• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Thermal transfer fluid with a composition based on the use of water, based on the use of water as a heat sink fluid, to which a thickener is added in small proportions to give the fluid viscosity, silicates and soda or potash in order to avoid possible corrosion and maintaining a basic pH, for its applications as a substitute for conventional thermal oil in its use as a heat sink fluid, providing a similar thermal performance with less environmental impact. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2828693A1
    申请号:ES201931046
    申请日:2019-11-27
    公开日:2021-05-27
    发明作者:Alvarez Jose Manuel Pineda
    申请人:Pineda Alvarez S L Cia;
    IPC主号:
    专利说明:

    [0001] Composition heat transfer fluid based on the use of water
    [0003] OBJECT OF THE INVENTION
    [0004] The invention, as expressed in the wording of the present specification, refers to a biodegradable and ecological fluid, a substitute for oil in its use as a coolant or heat sink in electrical or heating equipment.
    [0006] The field of application of the present invention is within the chemical sector by proposing a formula for a fluid that replaces oil in its applications within heat dissipative devices, more specifically in the air conditioning industry.
    [0008] BACKGROUND OF THE INVENTION
    [0009] As an introduction to the state of the art in the matter, it is convenient to introduce the concept of "heat sink fluid" as any liquid that, once stored in a device for this purpose and when heated using an electrical resistance, circulates inside the the circuits of the aforementioned device as a result of the difference in pressures that are generated, heated, as a consequence, the environment of the enclosure in which it is located.
    [0011] Thus, it is known by all how oil-based fluids are used in many commercial and industrial applications, for example, in industrial heating systems with thermal oil, making use of a combustion chamber through a coil. Thus, in these applications, the coil takes energy from the combustion, through the oil system pumped at low pressures that circulates through it, behaving like a thermal fluid that when heating the coils transmits the heat indirectly to a consumer, making use of of the corresponding hydraulic circuit.
    [0013] Another common application of the oil is as a thermal fluid inside a radiator, with a very similar operation to the industrial use of thermal oil. In these applications, the radiator connected to the electrical network provides energy in the form of heat through resistors placed inside it. Specifically, these resistors are in direct contact with the fluid or thermal oil contained in their interior, providing them with the necessary heat and pressure so that it expands and originates the corresponding flow of oil. inside the piping circuit that contains the radiator, until the surrounding environment is heated.
    [0015] Furthermore, heating systems that make use of thermal oil can operate at very low pressures, within a temperature range of up to 360 ° C.
    [0017] Delved into the origin and characteristics of thermal fluids, they can be classified into synthetic type or material type thermal fluids. The first group is made up of petroleum derivatives, to which different additives have been added in order to improve certain properties. On the other hand, mineral-type thermal oils are combinations of hydrocarbons to which different additives have also been added, the fundamental difference between both groups being the temperature range in which they operate, higher in synthetic-type thermal oils. .
    [0019] However, heating systems that operate with thermal oil, whether mineral, synthetic or even medicinal, are easily adapted to the requirements of each application, regardless of whether it is for the petrochemical sector, the food industry, automotive, wood , or any other sector or industry.
    [0021] Taking into account the inconveniences involved in the use of oil in today's society, since it comes from oil and, therefore, fossil fuels, it is a highly polluting fluid, when it is frequently discharged into the environment without any control. Specifically in the case of oil radiators, when their useful life ends, they usually end up in landfills where they are pressed to make better use of the metal or casing with the consequent discharge of the oil to the ground, which has a considerable environmental impact. In conclusion, there is a growing environmental awareness regarding the need to replace these thermal oils with other fluids that have similar performances during their life cycle, but that once they become waste after use, considerably reduce their impact on the environment. environment.
    [0023] Then, as a conclusion, the need arises to change the oil as a heat sink fluid, as it is usually a highly refined mineral oil for its production as a petroleum derivative and, therefore, from fossil fuels, which are limited resources. in nature and not renewable. Thus, today's society is becoming increasingly aware of the importance of caring for our environment, making our development sustainable over time in the face of the reality of climate change, as a consequence, among other things, of the disproportionate use of chemical products derived from petroleum, which at the end of their useful life generate a significant environmental impact.
    [0025] Taking into account the inventions present in the state of the art, identified by publication number and title, respectively;
    [0027] 1. ES2384848B1, Electric radiator with high performance and thermodynamic efficiency, in which the use of water as a thermal fluid is proposed, although it does not incorporate additional substances, does not solve the problems that its direct use incorporates.
    [0028] 2. ES1072521U, Low consumption electric convector radiator in which the thermal fluid is considered in oil or water, although obviously it is a proposal with specific and clearly differentiated purposes.
    [0029] 3. ES2233289T3, Heat transfer fluid containing nanoparticles and carboxylates, refers to the use of submicron particles (nanoparticles) and carboxylates to improve the heat transfer characteristics of heat transfer fluids or antifreeze coolants.
    [0030] 4. WO2015011318A1 World patent 2014-06-26. PCT / ES2014 / 070520 Thermal energy accumulation procedure in a device with condensable fluid where the problems associated with the use of water as a thermal fluid are already introduced, although obviously it is an invention with clearly differentiated purposes.
    [0031] 5. WO2013182713A1, Improved thermal fluids, where a new thermal fluid is proposed that is not based on the use of water.
    [0032] 6. ES2363288A1, Molten Salt Solar Receiver, which makes use of a thermal fluid of molten salts.
    [0033] 7. ES-2384848B1, High performance and thermodynamic efficiency electric radiator, in which the thermal fluid is water with additives.
    [0035] Faced with the described problem not solved by the state of the art, the proposed object of the present invention consists in the replacement of thermal oil as a heat sink fluid, with another fluid that does not come from fossil fuels, improving the environmental impact of the devices. that use it both throughout its useful life and after it, once it has become waste.
    [0036] A priori, as a starting conditioner, for a substance to be used as a heat carrier, it must meet the following conditions;
    [0038] S Low purchase price and easy to obtain.
    [0039] S Good thermal stability.
    [0040] S It must not deteriorate by corrosion the materials of the devices that contain it, radiators, pipes, coils, etc.
    [0041] S Low volatility.
    [0042] S Good heat transfer properties.
    [0043] S Low solidification point and low viscosity.
    [0045] Regarding the efficiency of its use, it is important to point out that a loss in energy efficiency can have secondary environmental impacts through an increase in the consumption of fossil fuels associated with a greater demand for electricity.
    [0047] Furthermore, in order to be integrated into the technology and equipment usually extended in the state of the art, it would be desirable that the new resulting fluid could replace the thermal oil without the need to carry out any changes in the existing equipment.
    [0048] Finally, it is also important to emphasize the importance that in heat transfer applications it is necessary that the fluid used is not a flammable substance. The expression "non-flammable" refers to a behavior before fire associated with a compound or compositions, by virtue of what is established in the ASTM E-681 of 2002 Standard.
    [0050] Given that the heat transfer agent with the most favorable calorific properties is water, as it allows the transmission of large amounts of heat at temperatures of up to 100 ° C without requiring high pressures, in combination with its easy obtaining, it has been investigated in the identification of a fluid that contains water as the main component and that can replace thermal oil.
    [0052] Continuing with the analysis of the behavior of water in the face of temperature changes and the problem to be solved, it is observed that as the water raises its temperature to 180 ° C, it develops a vapor pressure of 10 bar, reaching 50 bar for a temperature of 260 ° C, which inexorably involves the appearance of a series of risks that complicates its use. On the other hand, materials in prolonged contact with water suffer from corrosion and deterioration problems over time, which implies greater supervision and maintenance, making in practice that the use of indirect heating systems by means of steam is nowadays in regression.
    [0053] From the previous context, to obtain the composition of the heat sink fluid, the following conditions were proposed;
    [0055] S The fluid could not be composed of substances from fossil fuels.
    [0056] S The use of water as the main component requires a thickening substance that increases the viscosity of the resulting thermal fluid since water in its pure state has a viscosity that does not make its use in a heat dissipation system viable.
    [0057] S It is necessary that the resulting thermal fluid does not generate corrosion on the inner envelope of the device or installation that contains it.
    [0058] S Other properties present in the most widespread thermal fluids such as good properties for heat transfer, chemical stability, low or no toxicity and non-flammability.
    [0060] Based on the background and the problems described, the "Thermal transfer fluid with a composition based on the use of water", proposes a fluid based on water to which a set of components are added that gives it the appropriate characteristics for its use. as a thermal fluid, specifically, preventing it from producing the usual corrosion on containers when in contact with water, while its viscosity and energy efficiency is similar to that of the thermal oil it replaces, although it additionally provides the following advantages with respect to the state of the technical in the matter;
    [0061] S Savings in electricity consumption of the order of 30%, when comparing the use of a conventional thermal oil radiator, with respect to that which the fluid object of the invention would use while maintaining the same thermal performance.
    [0062] S Allows direct replacement of thermal oils on the market, since incorporating carboxymethylcellulose increases the viscosity of the resulting fluid, making it similar to that of a conventional thermal oil used as a heat sink in most heat-generating devices. hot.
    [0063] S Reduction of environmental impact associated with the use of the proposed fluid to replace thermal oil, by not incorporating any substance from fossil fuels.
    [0064] S Cost of acquiring water.
    [0066] EXPLANATION OF THE INVENTION
    [0067] By way of explanation of the invention, the "Heat transfer fluid with composition based on the use of water" is based on the use of water (H2O) as a heat sink fluid to which the following substances are added in the approximate proportions by weight indicated;
    [0069] A. Between 0.8% and 1% carboxymethylcellulose, in order to thicken the resulting solution.
    [0070] B. Between 0.2% and 0.7% silicates.
    [0071] C. Between 0.3% and 0.5% of sodium hydroxide (NaOH) or potassium hydroxide (KOH) as a chemical substance with alkaline properties, in order to avoid corrosion in the device in which it is used. locate the resulting fluid and maintain a basic pH.
    [0073] From the composition described, the use of silicates and sodium or potassium hydroxide prevents, on the one hand, the usual corrosion effect of water on the metallic elements with which it is in contact and, on the other, , maintains a basic pH in the range between 10 and 12, in which all the properties that the addition of carboxymethylcellulose has provided to the water remain stable.
    [0075] The referred "Heat transfer fluid based on the use of water composition" is obtained by making use of an industrial reactor provided with the following additional elements;
    [0077] A. Heating blanket, in order to accelerate and optimize the dissolution of the aforementioned substances.
    [0078] B. A stirrer that guarantees a uniform dissolution throughout the volume of fluid contained in the reactor.
    [0080] From the fluid obtained, object of the present invention, it finds application in any installation or device that requires the use of a thermal fluid, being therefore the most frequent application in electric oil radiators used in building heating systems, in which it can be used to replace thermal oil without any adaptation of the radiator providing thermal performance Equivalent to the oil it replaces and even more energy efficient.
    [0082] Illustrative examples of the invention are presented below, which are set out for a better understanding of the invention and which, in no case, should be considered a limitation of its scope.
    [0084] Thus, the aforementioned illustrative examples are a test where the operation of a radiator with different characteristics is compared when replacing the conventional thermal oil with the water-based thermal transfer fluid object of the present invention, in order to evaluate both its thermal performance and its energy efficiency.
    [0086] Example 1
    [0088] Use is made of a first solution based on the "Heat transfer fluid of composition based on the use of water" for a five-element oil radiator with a resistance of 1000 W power, according to the composition shown in Table 1 to continuation;
    [0093] Then in Figure 1, the data corresponding to the resulting temperatures in the same radiator were collected, both when using the oil as a thermal fluid and when replacing it with the fluid object of the present invention, showing that a higher temperature is reached when carrying out the substitution.
    [0095] Obviously, from the results obtained, with the replacement of the thermal fluid, the power of the resistance used inside the radiator could be reduced by the amount necessary to obtain temperatures similar to those obtained with oil as a heat sink fluid, consequently reducing the electrical consumption of the device with the consequent energy savings.
    [0097] Example 2
    [0099] A new solution is prepared with the same composition as that used in Example 1, making use on this occasion of two equal radiators of seven elements each. The power of the resistor housed in the radiator into which the additive water-based solution is to be introduced has only been reduced by 30%, without altering the original power in the second radiator, in order to carry out a new study. of temperatures comparing the temperatures obtained in individual radiators.
    [0101] Then, in Figure 2, the data of the temperatures obtained in both radiators were compiled, showing that by reducing the power of the radiator by 30%, the use of the solution based on additive water maintains the temperatures in the same range as the provided by the oil-filled radiator, consequently providing a thermal performance similar to that provided by the conventional oil-containing radiator, although reducing energy consumption by 30%.
    [0103] Example 3
    [0105] As a continuation of the previous examples and in order to confirm that they can be extrapolated to larger radiators, a new solution is prepared for a nine-element electric radiator.
    [0107] In this case, the comparison of the temperatures provided by three equal radiators is made, which only differ in the following aspects;
    [0109] A. A nine-element electric radiator that maintains the original electric power provided with conventional thermal oil.
    [0110] B. An electric radiator with a resistance of the same power as in the previous section equipped with the water-based fluid that is the object of the present invention.
    [0111] C. An electric radiator equipped with the water-based fluid object of the present invention, with a resistance of a power of 30% lower.
    [0112] By way of conclusion of the results obtained, in Figure 3, it is shown that despite the fact that in the radiator that makes use of the water-based solution the electrical power has been reduced by 30%, its thermal performance continues to be below above that provided by the oil-filled radiator at a higher electrical power.
    [0114] Example 4
    [0116] Next, a test was carried out in order to assess whether the fluid object of the present invention was actually biodegradable when in contact with plants.
    [0117] Specifically, tests were carried out with the species, "epipremnum aureum", commonly known as "potus", "pothos" or "potos" of the Araceae family native to Southeast Asia.
    [0119] The tests consisted of pouring 80 ml into different pots, for two days a week, of the following varieties of liquids;
    [0121] 1. Freshly manufactured fluid of the invention.
    [0122] 2. Fluid of the invention has once been used in an electric radiator.
    [0123] 3. Water.
    [0125] For this, five suitably numbered pits were used, from one to five, pouring freshly manufactured fluid of the invention into pits number one and two, fluid of the invention used in an electric radiator in pots number three and water in pots number four. and five, the latter called control plants, since the physical comparison of the ponds irrigated with the fluid of the invention were carried out with the latter to observe the changes they may have during the test.
    [0127] The test result showed that after three months, the plants watered with the fluid of the invention, both new and once used, did not show any deterioration, maintaining an appearance similar to that of the first day.
    [0129] That is, the plants watered with the fluid of the invention had a similar appearance to the control plants, which had been watered only with water, concluding that during During a period of 90 days, the plants had not suffered any type of disturbance when irrigated with the fluid of the invention, since they did not experience any apparent physical change during said test period.
    [0131] Once the concept expressed is established, the claim note is drawn up below, thus synthesizing the novelties that are to be claimed.
    权利要求:
    Claims (4)
    [1]
    1. Thermal transfer fluid with a composition based on the use of water, characterized by using water (H2O) as a heat sink fluid to which the following substances are added in the approximate proportions by weight indicated;
    A. Between 0.8% and 1% carboxymethylcellulose.
    B. Between 0.2% and 0.7% silicates.
    C. Between 0.3% and 0.5% of a chemical substance with alkaline properties.
    [2]
    2. Thermal transfer fluid with a composition based on the use of water, according to claim 1, characterized in that the chemical substance with alkaline properties is sodium hydroxide (NaOH).
    [3]
    3. Thermal transfer fluid with a composition based on the use of water, according to claim 1, characterized in that the chemical substance with alkaline properties is potassium hydroxide (KOH).
    [4]
    4. Equipment for obtaining the "Composition heat transfer fluid based on the use of water" of claims 1-3, characterized in that it consists of an industrial reactor equipped with a heating mantle and stirrer.
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    同族专利:
    公开号 | 公开日
    ES2828693B2|2021-11-03|
    WO2021105531A1|2021-06-03|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US20100006796A1|2008-07-11|2010-01-14|Honeywell International Inc.|Heat transfer fluid, additive package, system and method|
    ES2384848A1|2010-12-14|2012-07-13|Ignacio Durán Irazuzta|High-performance electric radiator with high thermodynamic efficiency|
    WO2017105395A1|2015-12-14|2017-06-22|Arteco Nv|Stabilization of hexagonal boron nitride nanoparticles|
    WO2018013630A1|2016-07-12|2018-01-18|Prestone Products Corporation|Heat transfer fluids and methods for preventing corrosion in heat transfer systems|
    法律状态:
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    优先权:
    申请号 | 申请日 | 专利标题
    ES201931046A|ES2828693B2|2019-11-27|2019-11-27|Composition heat transfer fluid based on the use of water|ES201931046A| ES2828693B2|2019-11-27|2019-11-27|Composition heat transfer fluid based on the use of water|
    PCT/ES2020/070113| WO2021105531A1|2019-11-27|2020-02-18|Thermal transfer fluid having a composition based on the use of water|
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