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Assignment 6
1.The article selected to be edit has the title Isolated Transformer.

2. The ideas' Key is to demonstrated the transformer's Isolation behavior and Applications.

3. The reference's used to certify the article's information is the main issue in this paper work.

4. I studied the transformers in one of my last classes and I like the transformer isolation applications.

5. It is an important tool using in many technologies works what are the technological standpoints?

6. This technology has a good ethical standpoint as assistance in the technology field.

7. The benefic of this transformer's application has a good standpoint in society.

8. The audience of Isolated transformer embrace different audiences like Electrical, Medical, Sciences, and more due to applications. — Preceding unsigned comment added by Josepazmino (talk • contribs) 20:09, 8 March 2021 (UTC)

Assignment 7
Isolation Transformer is an important transformer's application that permit to isolate devices or persons from an electrical damages. This isolation is used in Voltage Isolation transfer and Medical equipment like[1][2] electromagnetic Pulse Isolation transformer.[3] The isolation transformer allows a transformer to transfer electrical power from a source of alternating current (AC) to circuits, equipment or device while isolating them from the power source, usually for safety reasons. Isolation transformers separate the conductive path present between source and load. A transformer sold for isolation is often built with special insulation between primary and secondary, and is specified to withstand a high voltage between windings. Isolation transformers block transmission of the DC component in signals from one circuit to the other, but allow AC components in signals to pass. Transformers that have a ratio of 1 to 1 between the primary and secondary windings are often used to protect secondary circuits and individuals from electrical shocks between energized conductors and earth ground. Suitably designed isolation transformers block interference caused by ground loops. Isolation transformers with electrostatic shields are used for power supplies for sensitive equipment such as computers, medical devices, or laboratory instruments. A transformer step up or step down an incoming voltage using an iron core or air core. Two sides of the core has wound with cooper wires.[1] One side is connected to the AC voltage and calls Primary, and the other wire side with the output current or load is calls Secondary. The sources AC voltage produce a Magnetic field that induce a current flow from the Primary to Secondary. The current is transfer from the Primary to the Secondary without a Electric Connection. This equipment is isolate from high power sources to protect a system or person, grounding the transformer. Grounding the transformer's chassis or frame to the ground system.

Robbins / Miller, Allan H. / Wilhelm C. (2013). Circuit Analysis Fifth edition. NY USA: CENGAGE Learning. p. 830. Olson, Walter H. (unimap.edu.my). "ELECTRICAL SAFETY" (PDF). Check date values in: |date= and |archive-date= (help) Wenaas, Eric P. (Google / United States Patent). Electromagnetic pulse isolation transformer (PDF) https://patentimages.storage.googleapis.com/a2/79/3b/79f70ffce3d276/US4660014.pdf. Check date values in: |date= and |archive-date= (help); Missing or empty |title= (help) — Preceding unsigned comment added by Josepazmino (talk • contribs) 15:20, 15 March 2021 (UTC)

Assignment 7
Isolation Transformer is an important transformer's application that permit to isolate devices or persons from an electrical damages. This isolation is used in Voltage Isolation transfer and Medical equipment like[1][2] electromagnetic Pulse Isolation transformer.[3] The isolation transformer allows a transformer to transfer electrical power from a source of alternating current (AC) to circuits, equipment or device while isolating them from the power source, usually for safety reasons. Isolation transformers separate the conductive path present between source and load. A transformer sold for isolation is often built with special insulation between primary and secondary, and is specified to withstand a high voltage between windings. Isolation transformers block transmission of the DC component in signals from one circuit to the other, but allow AC components in signals to pass. Transformers that have a ratio of 1 to 1 between the primary and secondary windings are often used to protect secondary circuits and individuals from electrical shocks between energized conductors and earth ground. Suitably designed isolation transformers block interference caused by ground loops. Isolation transformers with electrostatic shields are used for power supplies for sensitive equipment such as computers, medical devices, or laboratory instruments. A transformer step up or step down an incoming voltage using an iron core or air core. Two sides of the core has wound with cooper wires.[1] One side is connected to the AC voltage and calls Primary, and the other wire side with the output current or load is calls Secondary. The sources AC voltage produce a Magnetic field that induce a current flow from the Primary to Secondary. The current is transfer from the Primary to the Secondary without a Electric Connection. This equipment is isolate from high power sources to protect a system or person, grounding the transformer. Grounding the transformer's chassis or frame to the ground system.

Robbins / Miller, Allan H. / Wilhelm C. (2013). Circuit Analysis Fifth edition. NY USA: CENGAGE Learning. p. 830. Olson, Walter H. (unimap.edu.my). "ELECTRICAL SAFETY" (PDF). Check date values in: |date= and |archive-date= (help) http://portal.unimap.edu.my/portal/page/portal30/Lecture%20Notes/KEJURUTERAAN_MEKATRONIK/Semester%201%20Sidang%20Akademik%2020172018/ENT321%20Safety%20Standards%20and%20Ethics%20in%20Biomedical%20Engineering/Supplementary%20Notes/Electrical%20Safety.pdf — Preceding unsigned comment added by Josepazmino (talk • contribs) 14:04, 7 May 2021 (UTC) Wenaas, Eric P. (Google / United States Patent). Electromagnetic pulse isolation transformer (PDF) https://patentimages.storage.googleapis.com/a2/79/3b/79f70ffce3d276/US4660014.pdf. Check date values in: |date= and |archive-date= (help); Missing or empty |title= (help) — Preceding unsigned comment added by Josepazmino (talk • contribs) 15:20, 15 March 2021 (UTC)

Assignment 8
Jose peer Review Marcus Lancelot's article — Preceding unsigned comment added by 2601:88:8200:62C0:4CFD:FB5B:91A2:545B (talk) 03:56, 26 March 2021 (UTC)

Assignment 9
I did not received any feedback from my peers, but I am working to improve my assignment.

Isolation Transformer is an important transformer's application that allows to isolate devices or people from an electrical damage. This isolation is used in Voltage Isolation transfer and Medical equipment like[1][2] Electromagnetic Pulse Isolation Transformer.[3] The isolation transformer allows a transformer to transfer electrical power from a source of alternating current (AC) to circuits, equipment, or devices while isolating them from the power source, usually for safety reasons. Isolation transformers separate the conductive path present between source and load. A transformer sold for isolation is often built with special insulation between primary and secondary, and is specified to withstand a high voltage between windings. Isolation transformers block transmission of the DC component in signals from one circuit to the other, but allows AC components in signals to pass. Transformers that have a ratio of 1:1 between the primary and secondary windings are often used to protect secondary circuits and individuals from electrical shocks between energized conductors and earth ground. Suitably designed, isolation transformers block interference caused by ground loops. Isolation transformers with electrostatic shields are used for power supplies for sensitive equipment such as computers, medical devices, or laboratory instruments. A transformer steps up or steps down an incoming voltage using an iron core or air core. Two sides of the core winds up with cooper wires.[1] One side is connected to the AC voltage and its called "Primary". The other wire sides with the output current or load and its called "Secondary". The sources AC voltage produce a magnetic field that induces a current flow from the Primary to the Secondary. The current is transferred from the Primary to the Secondary without an electric connection. This equipment is isolated from high power sources to protect a system or person, grounding the transformer, thus chasseing or transferring to the ground system.

Assignment 10
Article Edited Isolation Transformer is an important transformer's application that allows to isolate devices or people from an electrical damage. This isolation is used in Voltage Isolation transfer and Medical equipment like[1][2] Electromagnetic Pulse Isolation Transformer.[3] The isolation transformer allows a transformer to transfer electrical power from a source of alternating current (AC) to circuits, equipment, or devices while isolating them from the power source, usually for safety reasons. Isolation transformers separate the conductive path present between source and load. A transformer sold for isolation is often built with special insulation between primary and secondary, and is specified to withstand a high voltage between windings. Isolation transformers block transmission of the DC component in signals from one circuit to the other, but allows AC components in signals to pass. Transformers that have a ratio of 1:1 between the primary and secondary windings are often used to protect secondary circuits and individuals from electrical shocks between energized conductors and earth ground. Suitably designed, isolation transformers block interference caused by ground loops. Isolation transformers with electrostatic shields are used for power supplies for sensitive equipment such as computers, medical devices, or laboratory instruments. A transformer steps up or steps down an incoming voltage using an iron core or air core. Two sides of the core winds up with cooper wires.[1] One side is connected to the AC voltage and its called "Primary". The other wire sides with the output current or load and its called "Secondary". The sources AC voltage produce a magnetic field that induces a current flow from the Primary to the Secondary. The current is transferred from the Primary to the Secondary without an electric connection. This equipment is isolated from high power sources to protect a system or person, grounding the transformer, thus chasseing or transferring to the ground system.

Assignment 11
Reorganize essay

Article Edited Isolation Transformer is an important transformer's application that allows to isolate devices or people from an electrical damage. This isolation is used in Voltage Isolation transfer and Medical equipment like[1][2] Electromagnetic Pulse Isolation Transformer.[3] The isolation transformer allows a transformer to transfer electrical power from a source of alternating current (AC) to circuits, equipment, or devices while isolating them from the power source, usually for safety reasons. Isolation transformers separate the conductive path present between source and load. A transformer sold for isolation is often built with special insulation between primary and secondary, and is specified to withstand a high voltage between windings. Isolation transformers block transmission of the DC component in signals from one circuit to the other, but allows AC components in signals to pass. Transformers that have a ratio of 1:1 between the primary and secondary windings are often used to protect secondary circuits and individuals from electrical shocks between energized conductors and earth ground. Suitably designed, isolation transformers block interference caused by ground loops. Isolation transformers with electrostatic shields are used for power supplies for sensitive equipment such as computers, medical devices, or laboratory instruments. A transformer steps up or steps down an incoming voltage using an iron core or air core. Two sides of the core winds up with cooper wires.[1] One side is connected to the AC voltage and its called "Primary". The other wire sides with the output current or load and its called "Secondary". The sources AC voltage produce a magnetic field that induces a current flow from the Primary to the Secondary. The current is transferred from the Primary to the Secondary without an electric connection. This equipment is isolated from high power sources to protect a system or person, grounding the transformer, thus chasseing or transferring to the ground system.

Assignment 12
Add pictures to the work paper I have been working on this for 2 hours and I can not get the image that I want to share on my article. I need some help.

Assignment 13 Outline
A transformer is used to step-up or step-down Volts of Alterna Current VAC to the desired voltage in Electrical or Electronics circuits. Also, transformers provides Electrical Isolation between the chassis ground being at high voltage with respect to the facility's ground.[4] This Isolation is called Isolation Transformer which allows to separate devices or people from an electrical damage. This isolation is used in Voltage Isolation transfer and Medical equipment like [1][2] Electromagnetic Pulse Isolation Transformer.[3] The isolation transformer allows a transformer to transfer electrical power from a source of alternating current (AC) to circuits, equipment, or devices while isolating them from the power source, for safety reasons and circuit design. Isolation transformers separate the conductive path present between source and load. A transformer sold for isolation is often built with special insulation between primary and secondary, and is specified to withstand a high voltage between windings. Isolation transformers block transmission of the DC component in signals from one circuit to the other but allows AC components in signals to pass. Transformers that have a ratio of 1:1 between the primary and secondary windings are often used to protect secondary circuits and individuals from electrical shocks between energized conductors and earth ground. Suitably designed, isolation transformers block interference caused by ground loops. Isolation transformers with electrostatic shields are used for power supplies for sensitive equipment such as computers, medical devices, or laboratory instruments. A transformer steps up or steps down an incoming voltage using an iron core or air core. Two sides of the core winds up with cooper wires.[1] The Primary is connected to the AC voltage and the Secondary is relates to the output current or load and is called "Secondary". The sources AC voltage produce a magnetic field that induces a current flow from the Primary to the Secondary. The current is transferred from the Primary to the Secondary without an electric connection. This equipment is isolated from high power sources to protect a system or person, grounding the transformer, thus chasseing or transferring to the ground system.

Robbins / Miller, Allan H. / Wilhelm C. (2013). Circuit Analysis Fifth edition. NY USA: CENGAGE Learning. p. 830.

http://portal.unimap.edu.my/portal/page/portal30/Lecture%20Notes/KEJURUTERAAN_MEKATRONIK/Semester%201%20Sidang%20Akademik%2020172018/ENT321%20Safety%20Standards%20and%20Ethics%20in%20Biomedical%20Engineering/Supplementary%20Notes/Electrical%20Safety.pdf

https://patentimages.storage.googleapis.com/a2/79/3b/79f70ffce3d276/US4660014.pdf

Prof. Tom Houck/Rowan at Burlington County College/ Semiconductors 230/Lecture 2 Power Supplies pag.1

Assignment 14
Edition 14

A transformer is used to step-up or step-down Volts of Alterna Current VAC to the desired voltage in Electrical or Electronics circuits. Also, transformers provides Electrical Isolation between the chassis ground being at high voltage with respect to the facility's ground.[4] This Isolation is called Isolation Transformer which allows to separate devices or people from an electrical damage. This isolation is used in Voltage Isolation transfer and Medical equipment like [1][2] Electromagnetic Pulse Isolation Transformer.[3] The isolation transformer allows a transformer to transfer electrical power from a source of alternating current (AC) to circuits, equipment, or devices while isolating them from the power source, for safety reasons and circuit design. Isolation transformers separate the conductive path present between source and load. A transformer sold for isolation is often built with special insulation between primary and secondary, and is specified to withstand a high voltage between windings. Isolation transformers block transmission of the DC component in signals from one circuit to the other but allows AC components in signals to pass. Transformers that have a ratio of 1:1 between the primary and secondary windings are often used to protect secondary circuits and individuals from electrical shocks between energized conductors and earth ground. Suitably designed, isolation transformers block interference caused by ground loops. Isolation transformers with electrostatic shields are used for power supplies for sensitive equipment such as computers, medical devices, or laboratory instruments. A transformer steps up or steps down an incoming voltage using an iron core or air core. Two sides of the core winds up with cooper wires.[1] The Primary is connected to the AC voltage and the Secondary is relates to the output current or load and is called "Secondary". The sources AC voltage produce a magnetic field that induces a current flow from the Primary to the Secondary. The current is transferred from the Primary to the Secondary without an electric connection. This equipment is isolated from high power sources to protect a system or person, grounding the transformer, thus chasseing or transferring to the ground system.

Robbins / Miller, Allan H. / Wilhelm C. (2013). Circuit Analysis Fifth edition. NY USA: CENGAGE Learning. p. 830.

http://portal.unimap.edu.my/portal/page/portal30/Lecture%20Notes/KEJURUTERAAN_MEKATRONIK/Semester%201%20Sidang%20Akademik%2020172018/ENT321%20Safety%20Standards%20and%20Ethics%20in%20Biomedical%20Engineering/Supplementary%20Notes/Electrical%20Safety.pdf

https://patentimages.storage.googleapis.com/a2/79/3b/79f70ffce3d276/US4660014.pdf

Prof. Tom Houck/Rowan at Burlington County College/ Semiconductors 230/Lecture 2 Power Supplies pag.1

Assignment 15
Final paper A transformer is used to step-up or step-down Volts of Alterna Current (VAC) to the desired voltage in Electrical or Electronic Circuits. Also, transformers provide Electrical Isolation between the transformer’s chassis and the facility’s ground at low and high voltage. [4] This Isolation is called Isolation Transformer, which allows to separate devices or people from an electrical damage. This isolation is used in Voltage Isolation Transfer and medical equipment [1][2], like the Electromagnetic Pulse Isolation Transformer.[3] The isolation transformer allows a transformer to transfer electrical power from a separate windings input source of alternating current (AC) to an windings output like circuits, equipment, or devices. This power transfer is through an Electrostatic Faraday shielding around these windings while isolating them from the power source.[6] This is created for safety reasons and circuit design. Isolation transformers separate the conductive path present between the source and the load. A transformer sold for isolation is often built with special insulation between the Primary and Secondary windings, and is specified to withstand a high voltage between windings. Isolation Transformers block transmission of the Direct Current (DC) component in signals from one circuit to the other, yet it allows AC components in signals to pass. Transformers that have a ratio of 1:1 between the Primary and Secondary windings are often used to protect Secondary circuits and individuals from electrical shocks between energized conductors and earth ground. Suitably designed, Isolation Transformers block interference caused by ground loops. Isolation Transformers with electrostatic shields are used for power supplies for sensitive equipment; such as computers, medical devices, or laboratory instruments. A transformer steps up or steps down an incoming voltage using an iron core or air core. Two sides of the iron or air core are winds up with cooper wires to produce magnetic lines of force or magnetic Flux which increase the magnetic effect.[1] [7] The Transformer Primary side is connected to the AC voltage, while the Secondary side is related to the output current or load. The AC voltage applied at the transformer primary produce a magnetic field around the conductor that induces the current flow from the Primary windings to the transformer secondary windings without an electrical connection. This equipment is isolated from high power sources to protect a system or person, grounding the transformer chasses, or transferring to the ground system. At High Voltage, isolation transformer must be verified or tested to ensure the transformer withstand on an overvoltage, like lightning which could happen when the transformer in services. A voltage which excesses the transformer capacity or overvoltage is applied to the transformer to test its insulation capability, and this voltage is called Withstand Voltage.[5] The Transformer Insulation test is known as Megger test, this test process is similar as the High Voltage test, connecting the two testing terminal windings together and the other two terminal windings are connected to the center tank, transformer core, transformer case and the ground for safety precaution. Then, the voltage applied to the testing terminal started increasing until the desire testing voltage (Withstand voltage). When the Withstand voltage is reach, is held for a minute usually, before to reducing to it to zero and open the circuit, to see the transformer reaction.[7] The insulation resistance depends in the temperature cleanliness and dryness of the windings. There are two methods to verify any fault on the Insulation: -General Observations: like noise, smoke, or bubble in the breather. - Voltage Oscillogram Method, the voltage waveform is collapse in the Oscillogram. Overheating could happen on High Power Transformer due stray flux losses which produce eddy iron loss, eddy currents or cooper loss. This overheating on transformer causes spurious operations or equipment shut down.[6]

Robbins / Miller, Allan H. / Wilhelm C. (2013). Circuit Analysis Fifth edition. NY USA: CENGAGE Learning. p. 830. http://portal.unimap.edu.my/portal/page/portal30/Lecture%20Notes/KEJURUTERAAN_ Ele https://patentimages.storage.googleapis.com/a2/79/3b/79f70ffce3d276/US4660014.pdf Prof. Tom Houck/Rowan at Burlington County College/ Semiconductors 230/Lecture 2 Power Supplies pag.1 M S Naidu / V Kamaraju (2009). High Voltage Engineering Fourth edition. New Delhin- India: TATA Mc GRAW-HIL. p. 405 / 426 Paul Gill (1942) / Electrical Power Equipment Maintenance and Testing Second Edition. Boca Raton FL: CRC Press Taylor and Francis Group p. 812 Anthony J. Pansini (1999) / Electrical Transformer and Power equipment Third Edition. Lilburn GA: The Fairmont Press Inc p. 120

Assignment 15
Isolation Transformer Project

José Pazmino Rowan College at Burlington County Society Ethics and Technology Dr. Edem Tetteh May 16, 2021

Isolation Transformer Project A Transformer is used to step-up or step-down Volts of Alterna Current (VAC) to the desired voltage in Electrical or Electronic Circuits. In addition, Transformers provide Electrical Isolation between the transformer’s chassis and the facility’s ground at low and high voltage. This Isolation is called Isolation Transformer, which provide people or devices protection from electrical damage. This Isolation is an electrical safety used in Voltage Isolation Transfer and medical equipment (Robins & Wilhelm, 2013; Waler, 2008), like the Electromagnetic Pulse Isolation Transformer (Weenas & Wheeler, 1985). The Isolation Transformer allows a Transformer to transfer electrical power from separate windings input source of alternating current (AC) and windings output like circuits, equipment, or devices in a safety way. This power is transferred through an electrostatic faraday shield around these windings while isolating from the power source (Gill, 1942). This is created for safety reasons and circuit design. Isolation Transformers separate the conductive path present between the source and the load. A Transformer sold for isolation is often built with special insulation between the Primary and Secondary windings and is specified to withstand a high voltage between windings. Isolation Transformers block transmission of the Direct Current (DC) component in signals from one circuit to the other, yet it allows AC components in signals to pass. Transformers that have a ratio of 1:1 between the Primary and Secondary windings are often used to protect Secondary circuits and individuals from electrical shocks between energized conductors and earth ground. Suitably designed, Isolation Transformers block interference caused by ground loops. Isolation Transformers with electrostatic shields are used in power supplies for sensitive equipment, such as computers, medical devices, or laboratory instruments. A Transformer steps up or steps down an incoming voltage using an iron core or air core. Two opposites sides of the iron or air core are winded up with cooper wires to produce magnetic lines of force or magnetic flux, which increase the magnetic effect (Robins & Wilhelm, 2013; Pansini, 1999). The Transformer Primary side is connected to the AC voltage, while the Secondary side is related to the output current or load. The AC voltage applied at the transformer primary produces a magnetic field around the conductor that induces the current flow from the Primary windings to the Transformer’s Secondary windings without an electrical connection. This equipment is isolated from high power sources to protect a system or person, grounding the Transformer’s chassis, or transferring to the ground system. At high voltage, Isolation Transformer must be verified or tested to ensure the Transformer withstand on an overvoltage, like lightning which could happen when the Transformer is in service. A voltage, which exceeds the Transformer’s capacity or overvoltage, is applied to the Transformer to test its insulation capability. This voltage is called Withstand Voltage (Naidu & Kamaraju, 2009). The Transformer Insulation test is known as Megger test. This test process is similar as the High Voltage test, connecting the two testing terminal windings together and the other two terminal windings are connected to the center tank, transformer core, transformer case, and the ground for safety precaution. Then, the voltage applied to the testing terminal starter increasing until the desire testing voltage (Withstand Voltage) is reached. Once the Withstand Voltage is reached, it is held usually for a minute before reducing it to zero and opening the circuit to see the Transformer’s reaction (Pansini, 1999). The insulation resistance depends in the temperature cleanliness and dryness of the windings. There are two methods to verify any fault on the Insulation. The first method is by identifying the general observations, such as noise, smoke, or bubbles in the breather. The second method is the Voltage Oscillogram Method. This method is observed when the Voltage Waveform collapses onto the Oscillogram. Overheating could happen on High Power Transformer due to stray flux losses which produce iron loss, eddy currents or cooper loss. This overheating on transformer causes spurious operations or equipment shut down (Gill, 1942). Transformers are present in every Electrical circuit and in almost every Electronic circuit due to its capability to change the source voltage to the load circuit require voltage and its good isolation which permits implement safety circuits. The transformer design depends upon the voltage require on the secondary and the Megger test that allow the designer to measure the Withstand Voltage and the Isolation capability. References Gill, P. (2008). Electrical Power Equipment Maintenance and Testing (2nd ed.). CRC Press Taylor & Francis Group. Naidu, M. S. & Kamaraju, V. (2009). High Voltage Engineering (4th ed.). McGraw-Hill. Pansini, A. J. (1999). Electrical Transformer and Power Equipment (3rd ed.). The Fairmont Press Inc. Robbins, A. H. & Wilhelm, C. M. (2013). Circuit Analysis (5th ed.). CENGAGE Learning. Walter, H. O. (2008). Electrical safety Wenaas, E. P., Wheeler, R. M. (1985). Electromagnetic pulse isolation transformer, Patent Number 4,660,014