초록 ▼

A furnace in combination with a heat pump and solar panels for providing domestic hot water and forced hot or cooled air utilizing heat pump achieved efficiency levels in an on-demand and unlimited domestic hot water, heating and air conditioning system. In heating mode, recycled air acquires heat f

A furnace in combination with a heat pump and solar panels for providing domestic hot water and forced hot or cooled air utilizing heat pump achieved efficiency levels in an on-demand and unlimited domestic hot water, heating and air conditioning system. In heating mode, recycled air acquires heat from the heat pump's condenser coil and transfers this heat to the on-demand hot water.

대표청구항 ▼

The invention claimed is: 1. An electric forced-air hydronic furnace for heating water for an on-demand hot water system and heating a recirculating air flow in a continuous air duct system, a cold water supply and a hot water outlet, said furnace comprising: a. a housing, b. an electric flash heat

The invention claimed is: 1. An electric forced-air hydronic furnace for heating water for an on-demand hot water system and heating a recirculating air flow in a continuous air duct system, a cold water supply and a hot water outlet, said furnace comprising: a. a housing, b. an electric flash heater for heating water from said cold water supply to provide said on-demand hot water, c. a split heat pump having an evaporator component thereof located external of said housing and a condenser component thereof that emits heat located within said housing, d. a first heat exchanger within said housing that includes said condenser component as the heat source to heat said recirculating air flow when said heat pump is activated and said condenser component emits heat, e. a second heat exchanger within said housing that receives heated air from said first heat exchanger and includes a hydronic heat exchanger coil through which flows selectively either (i) water from said cold water supply to be heated by heat from said heated air and used for said on-demand hot water, or (ii) hot water from said flash heater to provide supplemental heat to said air flow across said second heat exchanger, f. a blower for forcing said recirculating air flow through said first and second heat exchangers, through said continuous air duct system and back to said first heat exchanger, and g. a control means for operating said furnace for heating and delivering said on-demand hot water and/or for heating said recirculating air. 2. A furnace according to claim 1, wherein said electric flash heater comprises at least first and second heat units operable independently of each other, said first heat unit adapted to provide said on-demand hot water, and said second heat unit adapted to provide hot water to said hydronic heat exchanger coil in said second heat exchanger in said furnace for providing supplemental heat to said recirculating air flow. 3. A furnace according to claim 1, wherein said flash heater comprises at least first and second heat units operable independently of each other, where the number of heat units activated corresponds to the quantity of on-demand hot water needed. 4. A furnace according to claim 3, wherein said electric flash heater has four separate units, each with capacity of about 2.5 gallons per minute. 5. A furnace according to claim 1, further comprising a cold water supply conduit system, comprising: a main inlet, a splitter including a first branch directing said water to said second heat exchanger coil and a second branch directing said water to said electric flash heater, and valve means to selectively control cold water flows into said branches. 6. A furnace according to claim 1, comprising pump and valve means to selectively direct heated water from said second heat exchanger either to said domestic hot water outlet or to said flash heater. 7. A furnace as defined in claim 1, operable with an electric power grid, further comprising a set of photovoltaic solar panels electrically coupled to said power grid and situated for exposure to sunlight, said solar panels adapted to function as an electric current source for reverse current flow into said power grid for net metering when said furnace has no demand for heat pump operation, said heat pump drawing current normally from said power grid when said furnace signals a demand for heat pump operation either to produce heat or refrigeration. 8. A furnace according to claim 7, wherein said solar panels are attached to said top and to at least two sidewall surfaces respectively of said heat pump. 9. A furnace according to claim 7, wherein said solar panels have a capacity for generating electrical current which when directed into a power grid achieves stored credits which are sufficient to substantially pay for electric current demanded by said heat pump during its normal operation. 10. A furnace according to claim 1, wherein said split heat pump comprises evaporator and condenser components external of said housing. 11. A furnace according to claim 1, wherein said split heat pump is selectively operated in reverse as an air conditioner, where said condenser component within said first heat exchanger within said housing operates as an evaporator absorbing heat from said air flow and thus cooling said recirculating air flow. 12. A method, using an electric forced-air hydronic furnace, for heating water for an on-demand hot water system and heating a recirculating air flow in a continuous air duct system, said furnace having a housing and operable with a cold water supply and a hot water outlet, said method comprising the steps: a. heating water from said cold water supply with an electric flash heater to provide said on-demand hot water, b. providing a split heat pump having an evaporator component thereof located external of said housing and the condenser component thereof that emits heat located within said housing, c. providing a first heat exchanger within said housing that includes said condenser component as the heat source to heat said recirculating air flow when said heat pump is activated and said condenser component emits heat, d. providing a second heat exchanger within said housing that receives heated air from said first heat exchanger and includes a hydronic heat exchanger coil through which flows selectively either (i) water from said cold water supply to be heated by heat from said heated air and used for said on-demand hot water, or (ii) hot water from said flash heater to provide supplemental heat to said air flow across said second heat exchanger, e. with a blower, forcing said recirculating air flow through said first and second heat exchangers, through said continuous air duct system and back to said first heat exchanger, and f. with control means, operating said furnace for heating and delivering said on-demand hot water and/or for heating said recirculating air. 13. A method according to claim 12, operable with an electric power grid, comprising the further steps: a. electrically coupling a set of photovoltaic solar panels situated for exposure to sunlight to said power grid, said panels adapted to function as an electric power source for reverse current flow into said power grid for net metering when said furnace has no demand for heat pump operation, and b. drawing current from said power grid to operate said heat pump when said furnace signals a demand for heat pump operation either to produce heat or refrigeration. 14. A method according to claim 13, comprising the further steps of attaching said solar panels to said top and sidewall surfaces respectively of said heat pump for overhead and lateral seen exposure. 15. A method according to claim 12, comprising the further steps of situating said evaporator component of said split heat pump in a location where it is exposed to outdoors ambient air. 16. A method according to claim 13, operable with an electric power grid, comprising the further steps: a. electrically coupling a set of photovoltaic solar panels situated for exposure to sunlight to said power grid, said panels adapted to function as an electric power source for reverse current flow into said power grid for net metering when said furnace has no demand for heat pump operation, and b. drawing current from said power grid to operate said heat pump when said furnace signals a demand for heat pump operation either to produce heat or refrigeration. 17. A method according to claim 12, wherein said split heat pump is selectively operated in reverse as an air conditioner, wherein said condenser component within said first heat exchanger within said housing operates as an evaporator, whereby said first heat exchanger absorbs heat from said air flow across said first heat exchanger which thus cools said recirculating air flow.