Technology Project Report: Client Research Challenge
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This technology project report focuses on the three possible sections of fire technologies, immediate warning, and immediate suppression of fires that needs improvement for the development. The report includes available fire technologies, operational and cost requirements of new technologies, and additional factors for consideration. Subject: Technology, Course Code: NA, Course Name: NA, College/University: NA
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Running head: TECHNOLOGY PROJECT REPORT
Technology Project Report: Client Research Challenge
Name of the Student:
Student ID:
Name of the University:
Author’s note:
Technology Project Report: Client Research Challenge
Name of the Student:
Student ID:
Name of the University:
Author’s note:
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1TECHNOLOGY PROJECT REPORT
Table of Contents
Introduction......................................................................................................................................2
Section 1: Fire Technologies (after an incident occurs)..................................................................2
1.1 Available Fire Technologies..................................................................................................2
1.2 Operational and Cost requirements of new technologies......................................................4
1.3 Additional Factors for Consideration....................................................................................6
Section 2: Immediate Warning........................................................................................................6
2.1 Available Fire Technologies..................................................................................................6
2.2 Operational and Cost requirements of new technologies......................................................7
2.3 Additional Factors for Consideration....................................................................................9
Section 3: Immediate Suppression of fires in confined spaces (in structures)................................9
3.1 Available Fire Technologies..................................................................................................9
3.2 Operational and Cost requirements of new technologies....................................................10
2.3 Additional Factors for Consideration..................................................................................12
Conclusion.....................................................................................................................................12
References......................................................................................................................................13
Table of Contents
Introduction......................................................................................................................................2
Section 1: Fire Technologies (after an incident occurs)..................................................................2
1.1 Available Fire Technologies..................................................................................................2
1.2 Operational and Cost requirements of new technologies......................................................4
1.3 Additional Factors for Consideration....................................................................................6
Section 2: Immediate Warning........................................................................................................6
2.1 Available Fire Technologies..................................................................................................6
2.2 Operational and Cost requirements of new technologies......................................................7
2.3 Additional Factors for Consideration....................................................................................9
Section 3: Immediate Suppression of fires in confined spaces (in structures)................................9
3.1 Available Fire Technologies..................................................................................................9
3.2 Operational and Cost requirements of new technologies....................................................10
2.3 Additional Factors for Consideration..................................................................................12
Conclusion.....................................................................................................................................12
References......................................................................................................................................13
2TECHNOLOGY PROJECT REPORT
Introduction
The inclusion of the project management technologies would be helpful for easing the
simplification of the activities defining the implication of the improved communication
formation (Alkhatib 2014). The completion of the effective influence of the activities would be
aligned for developing the influence of the innovative technology and development. The Country
Fire Authority (CFA) is responsible for keeping out fire and provides support by improving their
technologies. The development of the factors aligning the utilization of the innovation has been
done for evolving the inclusion of the successive development.
The following assignment has been developed for easing the implication of the factors
defining the utilization of the activities. The support and development of the technology is
developed for aligning the support and development via improved functional development. The
assignment would provide a highlight of the three possible sections of fire technologies,
immediate warning, and immediate suppression of fires that needs improvement for the
development.
Section 1: Fire Technologies (after an incident occurs)
1.1 Available Fire Technologies
The development of technologies has made it evident that the implication for deployment
of the activities for easing the utilization of the factors aligning the integration of the factors for
developing the alignment of factors aligning the simplification of the factors (Choudhary and
Pandey 2018). The various fire technologies for dealing with the issues of fire protection at CFA
after the incident has occurred include Sound Wave Fire Extinguisher and Water Mist System.
The implication would be aligned for modifying the implication of the factors deploying the
Introduction
The inclusion of the project management technologies would be helpful for easing the
simplification of the activities defining the implication of the improved communication
formation (Alkhatib 2014). The completion of the effective influence of the activities would be
aligned for developing the influence of the innovative technology and development. The Country
Fire Authority (CFA) is responsible for keeping out fire and provides support by improving their
technologies. The development of the factors aligning the utilization of the innovation has been
done for evolving the inclusion of the successive development.
The following assignment has been developed for easing the implication of the factors
defining the utilization of the activities. The support and development of the technology is
developed for aligning the support and development via improved functional development. The
assignment would provide a highlight of the three possible sections of fire technologies,
immediate warning, and immediate suppression of fires that needs improvement for the
development.
Section 1: Fire Technologies (after an incident occurs)
1.1 Available Fire Technologies
The development of technologies has made it evident that the implication for deployment
of the activities for easing the utilization of the factors aligning the integration of the factors for
developing the alignment of factors aligning the simplification of the factors (Choudhary and
Pandey 2018). The various fire technologies for dealing with the issues of fire protection at CFA
after the incident has occurred include Sound Wave Fire Extinguisher and Water Mist System.
The implication would be aligned for modifying the implication of the factors deploying the
3TECHNOLOGY PROJECT REPORT
analysis of the successful development process. The development of fire technologies would
help in developing the easy implication of the factors aligning the development of the activities
forming the implication of the system development supporting the inclusion of the activities
defining the completion of the activities aligning the simplification of the factors (Yuan, Zhang
and Liu 2015). The explanation of the fire technologies has been given below,
Sound Wave Fire Extinguisher: The sound wave extinguisher is developed supporting
the use of sound waves for taking out the implication of the factors defining the implication of
innovative technology at CFA. The sound wave technology would be helpful for defining the
alignment of the successive implication of the effective utilization of the innovation and
technology (Bhuyan, Bhattacharyya, and Kalita, 2017). The sound wave uses the technology of
sound wave for taking out the small fires in the locality. The sound wave extinguisher is helpful
for executing the implication of the operations and defining the utilization of the pollution free
suppression of the fires. The sound waves are helpful for defining the utilization of the fire
control method and implying the successive formation of the innovation technologies. The
extinguishing of the flames has been improved with the help of the development of the improved
functional and effective implication of the technology. The simplification of the factors would be
developed defining the successful implication of the factors defining the implication of the
activities. The extinguishing of the fires would be developed confining the implication of the
activities utilizing the sound waves of frequency 30-60 MHz for taking out the fires (Eugenio et
al. 2016). However, the technology is not very effective for dealing with the probability of large
fires or natural calamities. The factors defining the implementation of the factors aligning the
utilization of the improved innovation technologies were limited to small fires of very minimal
analysis of the successful development process. The development of fire technologies would
help in developing the easy implication of the factors aligning the development of the activities
forming the implication of the system development supporting the inclusion of the activities
defining the completion of the activities aligning the simplification of the factors (Yuan, Zhang
and Liu 2015). The explanation of the fire technologies has been given below,
Sound Wave Fire Extinguisher: The sound wave extinguisher is developed supporting
the use of sound waves for taking out the implication of the factors defining the implication of
innovative technology at CFA. The sound wave technology would be helpful for defining the
alignment of the successive implication of the effective utilization of the innovation and
technology (Bhuyan, Bhattacharyya, and Kalita, 2017). The sound wave uses the technology of
sound wave for taking out the small fires in the locality. The sound wave extinguisher is helpful
for executing the implication of the operations and defining the utilization of the pollution free
suppression of the fires. The sound waves are helpful for defining the utilization of the fire
control method and implying the successive formation of the innovation technologies. The
extinguishing of the flames has been improved with the help of the development of the improved
functional and effective implication of the technology. The simplification of the factors would be
developed defining the successful implication of the factors defining the implication of the
activities. The extinguishing of the fires would be developed confining the implication of the
activities utilizing the sound waves of frequency 30-60 MHz for taking out the fires (Eugenio et
al. 2016). However, the technology is not very effective for dealing with the probability of large
fires or natural calamities. The factors defining the implementation of the factors aligning the
utilization of the improved innovation technologies were limited to small fires of very minimal
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4TECHNOLOGY PROJECT REPORT
impact. The sound wave fire extinguisher does not require any coolant for taking out the fire. It
is helpful for causing no damage to the property while taking out the fire at CFA.
Water Mist System: The water mist system is developed considering the implication of
the improved functional and development model (Cheng et al. 2017). The water has been largely
used for tackling the fire and the water mist system uses the concept of converting the water into
steam for dealing with fire problems at CFA. The water is converted into mist (steam) for
ensuring that the fire is cooled comparatively in faster time period. The water mist system would
be developed considering the utilization of the steam for dealing with the implication of the
factors defining the implication of the fire safety system. The water mist system would be
defined for easing the implication of the factors aligning the utilization of the activities defining
the alignment for easing the implication of the factors aligning the utilization of the improved
factor development. The water is pressurized to convert into steam at normal temperature
allowing the working capability increment. The simplification of the factors has helped in
aligning the utilization of the improved factors for dealing with fire safety implication
(Mahdipour and Dadkhah 2014). The water mist system would be developed confining the
implication of the factors aligning the utilization of the factors defining the fire safety at CFA.
The implication of the fire safety would be dependent on the implication of the factors aligning
the utilization of the effective development of fire safety.
1.2 Operational and Cost requirements of new technologies
Operations and Cost Requirements of Sound Wave Fire Extinguisher: The operations
of the sound wave fire extinguisher are executed by the use of the principle of sound wave as a
material for the mechanism for taking out the implication of the factors listing the development
of the utilization of the improved communication process at CFA. The sound wave technology
impact. The sound wave fire extinguisher does not require any coolant for taking out the fire. It
is helpful for causing no damage to the property while taking out the fire at CFA.
Water Mist System: The water mist system is developed considering the implication of
the improved functional and development model (Cheng et al. 2017). The water has been largely
used for tackling the fire and the water mist system uses the concept of converting the water into
steam for dealing with fire problems at CFA. The water is converted into mist (steam) for
ensuring that the fire is cooled comparatively in faster time period. The water mist system would
be developed considering the utilization of the steam for dealing with the implication of the
factors defining the implication of the fire safety system. The water mist system would be
defined for easing the implication of the factors aligning the utilization of the activities defining
the alignment for easing the implication of the factors aligning the utilization of the improved
factor development. The water is pressurized to convert into steam at normal temperature
allowing the working capability increment. The simplification of the factors has helped in
aligning the utilization of the improved factors for dealing with fire safety implication
(Mahdipour and Dadkhah 2014). The water mist system would be developed confining the
implication of the factors aligning the utilization of the factors defining the fire safety at CFA.
The implication of the fire safety would be dependent on the implication of the factors aligning
the utilization of the effective development of fire safety.
1.2 Operational and Cost requirements of new technologies
Operations and Cost Requirements of Sound Wave Fire Extinguisher: The operations
of the sound wave fire extinguisher are executed by the use of the principle of sound wave as a
material for the mechanism for taking out the implication of the factors listing the development
of the utilization of the improved communication process at CFA. The sound wave technology
5TECHNOLOGY PROJECT REPORT
would be developed for aligning the implication of the factors defining the listing of the
technology innovation. The cost requirements for the implementation of the sound wave
extinguisher is shown below,
Particulars Sound Wave Fire Extinguisher
Cost of Hardware $15,000.00
Software Cost NA
Infrastructure
Cost NA
Labour Cost $250.00
Maintenance Cost $750.00
Total Cost $16,000.00
Operations and Cost Requirements of Water Mist System: The operations of the water
mist system are developed for aligning the development of the improved coolant application. The
water is converted into mist (steam) for ensuring that the fire is cooled comparatively in faster
time period at CFA. The water is pressurized to convert into steam at normal temperature
allowing the working capability increment (Artés et al. 2017). The water mist system would be
developed confining the implication of the factors aligning the utilization of the factors defining
the fire safety. The implication of the fire safety would be dependent on the implication of the
factors aligning the utilization of the effective development of fire safety at CFA. The steam
works 7 times faster than water for clearing the fire of the large spaces. The cost budget
estimation for the implementation of the water mist system are given below,
Particulars Sound Wave Fire Extinguisher Water Mist System
Cost of Hardware $15,000.00 $8,500.00
Software Cost NA $5,500.00
Infrastructure NA $12,000.00
would be developed for aligning the implication of the factors defining the listing of the
technology innovation. The cost requirements for the implementation of the sound wave
extinguisher is shown below,
Particulars Sound Wave Fire Extinguisher
Cost of Hardware $15,000.00
Software Cost NA
Infrastructure
Cost NA
Labour Cost $250.00
Maintenance Cost $750.00
Total Cost $16,000.00
Operations and Cost Requirements of Water Mist System: The operations of the water
mist system are developed for aligning the development of the improved coolant application. The
water is converted into mist (steam) for ensuring that the fire is cooled comparatively in faster
time period at CFA. The water is pressurized to convert into steam at normal temperature
allowing the working capability increment (Artés et al. 2017). The water mist system would be
developed confining the implication of the factors aligning the utilization of the factors defining
the fire safety. The implication of the fire safety would be dependent on the implication of the
factors aligning the utilization of the effective development of fire safety at CFA. The steam
works 7 times faster than water for clearing the fire of the large spaces. The cost budget
estimation for the implementation of the water mist system are given below,
Particulars Sound Wave Fire Extinguisher Water Mist System
Cost of Hardware $15,000.00 $8,500.00
Software Cost NA $5,500.00
Infrastructure NA $12,000.00
6TECHNOLOGY PROJECT REPORT
Cost
Labour Cost $250.00 $2,500.00
Maintenance Cost $750.00 $1,500.00
Total Cost $16,000.00 $30,000.00
1.3 Additional Factors for Consideration
The additional factors for consideration for the technology implementation by CFA are,
Maintenance Plan for the technology implementation
Hiring of professional for taking care of the device
Backup plan for ensuring the fire prevention in case of failure
Section 2: Immediate Warning
2.1 Available Fire Technologies
The various technologies for immediate alarming the people of the fire include
Personalized Vocal Smoke Alarms and Birdi-Fire and Carbon Monoxide Detector. The
implication would be aligned for modifying the implication of the factors deploying the analysis
of the successful development process at CFA. The development of fire technologies would help
in developing the easy implication of the factors aligning the development of the activities
forming the implication of the system development supporting the inclusion of the activities
defining the completion of the activities aligning the simplification of the factors at CFA (Mobin
et al. 2016). The development of technologies has made it evident that the implication for
deployment of the activities for easing the utilization of the factors aligning the integration of the
factors for developing the alignment of factors aligning the simplification of the factors. The
explanation of the fire technologies has been given below,
Cost
Labour Cost $250.00 $2,500.00
Maintenance Cost $750.00 $1,500.00
Total Cost $16,000.00 $30,000.00
1.3 Additional Factors for Consideration
The additional factors for consideration for the technology implementation by CFA are,
Maintenance Plan for the technology implementation
Hiring of professional for taking care of the device
Backup plan for ensuring the fire prevention in case of failure
Section 2: Immediate Warning
2.1 Available Fire Technologies
The various technologies for immediate alarming the people of the fire include
Personalized Vocal Smoke Alarms and Birdi-Fire and Carbon Monoxide Detector. The
implication would be aligned for modifying the implication of the factors deploying the analysis
of the successful development process at CFA. The development of fire technologies would help
in developing the easy implication of the factors aligning the development of the activities
forming the implication of the system development supporting the inclusion of the activities
defining the completion of the activities aligning the simplification of the factors at CFA (Mobin
et al. 2016). The development of technologies has made it evident that the implication for
deployment of the activities for easing the utilization of the factors aligning the integration of the
factors for developing the alignment of factors aligning the simplification of the factors. The
explanation of the fire technologies has been given below,
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7TECHNOLOGY PROJECT REPORT
Personalized Vocal Smoke Alarms: The personalized vocal alarms are conventional
smoke alarms that provide the option for aligning with the fire safety alignment (Landucci et al.
2015). The use of the clinical research design would be helpful for aligning with the alignment of
the factors defining the implication of the improved factors at CFA. The vocal alarms would be
aligned for integrating the alignment of the factors defining the simplification of the parent voice
smoke alarm for children. It has been seen that in most of the cased children tend to ignore the
alarm going off and causing serious damage to property and harm to the kids. The parent voice
alarm would help them in recognizing the alarm significantly causing less loss to the people at
CFA. The personalized alarms are effective for dealing with the fire safety effectively.
Birdi-Fire and Carbon Monoxide Detector: The device works with connection to the
Wi-Fi and links home condition to the phone over the cloud network at CFA. The alarm is multi-
linguistic and can be set according to user’s choice of language. The alarm can be turned off
using the phone and the battery can be easily changed (Saoudi et al. 2016). It has simplified the
way of working simultaneously as fire detector and carbon monoxide detector. The increased
level of carbon monoxide level can be detected with the help of this device at CFA. The
implication of the environmental sensor would be helpful for aligning the analysis of the
temperature from the surrounding level.
2.2 Operational and Cost requirements of new technologies
Operations of Personalized Vocal Smoke Alarms: The personalized vocal smoke alarms
include the inclusion of personalized voice message when fire breaks out. It can be developed
using customized voice with the help of message storage device and speaker for running off the
fire at CFA. In case of fire emergencies the personalized vocal alarm is triggered and the stored
Personalized Vocal Smoke Alarms: The personalized vocal alarms are conventional
smoke alarms that provide the option for aligning with the fire safety alignment (Landucci et al.
2015). The use of the clinical research design would be helpful for aligning with the alignment of
the factors defining the implication of the improved factors at CFA. The vocal alarms would be
aligned for integrating the alignment of the factors defining the simplification of the parent voice
smoke alarm for children. It has been seen that in most of the cased children tend to ignore the
alarm going off and causing serious damage to property and harm to the kids. The parent voice
alarm would help them in recognizing the alarm significantly causing less loss to the people at
CFA. The personalized alarms are effective for dealing with the fire safety effectively.
Birdi-Fire and Carbon Monoxide Detector: The device works with connection to the
Wi-Fi and links home condition to the phone over the cloud network at CFA. The alarm is multi-
linguistic and can be set according to user’s choice of language. The alarm can be turned off
using the phone and the battery can be easily changed (Saoudi et al. 2016). It has simplified the
way of working simultaneously as fire detector and carbon monoxide detector. The increased
level of carbon monoxide level can be detected with the help of this device at CFA. The
implication of the environmental sensor would be helpful for aligning the analysis of the
temperature from the surrounding level.
2.2 Operational and Cost requirements of new technologies
Operations of Personalized Vocal Smoke Alarms: The personalized vocal smoke alarms
include the inclusion of personalized voice message when fire breaks out. It can be developed
using customized voice with the help of message storage device and speaker for running off the
fire at CFA. In case of fire emergencies the personalized vocal alarm is triggered and the stored
8TECHNOLOGY PROJECT REPORT
voice message is played allowing the user to ensure that the personals are protected of the issues.
The following is the budget estimation of the technology,
Particulars Personalized Vocal Smoke Alarms
Cost of Hardware $8,500.00
Software Cost $6,500.00
Infrastructure Cost $9,000.00
Labour Cost $5,000.00
Maintenance Cost $1,500.00
Total Cost $30,500.00
Operations of Birdi-Fire and Carbon Monoxide Detector: The device works with
connection to the Wi-Fi and links home condition to the phone over the cloud network. The
alarm is multi-linguistic and can be set according to user’s choice of language. The alarm can be
turned off using the phone and the battery can be easily changed (Alam et al. 2015). The
increased level of carbon monoxide level can be detected with the help of this device at CFA.
The implication of the environmental sensor would be helpful for aligning the analysis of the
temperature from the surrounding level. The following is the cost budget analysis of the device,
Particulars Birdi-Fire and Carbon Monoxide Detector
Cost of Hardware $9,000.00
Software Cost $6,000.00
Infrastructure Cost $10,000.00
Labour Cost $7,250.00
Maintenance Cost $1,750.00
Total Cost $34,000.00
voice message is played allowing the user to ensure that the personals are protected of the issues.
The following is the budget estimation of the technology,
Particulars Personalized Vocal Smoke Alarms
Cost of Hardware $8,500.00
Software Cost $6,500.00
Infrastructure Cost $9,000.00
Labour Cost $5,000.00
Maintenance Cost $1,500.00
Total Cost $30,500.00
Operations of Birdi-Fire and Carbon Monoxide Detector: The device works with
connection to the Wi-Fi and links home condition to the phone over the cloud network. The
alarm is multi-linguistic and can be set according to user’s choice of language. The alarm can be
turned off using the phone and the battery can be easily changed (Alam et al. 2015). The
increased level of carbon monoxide level can be detected with the help of this device at CFA.
The implication of the environmental sensor would be helpful for aligning the analysis of the
temperature from the surrounding level. The following is the cost budget analysis of the device,
Particulars Birdi-Fire and Carbon Monoxide Detector
Cost of Hardware $9,000.00
Software Cost $6,000.00
Infrastructure Cost $10,000.00
Labour Cost $7,250.00
Maintenance Cost $1,750.00
Total Cost $34,000.00
9TECHNOLOGY PROJECT REPORT
2.3 Additional Factors for Consideration
The additional factors for consideration for the technology implementation by CFA are,
Implementing the alignment for easing the development
Alignment of the factors using the implementation of the factors
Backup plan for ensuring the fire prevention in case of failure
Section 3: Immediate Suppression of fires in confined spaces (in structures)
3.1 Available Fire Technologies
The various technologies for immediate suppression of the fire in a confined space
include the two step process. The first step is supported by the technology of Integrated Voice
Evacuation and Messaging System that would alarm the people and help them in evacuating the
site immediately (Saeed et al. 2018). The second step is bounded by the technology of Early
Suppression Fast Response Fire Sprinkler Systems (ESFR). The implication would be aligned
for modifying the implication of the factors deploying the analysis of the successful development
process at CFA. The development of fire technologies would help in developing the easy
implication of the factors aligning the development of the activities forming the implication of
the system development supporting the inclusion of the activities defining the completion of the
activities aligning the simplification of the factors (Merino et al. 2015). The explanation of the
fire technologies has been given below,
Integrated Voice Evacuation and Messaging System: The integrated voice evacuation
and messaging system is developed for forming the effective messaging and for the development
2.3 Additional Factors for Consideration
The additional factors for consideration for the technology implementation by CFA are,
Implementing the alignment for easing the development
Alignment of the factors using the implementation of the factors
Backup plan for ensuring the fire prevention in case of failure
Section 3: Immediate Suppression of fires in confined spaces (in structures)
3.1 Available Fire Technologies
The various technologies for immediate suppression of the fire in a confined space
include the two step process. The first step is supported by the technology of Integrated Voice
Evacuation and Messaging System that would alarm the people and help them in evacuating the
site immediately (Saeed et al. 2018). The second step is bounded by the technology of Early
Suppression Fast Response Fire Sprinkler Systems (ESFR). The implication would be aligned
for modifying the implication of the factors deploying the analysis of the successful development
process at CFA. The development of fire technologies would help in developing the easy
implication of the factors aligning the development of the activities forming the implication of
the system development supporting the inclusion of the activities defining the completion of the
activities aligning the simplification of the factors (Merino et al. 2015). The explanation of the
fire technologies has been given below,
Integrated Voice Evacuation and Messaging System: The integrated voice evacuation
and messaging system is developed for forming the effective messaging and for the development
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10TECHNOLOGY PROJECT REPORT
of the final voice messaging system for the individuals. It has been largely used for supporting
the evacuation process in multi storied buildings (Baesens et al. 2015). The fire detectors initiate
the voice alarms in all the sections allowing the integration of the improved functional and
effective processes at CFA. The voice messaging system would help them in listing the
allowance of the integrated voice system for the whole building. It would allow the message
transfer throughout the building for developing the effective alignment of the information.
Early Suppression Fast Response Fire Sprinkler Systems (ESFR): The fire sprinkler is
the most effective machine for dealing with the fires as it works cumulatively with the main
storage. The sprinkler system is integrated in all of the building for dealing with the fire. The
sprinkler would suppress the fire with the help of support and development of the factors
(Muhammad, Ahmad and Baik 2018). The suppression of the fire would be eased with the help
of the sprinkler system at CFA. The fire sprinkler exhausts the machines for the development of
the successive factors aligning the implementation. The suppression of the fire would be aligned
with the deployment of the improved analysis. The force of water would allow the safety
procurement for fire by minimizing the impact of the fire. The water force would be effectively
aligned for easing the implication of the fire safety.
3.2 Operational and Cost requirements of new technologies
Operations of Integrated Voice Evacuation and Messaging System: The integrated
voice evacuation and messaging system initiates the voice alarms in all the sections allowing the
integration of the improved functional and effective processes at CFA. The voice messaging
system would help them in listing the allowance of the integrated voice system for the whole
building (Parente, Pereira and Tonini 2016). It would allow the message transfer throughout the
of the final voice messaging system for the individuals. It has been largely used for supporting
the evacuation process in multi storied buildings (Baesens et al. 2015). The fire detectors initiate
the voice alarms in all the sections allowing the integration of the improved functional and
effective processes at CFA. The voice messaging system would help them in listing the
allowance of the integrated voice system for the whole building. It would allow the message
transfer throughout the building for developing the effective alignment of the information.
Early Suppression Fast Response Fire Sprinkler Systems (ESFR): The fire sprinkler is
the most effective machine for dealing with the fires as it works cumulatively with the main
storage. The sprinkler system is integrated in all of the building for dealing with the fire. The
sprinkler would suppress the fire with the help of support and development of the factors
(Muhammad, Ahmad and Baik 2018). The suppression of the fire would be eased with the help
of the sprinkler system at CFA. The fire sprinkler exhausts the machines for the development of
the successive factors aligning the implementation. The suppression of the fire would be aligned
with the deployment of the improved analysis. The force of water would allow the safety
procurement for fire by minimizing the impact of the fire. The water force would be effectively
aligned for easing the implication of the fire safety.
3.2 Operational and Cost requirements of new technologies
Operations of Integrated Voice Evacuation and Messaging System: The integrated
voice evacuation and messaging system initiates the voice alarms in all the sections allowing the
integration of the improved functional and effective processes at CFA. The voice messaging
system would help them in listing the allowance of the integrated voice system for the whole
building (Parente, Pereira and Tonini 2016). It would allow the message transfer throughout the
11TECHNOLOGY PROJECT REPORT
building for developing the effective alignment of the information. The following is the cost
benefit analysis of the technology,
Particulars Integrated Voice Evacuation and Messaging System
Cost of Hardware $10,000.00
Software Cost $8,000.00
Infrastructure
Cost
$10,500.00
Labour Cost $6,500.00
Maintenance Cost $2,000.00
Total Cost $37,000.00
Operations of Early Suppression Fast Response Fire Sprinkler Systems (ESFR): The
fire sprinkler exhausts the machines for the development of the successive factors aligning the
implementation. The suppression of the fire would be aligned with the deployment of the
improved analysis. The force of water would allow the safety procurement for fire by
minimizing the impact of the fire (Giitsidis et al. 2015). The water force would be effectively
aligned for easing the implication of the fire safety. The following is the cost benefit analysis of
the technology,
Particulars Early Suppression Fast Response Fire Sprinkler Systems (ESFR)
Cost of Hardware $12,500.00
Software Cost $10,500.00
Infrastructure $16,000.00
building for developing the effective alignment of the information. The following is the cost
benefit analysis of the technology,
Particulars Integrated Voice Evacuation and Messaging System
Cost of Hardware $10,000.00
Software Cost $8,000.00
Infrastructure
Cost
$10,500.00
Labour Cost $6,500.00
Maintenance Cost $2,000.00
Total Cost $37,000.00
Operations of Early Suppression Fast Response Fire Sprinkler Systems (ESFR): The
fire sprinkler exhausts the machines for the development of the successive factors aligning the
implementation. The suppression of the fire would be aligned with the deployment of the
improved analysis. The force of water would allow the safety procurement for fire by
minimizing the impact of the fire (Giitsidis et al. 2015). The water force would be effectively
aligned for easing the implication of the fire safety. The following is the cost benefit analysis of
the technology,
Particulars Early Suppression Fast Response Fire Sprinkler Systems (ESFR)
Cost of Hardware $12,500.00
Software Cost $10,500.00
Infrastructure $16,000.00
12TECHNOLOGY PROJECT REPORT
Cost
Labour Cost $7,500.00
Maintenance Cost $3,500.00
Total Cost $50,000.00
2.3 Additional Factors for Consideration
The additional factors for consideration for the technology implementation by CFA are,
Implementing the alignment for easing the development
Hiring of professional for taking care of the device
Backup plan for ensuring the fire prevention in case of failure
Conclusion
The following assignment had been developed for easing the implication of the factors
defining the utilization of the activities. The completion of the effective influence of the
activities had been aligned for developing the influence of the innovative technology and
development. The Country Fire Authority is responsible for keeping out fire and provides
support by improving their technologies. The development of the factors aligning the utilization
of the innovation had been done for evolving the inclusion of the successive development. The
assignment had provided a highlight of the three possible sections of fire technologies,
immediate warning, and immediate suppression of fires that needs improvement for the
development.
Cost
Labour Cost $7,500.00
Maintenance Cost $3,500.00
Total Cost $50,000.00
2.3 Additional Factors for Consideration
The additional factors for consideration for the technology implementation by CFA are,
Implementing the alignment for easing the development
Hiring of professional for taking care of the device
Backup plan for ensuring the fire prevention in case of failure
Conclusion
The following assignment had been developed for easing the implication of the factors
defining the utilization of the activities. The completion of the effective influence of the
activities had been aligned for developing the influence of the innovative technology and
development. The Country Fire Authority is responsible for keeping out fire and provides
support by improving their technologies. The development of the factors aligning the utilization
of the innovation had been done for evolving the inclusion of the successive development. The
assignment had provided a highlight of the three possible sections of fire technologies,
immediate warning, and immediate suppression of fires that needs improvement for the
development.
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13TECHNOLOGY PROJECT REPORT
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early forest fire detection and rapid mapping. In Fifth International Conference on Remote
Sensing and Geoinformation of the Environment (RSCy2017) (Vol. 10444, p. 104440R).
International Society for Optics and Photonics.
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14TECHNOLOGY PROJECT REPORT
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algorithms for fire detection: A review. Sensors, 18(2), p.553.
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detection from high altitude UAV images. In Parallel, Distributed and Network-Based
Processing (PDP), 2015 23rd Euromicro International Conference on (pp. 309-315). IEEE.
Jun, J.H., Kim, M.J., Jang, Y.S. and Kim, S.H., 2017. Fire Detection Using Multi-Channel
Information and Gray Level Co-occurrence Matrix Image Features. Journal of Information
Pocessing System, 13(3), pp.590-598.
Landucci, G., Argenti, F., Tugnoli, A. and Cozzani, V., 2015. Quantitative assessment of safety
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15TECHNOLOGY PROJECT REPORT
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climate. Science of the Total Environment, 559, pp.151-165.
Pillai, A., David, V.J., Shibu, R., Fernandes, J. and Shirke, A., 2018, March. F-Detect: Early
Detection of Forest Fires using Wireless Sensor Networks. In 1st International Conference On
Recent Innovation in Engineering and Technology (ICORIET-2018), Dr. DY Patil School of
Engineering & Technology, Pune(pp. 22-23).
Saeed, F., Paul, A., Rehman, A., Hong, W.H. and Seo, H., 2018. IoT-Based Intelligent Modeling
of Smart Home Environment for Fire Prevention and Safety. Journal of Sensor and Actuator
Networks, 7(1), p.11.
Saoudi, M., Bounceur, A., Euler, R. and Kechadi, T., 2016, March. Data mining techniques
applied to wireless sensor networks for early forest fire detection. In Proceedings of the
International Conference on Internet of things and Cloud Computing (p. 71). ACM.
Sowah, R., Ampadu, K.O., Ofoli, A., Koumadi, K., Mills, G.A. and Nortey, J., 2016, October.
Design and implementation of a fire detection and control system for automobiles using fuzzy
logic. In Industry Applications Society Annual Meeting, 2016 IEEE (pp. 1-8). IEEE.
Yuan, C., Zhang, Y. and Liu, Z., 2015. A survey on technologies for automatic forest fire
monitoring, detection, and fighting using unmanned aerial vehicles and remote sensing
techniques. Canadian journal of forest research, 45(7), pp.783-792.
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