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DateDate: 21-06-2019, 06:01

 Personal non-property and property rights for the invention belong to the author and protected under current legislation.
 In the continuation of the presentation of his ideas, touch series Cutlery "Innovator" platform "Innovator", after moderation, puts on investment show another innovative project - touch club "Innovator".
 With reference to the work of the mobile application Cutlery "Innovator" touch the circle "Innovator" also performs a number of functions along with other touch Cutlery this series. Given that in the Cup, mainly use for hot liquids ( tea, coffee.. ), a touch panel located on the handle of the Cup, which is a broader framework that allows you to conveniently view information and use the same touch screen. Sensors that are placed in the circle immediately deduce the temperature of the liquid in a circle on the touch panel. Can also define the main structure, for example the capacity of caffeine and sugar. You can view information ( calls, SMS, news ) with Your gadget is by interfacing with the touch mug. A heating element which is disposed in the hollow bottom of the touch circles, maintains a constant, preset temperature. As an additional feature, as well maybe in the bottom of the mug and placed a cooling element to expedite a cooling process hot liquids. Of course, monitoring it all are produced with gadget using a mobile application Cutlery. Charging this device is made using a new wireless charging technology. 
 The author of this idea and the platform "Innovator" invite developers of smart devices to implement the technology for touch mugs, which will keep the liquid inside in case of rollover.
 Considers the investment component or full redemption of the author's ideas.

DateDate: 21-06-2019, 05:56

Scientists from the National Laboratory of High Magnetic Fields (National High Magnetic Field Laboratory, MagLab) of the University of Florida set a new record for the strength of a permanent magnetic field generated by a new electromagnet with superconducting windings. In the same laboratory, there is also the previous owner of this record, an electromagnet that generates a field with a force of 45 Tesla, and a new electromagnet produces a field with a force of 45.5 Tesla. This is not like a huge breakthrough, however, this achievement opens the way to the creation of even more powerful magnets based on the use of the phenomenon of superconductivity.
Note that scientists have long been creating strong magnetic fields with the help of inductors, called solenoids. When an electric current passes through the coil windings, it creates a magnetic field. An increase in the strength of the current flowing through the windings leads to an increase in the generated magnetic field.
The electromagnet, producing a field of 45 Tesla, was the most powerful DC electromagnet for nearly two decades. This device was the key one around which all activities of MagLab specialists were concentrated, but in this laboratory there is also another magnet with windings “having electrical resistance”, roughly speaking, a copper coil producing a magnetic field of 33.6 Tesla. The windings of this magnet transmit a power of 31 MW, and in order to divert the released heat from them, it requires the pumping of thousands of liters of pre-cooled water.
Created in the laboratory MagLab new electromagnet was named “Little Big Coil 3”, its size in the assembled state does not exceed the size of a beer glass. Its superconducting windings are made from a non-traditional alloy of tin and niobium, instead a new material REBCO (rare-earth-barium-copper-oxide) is used, which becomes superconducting at a higher temperature. The thickness of the tape of this material does not exceed the thickness of a human hair, which allows for very dense winding. In addition, scientists have replaced the insulating material with a new material that does not affect the superconductivity of the windings and does not distort the generated magnetic field. All this set of measures allowed to increase the current density in the windings and to obtain a record strength of the field generated by them.
Note that such strong magnetic fields are used in basic scientific research, such as the study of the properties of new materials. The real value of this achievement is not at all in the practical use of the new magnet, the new materials and technologies used in its creation can be used to create new reliable and powerful facilities that will allow for previously impossible experiments and research.