![]() When a block of 10 photovoltaic cells reaches the end of the conveyor, it is turned over and placed in the buffer. Operating like this, the photovoltaic cells are closely located to each other when leaving the station, as if a soldered group of elements. The conveyor stops while the object is processed at the station, and then turns on so that the station accepts the next object. The belt type conveyor and the delay at the String soldering station help to display this soldering process as accurately as possible. In the model, for soldered objects, it might seem logical to create an agent of a new type, but this is impossible, since only one type of agent can exist on a conveyor line – in our case, SolarCell. In reality, at the String soldering station, new photovoltaic cells are soldered to the block of photovoltaic cells emerging from the station. Both stations process only one photovoltaic cell at a time (property Quantity = 1) and simultaneously load and unload agents by conveyor (the Loading property value is set to Simultaneous with unloading). The length of the stations - 0.2 meters - is the sum of the length of the photovoltaic cell and the distance to the cell following it. On the conveyor there are two stations - Cell sun simulation and test, with a delay of 1 second, and String soldering, the delay time for which is set by the solderingTime parameter. Properties of the solarCellConveyor element The width of the conveyor is 0.5 meters, the distance between the photovoltaic cells (gap) is 0.04 meters, and the speed is 0.2 m/s. The model uses a belt type conveyor ( Belt option in the Type property). To simulate a conveyor that transports photovoltaic cells between stations (small conveyor on the left above), we use the solarCellConveyor element (type Conveyor). Photovoltaic cell preparation conveyor (small conveyor)
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