded two credits for successful completion of this course.
(b) Introduction.
(1) Career and technical education
instruction provides content aligned with challenging academic standards and
relevant technical knowledge and skills for students to further their education
and succeed in current or emerging professions.
(2) The Architecture and Construction Career
Cluster focuses on designing, planning, managing, building, and maintaining the
built environment.
(3) In
Electrical Technology II, students will gain advanced knowledge and skills
needed to enter the workforce as an electrician, a building maintenance
technician, or a supervisor; prepare for a postsecondary degree in a specified
field of construction or construction management; or pursue an approved
apprenticeship program. Students will acquire knowledge and skills in safety,
electrical theory, tools, codes, installation of electrical equipment,
alternating current and direct current motors, conductor installation,
installation of electrical services, and electric lighting
installation.
(4) Students are
encouraged to participate in extended learning experiences such as career and
technical student organizations and other leadership or extracurricular
organizations.
(5) Statements that
contain the word "including" reference content that must be mastered, while
those containing the phrase "such as" are intended as possible illustrative
examples.
(c) Knowledge and skills.
(1) The student demonstrates
professional standards/employability skills as required by business and
industry. The student is expected to:
(A)
identify job opportunities with their accompanying job duties such as
electrician, building maintenance technician, manager, and electrical engineer;
and
(B) research careers along with
the education, job skills, and experience required to achieve a career
goal.
(2) The student
knows the issues associated with electrical hazards found on a jobsite. The
student is expected to:
(A) demonstrate safe
working procedures in a construction environment;
(B) explain the purpose of the Occupational
Safety and Health Administration (OSHA) and how it promotes safety on the
job;
(C) identify electrical
hazards and how to avoid or minimize them in the workplace; and
(D) explain safety issues concerning lockout
and tagout procedures, personal protection using assured grounding and
isolation programs, confined space entry, respiratory protection, and fall
protection.
(3) The
student gains knowledge of alternating current and direct current motors with
specific attention being given to main parts, circuits, and connections. The
student is expected to:
(A) define terms such
as ampacity, branch circuit, circuit breaker, controller, duty, full-load amps,
ground fault circuit interrupter, interrupting rating, motor circuit switch,
thermal protector, National Electrical Manufacturers Association design letter,
non-automatic, overcurrent, overload, rated full-load speed, rated horsepower,
remote control circuit, service factor, and thermal cutout;
(B) describe the various types of motor
enclosures;
(C) describe how the
rated voltage of a motor differs from the system voltage;
(D) describe the basic construction and
components of a three-phase squirrel cage induction motor;
(E) explain the relationships among speed,
frequency, and the number of poles in a three-phase induction motor;
(F) describe how torque is developed in an
induction motor;
(G) explain how
and why torque varies with rotor reactance and slip;
(H) define percent slip and speed
regulation;
(I) explain how the
direction of a three-phase motor is reversed;
(J) describe the component parts and
operating characteristics of a three-phase wound-rotor induction
motor;
(K) define torque, starting
current, and armature reaction as they apply to direct current
motors;
(L) explain how the
direction of rotation of a direct current motor is changed;
(M) describe the design and characteristics
of direct current shunt, series, and compound motors;
(N) describe dual-voltage motors and their
applications;
(O) describe the
methods for determining various motor connections; and
(P) describe general motor protection
requirements as delineated by the National Electrical Code.
(4) The student learns the purpose
for grounding and bonding electrical systems. The student is expected to:
(A) explain the purpose of grounding and the
scope of the National Electrical Code;
(B) distinguish between a short circuit and a
ground fault;
(C) define the
National Electrical Code ground-related terms;
(D) distinguish between system grounding and
equipment grounding;
(E) use the
National Electrical Code to size the grounding electrode conductor for various
alternating current systems;
(F)
explain the National Electrical Code requirements for the installation and
physical protection of grounding electrode conductors;
(G) explain the function of the grounding
electrode system and determine which grounding electrodes must be
used;
(H) define electrodes and
explain the resistance requirements for electrodes using the National
Electrical Code;
(I) use the
National Electrical Code to size the equipment grounding conductor for raceways
and equipment;
(J) explain the
function of the main bonding jumper and system bonding jumpers in the grounding
system and size the bonding jumpers for various applications;
(K) size the main bonding jumper for a
service using multiple service disconnecting means;
(L) explain the National Electrical Code
requirements for bonding of enclosures and equipment;
(M) explain effective grounding and its
importance in clearing ground faults and short circuits;
(N) explain the purposes of the grounded
conductor neutral in operation of overcurrent devices;
(O) explain the National Electrical Code
requirements for grounding separately derived systems, including transformers
and generators;
(P) explain the
National Electrical Code requirements for grounding at more than one building;
and
(Q) explain the National
Electrical Code grounding requirements for systems over 600 volts.
(5) The student properly bends all
sizes of conduit up to six inches. The student is expected to:
(A) describe the process of conduit bending
using power tools;
(B) identify all
parts of popular electric and hydraulic benders;
(C) avoid excessive waste when working with
conduit systems;
(D) bend offsets,
kicks, saddles, and segmented and parallel bends;
(E) explain the requirements for the National
Electrical Code for bending conduit;
(F) compute the radius, degrees in bend,
developed length, and gain for conduit up to six inches; and
(G) explain how to correct damaged conduit
and modify existing bends.
(6) The student learns to select and size
outlet boxes, pull boxes, and junction boxes. The student is expected to:
(A) describe the different types of
nonmetallic and metallic boxes;
(B)
calculate the required box size for any number and size of
conductors;
(C) explain the
National Electrical Code regulations for volume required per conductor in
outlet boxes;
(D) locate, install,
and support boxes of all types;
(E)
describe the National Electrical Code regulations governing pull and junction
boxes;
(F) explain the radius rule
when installing conductors in pull boxes;
(G) understand the National Electrical Code
requirements for boxes supporting lighting fixtures;
(H) describe the purpose of conduit bodies
and Type FS boxes;
(I) install the
different types of fittings used in conjunction with boxes;
(J) describe the installation rules for boxes
and fittings in hazardous areas;
(K) explain how boxes and fittings are
selected and installed; and
(L)
describe the various types of box supports.
(7) The student knows transportation,
storage, and setup of cable reels, methods of rigging, and procedures to
complete cable pulls in raceways and cable trays. The student is expected to:
(A) describe the various methods of
installing conductors in conduit;
(B) plan and set up for a cable
pull;
(C) describe how cable reels
are transported to the pulling site;
(D) set up reel stands and spindles for a
wire-pulling installation;
(E)
explain how mandrels, swabs, and brushes are used to prepare conduit for
conductors;
(F) install a pull line
for a cable-pulling operation;
(G)
explain the operation of power fish tape systems;
(H) prepare the ends of conductors for
pulling;
(I) describe the types of
cable pullers;
(J) describe the
process of high-force cable pulling;
(K) explain how to support conductors in
vertical conduit runs;
(L) describe
the installation of cables in cable trays;
(M) explain the importance of communication
during a cable-pulling operation; and
(N) calculate the probable stress or tension
in cable pulls.
(8) The
student installs cable trays and modifies cable trays and cable. The student is
expected to:
(A) describe the components that
make up a cable tray assembly;
(B)
explain the methods used to hang and secure a cable tray;
(C) describe how cable enters and exits cable
trays;
(D) select the proper cable
tray fitting for the situation;
(E)
explain the National Electrical Manufacturers Association standards for cable
tray installations;
(F) explain the
National Electrical Code requirements for cable tray installations;
(G) select the required fittings to ensure
equipment grounding continuity in cable tray systems;
(H) interpret electrical working drawings
showing cable tray fittings;
(I)
size a cable tray for the number and type of conductors contained in the
system;
(J) select rollers and
sheaves for pulling cable in specific cable tray situations; and
(K) designate the required locations of
rollers and sheaves for a specific cable pull.
(9) The student knows the methods of
terminating and splicing conductors of all types and sizes and the preparation
and taping of conductors. The student is expected to:
(A) describe how to make a good conductor
termination;
(B) prepare cable ends
for terminations and splices;
(C)
install lugs and connector onto conductors;
(D) train cable at termination
points;
(E) explain the role of the
National Electrical Code in making cable terminations and splices;
(F) explain why mechanical stress should be
avoided at cable termination points;
(G) describe the importance of using proper
bolt torque when bolting lugs onto bus bars;
(H) describe crimping techniques;
(I) select the proper lug or connector for
the job;
(J) describe splicing
techniques; and
(K) explain how to
use hand and power crimping tools.
(10) The student installs single- and
three-phase services, including metering equipment. The student is expected to:
(A) describe various types of electric
services for commercial and industrial installations;
(B) read electrical drawings and diagrams
describing service installation;
(C) calculate and select service-entrance
equipment;
(D) explain the role of
the National Electrical Code in service installations;
(E) install main disconnect switches, panel
boards, and overcurrent protection devices;
(F) identify the circuit loads, number of
circuits required, and installation requirements for distribution
panels;
(G) explain the types and
purposes of service grounding;
(H)
explain the purpose and required locations of ground fault circuit
interrupters;
(I) describe
single-phase service connections; and
(J) describe both wye-phase and
delta-connected three-phase services.
(11) The student knows the practical
application of fuses and circuit breakers. The student is expected to:
(A) explain the necessity of overcurrent
protection devices in electrical circuits;
(B) define the terms associated with fuses
and circuit breakers;
(C) describe
the operation of a circuit breaker;
(D) select the most suitable overcurrent
device for the application;
(E)
describe the operation of single-element and time-delay fuses;
(F) explain how ground fault circuit
interrupters can save lives;
(G)
calculate short circuit currents; and
(H) describe troubleshooting and maintenance
techniques for overcurrent devices.
(12) The student knows the practical
applications of contactors and relays. The student is expected to:
(A) describe the operating principles of
contactors and relays;
(B) select
contactors and relays for use in specific electrical systems;
(C) explain how mechanical contactors
operate;
(D) explain how
solid-state contactors operate;
(E)
install contactors and relays according to National Electrical Code
requirements;
(F) select and
install contactors and relays for lighting control;
(G) describe how overload relays
operate;
(H) connect a simple
control circuit; and
(I) test
control circuits.
(13)
The student learns the basic principles of human vision and the characteristics
of light. The student is expected to:
(A)
explain how the human eye works;
(B) describe the characteristics of
light;
(C) recognize the different
kinds of lamps and explain the advantages and disadvantages of each type,
including incandescent, halogen, fluorescent, and high-intensity
discharge;
(D) select and install
lamps into lighting fixtures; and
(E) recognize and install various types of
lighting fixtures, including surface mounted, recessed, suspended, and
track-mounted units.
Disclaimer: These regulations may not be the most recent version. Texas may have more current or accurate information. We make no warranties or guarantees about the accuracy, completeness, or adequacy of the information contained on this site or the information linked to on the state site. Please check official sources.
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