The main functional modules are:

• SCADA - SCADA module available via WWW
• DASHBOARDS - presentation of data for management purposes
• REPORTS - reporting module for presentation of measurement data collected in the system
• EFFICIENCY - module calculating PR coefficients of the farm's energy efficiency
• DECRETATIONS - event decrees for the purposes of calculating farm availability coefficients
• FORECASTS - forecasting energy generation based on weather data
• PRODUCTION PLAN - production planning and data exchange with OSD/OSP
• MOBILE APP - mobile application for service services
• NOTIFICATIONS - central management of notifications (SMS, email, push notifications in the mobile application)   [-]

SCADA module

• acquisition of measurement, binary, analog data
• control
• visualization
• event log
• alarms

Data presentation

• customizable dashboards
• presentation of key production indicators
• event information

Report module

• typical reports of recorded electrical and non-electrical parameters (U, I, P, Q, temp., solar radiation, ...)
• reports of efficiency and effectiveness coefficients of farm and inverter operation
• comparative reports object/object, object/t, temp., solar radiation
• report template editor
• automatic generation and distribution of reports (email, NAS)
• presentation in tabular and graph form
• export to files in xls, pdf format
• PR (Performance Ratio) coefficients calculated according to predefined templates enabling calculations for a farm or inverter

Availability module

• Event assignment manager
• Event dictionary definition
• Mapping physical events to system events
• Defining rules and logic for automatically created events (trigger, logical conditions, execution)
• Defining priorities
• Defining manually generated events
• Controlling event overlap and defining event boundaries

Mobile application

• selected information about the state of objects in the form of infoboxes: (measurements, status/event, availability)
• grouping and aggregation of data (tree structure)
• information about events
• notifications
• control options object on/off with confirmation

The classic solution is dedicated to large operators of RES installations. We have implementations of this type with the owner and operator of several hundred PV farms located throughout Poland and with owners of PV farms that produce electricity for their own needs.

The SYNDIS-OZE cloud solution is intended for owners of a smaller number of PV farms or companies managing PV farms belonging to many different investors.

The SYNDIS-OZE system, in addition to PV farms, is also used to supervise other RES facilities such as wind farms, energy storage facilities or electric vehicle charging stations.

In combination with our field controllers, it is a comprehensive solution for the developing RES market.   [-]

The standardized communication protocols implemented in the controller allow for communication and data exchange with inverters from different manufacturers. They also allow for full cooperation with various superior systems.

The device allows for the implementation of additional, individual user requirements, thanks to the possibility of using the logic function module, which allows for the implementation of any logical functions and executive algorithms using programmable logic.

The operation, communication, stored data and configuration of the device are protected in accordance with safety principles, in accordance with current requirements. The device is designed to work in difficult ambient conditions, in locations with high dust concentration, high humidity and the presence of electromagnetic interference.

Depending on the requirements and needs, the PPC controller can be implemented on various hardware platforms, providing great flexibility in the implementation of control tasks. Thanks to this, the same control tasks can be implemented using different system solutions adapted to the customer's requirements.

Depending on the requirements, different controller modules, power supplies and mounting cassettes can be used. The controller can be additionally supplemented with appropriate input and output modules enabling the connection of additional external devices.   []

Example 1: using the SO-52v11 controller

Example 2: using the SO-52v12 controller

Proposed solutions:

Example 1 – SO-52v11 controller

• PJC-865-C2 controller module (preferred) or other controllers of this type: PJC-865-42, PJC-865-A2
• MP01-17-9/3-L8/M9 cassette
• MZA-410 power supply

Example 2 – SO-52v12 controller

• pCU-02-48 controller module
• 16 cassette
• 230V power supply

Example 3 – SO-52v21 controller

• mCU-03-10 controller module
• 16N cassette
• 230V power supply

Example 4 – SO-54SR-901 controller

Example 5 – MSG-701 controller   []

Example 3: using the SO-52v21 controller

Example 4 and 5: using the SO-54SR-901 controller (left)
and MSG-701 (right)

The diagram shown in the figure below shows the idea of ​​the PPC controller as a coordinator of the work of various devices constituting the PPM.

The PPC controller block consists of three independent function blocks:

• input block
• control block
• output block

All blocks perform their functions independently of each other. Each of them provides the required data to the remaining controller blocks. A simplified logical diagram is shown in the figure below.   []

Logical design of the PPC controller

• communication with OSD/ODP
• communication with the investor
• communication PPC controller/inverter concentrators (inverters)
• communication with station devices
• communication with weather station, temperature sensors and pyranometer (option)
• communication with the measuring transducer at the object connection point (POI)
• remote cessation of active power generation
• remote reduction of active power generation (operation with power limitation)
• active power regulation
• reactive power regulation
• power guard (monitoring of generated output power and not allowing the excess of produced active power to be fed to the grid)

PPC controller operating modes

• off (regulation process is not performed)
• on (realization of the regulation process with the photovoltaic farm in accordance with the set parameters)
• simulation (real phenomena are replaced by their mathematical models)
• by-pass (test operation mode, the controller reads data from measurement points but does not perform the regulation process)
• emergency shutdown (emergency shutdown of the device, immediate shutdown of the photovoltaic farm bypassing the slow shutdown algorithm)   []

Logical design of the PPC controller