China supplier OEM Neodymium magnet for Norwegian Importers

China supplier OEM
 Neodymium magnet for Norwegian Importers

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Our merchandise are commonly identified and dependable by end users and will meet continually altering financial and social desires for Tela Kevlar , Insulation Products , Rubber Sheet , We sincerely welcome overseas customers to consult for the long-term cooperation and the mutual development.
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We have been ready to share our knowledge of advertising worldwide and recommend you suitable products at most aggressive costs. So Profi Tools present you ideal price of money and we've been ready to create with each other with China supplier OEM Neodymium magnet for Norwegian Importers, The product will supply to all over the world, such as: Ukraine , Spain , Turin , Our products are widely sold to Europe, USA, Russia, UK, France, Australia, Middle East, South America, Africa, and Southeast Asia, etc. Our products are highly recognized by our customers from all around the world. And our company is committed to continually improving effectiveness of our management system to maximize customer satisfaction. We sincerely hope to make progress with our customers and create a win-win future together. Welcome to join us for business!




  • https://www.iitutor.com
    Electric motors convert electrical energy into mechanical energy. They are found in the home in various appliances such as washing machines, clothes dryers, refrigerators, vacuum cleaners,
    CD players…
    Some motors operate on direct current (DC) while others require alternating current (AC)
    Now we start exploring the principle of electric motors.
    Magnetic field around a magnet
    Observation: opposite poles of magnets attract each other and like poles of magnets repel each other. Close to a magnet, a compass free to rotate takes a particular direction.
    Interpretation:
    Magnets are surrounded by magnetic fields. The direction of the magnetic field at a particular point is given by the direction of a compass (south to north) placed at this particular point.
    Representation of a magnetic field:
    Magnetic fields are represented in diagrams using lines. These show the direction and strength of the field. The density of the field lines represents the strength of the magnetic field. The closer the lines are together, the stronger the field.
    Arrows on the magnetic lines show the direction of a compass (South-North) placed in the magnetic field.
    Magnetic field lines never cross. When a region is influenced by the magnetic fields of two or more magnets or devices, the magnetic field lines show the strength and direction of the resultant magnetic field acting in the region. They show the combined effect of the individual magnetic fields.
    The spacing of the magnetic field lines represents the strength of the magnetic field. It follows that field lines that are an equal distance apart represent a uniform magnetic field.
    Magnetic field lines leave the N pole of a magnet and enter the S pole.
    Magnetic field around a straight current-carrying conductor
    Observation: a current in a straight current-carrying conductor produces a circular magnetic field around the conductor.
    The right-hand grip rule:
    When to use it?
    When the direction of current is known and we want to find the direction of the magnetic field.
    How to use it?
    The direction of the magnetic field around a straight current-carrying conductor is found using the right-hand grip rule. When the right hand grips the conductor with the thumb pointing in the direction of conventional current, the curl of the fingers gives the direction of the magnetic field around the conductor.
    Magnetic field around solenoid or an electromagnet
    Definition: a solenoid is a coil of insulated wire that can carry an electric current. The number of times that the wire has been wrapped around a tube to make the solenoid is known as the number of ‘turns’ or ‘loops’ of the solenoid. The magnetic fields around each loop of wire add together to produce a magnetic field similar to that of a bar magnet. Note that the magnetic field goes through the centre of the solenoid as well as outside it.
    As for a bar magnet we define a south and a north pole for a solenoid.
    How to determine the poles of a solenoid?
    Method 1: The right-hand grip rule
    When to us it?
    The direction of the current in the loops is known and we want to determine the poles of the solenoid.
    How to use it?
    The right hand grips the solenoid with the fingers pointing in the same direction as the conventional current flowing in the loops of wire and the thumb points to the end of the solenoid that acts like the N pole of a bar magnet; that is, the end of the solenoid from which the magnetic field lines emerge.
    Method 2
    Draw a diagram of the ends of the solenoid, and mark in the direction of the conventional current around the solenoid. Then mark on the diagram the letter N or S that has the ends of the letter pointing in the same direction as the current. N is for an anticlockwise current, S is for a clockwise current.
    Definition: an electromagnet is a solenoid that has a soft iron core. When a current flows through the solenoid, the iron core becomes a magnet. The polarity of the iron core is the same as the polarity of the solenoid. The core produces a much stronger magnetic field than is produced by the solenoid alone. The magnetic field of a permanent magnet is compared to that of an electromagnet.
    The strength of an electromagnet can be increased by:
    - increasing the current through the solenoid
    - adding more turns of wire per unit length for a long solenoid
    - increasing the amount of soft iron in the core.

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