Microwave heating glass bending process

1. A system comprising:

• a first furnace comprising infrared heaters and temperature sensors;
  
  a second furnace comprising infrared heaters, a device that produces ultra-high frequency, high-power electromagnetic waves, and an optical system for controlling shape, location and movement of a beam of the device to a glass sheet on a bending iron within the second furnace, and one or more infrared (IR) imaging sensors;
  
  a conveyor system for carrying the glass sheet on the bending iron through the first and second furnaces;
  
  a computer system connected to the one or more IR imaging sensors and one or both of the ultra-high frequency, high-power device and the optical system, the computer system comprising one or more processors programmed or configured to control selective heating by the ultra-high frequency, high-power device to heat and bend the glass sheet in the second furnace, wherein the one or more processors are further programmed or configured to;
  
  obtain a temperature profile of the glass sheet at a plurality of time points during bending of the glass sheet in the second furnace from the one or more IR imaging sensors,compare, during the bending of the glass sheet in the second furnace, the obtained temperature profile to a reference temperature distribution, andcontrol the ultra-high frequency, high-power device to selectively heat the glass sheet to match the reference temperature distribution during the bending of the glass sheet in the second furnace,wherein the reference temperature distribution defines a plurality of reference temperatures of a plurality of portions of the glass sheet at the plurality of time points during the bending of the glass sheet in the second furnace,wherein a first reference temperature of a first portion of the plurality of portions of the glass sheet at a first time point in the reference temperature distribution during the bending of the glass sheet in the second furnace is different than a second reference temperature of the first portion of the glass sheet at a second time point in the reference temperature distribution during the bending of the glass sheet in the second furnace,wherein, without the glass sheet being removed from the second furnace, the one or more microprocessors are further programmed or configured to;
  
  obtain, from the one or more IR imaging sensors, a first measured temperature of the first portion of the plurality of portions of the glass sheet at the first time point during the bending of the glass sheet in the second furnace;
  
  compare the first measured temperature to the first reference temperature;
  
  control the ultra-high frequency, high-power device to selectively heat the first portion of the glass sheet to match the first reference temperature during the bending of the glass sheet in the second furnace;
  
  obtain, from the one or more IR imaging sensors, a second measured temperature of the first portion of the plurality of portions of the glass sheet at the second time point during the bending of the glass sheet in the second furnace;
  
  compare the second measured temperature to the second reference temperature; and
  
  control the ultra-high frequency, high-power device to selectively heat the first portion of the glass sheet to match the second reference temperature during the bending of the glass sheet in the second furnace; and
  
  one or more positional sensors in the second furnace to obtain positional data for one or more portions of the glass sheet during bending, wherein the positional sensors are connected to the computer system, and wherein the one or more processors are further programmed or configured to;
  
  obtain data from the one or more positional sensors at one or more time points during the bending of the glass sheet;
  
  produce a shape profile for the glass sheet from the obtained data from the one or more positional sensors at the one or more time points;
  
  compare the obtained shape profile to a reference shape profile concurrently with comparing the obtained temperature profile to the reference temperature distribution; and
  
  control the ultra-high frequency, high-power device to selectively heat the glass sheet to match a shape profile of the glass sheet to the reference shape profile.