NEW
INNOVATOR

The power plant
for your power distribution

Innovative
grid distribution

The NEW INNOVATOR is a complex, bidirectional operating power distribution system for up to 8 resp. 12 devices, representing the summit of the innovative SCHNERZINGER power distribution technology.

At first sight the NEW INNOVATOR may appear to be an oversized power bar; it actually is a small power plant to process even highest impulse currents at full speed, thanks to the ATOMIC BONDING formatting processes.

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Power

atomic-bonding-icon

Atomic
Bonding

Innovative
Power distributor

The NEW INNOVATOR is a power plant that transmits even highest pulse currents at full speed and fully cleared from interfering fields

Bidirectional protection

The absolutely recommended use of SCHNERZINGER POWER CORDS and the NEW INNOVATOR PROTECTOR forms a closed system, with an uninterrupted bidirectional mode of action.

Combined with the use of a GROUND GUARD processing of highest impulse currents is additionally absolutely free of interfering fields thanks to GIGA CANCELING technology.

CUSTOMER TESTIMONIALS

More SCHNERZINGER POWER PRODUCTS

ATOMIC BONDING vs. Monocyrstaline OCC / UPOCC Conductors

In contrast to the often only temporarily effective advantages of established treatment and manufacturing processes on the reproduction quality of high-quality audio cables, e.g. cryogenization or OCC or UPOCC casting processes, SCHNERZINGER cables with ATOMIC BONDING conductors enable an audibly purer and unrivaled true-to-life signal transmission - and this permanently! 

In order to recognize the essential advantage of the SCHNERZINGER ATOMIC BONDING technology compared to conventional methods, some background knowledge about the industrial processing of wires used as conductor material in the audio sector is required:

CONVENTIONAL CASTING METHODS:

To manufacture the conductor material in most audio cables, thick copper or silver strands are repeatedly drawn through so-called drawing dies until the wires are thin enough for further use. Every drawing process means enormous mechanical stress, which causes the crystalline grain structure of the wires to disintegrate into many crystals. In a sense, the audio signals have to find their way through many of these grain structures. The flow through the grain boundaries from grain to grain creates an enormous resistance potential every time, which is known to cause slowed signal transport.

The more complex casting process is therefore often used for higher-quality audio cables. Here, liquid copper or silver is continuously poured into molds, which results in longer grain structures. In the even more complex monocrystalline OCC or UPOCC (Ultra-Pure Ohno Continuous Casting) process, the molds are even heated and slowly cooled to prevent the material from solidifying too quickly. This process was developed by Prof. Ohno in the 1980s for industry so that fewer cracks occur in the sheet metal when the copper strands are rolled out

INNOVATIVE APPROACH WITH ATOMIC BONDING:

SCHNERZINGER ATOMIC BONDING, on the other hand, takes a completely different approach:

To easily get the idea of the innovative development approach ATOMIC BONDING, simply envision a conducting wire as a pipe filled with ice cubes, whereby the ice cubes symbolically illustrate the inner grain structure of the wire.

Since long-chain metal structures are quite sensitive and easily disintegrate again after the manufacturing process, e.g. due to vibrations and bending processes, ATOMIC BONDING is a technologically extremely complex process which does not aim at bonding individual ice cubes to form a closed, long-chain monostructure, but on the contrary at crushing the cubes. This results in the smallest ice structure components, which can subsequently be compressed into a stable, homogeneous ice mass with very high cohesive forces in the tube.

A compacted, fused mass of ice has a closed, extremely stable structure - without any gaps. This fact forms the basis for a highly pure and perfect impulse chain - for a true-to-life signal transmission.