Final Architecture Design. Figure 7, below, outlines the connectivity between the components installed under the type 1 heating and hot water system. While Table 1 outlines the details of the component parts of this installation type.
Final Architecture Design. The line diagram below (Figure 9 outlines the architecture (both data and hardwire connections of the equipment within the type 2 installations, followed by Table 3. Figure 9: Type 2 architecture Table 3 Type 2 Component List Component Description/Specification Connectivity Location VSCON The VSCON unit builds upon the Raspberry Pi platform. It monitors for, and transmits curtailment information from the local smart grid. Modbus-RTU from the wind turbine. Ethernet (TCP) to onsite router. Wind Turbine VNet Cloud-base control aggregator responsible for the smart functionality controlling of all equipment (either directly or indirectly), on both the generation and demand side of the SMILE infrastructure. TCP connection between internet routers located at wind farm and customer’s home. OVO Data Centre VNet Gateway The Gateway unit also builds upon the Raspberry Pi platform, and provides on-site control of equipment by Ethernet (TCP) from onsite router, and RS- 232 serial link to the Sunamp controller. Customer’s Home relaying information from VNet, and also returning data back again for processing. Sunamp Qontroller Controller unit dedicated to the control and monitoring of Sunamp PCM heat battery. In this configuration, the Qontroller is acts as the conduit between VNet control signals and the charge/discharge control of the PCM heat batteries. Controlled by the VCharge (OVO) Gateway unit via RS- 232 serial line. Customer’s Home Sunamp PCM Heat Battery Stores thermal energy. Scaled to required size in 2.8kW units, with storage capacities of 3, 6, 9 and 12kWh. Thermal energy stored in Phase Change Material solutions in sealed blocks. Heat exchangers transfer either heat to or from water flowing through the battery depending on charging or discharging. Controlled by Sunamp Controller via RS-232. Customer’s Home Air Source Heat Pump Principal source of heat. Daikin Altherma high temperature split block unit with a rated power input between 4kW and 6kW, and a rated output between 11 and 16kW, respectively. Direct plumbed closed-loop hot water loop. Comms link between Sunamp Qontroller and Daikin ASHP controller. Customer’s Home Daikin Controller Daikin controller will provide control of the ASHP by responding to data transmitted from VNet, via Dynamo. The controller will also process data from the hot water storage and signal the ASHP and hot water pumps accordingly. Modbus-RTU comms connection with VCharge (OVO) Dynamo and Daikin ASHP. Customer’s Home
Final Architecture Design. The line diagram below (Figure 12) outlines the architecture of the type 3 installations. While Table 4 outlines the component pieces of the installation type. Figure 12 Type 3 Architecture Table 4 Type 3 Component List Component Description/Specification Connectivity Location VSCON The VSCON unit builds upon the Raspberry Pi platform. It monitors for, and transmits curtailment information from the local smart grid. Modbus-RTU from the wind turbine. Ethernet (TCP) to onsite router. Wind Turbine VNet Cloud-base control aggregator responsible for the smart functionality controlling of all equipment (either directly or indirectly), on both the generation and demand side of the SMILE infrastructure. TCP connection between internet routers located at wind farm and customer’s home. OVO Data Centre VNet Gateway The Gateway unit also builds upon the Raspberry Pi platform, and provides on-site Ethernet (TCP) from onsite router, and RS- 232 serial link to the Sunamp controller. Customer’s Home control of equipment by relaying information from VNet, and also returning data back again for processing. VCharge Dynamo A separate unit which provides remote control of the hot water cylinder’s immersion element. Connects to the VCharge (OVO) Data Centre via the customer's home’s internet router. Customer’s Home Hot Water Cylinder (Heatrae Sadia Megaflo, or equivalent) Hot water storage typically ranges in capacity between 100 and 300L. Heated in- directly from ASHP. Each cylinder, depending on the model with either have a single or double immersion element; each equating to a power consumption of 3kW. High level of inbuilt insulation provides lower levels of heat loss in comparison to conventional hot water cylinders. Will supply hot water to taps, showers and baths. Connection to, and controlled by VCharge (OVO) Dynamo. Plumbed closed-loop hot water connection with ASHP. Customer’s Home Hot Water Buffer/Accumulator Tank Will be directly fed with hot water from the heat pump. It will have no immersion element or indirect heating coil. Hot water will supply central heating systems. Expected to be between 500-1,000L storage capacity; providing at least 24 hours of heating capacity. High level of thermal insulation will allow tank to be situated outside or in garage. Physical open-loop hot water connection with ASHP. Customer’s Home Air Source Heat Pump Principal source of heat. Daikin Altherma high temperature split block Direct plumbed closed-loop hot water loop. Comms link ...
Final Architecture Design. The following line diagrams (Figure 14) and component list (Table 5) illustrates the power and data links within the type 4 installation and the individual component parts. Figure 14 Type 4 Architecture Table 5 Type 4 Architecture Component Description/Specification Connectivity Location VSCON The VSCON unit builds upon the Raspberry Pi platform. It monitors for, and transmits curtailment information from the local smart grid. Modbus-RTU from the wind turbine. Ethernet (TCP) to onsite router. Wind Turbine XxXxx Cloud To provide remote control of charging/discharging events of lithium-ion battery, while also acting as remote monitoring. TCP internet link between VCharge (OVO) data centre and the customer’s home’s internet router XxXxx Data Centre VNet Cloud-base control aggregator responsible for the smart functionality controlling TCP connection between internet routers located at wind farm and OVO Data Centre of all equipment (either directly or indirectly), on both the generation and demand side of the SMILE infrastructure. customer’s home. Gateway The Gateway unit also builds upon the Raspberry Pi platform, and provides on-site control of equipment by relaying information from VNet, and also returning data back again for processing. Ethernet (TCP) from onsite router, and RS- 232 serial link to the Sunamp controller. Customer’s Home VCharge Dynamo A separate unit which provides remote control of the hot water cylinder’s immersion element. Connects to the VCharge (OVO) Data Centre via the customer's home’s internet router. Customer’s Home XxXxx Lithium-ion Battery (Scenario 1) 3.6kW/ 7.5kWh battery. This will monitor and match the instantaneous power demand of the ASHP to reduce the net power demand to zero until discharged. The aim of which is to charge the battery at off-peak times to allow ASHP to operate during peak times; giving a great level of DSM to meet curtailment events. Connected to the XxXxx data centre via the customer’s home’s internet router. This helps dictate when the battery charges from the grid and provides power to the ASHP, while also sending back data. Customer’s Home Hot Water Cylinder (Heatrae Sadia Megaflo, or equivalent) Hot water storage typically ranges in capacity between 100 and 300L. Heated in- directly from ASHP. Each cylinder, depending on the model with either have a single or double immersion element; each equating to a power consumption of 3kW. High level of inbuilt insulation provides lower levels of heat loss in com...
