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4C System Enhancing Eyes Theory and Functionality
For years, high performance paintball markers have minimized paintball breakage by using a break-beam infrared sensor system commonly known as íÇeyeéª. These eye systems are traditionally positioned at the bottom of a markers breech. Single sensor eye systems will only allow a marker to fire when a paintball has finally rested on the bottom of the breech, therefore breaking the infrared beam and communicating íÇfireí_ to the markers micro-controller. A broad spectrum of controlled testing has proven this current eye system to be the predominant limiting factor when seeking out maximum rate of fire potential. Our engineering staff at Bob Long Technologies has successfully implemented an advanced system of optoelectronics which can increase a markers cycle rate almost 40%. The multi-sensor 4C System Enhancing Eyes define the absolute cutting edge in electronic marker technology.
There are two instances of wasted time in a markers firing sequence (cycle time). One instance occurs during the time taken for a micro-controller to energize the coil of a solenoid. The second instance occurs during the time taken for a markers bolt to respond to the recently transferred air pressure. This combined time can be 20mS or greater. A marker cycling at 20 balls per second has a cycle time of 50mS, so 20mS would account for 40% of the total cycle time. Using multiple sensors around the breech provides the information needed to accelerate the cycle time. A sensor near the top of the breech indicates whether or not another paintball is ready to be loaded. A sensor near the bottom of the breech indicates whether or not a paintball is properly staged and ready to be propelled. These sensors working in tandem provide us with valuable time measurements and other consistency data. Because we now know how long it takes paintballs to move down through the breech into the final staged position, we energize the solenoid coil early so when a paintball reaches the final staged position the bolt has begun its forward movement. This timing adjustment, made possible by 4C System Enhancing Eyes, eliminates all wasted time in a markers firing sequence.
4C "Play and Play"
Here is a more detailed description of how the 4C System Enhancing Eyes work. The time it takes for a markers bolt to move back past sensors toward final open position, allowing a paintball to fall, will be recorded. The time it takes for the next paintball to pass by the top sensor while falling will be recorded. The time difference between these measurements will be calculated by the markers micro-controller and a paintballs falling velocity will be obtained. This falling velocity will indicate if the hopper being used is force-fed or gravity-fed. Use of a force-fed hopper will result in the much higher falling velocity of paintballs. Force-feeding also provides the best estimates of time required for a paintball to fall into its final staged position. Because vital measurements have been obtained by the 4C System Enhancing Eyes a solenoids coil can now be pre-energized, factoring for mechanical delay. Use of a gravity-fed hopper will result in a slow inconsistent falling velocity. If a gravity-fed hopper is detected the pre-energizing sequence is ruled out by the micro-controller and only the bottom sensor will be used in processing when the firing sequence should begin. Assume it takes 15mS to get a markers bolt moving forward (calculating 20mS for a ball to fall past upper sensor into final staged position at lower sensor). In this instance the solenoid can be activated 5mS after the upper sensor is triggered. 15mS later the paintball will reach its final staged position at the same time the bolt has begun its forward movement. This cycle timing adjustment, made possible by 4C System Enhancing Eyes, eliminates all wasted time in a markers firing sequence.