Variable height for thrust correction through pressure sensing in electrostatic coating system

We claim: 1 . An electrostatic edible coating system having a variable height mechanism for thrust correction through pressure sensing comprising: a first unit consisting of a motion and orientation control and twin-phase air-assisted and forced-liquid flow based electrostatic nozzle(s); a second unit comprising a roller-conveyor, a material accumulator for drifted uncoated-coating material, a pressure sensor and an induction motor configured to drive the roller-conveyor, and a third unit consisting of a control unit for position and orientation, an electrical cabinet including application specific high voltage power supply unit with current controlling mechanism for charging of liquid sprays and input voltage signals to drive motors and controlling units, an air compressor, a coating material reservoir and a liquid flow control pump, wherein disinfected, washed and dried fruits and vegetables fed on a receiver unit of roller-conveyor system driven by the induction motor with controlled revolutions per minute (rpm) and power are coated with coating material from a material reservoir, pumped by the liquid flow control pump to twin-phase air-assisted and forced-liquid flow based electrostatic nozzle(s) via a manifold with controlled pressure and residence time for uniform coating of edible materials with different viscosity. 2 . The system as claimed in claim 1 wherein the twin-phase air-assisted and forced-liquid based electrostatic nozzle(s) comprises a nozzle head consisting of six number of equidistant air passage coaxially around a liquid passage tip, an outer cap, an inner cap, a connecting coupler, a charging electrode, a connecting electrode, a metallic air supply connector and a metallic liquid connector with a liquid passage tip extending up to a region of an inner cap, where mixing of compressed air and liquid supplied by the liquid flow control pump takes place at an atomization zone. 3 . The system as claimed in claim 1 wherein the nozzle(s) has two inputs comprising compressed air from the air compressor and a liquid material reservoir pumped by the liquid flow control pump to compensate for an offset in the desired liquid flow rate due to change in viscosity of liquid coating material via manifold and the nozzle(s) may vary in number as per the requirement of liquid flow rate and the edible materials to be coated. 4 . The system as claimed in claim 1 wherein the height adjustment of the tip of the twin-phase air-assisted and forced-liquid flow based electrostatic nozzle(s) from the roller-conveyor is done using a motion control system comprising the pressure sensor, a feedback and an assembly of servo-motors which adjusts the position of the twin-phase air-assisted and forced-liquid based electrostatic nozzle(s) in x, y and z axes and orientation. 5 . The system as claimed in claim 1 wherein an assembly of servo-motors consists of four servo-motors including an z axis servo-motor, an x-y axis servo-motor to adjust position of the electrostatic nozzles(s) to accommodate a number of objects to be coated, a spray envelop control servo-motor to adjust the distance between the electrostatic nozzles for uniform and a complete coverage and nozzle tilt-control servo-motor to adjust the orientation of the electrostatic nozzle(s) for an efficient coverage of objects. 6 . The system as claimed in claim 1 wherein an uncoated-coating material collected in a V-shaped material accumulator attached below the roller-conveyor is carried back to the coating material reservoir through a liquid material recollecting pipe. 7 . The system as claimed in claim 1 wherein the pressure sensor is removable or movable from the roller-conveyor after a one-time height measurement and setting of the nozzle(s) height from the edible material to be coated. 8 . The system as claimed in claim 1 further comprising a high voltage generation unit for charging of liquid sprays in the range of 1.0-1.7 kV, wherein the high voltage generation unit comprises four sub-units including a DC to AC conversion, an AC to AC conversion, an AC to DC conversion and a device protection and current controlling mechanism, wherein: the DC to AC conversion sub-unit comprises a DC voltage source, a voltage regulator, a PWM generator, a frequency selector and a power MOSFET which finally goes to primary windings of a Fly-Back transformer (AC to AC conversion subunit); the AC to DC conversion sub-unit consists of a voltage multiplier, a rectifier, a filter and a regulator circuitry which produces a desired high voltage for the charging of liquid sprays; and the device protection and current controlling mechanism includes a bridge rectifier, a voltage divider, an A/D converter and a duty cycle selector to avoid any kind of failure leaving to the damage of high voltage generation unit. 9 . The electrostatic edible coating system as claimed in claim 1 , wherein an arrangement of dissipating stray current generated by attracting charged droplets to nozzle(s) body is made via a very high resistance which is connected to ground to avoid any shock and hazards. 10 . The system as claimed in claim 2 wherein the nozzle head, the outer cap and the inner cap are made of insulating, chemically non-reactive and food grade material which withstands high voltage up to a certain kilovolts along with all the liquid pipes used in the coating system are made up of food grade material which is non-reactive and non-corrosive in nature at normal/standard temperature and pressure. 11 . The system as claimed in claim 1 , wherein the edible materials include Aloe Vera leaf gel, antimicrobials, antioxidants, polysaccharides and protein-based materials.