An electromagnet is a special type of magnet in which a magnetic field is created by applying an electric current to that magnet. In the absence of current, the magnetic field disappears, and this feature is useful in many areas of electrical engineering.
An electromagnet is a fairly simple device, so its manufacture is quite simple and inexpensive. Even some schools show students the basic technique of making electromagnets using a wire, a nail and a battery.
And students watch in amazement as the quickly built electromagnet lifts lightweight metal objects such as paper clips, pins and nails.
But you can also make your own powerful DC electromagnet that is several times stronger than the ones they make in classrooms.
So, first, place your fingers on the wire 50 centimeters from the end. Wrap the wire around the top of the steel pin (you can use a large nail), starting from where your fingers rest on the wire. Carry out the winding smoothly and carefully until the very end of the pin.
Once you reach the end, begin wrapping the wire over the first layer, making a new wrap towards the top of the pin. Then wrap the wire back over the pin towards the bottom, making a second layer.
Cut the wire from the coil, leaving a 50cm piece of wire at the bottom of the pin.
Next, connect the top copper wire to the negative terminal and the bottom copper wire to the positive terminal of the battery. Make sure the wires make good contact with the terminals.
It is advisable to have a button to turn on the battery, or you can put a contactor on one end of the wire to supply power to the electromagnet, completing the circuit when needed.
After successful assembly, check the functionality of the electromagnet by bringing various metal objects to it.
It should be noted that the more powerful the battery you use, the more powerful your electromagnet will be.
Increasing the battery voltage and using more layers of the electromagnetic coil increases the power of the electromagnet.
But at the same time, you need to monitor the condition of the wire, since it can become very hot, which can ultimately be dangerous. If the thickness of the wire is small, then such wire will generate more heat.
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A little physics
As we remember (or don’t remember) from physics lessons, in order to convert electric current into a magnetic field, we need to create induction. Inductance is created using an ordinary coil, inside which this field arises and is transmitted to the steel core around which the coil is wound.
Thus, depending on the polarity, one end of the core will emit a field with a minus sign, and the opposite end will emit a field with a plus sign. But visual magnetic abilities are not affected in any way by polarity. So, when you are done with physics, you can begin decisive action to create a simple electromagnet with your own hands.
Materials for making the simplest magnet
First of all, we need any inductor with a copper wire wound around the core. This can be a regular transformer from any power supply. An excellent way to create electromagnets is to wind them around the narrowed back of picture tubes of old monitors or televisions. The conductor threads in transformers are protected by insulation consisting of an almost invisible layer of special varnish that prevents the passage of electric current, which is exactly what we need. In addition to the indicated conductors, to create an electromagnet with your own hands you also need to prepare:
- A regular one and a half volt battery.
- Scotch tape or tape.
- Sharp knife.
- Hundreds of nails.
Spot welding from the microwave - DRIVE2
Good day to all! And so I will begin. I once saw on the Internet spot welding from a microwave transformer and decided to make it myself. I disassembled the microwave and took out the transformer with the microwave surge protector. Next, I sawed the transformer along the weld seams for the convenience of dismantling the old secondary winding and winding the new one!
For ease of assembly, I wrapped tape around the core so that the winding would slide better when pressed.
It's in the trash
I left the primary winding as original, and wound the secondary winding with KG-35 squares of copper wire, the winding took 1 meter, but in order for the leads to be longer, I advise you to take 2 meters of wire. I wound 3 turns without 1/4 turn.
We put the primary in place
The process of making a simple magnet
We start by removing the wires from the transformer. As a rule, its middle is located inside the steel frame. You can, after removing the surface insulation on the coil, simply unwind the wire, dragging it between the frames and the coil. Since we don't need a lot of wire, this method is the most acceptable here. When we have released enough wire, we do the following:
- We wind the wire removed from the transformer coil around a nail, which will serve as a steel core for our electromagnet. It is advisable to make turns as often as possible, pressing them tightly against each other. Do not forget to leave a long end of the wire at the initial turn, through which our electromagnet will be powered to one of the poles of the battery.
- When we reach the opposite end of the nail, we also leave a long conductor for powering. We cut off the excess wire with a knife. To prevent the spiral we wound from unraveling, you can wrap it with tape or tape.
- We strip both ends of the wire coming from the wound nail from the insulating varnish with a knife.
- We lean one end of the stripped conductor against the positive of the battery and secure it with tape or tape so that the contact is well maintained.
- We wind the other end to the minus in the same way.
The electromagnet is ready for use. By scattering metal clips or tacks on the table, you can check its functionality.
Making a welding machine from a microwave transformer
The device has been in use for 5 years now, and by the way it works well, although the CA is not used very often. The transformer from which the welding machine is made was torn out of a rather strong microwave oven, as was the fan that was installed to cool the windings. The secondary winding has been removed from the transformer without affecting the network winding (description of the technology here). The next step to take is winding the new secondary winding with a thick cable (under 10 mm in diameter).
How to make a more powerful magnet?
How to make an electromagnet with more powerful magnetic properties with your own hands? The strength of magnetism is influenced by several factors, and the most important one is the electrical current of the battery we use. For example, by making an electromagnet from a square 4.5 volt battery, we will triple the strength of its magnetic properties. The 9-volt crown will give an even more powerful effect.
But do not forget that the stronger the electric current, the more turns will be required, since the resistance with a small number of turns will be too strong, which will lead to strong heating of the conductors. If they are heated too much, the insulating varnish may begin to melt, and the turns will begin to short-circuit to each other or to the steel core. Both will sooner or later lead to a short circuit.
Also, the strength of magnetism depends on the number of turns around the magnet core. The more there are, the stronger the induction field will be, and the stronger the magnet will be.
How to make a simple electromagnet - step-by-step instructions with diagrams
Such a device is convenient because its operation is easy to control using electric current - changing the poles, changing the force of attraction. In some matters it becomes truly indispensable, and is often used as a constructive element of various homemade products. It’s not difficult to make a simple electromagnet with your own hands, especially since almost everything you need can be found in every home.
What you will need
- Any suitable sample made of iron (it is highly magnetic). This will be the core of the electromagnet.
- The wire is copper, always with insulation to prevent direct contact of the two metals. For a homemade electric magnet, the recommended cross-section is 0.5 (but not more than 1.0).
- DC source - battery, battery, power supply.
Additionally:
- Connecting wires for connecting an electromagnet.
- Soldering iron or electrical tape to secure contacts.
This is a general recommendation since the electromagnet is made for a specific purpose. Based on this, the components of the circuit are selected.
And if it is done at home, then there cannot be any standard - whatever is at hand will do.
For example, in relation to the first point, a nail, a lock shackle, or a piece of iron rod are often used as a core - the choice of options is huge.
Winding
The copper wire is carefully wound onto the core, turn by turn. With such scrupulousness, the efficiency of the electromagnet will be the maximum possible.
After the first “pass” along the iron sample, the wire is laid in a second layer, sometimes a third. It depends on how much power the device requires.
But the direction of winding must remain unchanged, otherwise the magnetic field will become “unbalanced”, and the electromagnet will hardly be able to attract anything to itself.
To understand the meaning of the ongoing processes, it is enough to remember the physics lessons from the high school course - moving electrons, the EMF they create, the direction of its rotation.
After winding is completed, the wire is cut so that the leads can be conveniently connected to the power source. If it's a battery, then directly. When using a power supply, battery or other device, you will need connecting wires.
What to consider
There are certain difficulties with the number of layers.
- As turns increase, reactance increases. This means that the current strength will begin to decrease, and the attraction will become weaker.
- On the other hand, increasing the current rating will cause the winding to heat up.
The operating principle of the electromagnet is described in detail in the following video:
Connection
- Cleaning the copper terminals. The wire is initially coated with several layers of varnish (depending on the brand), and it is known to be an insulator.
- Soldering copper and connecting wires. Although this is not essential, you can twist it by insulating it with a PVC pipe or adhesive tape.
- Fixing the second ends of the wires on the clamps. For example, the “crocodile” type. Such removable contacts will allow you to easily change the poles of the electromagnet, if necessary during its use.
Useful tips
- To make a powerful electromagnet, home craftsmen often use a coil from an MP (magnetic starter), relays, or contactors. They are available for both 220 and 380 V.
It is not difficult to select an iron core based on its internal cross-section. For ease of control, you need to include a rheostat (variable resistance) in the circuit. Accordingly, such an electric magnet is already connected to the outlet.
The force of attraction is regulated by changing the R chain.
- You can increase the power of an electromagnet by increasing the cross-section of the core. But only up to certain limits. And here you have to experiment.
- Before making an electric magnet, you need to make sure that the selected iron sample is suitable for this. The check is quite simple. Take a regular magnet; There are a lot of things in the house on such “suction cups”. If it attracts the part selected for the core, it can be used. If the result is negative or “weak,” it is better to look for another sample.
Making an electromagnet is quite simple. Everything else depends on the patience and ingenuity of the master. You may have to experiment to get what you need - with the supply voltage, wire cross-section, and so on. Any homemade product requires not only a creative approach, but also time. If you do not regret it, then an excellent result is guaranteed.
Making a more powerful magnet
Let's try to make a 12 volt electromagnet with our own hands. It will be powered by a 12-volt AC power supply or a 12-volt car battery. To manufacture it, we will need a much larger amount of copper conductor, and therefore we should initially remove the internal coil with copper wire from the prepared transformer. A grinder is the best way to extract it.
What we need for production:
- A steel horseshoe from a large padlock, which will serve as our core. In this case, it will be possible to magnetize the pieces of iron at both ends, which will further increase the lifting capacity of the magnet.
- Coil with copper wire in varnished insulation.
- Insulating tape.
- Knife.
- Unnecessary 12 volt power supply or car battery.
The process of making a powerful 12-volt magnet
Of course, any other massive steel pin can be used as a core. But a horseshoe from an old castle will do just fine. Its bend will serve as a kind of handle if we start lifting loads of impressive weight. So, in this case, the process of making an electromagnet with your own hands is as follows:
- We wind the wire from the transformer around one of the horseshoes. We place the coils as tightly as possible. The curve of the horseshoe will interfere a little, but that's okay. When the length of the side of the horseshoe ends, we lay the turns in the opposite direction, on top of the first row of turns. We make a total of 500 turns.
- When the winding of one half of the horseshoe is ready, wrap it with one layer of electrical tape. The original end of the wire, intended for recharge from a current source, is brought out to the upper part of the future handle. We wrap our coil on the horseshoe with another layer of electrical tape. We wind the other end of the conductor to the bending core of the handle and make another coil on the other side.
- We wind the wire on the opposite side of the horseshoe. We do everything the same as in the case of the first side. When 500 turns have been laid, we also remove the end of the wire for power supply from an energy source. For those who don't understand, the procedure is clearly shown in this video.
The final stage of making an electromagnet with your own hands is recharging to the energy source. If it is a battery, we extend the ends of the stripped conductors of our electromagnet using additional wires, which we connect to the battery terminals. If this is a power supply, cut off the plug going to the consumer, strip the wires and screw a wire from the electromagnet to each one. Insulate with electrical tape. We plug the power supply into the outlet. Congratulations. You have made with your own hands a powerful 12-volt electromagnet that is capable of lifting loads over 5 kg.
Electromagnet
An electromagnet is an electrical device that creates a magnetic field when an electric current passes through it. Electromagnets (EM) are used in almost all areas of human activity.
Story
In 1824, the scientist Sturgeon created the first electromagnet. The design was a horseshoe-shaped iron rod with 18 turns of copper core. When the ends of the conductor were connected to a galvanic battery, the device acquired the properties of a magnet. Weighing about two hundred grams, the prototype electromagnet was capable of attracting metal objects weighing up to 4 kg.
Operating principle
To understand how electromagnets work, we need to look at their design. A simple device explains the principle of operation of an electromagnet. When an electric charge flows through the body of the winding, magnetic field radiation occurs, penetrating the magnetic circuit.
Magnetic flux formula
Inside a metal or ferromagnet, in accordance with the laws of physics, microscopic magnetic fields called domains are formed. Their fields, under the external influence of the winding, are arranged in a certain order. As a result, the magnetic forces of the domains are summed up, forming a strong magnetic field, giving the magnetic circuit the ability to attract massive metal objects.
Important! To stop electromagnetic induction, it is enough to disconnect the EM from the current source. In this case, a particle of the magnetic field will remain. This effect is called hysteresis.
Device
An electromagnet is a simple structure consisting of an electromagnetic coil with a metal or ferromagnetic core. An additional detail is the anchor. This element is used in relays. Attracted to the magnet, it closes the terminals of the electrical device.
Classification
EMs are distinguished by the methods of creating magnetic fields. There are three types of electromagnets:
- AC electromagnet;
- neutral DC device;
- polarized DC EM.
Magnets operating on alternating current change the direction of the magnetic flux along with twice the frequency of the electric current.
Neutral EMs connected to a direct current source create magnetic fluxes that do not depend on the direction of the electric current.
In polarized devices, the orientation of the magnetic flux is tied to the direction of the electric current. Polarized EMs consist of two magnets. One of them directs a polarizing magnetic field flux to the second electromagnet to turn it off.
Advantages of using electromagnets
The main advantage of an electric magnet over a constant source of magnetic field is that it is brought into working condition under the influence of electric current.
That is, when it is necessary to exert a magnetic influence on a certain part of space, the current is turned on.
This allows for rhythmic operation of the EM, which is successfully used in various types of electrical equipment, instruments and devices.
An electromagnet can be found in electric meters, separator units, transformers, television and audio equipment and other devices.
Powerful magnets are installed on overhead cranes in the workshops of metallurgical plants and winches of scrap metal collection enterprises.
Lifting electromagnets
One of the first applications of EMs is as speakers. The sound device is based on an electromagnet, which causes the membrane to vibrate in the audio range.
EMs are used in metal detectors to detect metal-containing objects underground, in water and in various areas.
Superconducting electromagnet
Superconductivity is considered the property of materials with resistance close to zero. Electromagnets with practically zero resistance have a super-powerful magnetic field. The force of magnetic influence can cause diamagnetic materials such as pieces of lead and organic objects to float in space.
As physicists have noticed, metals acquire the property of superconductivity at ultra-low temperatures.
To obtain the superconductivity effect, the EM windings are placed in a Dewar flask with liquid helium, which is equipped with a valve to release the vapor of the substance.
Superconducting magnets are used in medical equipment - MRI (magnetic resonance tomography) machines. Experimental hovercraft trains use superconducting magnets.
The most powerful electromagnet
The most powerful magnets are built into the Large Hadron Collider. This is a charged particle accelerator designed to accelerate counter flows of heavy lead ions and protons.
The collider is located on the territory of the European Nuclear Research Center near Geneva (Switzerland).
About 10 thousand scientists and engineers from more than 100 countries of the world took part in its construction and are conducting research.
How to make a 12v electromagnet
The easiest way to make an electromagnet is to take a regular nail, wire and battery. An insulated wire is wound along the entire length of the rod. The ends of the conductor are pressed against the poles of the battery.
To ensure that the charge is not wasted, one end of the wire is soldered to the positive contact. The other ending should be made in the form of a spring-loaded arc, which is pressed against the battery terminal with a minus sign.
The bottom photo shows how you can make an electromagnet at home.
DIY electromagnet
Note! When making an electromagnet with a battery, you can use a contact block from an old device. To turn off the magnet, it will be enough to remove the battery from the contact box.
Calculations
Before you start assembling an electromagnet with your own hands, make a preliminary calculation of its parameters. Structural elements are calculated separately for DC and AC EVs.
For DC
Before making calculations, the required value of the magnetomotive force (MF) of the coil is determined. The winding parameters must provide the required MMF, at the same time the coil must not overheat, otherwise the insulating layer of the winding wire will be lost. The initial data for the calculation are the voltage in the wire of the electromagnetic coil and the required value of the magnetomotive force.
Methods for calculating DC electromagnets are constantly published on the Internet. There you can also select formulas for determining the MMF, the cross-section of the core and winding wire, and its length.
Additional Information. Mostly on the Internet they look for calculations of 12 volt electromagnets made by themselves. Depending on your needs, you can take different calculation paths. Basically, “recipes” are chosen to determine the cross-section and length of the winding wire powered by a standard “A” or “AA” format battery.
For AC
The basis for EM AC is the calculation of the winding. As in the previous case, they are guided by the initial requirements for the MMF value.
Despite the large number of recommended calculation formulas, most often the “capabilities” of a device are determined by an experienced selection of the parameters of its design parts.
Methods for calculating EM alternating current can always be found on the World Wide Web (Internet).
Examples of using EM
The following devices can be cited as examples of the use of electromagnets:
- TVs;
- transformers;
- car starting devices.
TVs
Modern homes are usually filled with various electrical appliances. Being near a television receiver, they can influence the television screen (TV) by magnetic induction. TV already has built-in protection against screen magnetization. If multi-colored spots appear on the display field, then turn off the device for 10-20 minutes. Built-in protection will remove magnetization of the screen.
In some cases, this method does not provide the desired help. Then a special electromagnet is used, which is called a choke. This is a kind of induction coil. The device is connected to a household power outlet and passed along and across the screen. As a result, the induced magnetic fields are absorbed by the inductor.
Transformers
The design of transformers is very similar to the structure of electromagnets. Both there and there there are windings and cores. The difference between a transformer and an EM is that the former has a closed magnetic circuit. Therefore, the summed magnetic force is nullified by counter magnetic fluxes.
Car starting device
The car starter works as a starting device for the engine. It turns on while the engine is starting. The temporary transfer of starting force to the engine crankshaft is provided by a retractor electromagnet.
When you turn the key in the ignition switch, the EM pulls the gear into the crankshaft teeth. During contact, the starter motor cranks the engine until a fuel combustion cycle occurs in the engine cylinders. The traction relay then turns off the electromagnet and the starter gear returns to its original position. After which the car can move.
Electromagnets have entered the sphere of human activity so tightly that existence without them is unthinkable. Simple devices can be found everywhere. Knowledge of the principle of their operation will allow the home handyman to cope with minor repairs of household electrical devices.