Patent Application
20200095896
The invention is related to the generation of mechanical or electrical power from thermal energy including solar energy or heat energy lying in water in the ocean by evaporation/sublimation and condensation cycle brought by the difference in temperatures with liquids (or even solids or gases) based on the adjustable temperatures in a closed environment and the use of buoyancy factor to increase the efficiency of the energy production.
There has been so long the heat energy has been brought into use. From the beginning of steam engine to the latest diesel engine the heat energy has been being converted to mechanical or electrical energy. There are internal and external combustion engine. Steam engine is the external combustion engine and diesel and petrol engines are internal combustion engines. In internal combustion engines the thermal energy of the fuel is converted to mechanical or electrical energy as per the laws of thermodynamics that considers the temperature-pressure-volume relationships. However under the external combustion engine, steam is generated and used to run turbine or develop Rankin cycle. Coal or other heat is used for steam generation including solar energy.
In some thermal energy conversion to electrical or mechanical energy, external heat energy is utilized as given below:
As per U.S. Pat. No. 9,297,366B2 the ions generated through photo voltaic is transferred from high concentration to low concentration of steam and reverted through thermal power by bringing back the low concentration steam to normal position.
Similarly, in U.S. Pat. No. 8,794,002B2, a working fluid is used as a heat exchanger and low pressure and high pressure area are created whereby the working fluid is directed from high pressure side to low pressure side and controlled at the working area where it is converted to mechanical energy.
As per U.S. Pat. No. 8,011,182B2A power generator utilizing gases and the gravitational force as efficiently as the buoyant force which act on an apparatus in a natural or man-made liquid medium and convert such forces into mechanical energy. The power generator includes methods for a plurality of weighted uniquely configured variable density containers which ascend and descend in a primarily vertical plane and which drive one or more chains, belts or conveyances with rotating sprockets or pulleys on horizontally aligned shafts in primarily a vertical arrangement upon such apparatus.
Solar panel only captures and converts into electrical energy the light energy from sun and requires the storage in the form of batteries during the hours when there is no sunlight like cloudy times or during night.
All these conversion methods have a theoretical efficiency of less than 65% and practically more less.
Most of the heat energy conversion methods use high temperature. As the petrol and diesel engine make the air to go above 2000 Deg. Celsius and the fuel is totally spent. Steam energy also requires the steam to go around 600 Degree Celsius. Even in other conversion systems, high temperatures are preferred. Due to the high temperature requirement, the heat energy with mild temperatures say less than 10 Deg. Celsius cannot be efficiently used.
Therefore, there is a need of invention or innovation where the low temperature heat energy could be brought in use with high efficiency. There is a need where the vast solar energy can be brought in use with less cost. There is a need where the easy storage of the energy can be done and converted to electrical energy on necessity. There is a need where a renewable solar energy can be brought in use to the extent. There is a need to meet the future energy crisis. There is a need to find the fin-tech system requirement of energy which could be equal to/more than the energy the whole world is using today. There is a need where the wasted energy and garbage can be brought to use. There is a need where clean energy can be highly adopted replacing the black energy. There is a need where solar energy can be harnessed to decrease the global warming. There is a need where the abundant solar or geo-thermal energy can be used to solve energy crises. There is a need where the heat energy lying in the seas and oceans can be exploited during winter where the temperatures on the surface are very low.
The generation of mechanical or electrical energy from heat energy through the process of evaporation or sublimation and condensation along with the application of buoyancy factor to increase the efficiency of the energy production whereby the vapor obtained through a liquid when boiled or solid when sublimed or gas when pressurized by the input of heat energy at required evaporating, boiling or sublimating temperature is allowed to rise at a higher level/s in a liquid such that due to buoyancy the vapor is accelerated above and thus the energy obtained is increased as the vapor rises to the height at which the turbine is kept immersed in the liquid and the gas passes through the turbine rotating it and the vapor is condensed by the help of liquid kept in the condenser the temperature of which under normal conditions, do not exceed the boiling/sublimating point of the liquid(or solid) inside the vessels that is to be evaporated or sublimed and condensed or the temperature of the vapor boiled, evaporated or sublimed or condensed through any other possible means.
As the vapor rises through the liquid in the liquid chamber it accelerates in upward direction and then rotates the turbine immersed in the liquid generating a energy that is equal to the weight of liquid equivalent to volume of the gas passing through the turbine multiplied by the height of the turbine. Moreover, the energy is also added up during the process of flow of vapor from evaporating medium to condensing medium on the turbine kept in vapor medium.
Any prevailing temperature differences of some degrees can be easily utilized, even low temperatures (say about zero deg and −10 Degree Celsius or less) and energy be generated which is increased by the buoyancy factor. Due to the working of the technology even at low temperatures, easy energy storage medium can be used, say salts and hydroxides (e.g. NAOH) where thermal energy is stored during dehydration and obtained on their hydration or latent heat from salts stored in melting phase or even water below at ocean which is above 0 Degree Celsius where the temperature on the surface are freezing during winter acting as a natural storage. Or hot water sources natural or others also can be utilized as a storage source of thermal energy.
My invention can convert the low temperature heat energy to mechanical or electrical energy. It can convert more than 100% of the input heat energy to output without the expense of extra material or energy. It can harness the vast thermal energy from sun with ease and low cost simple technology which has become the bottleneck of bringing it in use. It can have easy storage mechanism where we can even store huge energy and utilize in need. With this technology we can store 100 s of megawatts for months or more with low cost and ease. Such a low temperature output storage given by chemicals (e.g. salt or hydroxides hydration and dehydration etc.) can be transported without losing the energy stored. The wastes that can provide thermal energy could be best utilized. As the solar energy is a renewable and clean energy the huge energy can be best utilized and stored thereby reducing the consumption of black energy and the global energy as well. It finally helps to solve the future energy crisis to the extent. The vast energy lying in the ocean where the temperature of water below is above 0 Degree Celsius and the temperature on the surface are freezing during winter can be best utilized to generate electrical energy which had never been possible.
The invention uses the following parts/items:
The Surface/Flat vessels 1 are the ones where the heating is required for evaporation or sublimation. Generally it is made in plain shape so that the heat from sun or hot water from heat storage medium or when dipped in ocean falls in the largest surface area. The shape of vessels however be changed according to the heat source applied. There is liquid inside the surface vessels. And the surface vessels 1 are kept such that it can be heated. So for solar energy they are kept facing towards the sunlight [
At the top of the chamber there is a Liquid Turbine 8 which is also immersed in the liquid. The top most part of the chamber is connected to the Gas Chamber 5. For multiple Chambers [
All the turbines 8, 9, 10 are connected to the axle 12 and axle 12 to the generator 13. The Axle and Chambers are all supported by tower 14. At the below part of the gas chamber 7, there is a liquid re-input section 23. And just above the liquid re-input section 23, a next gas turbine 11 is present through which the gas flows to the condenser 31 through cylinder 32. There is a gas turbine 11 which is also connected to the axle 12 and two valves 29 and 30 and a washer 25 in the liquid re-input section 23. The pipes 17 and 18 are connected inward and outward the condenser 31 respectively. The washer 24 and 25 are joined with same upward and downward flow. Above the washer 24 and below the turbine 11 in gas chamber 7, there is a Pusher 34 connected to an external circuit.
The condenser 31 connected with the final gas chamber 7 [Single gas Chamber for
The axle 12 is the one which is connected to the generator 13 that converts the rotational mechanical energy of turbine/axle to electrical energy.
Moreover, for the production of electricity without the use of sunlight, where hot water obtained from chemicals like NAOH hydration or molten salt or other means is used as given in
Furthermore, where the heat from lakes, seas or oceans with frozen upward layer during winter are to be used as given in
According to my invention, the liquid (or solid or gas) is placed in the flat surface vessel/s 1 completely enclosed, which is allowed to boil (or sublime or pressurize) in the presence of heat. The vessels 1 can be heated through direct sunlight [
On the other hand, from the Liquid chamber 2 the vapor goes to the top to the Liquid chamber 2 above the turbine 8 and meets the Gas Chamber 5. In
In the gas chamber 7, the pressure of vapor increases with time. The vapor with increased pressure passes to the condenser through Gas turbine 11 and cylinder 32. The gas passes to the condenser 31 through cylinder 32 to control pressure the size of which depends upon the temperature of the input energy and rate of condensation. For lower condensation and higher evaporation larger cylinder is required. As for instance, if high temperature heat energy like hydrogen gas or others is applied on the operating liquid say di-chloro methane with boiling point 39.6 degree Celsius then, the pressure may increase rapidly then the condenser's capacity. So the cylinder may hold the vapor for some time before condensation. The gas turbine 11 is also connected to the axle 12 that generates electricity when rotates. Now the gas passes to the condenser 31. On condenser 31, the gas enters to the multiple number of pipes 33 through pipe 17. The multiple number of pipes acting as inter-connection medium between the vapor and the liquid in the condenser 31 are maintained to increase the surface area of the vapor to contact with outer low temperature liquid (generally water or other liquid/s or gases based on the temperature requirement) in the condenser 31. The temperature of water (or other liquid or others) in the condenser 31 is lower than the temperature of vapor in the multi pipes 33. So, the vapor condenses transferring heat to the water (or other liquid/s) in the condenser 31.
Finally, the condensed vapor in liquid form (or solid or dense gas depending upon the nature of material to be evaporated or sublimed or pressurized inside the surface/flat vessels 1) in condenser multi-pipes 33, moves to liquid re-input section 23 through condenser out pipe 18 and liquid input valve 29. When the weight of the condensed liquid in liquid re-input section 23 and condenser-out-pipe 18 kept vertical, is greater than the weight of the washers and the pressure above the washer 24, it pushes the washer 25 along with washer 24 gradually upwards. As the washer 24 is being pushed up gradually to the pusher 34, the weight of the condensed liquid in the outward pipe 18 of the condenser 31 increases, and the washer is further pushed upward to the switching part of pusher which when touched by washer 24 starts the flow of electricity to the motor of pusher connected to the external circuit. The pusher pushes the washer 24 along with 25 downwards and expels the liquid in section 23 outwards. When the pusher pushes the washer 24 to minimum level, the switching of the power to the motor of pusher is off and the pusher stops pushing. The washers again move up gradually as before due to increasing weight of condensed liquid in vertical liquid out pipe 18 entering in section 23. Thus, there is upward and downward movement of both the washers 24 and 25 with the continuous flow of the condensed liquid accumulated in the liquid re-input section 23 outwards to the pipe 16 through valve 30 and then to surface vessel/s 1. The condensed vapor can be re-input to the vessels through application of external motor.
In this manner, as long as there is heat supply in the vessel/s 1, there is continuous evaporation and condensation and the system generates electricity through the generator 13 that contains an alternator rotated by the axle 12. The mechanical or electrical energy produced due to the evaporation and condensation process is highly increased using the buoyancy factor that depends upon the height of the tower chamber i.e. the height to which the gases rises in the liquid. The gas can be raised in one liquid chamber to a very tall height or a number of times to small height by maintaining different liquid-gas chambers between evaporation and condensation process.
Here, buoyancy factor is used to increase efficiency. With the buoyancy factor, if anything that is lighter than the liquid in which it is immersed is allowed to move freely, it moves in upward direction with the force equal to the weight of the liquid displaced by the free floating material & height of the liquid. Here, the free floating material is the vapor produced during the evaporation. The heat energy falling on the Vessel/s evaporates the liquid in the vessel/s depending upon the intensity of heat energy, surface area, boiling point of the liquid, mass of liquid and the enthalpy of vaporization of the liquid. The vapor acts as the immersed material with density lower than the liquid. There is a flow of vapor in upward direction to the top of the Liquid Chamber/s. Here the upward flowing vapor carries the energy that depends upon the weight of the liquid displaced and the height of the turbine. The more the height of the turbine the more the vapor accelerates in upward direction due to continuous upward force called buoyancy force acting on it.
The system is capable to generate excess energy using the buoyancy factor because of the difference in the volume of the matter input at bottom level and the volume of matter raising brought about by the external thermal energy. Most of the buoyancy/gravity mechanisms fail because the energy obtained from raising the low density matter in the liquid should be equally used to input the matter at the bottom of the liquid so as to make it continuous. Or in other words energy gained is equal to energy loss. Say, in a liquid of density ‘d’ and height ‘h’, a low density matter with weight ‘w’ and volume ‘v’ is input at bottom. It accelerates in upward direction due to buoyancy force. And the energy obtained is equal to the weight of liquid displaced to the height of liquid less weight of the matter raising. Gravitational force pulls the matter downward.
So,
Energy gain=[(v*d)*g*h]−w*h
[Energy=mass of liquid displaced*acceleration due to gravity*height]&
[Mass=volume*density] (i)
Again when we input the same matter from the lowest level to continue the process there is energy input which is energy loss. This input energy loss is energy obtained from the matter falling from the raised height less energy spent on input due to the change in the volume of the whole liquid at top when we put the same matter at the same pressure of liquid at bottom. Or change in pressure at bottom due to rise of volume at top. The loss energy is also the same.
Energy loss=−[(P*v)−w*h]
[Energy on changing volume=Pressure*change in volume of liquid=change in pressure due to rise of liquid then previous height*volume of matter]
We know that,
However under our system, the input material at the bottom is liquid with less density which is converted to vapor by the external thermal energy before allowing it to rise. Now the vapor of same mass as input but multiple times lesser density or higher volume is made to rise to certain height and obtain the increased energy from buoyancy. The increased energy is because of the difference in volume of the input matter (condensed liquid) and rising matter (evaporated vapor). And the increment is equal to the times of volume of vapor that is allowed to riseand volume of condensed liquid input at bottom.
Say in above equation, the volume of vapor is ‘n’ times of the volume of liquid then,
Energy gained(from vapor rise)=(n*v*d)*g*h (iii)
Let, volume of vapor is n times volume of liquid of same mass
Or, n=Vv/V1=D1/Dv [i.e. density of liquid to vapor]
As the vapor is converted to liquid before input, so,
Here multiplication of volume and density is the mass which when multiplied by acceleration due to gravity is the weight so,
Net Energy=w*h(n−1)
Net Power=w*h(n−1)/t
Where, t is the time required for converting the liquid into vapor along with the rising of the vapor to the height or conversion of vapor to liquid and input of liquid whichever is earlier.
Thus energy gained is number of times the volume of vapor greater than the volume of liquid. However if two different liquids are used the density of both the liquids affect output. The vapor displaces multiple times of the liquid input at the height where turbine is kept. The energy rotating the turbine can thus be calculated by the weight of the mass displaced and the height at which the turbine is situated. Or in other words the potential energy of the liquid displaced at the height of turbine due to vapor less the potential energy of liquid displaced at that height on input of condensed liquid is the total energy produced.
Energy generated on liquid Turbine (E1)=Weight of liquid displaced (W)*Height of the turbine (H)*(proportion of density of vapor and liquid−1)
This is given by:
Here, the weight of liquid that is converted in to vapor depends upon the latent heat of vaporization of the liquid, rate of energy falling per unit time and area, surface area of evaporating vessels, acceleration due to gravity, density of liquid and density of vapor.
Now the weight of the liquid displaced on evaporation is calculated as below:
Weight of liquid displaced on input of condensed vapor considering same rate of condensation is given by:
Moreover, the vapor is condensed by external energy and input to the system with less volume but high density than the vapor phase. During condensation also we can obtain some energy due to change in pressure. Because of condensation the vapor passes from the vapor chamber to condenser, this flow of vapor also generates some energy.
The energy generated due to the change in volume of the gas in gas chamber, through gas turbine, can be calculated as the work done due to the change in volume.
If E2 is the energy generated during time T by the condensation of V volume of gas at the pressure P then, the energy generated can be calculated as:
The power is given as below:
The Energy efficiency of the system is given by:
The normal pressure is maintained at condensation chamber so,
The efficiency of the system can be increased with the increase in the total output i.e. the energy generated for a given input. For a given liquid, all the factors in the total energy or in Efficiency cannot be changed except the height.
Thus, the efficiency of energy generated is directly related to the height of the tower chamber to which the vapor flows from bottom. Therefore, if the height is increased to the extent required, the efficiency can be increased, even more than 100%.
Moreover, the efficiency is always positive because the density of liquid is always greater than the density of vapor. Therefore, the system works because of the difference in volume of a given mass in vapor and liquid phase and is highly supported by the increase in height.
However, with the increase in height, the pressure at the bottom increases. The increase in pressure at the bottom of the chamber decreases the volume of the vapor. Due to decrease in the volume of vapor the buoyancy force decreases at below and increases gradually as it accelerates upward. Thus the buoyancy force increases gradually bringing meta-acceleration.
For our purpose we can consider the average volume of vapor for considering the mass of liquid displaced.
Although the average volume decreases with increased pressure, it always remains more than half then at STP.
Here, P1 is atmospheric pressure and Vt is also volume of certain mass at the atmospheric pressure so, both are constant for a given input. However, the P2 increases with increased height. Therefore average volume decreases with increased height thereby increasing the density of vapor [Dv].
Decrease in average volume with increased height will have reduction on the generation of electricity and the efficiency of the system.
Dv=m/Vt
New density is given by,
Thus there is increase in density of the vapor, but the density never increase more than twice.
As at a atmospheric pressure P1 the volume Vt of the mass “m” is constant.
New efficiency is given by,
The new density can go up to twice the previous density, or the average volume of vapor may go up to half than that, at the top, the efficiency may fall by 50% of previous where the vapor at the top and bottom was considered same. Even though, it still can reach above 100% with increased height. This height can be attained before the critical temperature and pressure of the vapor of the evaporated and/or sublimed and/or pressurized gas is reached.
Effect of Pressure with increased height on Latent heat of Vaporization
At increasing pressures the density of vapor increases and at the critical pressure the boiling point will be the temperature where the latent heat of vaporization is zero.
Therefore, with the increase in pressure the boiling point increases but the latent heat of vaporization decreases.
Increase in height has the following benefit:
It increases the pressure of the liquid boiling on the vessel. It increases the pressure thereby reducing the latent heat of vaporization which increases the efficiency.
As the more masses are converted to gaseous state with the same heat falling on the surface with the increase in height, the mass of the liquid at that height with volume equivalent to the volume of gas evaporated from the liquid in the vessel, increases. Thus, with increased height the efficiency increases and exceeds 100%. However, the increment is not infinity but limited to critical temperature and pressure of the liquid that is converted to vapor by the use of thermal energy.
The efficiency of pentane liquid at different heights can be seen in the attached Table below:
111 125.00
199 325.00
297 325.00
395 325.00
493 325.00
591 325.00
689 325.00
787 325.00
885 325.00
983 325.00
As for instance, Say the energy of 330 W is falling per square meter. The Surface Area of the vessel [A] is 1 square meter over which the solar power is falling. Let the time of calculation is one hour. Let the liquid has a latent heat of vaporization of 323 kj/kg. Let the density of the liquid is 1323 kg/m3 and the density of the vapor is 2.114 kg/m3.
Now the energy input [EI]=330*3600=1188 KJ
The efficiency is given as:
In the above example if we increase the height of turbine to say 60 meter, the new calculation would be as follows:
The efficiency of the new system comes to 115%
Here, the surface area of the metal surface in which vapor is enclosed is maintained such a way that it is able to transfer the heat required to condense the vapor to the liquid at the rate the vapor is produced.
Therefore, the heat to be lost during vaporization is equal to the enthalpy of vaporization.
That is, total energy lost is equal to the total energy gained during vaporization.
The system as per my invention works in the condition where the boiling and condensation is possible. Under natural conditions, water has a freezing point of 0 Deg. Celsius so in a condenser water can be used and the boiling point of liquid in the vessel should always be more than that of the liquid in the condenser. If the room temperature is 20 Deg. Celsius, any liquid with the boiling point more than 30 degree can normally be used. Thus with a temperature difference of normally 15 Deg. Celsius between the boiling point of the liquid in the vessel to be boiled and the room temperature at which the liquid in the condenser is not frozen can be used. Generally, we can use water in the condenser and the liquids like di-chloro-methane (Bp. 34.6 Deg. Celsius), Methanol (Bp. 63.4 Deg. Celsius), Ethanol (Bp. 74 Degree Celsius) etc. in the vessels.
The liquids to be boiled are air locked and do not come in contact with air so the liquids with auto ignition more than 350 Deg. Celsius can be used. The temperature of the vapor will never go in excess of 100 Deg. Celsius.
The boiling liquid is totally inside the pipes and chambers and cannot come in contact with environment so the hazard of the liquids in vapor phase it totally minimized.
From the above we can draw that the electricity generation starts as and when the liquid starts evaporating (boiling), and the boiling point of the liquid used in generally low. Say if we use ethanol the boiling point is about 64 Deg. Celsius which is easily reached in some minutes where the normal temperature is about 30 Deg. Celsius. Or if we use the di-chloro methane with boiling point 34.6 Deg. Celsius, the generation of electricity starts even if the room temperature is around 20 Deg. Celsius although there should be enough heat from sun or others.
Or in other words, with sufficient heat energy the power generation starts at low temperature also. This property of the system can be better utilized. Even the places with low sunlight the power generation can be started.
Moreover, the storage of energy is possible with those materials that releases low temperature heat energy and can be regained to original form. As and when we dissolve the Sodium hydroxide (NAOH), Calcium Chloride (Cacl2) or Calcium Hydroxide (CaOH2) in water heat energy is released rising the temperature of water to about 80 Degree Celsius or above. Now, with sufficient quantity of such heat releasing materials electrical energy can be generated. Again these materials can be evaporated in sun light or others and reused for production of electrical energy when there is no sunlight.
Similarly various salts have a low melting point which can be used for storage as they store heat equal to latent heat of vaporization and release when crystallize. Moreover, some salts like Sodium acetate (CH3COONa), calcium nitrate (CaNo3) etc, are super-cooled or meta-stable liquid that do not crystallize below their melting points. And on crystallization even at room temperature, they release the heat equal to latent heat of vaporization. So for such salts maintaining of temperature above melting point before using their heat are not required and are thus easier for storage.
Here we take Sodium Hydroxide which is exothermic when dissolved in water. NaOH.H2O releases 21.4 KJ/KG of energy when dissolved in water. It has a capacity of dissolving of 1:1 at 100 Deg. Celsius. So, with the dissolving of 1 kg of sodium hydroxide in 1 liter of water, we can get 548.97 KJ per kg (@21.4 KJ/mol.) of heat energy and as our invention system converts 100% or more of the heat energy to electrical energy so at least 100 percent of energy or 548.97 KJ of electrical energy can be considered from 1 kg of dry NaOH. 1 MW requires (1 MJ*84,600 sec=) 84,600 MJ of energy storage per day. It can be stored in 157.39 Mt of NaOH.
Similarly, considering @16.2 KJ/mol of energy released on dissolving calcium hydroxide on water we can store 1 MW Day of energy in 297.66 MT of CaOH2 and requires dehydrating for reuse (297.66 cubic meter*0.005 height).
Moreover, considering @ 81.3 KJ/mol (=739 J/gm) of energy released on dissolving calcium chloride on water, we can store 1 MW Day of energy in 116.913 MT.
When sodium acetate is heated above melting point i.e. 58 Degree Celsius it releases a heat energy of 264-289 Kj/kg even at room temperature on crystallization. So to store 1 MW Day of energy 306.5 ton of sodium acetate is required. Moreover, it releases extra heat energy while cooling it can also be utilized efficiently.
When Calcium Nitrate is heated above melting point i.e. 42.7 Degree Celsius it releases a heat energy of 153 KJ/Kg (36.1 Kj/mol) even at room temperature on crystallization. So to store 1 MW Day of energy 552.9 ton of sodium acetate is required. Moreover, it releases extra heat energy while cooling it can also be utilized efficiently.
During the winter the ocean surface can go temperature below −4 Degree Celsius to even −30 Degree Celsius or lower in some northern and southern areas. Due to such low temperature the upper part of seas or ocean is frozen, however there is still water below some thickness of ice which protects the wild life in water. Therefore the temperature of water is certainly above 0 degree Celsius. Considering the liquid Butane which has a boiling point of −1 degree Celsius and melting point of −114 degree Celsius we can use it in our system to generate electrical energy.
Here the boiling is done by the water below the ice which is above 0 degree Celsius and condensation can be done on the surface the temperature is generally below −4 degree Celsius no matter it reaches −50 degree Celsius or lower. Enormous energy can be obtained from it. One liter of water has 4.1 kj/kgK. Or in other words one cubic meter of water can have 4 MJ of energy stored with only one degree difference in temperature. Therefore thousands of Megawatts of energy can be easily generated with this vast source.
However, if the temperature above the surface is consistently below −10 degree Celsius or below we can use other liquids for greater efficiency. Say chlorine has a boiling point of −35 Degree Celsius. So if the surface temperature falls persistently below −35 Degree Celsius then chlorine liquid can be used instead of butane. Similarly Iso-propane has boiling point of −10 Degree Celsius which can be used for temperature persisting below −10 degree Celsius. However, for summer seasons these liquids like Butane, Iso-propane, chlorine etc may convert to gases so should be kept in cold storage or storage tanks that can handle the required pressure. And the liquid in our system be changed according to the temperature. Say if it is nearly 20 degree Celsius then, di-chloro-methane (Bp. 39.6 Degree Celsius), pentane (B.p. 36 Degree Celsius) or similar liquid with boiling points in excess of 30 degrees are suitable. And those liquids with low boiling point can again be reused during next winter when the temperature falls below −4 degree Celsius or lower.
In summary it can be said, that claimed invention provides the following uses and benefits:
| Number | Date | Country | Kind |
|---|---|---|---|
| 681 | Sep 2018 | NP | national |
