Solar energy absorption and distribution system with full solar, solar assist, and fireplace heat exchanger modes
First Claim
1. A system for controlling the environment in a building via a combination of air pre-heating and pre-cooling means automatically controlled and programmed by energy sensing devices integrated into a single system, said building having a roof exposed to solar radiation and forming the upper surface of a chamber containing a body of air which is heated by solar energy impinging on the roof, said roof and chamber configured to define an upper region of the chamber to which the solar heated air in the chamber rises, said system comprising:
- a conventional heating and air conditioning system in the building, including a furnace with an evaporator, blower means, and air distribution and air return ducting leading to and from enclosed areas of the building;
an elongate collector duct in the upper region of the chamber extending lengthwise of the chamber and having a longitudinally extending slot therein for entry of the solar pre-heated air from the chamber into the collector duct;
a supply duct having an inlet connected with the collector duct for supplying solar pre-heated air to the air return ducting of the conventional heating system for distribution of the heated air to the enclosed areas;
said slot in the collector duct having a cross-section greater than the cross-section of the inlet to the supply duct to insure that all of the highest temperature air in the chamber is induced into the collector duct and thus the supply duct;
a blower in the ducting for drawing air from the chamber and through the collector duct and supply duct and forcing the air through the distribution ducting;
damper means at the juncture of the supply duct and conventional return ducting for selectively closing off flow from one of the supply duct and return ducting and opening the other to the blower; and
thermostatically controlled means in the chamber and in the enclosed areas to (a) automatically operate the damper means to admit solar heated air from the chamber to the distribution ducting and to deenergize the furnace when the temperature of the solar heated air in the chamber is above a first predetermined value, (b) admit air from the conventional air return ducting while precluding flow of air from the collector duct and to energize the furnace when the temperature is below a second predetermined value, and (c) admit solar heated air from the chamber through the air return ducting directly to the furnace and to energize the furnace when the temperature of the solar heated air in the chamber is between said predetermined values.
0 Assignments
0 Petitions
Accused Products
Abstract
A heating and cooling system, which in the "heating" mode provides fresh, filtered, solar heated air which may be augmented by a fireplace(s) heat exchanger to selectively complement or supplant a heating system otherwise fueled by mass-purchased fossil fuels (oil, gas, coal, etc.), without resorting to intermediate steps, i.e., heat pump assist, liquid conversions, low level air mixing, etc. A collector duct extends along the peak region of an attic space to direct air, heated by solar energy impinging on the roof, to the intake of a heating and/or distribution system within the building. Vents admit outside air to the attic space, adjacent the eaves, so the air is heated by the hot roof and rises to the inlet slot of the duct in the peak region. The duct transfer can be closed and a further inlet opened to admit normal return air from the occupied areas to the heating and distribution system. In the absence of adequate solar heated air, a heat exchanger installed in a conventional fireplace may be selectively energized to perform a similar function. In the "cooling" mode, the system provides outside, cool air to the distribution system within the building, either in lieu of air normally cooled by the air-conditioning compressor, or as supply air thereto for normal cooling function.
-
Citations
3 Claims
-
1. A system for controlling the environment in a building via a combination of air pre-heating and pre-cooling means automatically controlled and programmed by energy sensing devices integrated into a single system, said building having a roof exposed to solar radiation and forming the upper surface of a chamber containing a body of air which is heated by solar energy impinging on the roof, said roof and chamber configured to define an upper region of the chamber to which the solar heated air in the chamber rises, said system comprising:
-
a conventional heating and air conditioning system in the building, including a furnace with an evaporator, blower means, and air distribution and air return ducting leading to and from enclosed areas of the building; an elongate collector duct in the upper region of the chamber extending lengthwise of the chamber and having a longitudinally extending slot therein for entry of the solar pre-heated air from the chamber into the collector duct; a supply duct having an inlet connected with the collector duct for supplying solar pre-heated air to the air return ducting of the conventional heating system for distribution of the heated air to the enclosed areas; said slot in the collector duct having a cross-section greater than the cross-section of the inlet to the supply duct to insure that all of the highest temperature air in the chamber is induced into the collector duct and thus the supply duct; a blower in the ducting for drawing air from the chamber and through the collector duct and supply duct and forcing the air through the distribution ducting; damper means at the juncture of the supply duct and conventional return ducting for selectively closing off flow from one of the supply duct and return ducting and opening the other to the blower; and thermostatically controlled means in the chamber and in the enclosed areas to (a) automatically operate the damper means to admit solar heated air from the chamber to the distribution ducting and to deenergize the furnace when the temperature of the solar heated air in the chamber is above a first predetermined value, (b) admit air from the conventional air return ducting while precluding flow of air from the collector duct and to energize the furnace when the temperature is below a second predetermined value, and (c) admit solar heated air from the chamber through the air return ducting directly to the furnace and to energize the furnace when the temperature of the solar heated air in the chamber is between said predetermined values. - View Dependent Claims (2, 3)
-
Specification
-
- Resources
-
Current AssigneeJohn P. Sheridan
-
Original AssigneeJohn P. Sheridan
-
InventorsSheridan, John P.
-
Primary Examiner(s)Makay, Albert J.
-
Assistant Examiner(s)Bennett, Henry
-
Application NumberUS06/220,237Time in Patent Office1,183 DaysField of Search165/DIG. 2, 165/DIG. 4, 165/2, 165/16, 165/485, 126/429, 237/8 R, 237/48, 236/1 G, 98/33 AUS Class Current165/48.2CPC Class CodesF24D 11/0257 air heating systemF24F 5/0046 using natural energy, e.g. ...F24F 7/025 with forced air circulation...Y02A 30/272 Solar heating or coolingY02B 10/20 Solar thermalY02B 10/70 Hybrid systems, e.g. uninte...Y02B 30/13 Hot air central heating sys...
