CA2458909A1 - Heat and solar energy motor-arel - Google Patents

Description

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Name of the invention Sv ~ WR ~
Goal: To have energy without pollution LIST OF PIECES
1- Sun

2- Heat of the sun

3- Big loupes 8, IS and 20 feet in diameter

4- Amplified heat

5- System of small loupes 1, 3 and 5 inches in diameter 7- Radiant heat-radiator 8- Pump 9- Liquid tank containing stored heat 11- Oil 16- Insulation 19- Gas at its normal volume 20- Arrow showing the direction of the gas 21- Pump that builds the pressure 22- Hose and gas inlet 23- Radiator-exchanger 24- Gas that grows 25- Expanded gas 26- Exit pipe 27- Piston engine, turbines or other.
28- Generator or other 29- Gas at the engine outlet 30- Hose 31- Radiator-heat exchanger 32- Expanded gas 33- Hose 34- Reserve for gas 39- Hot oil reserve 40- Hot oil 41- Hot oil entering the pipes 42- Pump 44- Radiator-exchanger 45- Hot oil outlet 46- Piping 47- Hot oil found at the reserve 48- Hot oil that enters the reserve 50- Liquid heater 51- Entrance 52- Exit 55- Solar energy sensor 61- Anti-return 62- Safety valve 63- Gas expansion and recovery tank 64- Safety valve 65- Oil expansion and recovery tank 70- Oil inlet pipe 71- Oil outlet pipe 72- Normal gas inlet pipe 73- Expired gas outlet pipe 74- Fluid inlet pipe (102) 75- Liquid outlet pipe (102) 76- Inlet pipe of dilated gas 77- Retracted gas outlet pipe 89- Chimney 90- Steam heated 91- Fire (refineries) 92- Heat 93- Heat Recovery Stage 1 94- Stage 2 heat recovery unit 95- Stage 3 heat recovery unit 96- Piping that transports heat to the reserve 97- Pipe that will be used to evacuate the water coming from the steam ° ~ d, ~ ~ - a MotorRelar thermal and solar.
In the description of this invention, means are used mechanical. To demonstrate the principles of operation, without any mechanical use restriction for operation. We use the amplified heat from the sun to heat the oil. We use .all means known and unknown, fire activated by oil, coal, cogeneration, rays laser, gamma rays, etc. to heat the oil.
Amplified heat The amplified heat of the sun is produced as follows. We will place between the mass to be heated and the sun, a system of loupes, panes known, mirrors or others allowing the concentration of the sun's rays to achieve a much higher degree of heat. We can replace the magnifying system by any known or unknown system that would do the same job. This same principle will be used with other known means and not known: the sun will be replaced by another source of heat such as Light, laser beams, gamma rays, etc. We will put a system of magnifying glasses, special glass, concave glass, mirrors, magnifying glasses or other between the shelves of The highest light mentioned and the mass to be heated.
Store the heat The thermal oil is used, the quenched oil to store the heat, you can also use any kind of liquid, gel, liquefiable fats or no or other materials having the same properties.
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Recovery and storage of cold We will take the coolness of night, cold, water, wind or other natural colds. However, if necessary, cold will be produced by mechanical or other means such as liquid nitrogen, etc.
Cold storage will be done in all kinds of liquids, gels or other materials (mass) that can be used for this purpose.
Transfer of cold and heat The transfer of heat or cold will be done by any kind of means known or unknown.
Pumping number 21 Pumping will be done by any kind of pumps regardless of the model, which can produce pressure.
Engine number 27 To use the power produced, we will use all kinds of engines that can react to the pressure created by the expansive material used.
The device that receives the power produced (number 28) will be all kinds of apparatus requiring rotary power or other for its functioning such as generator, compressor, pump and any other known or unknown.

Heat produced This heat will be used wherever heat is needed. We will use the heat produced at the place where the heat created a reaction and this without no restrictions.
Example: A frigidaire that runs on propane gas works from following way: This kind of fridge works with Liquid Nitrogen.
She is always very cold. When liquid nitrogen is heated, it becomes puts in motion and circulates on its own. In this kind of fridge, we uses propane to heat liquid nitrogen, which begins to circulate in the piping of the refrigerator. We will use the heat produced wherever the heat creates a reaction or other without any restrictions.
Heat recovery We will recover all the heat lost in the industries, central nuclear power plants, thermal power stations or wherever heat is lost and this without any restriction Gas or eznansibles We will use all gases, liquids, liquefied gases, rare gases or any other materials in liquid form, gel, etc. which takes volume in contact with the heat.
Ezgansion tank Any type of tank or cylinder manufactured with materials capable of withstanding the pressure produced and allowing expansion when necessary. . ~

Amplify the heat and concentrate the energy of the sun We will amplify the heat of the sun by the means to demonstrate for create hot air, hot liquids, hot gels or any kind of hot masses.
Solar collectors We will use the systems demonstrated to amplify the solar energy to produce electricity or others with solar or other sensors.

6 ~ 9L a Drawing number 1 This is why we introduce the c (2) p rojected by the eye (1) s 1 ecapteur-radiator (7) heat. Oil (11) flows from the reserve (9) through the pipes (17).
To allow the circulation of the oil (11), there is a pump (8).
Drawing number 2 The heat (2) coming from the sun (1) goes towards the radiator sensor (7).
On the sensor (7), there is a system of multiplication (5) of heat (2) of the sun (1).
The first heat multiplication system (5) (2) operates in the same way next. The heat sensor (7) is covered with small or medium magnifying glasses (5).
One can also use a magnifying glass system (3). We hold the sensor

(7) with the small loupes (5) at the right angle to the sun (1) by means mechanical and already known electronic The big loupes (3) will be kept to the good ones angles with the sun (1) with mechanical and electronic means.
The number 50 is a liquid heater (pool or other) that works in catching solar energy. This energy is amplified by the system by the system magnifying glass 5.
Number 51 is the cold liquid inlet. Number 52 is the exit of the liquid that has been warmed.
The SS number shows us another different kind of energy sensor solar.
We will multiply the solar energy with the system of small loupes (5).
Drawing number 3 The amplified heat (2) is accumulated in the heat store (9). oil (I 1) which is in the tank (9) will be used to heat other liquids of the reserve (14).
The circulation of the liquid and the oil will be done by pipes (17) and pumps (8).
t ~~ ~ .v Drawing number 4 This drawing shows us all the operation of a motor that is powered by a gas that expands with heat and shrinks cold.
The gas is in the reserve (34). The gas (I 9) is sucked by a pump (21).
This pump (21) built with pressure. The pumped gas (19) goes into the pipe (22) and between in the exchanger radiator (23). Gas (19) in contact with heat is expansionne (24). As it expands, the gas (24) creates a pressure. The expanded gas (25) directs in the hose (26) and enters the engine (27) and by its pressure forces the engine (27) to turn.
The motor (27) rotates a generator (28) or the like. The dilated gas (25) come out at number 29 and enters the pipe (30) and goes to the radiator (31). The radiator (31) is cooled to ambient air or liquid. Number 32 shows us that the dilated gas (25) retracts upon contact with the cold (32). Expanded gas (25), with contact from cold to resumed its shape (i 9), and descends into the pipe (33). The degree of cold used for the refresh the gas must meet the specifications of each different gas ( 19) that we can used. Too cold a temperature could prevent the good operation.
Now, we run hot oil (40) to warm the gas (19) which is in its normal state. The hot oil (40) is directed into the pipe (41).
oil hot (40) is conveyed in the pipe (46) by a pump (42). oil hot (40) then directs into the radiator-exchanger (44) which heats the gas (24). The gas (19) becomes dilated (25). The hot oil (40) exits the radiator (45) and directs in the pipe (46) and then (47) to the hot oil reservoir (39). There is a valve anti-return (61).
Safety valves (62) will be connected by pipes to a tank (63) expansion and gas recovery (19).
The hot oil (40) is stored in the reserve (39). This oil has been heated by solar energy, energy (heat recovered) or other.
Although not shown on all drawings, all pipe systems, radiators, pumps and reserves must be very well insulated (16). Number 64 is a valve of safety that is connected to an expansion tank and oil recovery.
O dQ o '~. d Drawing number 5 Radiator-exchanger (44) which heats the expanded gas (25).
The hot oil (I 1) enters through the bottom pipe (70), circulates and exits through the pipe of high (7 I) and warms the gas (19). Gas (19) enters through the bottom pipe (72) and goes out by top pipe (73). In passing, the gas that is heated expands (24). You notice that the pipe 72 is smaller than the pipe 73. This difference in size is important because the gas expands (25) and must exit faster than the gas retracted (19) enter. It is easier to have a high pressure in a smaller pipe.
Drawing number 6 Radiator retracts the gas (25) The expanded gas (25) enters the radiator through the pipe (76) through the radiator (31). By the way, the dilated gas (25) is refreshed passes through the hose (97), picks up its normal volume (19) and exits through the pipe (97).
Drawing number 7 This drawing shows us several industries and nuclear power plants that reject their heat and their superheated steam in the atmosphere or in different points of water.
Drawing number 8 This drawing shows us chimneys that reject heat in the atmosphere.
90 - Steam overheated 91 - Fire (refineries) 92 - Heat Is not demonstrated in this drawing, the heat rejected in different water points.
Q oC ~ ~ .. o The numbers 93-94-95 are heat recuperators. The recuperator (93) is bigger because it recovered a greater amount of heat to a greater degree Student. The recuperator 94 will do the same work as the 93. The temperature of the heat will be lower than that of the recuperator 93. I) is the same for the recuperator 95 face at 94 which will do the same thing as the 94 and the heat temperature will be lower that of the 94. If there is a condensation, it will be evacuated by the pipes (97).
The heat recovery will be done with the circulation of hot oil to the thermal reserve through the pipe system (96). This heat will serve to make operate a "thermal Arel engine" (drawing number 4) or for any other use.
Drawing number 9 This drawing shows us a system of cold recovery and storage of cold. The recuperator (100) of cold can recover the cold in the air or in water.
The cold will be stored in the reserve (1 OI). To store the cold, we will take liquids, preferably water to avoid pollution. However, if our recuperator (100) work in the North Pole or in winter, we will use a liquid (102) which do not freeze, antifreeze or other. The circulation of the liquid will be done by a system of pumps (8) and piping (17) Drawing number 10 Heat transfer This drawing shows us a radiator-heat exchanger with heat transfer or cold.
Number 210 represents a radiator. This radiator (210) is enfenmé in a box (200) A liquid (212) enters the radiator (210) through the inlet (211).
arrows with round points show us the direction that the liquid follows (213) and directs to the loudness 214.
The radiator (210) is in the box (200) where an oil (206) circulates. oil (206) enter through the entrance (201). So, all the arrows with squares show The direction that the oil follows and goes to the exit (205). Oil being a lot hotter than the liquid, it will transmit its heat to the liquid. This is called a transfer of heat. The same principle can be used to transfer cold. All the system is isolated (16).
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