Last But Not Least<\/strong><\/h3>\n\n\n\nAmmeters have been pivotal in the electrical technology field. Without them, we wouldn\u2019t know the amount of current flowing through a circuit, and thereby most of the electric devices and systems ever invented would not be possible. In your school physics laboratory, you\u2019ll be using an ammeter to measure the current flowing through one of your first circuits \u2012 respect it, love it. An ammeter is like a finger on the pulse of the live wire.<\/p>\n","protected":false},"excerpt":{"rendered":"
If you\u2019ve gone through physics practical classes of most school boards, experiments based on electricity would have been part of the lessons and you must have seen an ammeter in action. It is part of most electricity-related textbooks for school classes 10 to 12 as well. Today, we will tell you what exactly an ammeter is, how it works, how much it costs, and how many types of them are there. One thing you can be certain of \u2012 ammeters are an obvious part of any electronics or physics lab equipment package . Definition of an Ammeter An ammeter is an instrument for measuring the current flowing through a live circuit. The word \u2018ammeter\u2019 is actually an abbreviation for the word \u2018ampere meter\u2019… why? It is because the current flowing through a circuit is measured in Amperes (A) and this meter counts that \u2012 hence the name. There are milli-ammeters and micro-ammeters as well, for measuring smaller and smaller amounts of currents in tinier electrical circuits. Or even in living matter. Early History To be precise, ammeters are evolutions of galvanometers, which were used to detect the presence of electricity in a circuit. It was Hans Christian \u00d8rsted who first noticed that a compass needle moves if there\u2019s a wire close to it passing electricity, way back in 1820. After that, this idea was used in tangent galvanometers to measure currents. But all of them had a problem \u2012 they had to be set up along the earth\u2019s magnetic axis, and depended upon the earth\u2019s magnetic force and so were not that much dependable. This was solved by using permanent magnets to provide the \u2018force field\u2019 in which the needle mechanism can move. Thus true ammeters were born. The D’Arsonval galvanometer is a good example of an early true ammeter. Working Principle of an Ammeter To put it most simply, an ammeter is nothing but a galvanometer with a shunt resistance. A galvanometer can only detect small currents, and you cannot send a full circuit\u2019s current through it \u2012 it would not survive that. So instead what we do is to add a low-value resistor in parallel with the galvanometer. The maximum amount of current passes through the resistor (which we call that shunt resistance), and a proportional small current passes through the galvanometer. The reading on the meter remains proportional, and with the correct value shunt resistance, we can interpret the reading as the correct value of current passing through the circuit. We would discuss the details of how to convert a galvanometer to an ammeter in a later article. An ammeter is like a finger on the pulse of the live wire. How to Place an Ammeter in a Circuit Since an ammeter is supposed to measure the current in a circuit, it has to be connected in a way so that it does not disturb the normal current flowing through the system. An ammeter has very low (ideally, zero) internal resistance. So, if you connect it in parallel to two points, the whole current will pass through the meter itself and the actual circuit will not have any power (at least, the point between which you\u2019re measuring). This is why an ammeter must be connected in series in the circuit to measure the current flowing through it. When in series, an ideal ammeter acts like just another piece of wire, so the current doesn\u2019t get affected. Please note that so far we\u2019ve talked about DC ammeters only; anything you\u2019ve learned above applies to a direct current flowing through a circuit. For measuring AC current, see below. Types of Ammeters Though not very complicated to begin with, ammeters can vary depending upon their inner mechanism. The most common ammeter types are as follows: Moving Coil Ammeter As we have mentioned above, the basic ammeter was just a compass, deflecting due to electromagnetic force created by a nearby live wire. But it was found to be far better to use a static strong magnet to deflect a loosely held wire itself. This is the basic idea behind the moving coil ammeter. A moving coil ammeter has three main components \u2012 a permanent magnet, a spiral spring, and a coil of thin wire mounted on the spring. The needle is also mounted on the spring too. When current flows through the coil, it creates a magnetic field and the field from the permanent magnet pushes it. Since the magnet is immovable but this coil is mounted on a spiral spring, it gives way and rotates as per the strength of its magnetic field. And so the needle moves and we see a reading. It was Edward Weston who perfected this type of moving coil ammeter first. These meters have linear scales and can measure current from a few micro-amperes to 10 milli-amperes. These ammeters have a precise direction of current; meaning they have a positive and a negative pole. Also, they cannot measure AC current. Moving Magnet Ammeter Operating on more or less the same principle as above, the moving magnetic ammeter keeps the magnet moving while keeping the coil static. The coil sits cozily with the meter case, while a tiny but good magnet sits on top of the spiral spring with the needle. Moving magnet ammeters can have big, thick coils, and so they can detect much higher amounts of currents like 20-50 Amperes. They are also larger than the previous kind of ammeters. In fact, some of them have so powerful magnets, instead of spiral springs they have to use some other mechanism to fix the magnet. Electrodynamic Ammeter or AC Ammeter What if, instead of using one magnet and one coil, we use both coils? The result is what we call an electrodynamic ammeter. Instead of a magnet, it has a coil acting as an electromagnet, and the other coil sits on a spring-work platform with the needle as usual. Instead of a permanent magnetic field, the needle moves on the influence of the temporary magnet created by the bigger coil. Since the polarity of<\/p>\n","protected":false},"author":9,"featured_media":510,"comment_status":"open","ping_status":"open","sticky":false,"template":"","format":"standard","meta":{"footnotes":""},"categories":[11,4,6,1],"tags":[],"ppma_author":[380],"class_list":["post-151","post","type-post","status-publish","format-standard","has-post-thumbnail","hentry","category-equipment","category-learning","category-physics","category-product"],"yoast_head":"\n
What is an Ammeter and Why Do We Use It | Labkafe - Labkafe Blogs<\/title>\n<meta name=\"robots\" content=\"index, follow, max-snippet:-1, max-image-preview:large, max-video-preview:-1\" \/>\n<link rel=\"canonical\" href=\"https:\/\/www.labkafe.com\/blog\/what-is-an-ammeter-and-why-do-we-use-it-labkafe\/\" \/>\n<meta property=\"og:locale\" content=\"en_US\" \/>\n<meta property=\"og:type\" content=\"article\" \/>\n<meta property=\"og:title\" content=\"What is an Ammeter and Why Do We Use It | Labkafe - Labkafe Blogs\" \/>\n<meta property=\"og:description\" content=\"If you\u2019ve gone through physics practical classes of most school boards, experiments based on electricity would have been part of the lessons and you must have seen an ammeter in action. It is part of most electricity-related textbooks for school classes 10 to 12 as well. Today, we will tell you what exactly an ammeter is, how it works, how much it costs, and how many types of them are there. One thing you can be certain of \u2012 ammeters are an obvious part of any electronics or physics lab equipment package . Definition of an Ammeter An ammeter is an instrument for measuring the current flowing through a live circuit. The word \u2018ammeter\u2019 is actually an abbreviation for the word \u2018ampere meter\u2019… why? It is because the current flowing through a circuit is measured in Amperes (A) and this meter counts that \u2012 hence the name. There are milli-ammeters and micro-ammeters as well, for measuring smaller and smaller amounts of currents in tinier electrical circuits. Or even in living matter. Early History To be precise, ammeters are evolutions of galvanometers, which were used to detect the presence of electricity in a circuit. It was Hans Christian \u00d8rsted who first noticed that a compass needle moves if there\u2019s a wire close to it passing electricity, way back in 1820. After that, this idea was used in tangent galvanometers to measure currents. But all of them had a problem \u2012 they had to be set up along the earth\u2019s magnetic axis, and depended upon the earth\u2019s magnetic force and so were not that much dependable. This was solved by using permanent magnets to provide the \u2018force field\u2019 in which the needle mechanism can move. Thus true ammeters were born. The D’Arsonval galvanometer is a good example of an early true ammeter. Working Principle of an Ammeter To put it most simply, an ammeter is nothing but a galvanometer with a shunt resistance. A galvanometer can only detect small currents, and you cannot send a full circuit\u2019s current through it \u2012 it would not survive that. So instead what we do is to add a low-value resistor in parallel with the galvanometer. The maximum amount of current passes through the resistor (which we call that shunt resistance), and a proportional small current passes through the galvanometer. The reading on the meter remains proportional, and with the correct value shunt resistance, we can interpret the reading as the correct value of current passing through the circuit. We would discuss the details of how to convert a galvanometer to an ammeter in a later article. An ammeter is like a finger on the pulse of the live wire. How to Place an Ammeter in a Circuit Since an ammeter is supposed to measure the current in a circuit, it has to be connected in a way so that it does not disturb the normal current flowing through the system. An ammeter has very low (ideally, zero) internal resistance. So, if you connect it in parallel to two points, the whole current will pass through the meter itself and the actual circuit will not have any power (at least, the point between which you\u2019re measuring). This is why an ammeter must be connected in series in the circuit to measure the current flowing through it. When in series, an ideal ammeter acts like just another piece of wire, so the current doesn\u2019t get affected. Please note that so far we\u2019ve talked about DC ammeters only; anything you\u2019ve learned above applies to a direct current flowing through a circuit. For measuring AC current, see below. Types of Ammeters Though not very complicated to begin with, ammeters can vary depending upon their inner mechanism. The most common ammeter types are as follows: Moving Coil Ammeter As we have mentioned above, the basic ammeter was just a compass, deflecting due to electromagnetic force created by a nearby live wire. But it was found to be far better to use a static strong magnet to deflect a loosely held wire itself. This is the basic idea behind the moving coil ammeter. A moving coil ammeter has three main components \u2012 a permanent magnet, a spiral spring, and a coil of thin wire mounted on the spring. The needle is also mounted on the spring too. When current flows through the coil, it creates a magnetic field and the field from the permanent magnet pushes it. Since the magnet is immovable but this coil is mounted on a spiral spring, it gives way and rotates as per the strength of its magnetic field. And so the needle moves and we see a reading. It was Edward Weston who perfected this type of moving coil ammeter first. These meters have linear scales and can measure current from a few micro-amperes to 10 milli-amperes. These ammeters have a precise direction of current; meaning they have a positive and a negative pole. Also, they cannot measure AC current. Moving Magnet Ammeter Operating on more or less the same principle as above, the moving magnetic ammeter keeps the magnet moving while keeping the coil static. The coil sits cozily with the meter case, while a tiny but good magnet sits on top of the spiral spring with the needle. Moving magnet ammeters can have big, thick coils, and so they can detect much higher amounts of currents like 20-50 Amperes. They are also larger than the previous kind of ammeters. In fact, some of them have so powerful magnets, instead of spiral springs they have to use some other mechanism to fix the magnet. Electrodynamic Ammeter or AC Ammeter What if, instead of using one magnet and one coil, we use both coils? The result is what we call an electrodynamic ammeter. Instead of a magnet, it has a coil acting as an electromagnet, and the other coil sits on a spring-work platform with the needle as usual. Instead of a permanent magnetic field, the needle moves on the influence of the temporary magnet created by the bigger coil. Since the polarity of\" \/>\n<meta property=\"og:url\" content=\"https:\/\/www.labkafe.com\/blog\/what-is-an-ammeter-and-why-do-we-use-it-labkafe\/\" \/>\n<meta property=\"og:site_name\" content=\"Labkafe Blogs\" \/>\n<meta property=\"article:publisher\" content=\"https:\/\/www.facebook.com\/labkafe\" \/>\n<meta property=\"article:published_time\" content=\"2022-02-21T09:30:25+00:00\" \/>\n<meta property=\"article:modified_time\" content=\"2024-08-13T12:09:09+00:00\" \/>\n<meta property=\"og:image\" content=\"https:\/\/www.labkafe.com\/blog\/wp-content\/uploads\/2022\/02\/Ammeters-Definition-Working-Principle-Types.jpg\" \/>\n\t<meta property=\"og:image:width\" content=\"2240\" \/>\n\t<meta property=\"og:image:height\" content=\"1260\" \/>\n\t<meta property=\"og:image:type\" content=\"image\/jpeg\" \/>\n<meta name=\"author\" content=\"Swarna Karmakar\" \/>\n<meta name=\"twitter:card\" content=\"summary_large_image\" \/>\n<meta name=\"twitter:label1\" content=\"Written by\" \/>\n\t<meta name=\"twitter:data1\" content=\"Swarna Karmakar\" \/>\n\t<meta name=\"twitter:label2\" content=\"Est. reading time\" \/>\n\t<meta name=\"twitter:data2\" content=\"7 minutes\" \/>\n<script type=\"application\/ld+json\" class=\"yoast-schema-graph\">{\"@context\":\"https:\\\/\\\/schema.org\",\"@graph\":[{\"@type\":\"Article\",\"@id\":\"https:\\\/\\\/www.labkafe.com\\\/blog\\\/what-is-an-ammeter-and-why-do-we-use-it-labkafe\\\/#article\",\"isPartOf\":{\"@id\":\"https:\\\/\\\/www.labkafe.com\\\/blog\\\/what-is-an-ammeter-and-why-do-we-use-it-labkafe\\\/\"},\"author\":{\"name\":\"Swarna Karmakar\",\"@id\":\"https:\\\/\\\/www.labkafe.com\\\/blog\\\/#\\\/schema\\\/person\\\/f9b16f9c5737620eff8f6d2edf4934ca\"},\"headline\":\"What is an Ammeter and Why Do We Use It | Labkafe\",\"datePublished\":\"2022-02-21T09:30:25+00:00\",\"dateModified\":\"2024-08-13T12:09:09+00:00\",\"mainEntityOfPage\":{\"@id\":\"https:\\\/\\\/www.labkafe.com\\\/blog\\\/what-is-an-ammeter-and-why-do-we-use-it-labkafe\\\/\"},\"wordCount\":1530,\"commentCount\":0,\"publisher\":{\"@id\":\"https:\\\/\\\/www.labkafe.com\\\/blog\\\/#organization\"},\"image\":{\"@id\":\"https:\\\/\\\/www.labkafe.com\\\/blog\\\/what-is-an-ammeter-and-why-do-we-use-it-labkafe\\\/#primaryimage\"},\"thumbnailUrl\":\"https:\\\/\\\/www.labkafe.com\\\/blog\\\/wp-content\\\/uploads\\\/2022\\\/02\\\/Ammeters-Definition-Working-Principle-Types.jpg\",\"articleSection\":[\"Equipment\",\"Learning\",\"Physics\",\"Product\"],\"inLanguage\":\"en-US\",\"potentialAction\":[{\"@type\":\"CommentAction\",\"name\":\"Comment\",\"target\":[\"https:\\\/\\\/www.labkafe.com\\\/blog\\\/what-is-an-ammeter-and-why-do-we-use-it-labkafe\\\/#respond\"]}]},{\"@type\":\"WebPage\",\"@id\":\"https:\\\/\\\/www.labkafe.com\\\/blog\\\/what-is-an-ammeter-and-why-do-we-use-it-labkafe\\\/\",\"url\":\"https:\\\/\\\/www.labkafe.com\\\/blog\\\/what-is-an-ammeter-and-why-do-we-use-it-labkafe\\\/\",\"name\":\"What is an Ammeter and Why Do We Use It | Labkafe - 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It is part of most electricity-related textbooks for school classes 10 to 12 as well. Today, we will tell you what exactly an ammeter is, how it works, how much it costs, and how many types of them are there. One thing you can be certain of \u2012 ammeters are an obvious part of any electronics or physics lab equipment package . Definition of an Ammeter An ammeter is an instrument for measuring the current flowing through a live circuit. The word \u2018ammeter\u2019 is actually an abbreviation for the word \u2018ampere meter\u2019… why? It is because the current flowing through a circuit is measured in Amperes (A) and this meter counts that \u2012 hence the name. There are milli-ammeters and micro-ammeters as well, for measuring smaller and smaller amounts of currents in tinier electrical circuits. Or even in living matter. Early History To be precise, ammeters are evolutions of galvanometers, which were used to detect the presence of electricity in a circuit. It was Hans Christian \u00d8rsted who first noticed that a compass needle moves if there\u2019s a wire close to it passing electricity, way back in 1820. After that, this idea was used in tangent galvanometers to measure currents. But all of them had a problem \u2012 they had to be set up along the earth\u2019s magnetic axis, and depended upon the earth\u2019s magnetic force and so were not that much dependable. This was solved by using permanent magnets to provide the \u2018force field\u2019 in which the needle mechanism can move. Thus true ammeters were born. The D’Arsonval galvanometer is a good example of an early true ammeter. Working Principle of an Ammeter To put it most simply, an ammeter is nothing but a galvanometer with a shunt resistance. A galvanometer can only detect small currents, and you cannot send a full circuit\u2019s current through it \u2012 it would not survive that. So instead what we do is to add a low-value resistor in parallel with the galvanometer. The maximum amount of current passes through the resistor (which we call that shunt resistance), and a proportional small current passes through the galvanometer. The reading on the meter remains proportional, and with the correct value shunt resistance, we can interpret the reading as the correct value of current passing through the circuit. We would discuss the details of how to convert a galvanometer to an ammeter in a later article. An ammeter is like a finger on the pulse of the live wire. How to Place an Ammeter in a Circuit Since an ammeter is supposed to measure the current in a circuit, it has to be connected in a way so that it does not disturb the normal current flowing through the system. An ammeter has very low (ideally, zero) internal resistance. So, if you connect it in parallel to two points, the whole current will pass through the meter itself and the actual circuit will not have any power (at least, the point between which you\u2019re measuring). This is why an ammeter must be connected in series in the circuit to measure the current flowing through it. When in series, an ideal ammeter acts like just another piece of wire, so the current doesn\u2019t get affected. Please note that so far we\u2019ve talked about DC ammeters only; anything you\u2019ve learned above applies to a direct current flowing through a circuit. For measuring AC current, see below. Types of Ammeters Though not very complicated to begin with, ammeters can vary depending upon their inner mechanism. The most common ammeter types are as follows: Moving Coil Ammeter As we have mentioned above, the basic ammeter was just a compass, deflecting due to electromagnetic force created by a nearby live wire. But it was found to be far better to use a static strong magnet to deflect a loosely held wire itself. This is the basic idea behind the moving coil ammeter. A moving coil ammeter has three main components \u2012 a permanent magnet, a spiral spring, and a coil of thin wire mounted on the spring. The needle is also mounted on the spring too. When current flows through the coil, it creates a magnetic field and the field from the permanent magnet pushes it. Since the magnet is immovable but this coil is mounted on a spiral spring, it gives way and rotates as per the strength of its magnetic field. And so the needle moves and we see a reading. It was Edward Weston who perfected this type of moving coil ammeter first. These meters have linear scales and can measure current from a few micro-amperes to 10 milli-amperes. These ammeters have a precise direction of current; meaning they have a positive and a negative pole. Also, they cannot measure AC current. Moving Magnet Ammeter Operating on more or less the same principle as above, the moving magnetic ammeter keeps the magnet moving while keeping the coil static. The coil sits cozily with the meter case, while a tiny but good magnet sits on top of the spiral spring with the needle. Moving magnet ammeters can have big, thick coils, and so they can detect much higher amounts of currents like 20-50 Amperes. They are also larger than the previous kind of ammeters. In fact, some of them have so powerful magnets, instead of spiral springs they have to use some other mechanism to fix the magnet. Electrodynamic Ammeter or AC Ammeter What if, instead of using one magnet and one coil, we use both coils? The result is what we call an electrodynamic ammeter. Instead of a magnet, it has a coil acting as an electromagnet, and the other coil sits on a spring-work platform with the needle as usual. Instead of a permanent magnetic field, the needle moves on the influence of the temporary magnet created by the bigger coil. 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