please help me solve this problem i would appeticate it!!!! The first picture is the question. The second picture is table one. Third picture is figure one. The final piture is table 2.

In order to reduce the economic costs and carbon emissions, it is proposed to make use of geothermal energy (hot water available at 50C, year around) at a reasonable depth and the solar energy (PV panels) to enable a building a zero energy building. Assuming the hourly loads the building located in Houston is as shown in the attached Table. Determine the annual cost savings of using the geothermal energy or/and solar energy as produced by the panels. Assuming the heat pump employed to meet the peak heating/cooling loads as shown in the Table 1 . What additional data you need to proceed with design project. Write an executive summary for the project (not exceeding a page or two pages as per the sample summary requirements) along with the supporting calculations. Assume the equivalent full-load hours of cooling to be 1500 hours/year and equivalent full-load hours of heating to be 300 hours/year. Make reasonable assumptions, determine the simple payback period. Installed cost of PV panels is about $1.50 /watt capacity. Determine the number panels required to meet the peak heating/cooling loads along with the electrical loads due to the equipment and lighting. Equip Eloc Load, kW(day)=0.1 (night) =0 (holidays) =0 No hrsyr: Hot Eqpmt an: 0 Cool Eqpmt on: 0 Eqpmt Oet: 0 Elec. Lights, Wh*2 =1( night) =0.05 (holidays) =1 DCV Systom. Orf Zc= Enorgy Focovery System: OH Son Ert 0.85 Lat Eirt Infilfation, fraction of ACH=0,15 Vontlation, cfmperson =15 Hot Water Cons, galpersonltay =2 U- of Glass(Btufr.t. 2.F)=0.8 S.C of Glass =0.85 Eloc Power CostcentshWh =15 Gas Fuel Cost, contshtherm =123 Eoonomisor. Of Eloo kW limt 50kW cost 14.5 Wint: Therm sot =72FN. Setback =65 F Throll Range =F Sum: Thm set =76F N.Setbock =65F Throd Range =F Pk H/lat.Load, tons =1.33/0.2 in Month =3 on Day =8 at hr =7 : Peak Clmaxil, tons =3.1/0.4 in month =8 on Day =1 at hr =14 Figure 1. Schematic of Heat Pump with Remunerator and the Thermal Storage syseu. Table 2. Thermodynamic Properties at each State of the System shown in Figure 1. In order to reduce the economic costs and carbon emissions, it is proposed to make use of geothermal energy (hot water available at 50C, year around) at a reasonable depth and the solar energy (PV panels) to enable a building a zero energy building. Assuming the hourly loads the building located in Houston is as shown in the attached Table. Determine the annual cost savings of using the geothermal energy or/and solar energy as produced by the panels. Assuming the heat pump employed to meet the peak heating/cooling loads as shown in the Table 1 . What additional data you need to proceed with design project. Write an executive summary for the project (not exceeding a page or two pages as per the sample summary requirements) along with the supporting calculations. Assume the equivalent full-load hours of cooling to be 1500 hours/year and equivalent full-load hours of heating to be 300 hours/year. Make reasonable assumptions, determine the simple payback period. Installed cost of PV panels is about $1.50 /watt capacity. Determine the number panels required to meet the peak heating/cooling loads along with the electrical loads due to the equipment and lighting. Equip Eloc Load, kW(day)=0.1 (night) =0 (holidays) =0 No hrsyr: Hot Eqpmt an: 0 Cool Eqpmt on: 0 Eqpmt Oet: 0 Elec. Lights, Wh*2 =1( night) =0.05 (holidays) =1 DCV Systom. Orf Zc= Enorgy Focovery System: OH Son Ert 0.85 Lat Eirt Infilfation, fraction of ACH=0,15 Vontlation, cfmperson =15 Hot Water Cons, galpersonltay =2 U- of Glass(Btufr.t. 2.F)=0.8 S.C of Glass =0.85 Eloc Power CostcentshWh =15 Gas Fuel Cost, contshtherm =123 Eoonomisor. Of Eloo kW limt 50kW cost 14.5 Wint: Therm sot =72FN. Setback =65 F Throll Range =F Sum: Thm set =76F N.Setbock =65F Throd Range =F Pk H/lat.Load, tons =1.33/0.2 in Month =3 on Day =8 at hr =7 : Peak Clmaxil, tons =3.1/0.4 in month =8 on Day =1 at hr =14 Figure 1. Schematic of Heat Pump with Remunerator and the Thermal Storage syseu. Table 2. Thermodynamic Properties at each State of the System shown in Figure 1