DESC:BACKGROUND
Technical Field
[001] Embodiments herein generally relate to a process of making an energy retaining garments, and more particularly, to a process of making the energy retaining garment without converting ceramics.
Description of the Related Art
[002] In a conventional process of making energy retaining garments provides some drawbacks and the conventional process makes the resultant garments so thick, heavy and cumbersome such that they are uncomfortable for a wearer. In an existing technology, a chemical composition, and ceramic materials are directly applied to a garment using a screen printing or forming a solution with textile auxiliary agents such as binders, softeners. The ceramic materials are applied by a pad dry cure or a dip dry cure method. The ceramic materials are made by mixing minerals in a specific composition and heating at a very high temperature of 1200-1300C. After the ceramic materials are utilized for energy retaining. The heating process (for converting ceramics) is a not an easy task and consumption of resources for the heating process are too high. The heating process makes the entire process is unsustainable and costlier.
[003] Accordingly, there remains a need for a less cumbersome process for making the energy retaining garments.
SUMMARY
[004] In view of a foregoing, an embodiment herein provides an energy retaining composition that is coated in a garment for enabling the garment to maintain an optimal energy recovery without affecting the breathability. The energy retaining composition comprises (a) from 36 % to 45 % of cyclosilicate, wherein the cyclosilicate comprises tourmaline, wherein the tourmaline comprises at least one of schorl tourmaline, dravite tourmaline or elbaite tourmaline; (b) from 30 % to 35 % of phyllosilicate, wherein the phyllosilicate comprises from 27 % to 30 % of kaolinite and from 3 % to 5 % of montmorillonite; (c) from 10 % to 15 % of metal oxide, wherein the metal oxide comprises at least one of aluminum oxide (Al2O3), zinc oxide (ZnO), titanium dioxide (TiO2) or zirconium oxide (ZrO2), (d) from 6 % to 10 % of tectosilicate, wherein the tectosilicate comprises quartz, and (e) from 0.5 % to 1.5 % of adhesive polymer, wherein the adhesive polymer comprises polyacrylic Acid.
[005] In an embodiment, the energy retaining composition comprises from 5 % to 10 % of mineral oxide, wherein the mineral oxide comprises silicon dioxide (SiO2). The energy retaining composition comprises at least one of (a) from 1 % to 2.5 % of silver, and (b) from 3.5 % to 5 % of Jade.
[006] In another embodiment, the energy retaining composition comprises (a) from 5 % to 15 % of at least one of Poly vinyl fluoride (PVF), Poly urethane (PU), or an epoxy compound as a binding agent, and (b) from 0.5 % to 11 % of wetting agent. The wetting agent comprises Iso propyl alcohol.
[007] In yet another embodiment, the energy retaining composition comprises from 0.02 % to 10.02 % of conducting polymer, wherein the conducting polymer comprises polypyrrole.
[008] In yet another embodiment, the jade crystal comprises aluminum content for increasing efficiency of the energy retaining and energy recovery.
[009] In yet another embodiment, an energy retaining composition that is coated in a garment for enabling the garment to maintain an optimal energy recovery without affecting the breathability is provided. The energy retaining composition comprises (a) 36 % of cyclosilicate, wherein the cyclosilicate comprises tourmaline, wherein the tourmaline comprises schorl tourmaline; (b) 32 % of phyllosilicate, wherein the phyllosilicate comprises 29 % of Kaolinite and 3 % of montmorillonite; (c) 15 % of metal oxide, wherein the metal oxide comprises titanium dioxide (TiO2); (d) 10 % of mineral oxide, wherein he mineral oxide comprises silicon dioxide (SiO2); (e) 6 % of tectosilicate, wherein the tectosilicate comprises quartz; and (f) 1 % of adhesive polymer, wherein the adhesive polymer comprises polyacrylic Acid.
[0010] In yet another embodiment, an energy retaining composition that is coated in a garment for enabling the garment to maintain an optimal energy recovery without affecting the breathability is provided. The energy retaining composition comprises (a) 20 % of cyclosilicate, wherein the cyclosilicate comprises tourmaline, wherein the tourmaline comprises schorl tourmaline; (b) 25 % of phyllosilicate, wherein the phyllosilicate comprises 20 % of Kaolinite and 5 % of montmorillonite; (c) 45 % of metal oxide, wherein the metal oxide comprises 20 % of zinc oxide (ZnO) and 25 % of titanium dioxide (TiO2); (d) 5 % of mineral oxide, wherein the mineral oxide comprises silicon dioxide (SiO2); (e) 5 % of tectosilicate, wherein the tectosilicate comprises quartz; and (f) 1 % of adhesive polymer, wherein the adhesive polymer comprises polyacrylic Acid.
[0011] In one aspect, a process of preparing a breathable energy retaining textile article is provided. The process comprises (a) preparing a slurry of energy retaining composition comprising mixing (i) from 36 % to 45 % of cyclosilicate, wherein the cyclosilicate comprises tourmaline, wherein the tourmaline comprises at least one of schorl tourmaline, dravite tourmaline or elbaite tourmaline; (ii) from 30 % to 35 % of phyllosilicate, wherein the phyllosilicate comprises from 27 % to 30 % of kaolinite and from 3 % to 5 % of montmorillonite; (iii) from 10 % to 15 % of metal oxide, wherein the metal oxide comprises at least one of aluminum oxide (Al2O3), zinc oxide (ZnO), titanium dioxide (TiO2) or zirconium oxide (ZrO2); (iv) from 6 % to 10 % of tectosilicate, wherein the tectosilicate comprises quartz; and (v) from 0.5 % to 1.5 % of adhesive polymer, wherein the adhesive polymer comprises polyacrylic Acid, (b) heating the energy retaining composition at 120-150 degrees Celsius and cooling at room temperature overnight, (c) mixing the energy retaining composition with at least one binder, an antimicrobial agent comprises silver and a cooling agent comprises Jade in water at a ratio of 1:1, (d) heating the energy retaining composition comprising the binder, the antimicrobial agent and the cooling agent at 120-150 degree Celsius and cooling at room temperature overnight, (e) coating the energy retaining composition on the textile article 104 in a reiki healing pattern using a screen printing to obtain patterned energy retaining textile article, which enables the patterned energy retaining textile article to maintain an optimal energy recovery without affecting the breathability.
[0012] In one embodiment, the reiki healing pattern comprises a layer which is built inside the energy retaining textile article to enable the patterned energy retaining textile article as breathable. The patterned energy retaining garment maintains an optimal energy recovery without affecting the breathability. The textile article is a garment.
[0013] In another embodiment, the process of preparing a breathable energy retaining textile article is a low temperature heating process or a non sintering heating process or a non ceramic heating process.
[0014] In yet another embodiment, the addition of jade provided cooling properties and the addition of silver provide antimicrobial properties.
[0015] In yet another embodiment, the process employs a NON-CERAMIC process for preparing energy retaining composition with ER retention and reflection properties and high emissivity; in contrast other ER property powders are made using ceramics. The process of preparing the energy retaining composition with Far IR properties, through NON-CERAMIC Route provides improved retention and reflection properties when coated on garment or article. Emission and reflectivity of energy retaining composition is in a range of 8- 14 micron, which may be easily absorbed by the human body.
[0016] These and other aspects of the embodiments herein will be better appreciated and understood when considered in conjunction with the following description and the accompanying drawings. It should be understood, however, that the following descriptions, while indicating preferred embodiments and numerous specific details thereof, are given by way of illustration and not of limitation. Many changes and modifications may be made within the scope of the embodiments herein without departing from the spirit thereof, and the embodiments herein include all such modifications.

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] The embodiments herein will be better understood from the following detailed descriptions with reference to the drawings, in which:
[0018] FIG. 1 illustrates a thermal profile of a human body with an energy retaining garment according to an embodiment herein;
[0019] FIG. 2 illustrates a prospective view of a reiki healing pattern according to an embodiment herein; and
[0020] FIG. 3 is a flow diagram that illustrates a process of making the energy retaining garment without converting ceramics according to an embodiment herein.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

[0021] The embodiments herein and the various features and advantageous details thereof are explained more fully with reference to the non-limiting embodiments that are illustrated in the accompanying drawings and detailed in the following description. Descriptions of well-known components and processing techniques are omitted so as to not unnecessarily obscure the embodiments herein. The examples used herein are intended merely to facilitate an understanding of ways in which the embodiments herein may be practiced and to further enable those of skill in the art to practice the embodiments herein. Accordingly, the examples should not be construed as limiting the scope of the embodiments herein.
[0022] As mentioned, there remains a need for a less cumbersome process for making the energy retaining garment. The embodiments herein achieve this by making a mineral composition which does not require high heat treatment to convert to ceramics. Referring now to the drawings and more particularly to FIGS. 1 through 3, where similar reference characters denote corresponding features consistently throughout the figures, there are shown preferred embodiments.
[0023] FIG. 1 illustrates a thermal profile 106 of a human body 102 with an energy retaining garment 104 according to an embodiment herein. The energy retaining garment 104 includes an energy retaining composition and a reiki healing pattern (not shown in this fig). The energy retaining composition includes a clay material (e.g., kaolinite), one or more minerals, one or more oxides and one or more rare earth minerals. The one or more minerals include a tourmaline. The one or more oxide includes an iron oxide, an aluminum oxide, and a zinc oxide. The one or more rare earth mineral includes quartz and granite. The materials present in the energy retaining composition include energy reflecting and energy generating characteristics.
[0024] Ratio of the energy retaining composition may be 50 percentage (%) of the Kaolinite, 36-45 percentage (%) of the tourmaline, 7 percentage (%) of the aluminum oxide (Al2O3), 7 percentage (%) of a zirconium dioxide (ZrO2), 7 percentage (%) of a titanium dioxide (TiO2), 9 percentage (%) of a silicon dioxide (SiO2), a Binder (4 percentage (%) of PVF/PVC), 1 percentage (%) of a wetting agent and 2 percentage (%) of a jade crystal (jadeite).
[0025] In one specific embodiment, the ratio of the energy retaining composition is 45 percentage (%) of the tourmaline, 7 percentage (%) of the aluminum oxide (Al2O3), 7 percentage (%) of the zirconium dioxide (ZrO2), 7 percentage (%) of the titanium dioxide (TiO2), 9 percentage (%) of the silicon dioxide (SiO2), 15 percentage (%) of a montmorillonite, 5 percentage (%) of the quartz, 1 percentage (%) of a silver, 1 percentage (%) of the wetting agent, 3 percentage (%) of a polyacrylic Acid and 2 percentage (%) of the Jade crystal (jadeite).
[0026] In another specific embodiment, the ratio of the energy retaining composition is 55 percentage (%) of the aluminum oxide (Al2O3), 10 percentage (%) of the zirconium dioxide (ZrO2), 10 percentage (%) of the titanium dioxide TiO2, 15 percentage (%) of silicon dioxide (SiO2), 1 percentage (%) of the Silver, 1 percentage (%) of the wetting agent, 3 percentage (%) of the polyacrylic acid, 5 percentage (%) of a PVF/a poly urethane, and 2 percentage (%) of the jade crystal (jadeite).
[0027] In yet another specific embodiment, the ratio of the energy retaining composition is 0.45 percentage (%) of an indium tin oxide, 0.02 percentage (%) of a conducting polymer, 5 percentage (%) of the poly urethane/an epoxy, 0.5 percentage (%) of the wetting agent (as 20% dispersion) and 2 percentage (%) of the jade crystal (jadeite).
[0028] In yet another specific embodiment, the ratio of the energy retaining composition is 50 percentage (%) of the aluminum oxide (Al2O3), 10 percentage (%) of the zirconium dioxide (ZrO2), 10 percentage (%) of the titanium dioxide (TiO2), 15 percentage (%) of the silicon dioxide (SiO2), 1 percentage (%) of the Silver, 1 percentage (%) of the wetting agent, 3 percentage (%) of the polyacrylic acid, 5 percentage (%) of the epoxy, 5 percentage (%) of the quartz and 2 percentage (%) of the jade crystal (jadeite).
[0029] In yet another specific embodiment, the ratio of the energy retaining composition is 50 percentage (%) of the kaolinite, 10 percentage (%) of the aluminum oxide (Al2O3), 7 percentage (%) of the zirconium dioxide (ZrO2), 7 percentage (%) of the titanium dioxide (TiO2), 19 percentage (%) of the silicon dioxide (SiO2), the binder (5 percentage (%) of the PVF/PVC), 1 percentage (%) of the wetting agent, 1 percentage (%) of the Silver and 2 percentage (%) of jade crystal (jadeite).
[0030] The ratio of the energy retaining composition may be 50-60 percentage (%) of the Kaolinite. 36-45 percentage (%) of the tourmaline, 7-17 percentage (%) of the aluminum oxide (Al2O3), 7-17 percentage (%) of the zirconium dioxide (ZrO2), 7-17 percentage (%) of the titanium dioxide (TiO2), 9-19 percentage (%) of the silicon dioxide (SiO2), the Binder (4-14 percentage (%) of PVF/PVC), 1-11 percentage (%) of the wetting agent and 2-12 percentage (%) of a jade crystal (jadeite).
[0031] In one embodiment, the ratio of the energy retaining composition is in a range of 45-55 percentage (%) of the tourmaline, 7-17 percentage (%) of the aluminum oxide (Al2O3), 7-17 percentage (%) of the zirconium dioxide (ZrO2), 7-17 percentage (%) of the titanium dioxide (TiO2), 9-19 percentage (%) of the silicon dioxide (SiO2), 15-25 percentage (%) of the montmorillonite, 5-15 percentage (%) of the quartz, 1-11 percentage (%) of the silver, 1-11 percentage (%) of the wetting agent, 3-13 percentage (%) of the polyacrylic Acid and 2-12 percentage (%) of the Jade crystal (jadeite).
[0032] In another embodiment, the ratio of the energy retaining composition is in a range of 55-65 percentage (%) of the aluminum oxide (Al2O3), 10-20 percentage (%) of the zirconium dioxide (ZrO2), 10-20 percentage (%) of the titanium dioxide TiO2, 15-25 percentage (%) of silicon dioxide (SiO2), 1-10 percentage (%) of the Silver, 1-10 percentage (%) of the wetting agent, 3-13 percentage (%) of the polyacrylic acid, 5-15 percentage (%) of the PVF/the poly urethane, and 2-12 percentage (%) of the jade crystal (jadeite).
[0033] In yet another embodiment, the ratio of the energy retaining composition is in a range of 0.45-10.45 percentage (%) of the indium tin oxide, 0.02-10.02 percentage (%) of a conducting polymer, 5-15 percentage (%) of the poly urethane/the epoxy, 0.5-10.5 percentage (%) of the wetting agent (as 20-30% dispersion) and 2-12 percentage (%) of the jade crystal (jadeite).
[0034] In yet another embodiment, the ratio of the energy retaining composition is in a range of 50-60 percentage (%) of the aluminum oxide (Al2O3), 10-20 percentage (%) of the zirconium dioxide (ZrO2), 10-20 percentage (%) of the titanium dioxide (TiO2), 15-25 percentage (%) of the silicon dioxide (SiO2), 1-11 percentage (%) of the Silver, 1-11 percentage (%) of the wetting agent, 3-13 percentage (%) of the polyacrylic acid, 5-15 percentage (%) of the epoxy, 5-15 percentage (%) of the quartz and 2-12 percentage (%) of the jade crystal (jadeite).
[0035] In yet another embodiment, the ratio of the energy retaining composition is in a range of 50-60 percentage (%) of the kaolinite, 10-20 percentage (%) of the aluminum oxide (Al2O3), 7-17 percentage (%) of the zirconium dioxide (ZrO2), 7-17 percentage (%) of the titanium dioxide (TiO2), 19-29 percentage (%) of the silicon dioxide (SiO2), the binder (5-15 percentage (%) of the PVF/PVC), 1-10 percentage (%) of the wetting agent, 1-10 percentage (%) of the Silver and 2-20 percentage (%) of jade crystal (jadeite).
[0036] The energy (e.g., heat) of the human body 102 is released in the form of an Infrared Radiation (IR). A part of the energy (e.g., heat) is reflected back to the human body 102 using the energy retaining coating. Another part of the energy (heat) is absorbed by the energy retaining coating. The energy retaining coating slowly releases an absorbed energy (heat) back to the human body 102 over a predetermined period of time. The energy retaining coating further generates the IR radiation which is beneficial to the human body 102. In one embodiment, the jade is a coolant material. The jade material increases efficiency of the energy retaining and energy recovery.
[0037] The energy retaining composition applies to the energy retaining garment 104 as a coating finish. The energy retaining composition is not breathable. The energy retaining composition is applied to the reiki healing pattern to obtain a patterned energy retaining garment. The reiki healing pattern is layer which is built in the energy retaining garment 104. The energy retaining garment 104 coated without affecting the breath ability. The pattern streamlines maintain the flow of the energy and the optimal retaining of energy. The patterned energy retaining garment is breathable.
[0038] FIG. 2 illustrates a prospective view of a reiki healing pattern 202 according to an embodiment herein. The reiki healing pattern 202 is layer which is built inside the energy retaining garment 104. The energy retaining composition is applied to the energy retaining garment 104 as a coating finish. In one embodiment, the retaining composition is printed onto the energy retaining garment 104 by applying the reiki healing pattern 202 using a screen printing. The energy retaining composition is not breathable. The energy retaining composition is applied to the reiki healing pattern 202 to obtain the patterned energy retaining garment. The reiki healing pattern 202 makes the energy retaining composition breathable. The patterned energy retaining garment maintains flow of the energy and the optimal retaining of energy.
[0039] FIG. 3 is a flow diagram that illustrates a process of making the energy retaining garment 104 without converting ceramics according to an embodiment herein. At step 302, a slurry of energy retaining composition is prepared by mixing (i) from 36 % to 45 % of cyclosilicate, wherein the cyclosilicate comprises tourmaline, wherein the tourmaline comprises at least one of schorl tourmaline, dravite tourmaline or elbaite tourmaline; (ii) from 30 % to 35 % of phyllosilicate, wherein the phyllosilicate comprises from 27 % to 30 % of kaolinite and from 3 % to 5 % of montmorillonite; (iii) from 10 % to 15 % of metal oxide, wherein the metal oxide comprises at least one of aluminum oxide (Al2O3), zinc oxide (ZnO), titanium dioxide (TiO2) or zirconium oxide (ZrO2); (iv) from 6 % to 10 % of tectosilicate, wherein the tectosilicate comprises quartz; and (v) from 0.5 % to 1.5 % of adhesive polymer, wherein the adhesive polymer comprises polyacrylic Acid. At step 304, the energy retaining composition is heated at 120-150 degrees Celsius and then cooled at room temperature overnight. At step 306, the energy retaining composition is mixed with at least one binder, an antimicrobial agent comprises silver and a cooling agent comprises Jade in water at a ratio of 1:1. At step 308, the energy retaining composition comprising the binder, the antimicrobial agent and the cooling agent is heated at 120-150 degree Celsius and then cooled at room temperature overnight. At step 310, the energy retaining composition is coated on the textile article in a reiki healing pattern using a screen printing to obtain patterned energy retaining textile article, which enables the patterned energy retaining textile article to maintain an optimal energy recovery without affecting the breathability.
[0040] In the above-mentioned process, there is no necessity for heating (to convert ceramics). The process of making energy retaining garments avoids heating because the conventional heating process (for converting ceramics) is a difficult task and consumption of resources for the heating process are too high. The conventional heating process makes the entire process is unsustainable and costlier. The method of making the energy retaining garment 104 is a less cumbersome process without converting ceramics. The patterned energy retaining garment is more efficient in energy management. The patterned energy retaining garment maintains the flow of the energy and the optimal retaining of energy efficiently. For example, in the above-mentioned process may influence the growth of ragi seeds in garden pots. An interior part of the garden pots may be covered with a cotton fabric. In one embodiment, the interior part of the garden pots is covered with a fabric that is coated with the energy retaining composition. In yet another embodiment, the interior part of the garden pots is covered with the fabric without the energy retaining composition. The garden pots are covered with the fabric that is coated with the energy retaining composition to lead faster sprouting of the ragi seeds and greater life time period in the garden pots. The fabric without the energy retaining composition in the garden pots may lead to slower sprouting of the ragi seeds and lesser life time period in the garden pots.
[0041] The energy retaining (A multi mineral matrix) chemical composition for energy recovery with a help of Far Infra-red (IR) is synthesized by mixing (a) one or more phyllosilicates (e.g., kaolinite, montmorillonite), (b) one or more cyclosilicates (e.g., schorl tourmaline, dravite tourmaline or elbaite tourmaline), (c) one or more metal oxides (e.g., an aluminum oxide, and a zinc oxide, titanium dioxide, zirconium oxide), (d) conducting polymers (e.g., polypyrrole), (e) mineral oxides (e.g., silicon dioxide); (f) adhesive polymer (e.g., polyacrylic acid), and (g) one or more tectosilicates (e.g., a quartz and a granite) and its usefulness tested out through a series of experiments. These experiments are tested for reflectivity, heat retention and overall effect of the ER composition and its FAR-IR emitting properties on both plants and humans. Emission and reflectivity of the energy retaining composition is in a range of 8- 14 micron, which may be easily absorbed by the human body. All the compounds as provided in the below examples are mixed together and made into a slurry of energy retention composition. The energy retention composition was then heated at 150 degrees Celsius for 1 hour and then allowed to cool overnight.
[0042] Example 1:
[0043] In one specific embodiment, the ratio of the energy retaining composition comprises 45 percentage (%) of the tourmaline, 29 percentage (%) of the Kaolinite, 10 percentage (%) of the titanium dioxide (TiO2), 5 percentage (%) of a montmorillonite, 10 percentage (%) of the quartz, and 1 percentage (%) of a polyacrylic Acid.
[0044] Example 2:
[0045] In one specific embodiment, the ratio of the energy retaining composition comprises 36 percentage (%) of the tourmaline, 29 percentage (%) of the Kaolinite, 15 percentage (%) of the titanium dioxide (TiO2), 10 percentage (%) of the silicon dioxide (SiO2), 3 percentage (%) of a montmorillonite, 6 percentage (%) of the quartz, and 1 percentage (%) of a polyacrylic Acid.
[0046] The energy retention composition as shown in Example 1 and example 2 shows greater ER heating up properties and emissivity.
[0047] Example 3:
[0048] In one specific embodiment, the ratio of the energy retaining composition comprises 20 percentage (%) of the tourmaline, 20 percentage (%) of the Kaolinite, 20 percentage (%) of the zinc oxide (ZnO), 25 percentage (%) of the titanium dioxide (TiO2), 5 percentage (%) of the silicon dioxide (SiO2), 5 percentage (%) of the quartz, and 5 percentage (%) of a montmorillonite.
[0049] The energy retention composition as shown in example 3 shows greater ER reflecting properties and also heat retention properties.
[0050] Example 4:
[0051] In one specific embodiment, the ratio of the energy retaining composition comprising 40 percentage (%) of the zinc oxide (ZnO), 40 percentage (%) of the titanium dioxide (TiO2), 20 percentage (%) of the Aluminium Oxide (Al2O3).
[0052] The energy retention composition as shown in example 4 shows greater ER reflecting properties.
[0053] Experiment 1: Heat retention of coated fabrics.
[0054] 100% cotton fabrics (white colour) are coated with different energy retention composition as provided in examples 1 to 4. The cotton fabrics are then kept at 45 degrees Celsius at 30 cm from a 220W Far Infra-red (IR) lamp emitting far IR rays in a range of 8-14 micrometer at 37 degrees Celsius. The fabrics are then heated up and cool down over 5 minute’s duration and the temperature are measured. The heat retention after 5 min and cool down is measured across the samples.
[0055] Table 1:
Heat Retention Test
Heat Up Cool down
Samples 1 min 5 min 1 min 5 min
White Fabrics 39 40.6 22 21.8
Example 1 41.9 42.3 25 22.8
Example 2 40.1 41.5 25.3 23
Example 3 38.5 40.7 24.5 23
Example 4 37.2 40.1 22.6 22.6

[0056] The above table indicates better heat retention for the fabric that is coated with the energy retention composition as shown in examples 1 to 4 than white fabric. The fabrics coated with example 1 and 2 shows better heating retention properties. The fabrics coated with example 3 and 4 shows better heat reflection properties. The white colour fabric is a natural good reflecting fabric.
[0057] Experiment 2: Heat reflection of copper sheet that is coated with the energy retention composition as shown in examples 1 to 4 on one side.
[0058] Pure 1 millimeter (mm) copper sheets are coated with different the energy retention composition as shown in examples 1 to 4. The copper sheets are kept at 45 degrees Celsius at 30 cm from a 220W Far Infra-red map emitting far IR rays in a range of 8-14 micron at 37 degrees Celsius. The copper sheets are then heated up and cool down over a 5 min duration and the temperature is measured. The back-side temperature of the copper sheets is also measured. The difference in back-side temperature between the different copper sheets that are coated with the energy retention composition as shown in examples 1 to 4 provides the heat reflection across the samples.
[0059] Table 2:
Heat Reflection Test
Heat Up Cool down
Samples 1 min 5 min 1 min 5 min
Copper Sheet 52.9 55.51 22.6 22.4
Example 1(High1) 41.4 41.9 22.9 22.4
Example 2(High2) 41.1 41.2 23 22.6
Example 3(Balance) 39.3 40 23.1 22.5
Example 4(Reflect) 38.4 38.8 22.6 22.3

[0060] The above table indicates comparable heat retention to copper sheets. The copper sheet coated with the energy retention composition of example 1 and 2 shows better heating up. The copper sheet coated with the energy retention composition of example 3 and 4 shows better heat reflection. The Pure copper sheet is a natural excellent conductor of heat. The pure copper sheet has high thermal conduction and heat storage properties. Thus, the pure copper sheet coated energy retention composition has better heating up and better retention.
[0061] Experiment 3: Human Trials with energy retention (ER) composition coated t-shirts.
[0062] T-shirt is coated with a chemical solution made with (8%) of the energy retention (ER) composition mixed with (1%) of a binder and (1%) of silver. The energy retention (ER) composition was prepared by slurry of composition, heated at 250 degrees Celsius.
[0063] The T-shirts are worn by users divided into 2 groups of 5 members each:
•Group 1 users wear the t-shirts to work for 5-7 days.
•Group 2 users wear the t-shirts sleeping at night for 5-7 days.
[0064] Table 3: The table shows improvement in energy retention on t-shirts worn by Group 1 users when doing sit ups, push ups and jump jacks.
Group 1
Name Before After Improvement
Sit Ups Push Ups Jump Jacks Energy Level Sit Ups Push Ups Jump Jacks Energy Level Sit Ups Push Ups Jump Jacks
Subject 1 22 23 50 9 26 26 65 10 18.18181818 13.04347826 30
Subject 2 20 20 44 9 22 28 57 10 10 40 29.54545455
Subject 3 15 21 54 9 20 23 58 10 33.33333333 9.523809524 7.407407407
Subject 4 22 23 57 8 27 23 57 10 22.72727273 0 0
Subject 5 16 22 30 7 NA NA NA NA NA NA NA

[0065] Table 4: The table shows improvement in energy retention on t-shirts worn by Group 2 users when doing sit ups, push ups and jump jacks.

Group 2
Name Before After Improvement
Sit Ups Push Ups Jump Jacks Energy Level Sit Ups Push Ups Jump Jacks Energy Level Sit Ups Push Ups Jump Jacks
Subject 1 22 24 60 7 26 28 70 7 18.18181818 16.66666667 16.66666667
Subject 2 20 20 56 7 26 22 56 7 30 10 0
Subject 3 22 12 62 7 20 13 52 7 -9.090909091 8.333333333 -16.12903226

[0066] Experiment 4: Emissivity test on glass plates coated with the samples (i.e. energy retention composition of example 1 to 4).
[0067] Glass plates are coated with the different samples (i.e. the energy retention composition of example 1 to 4). The coated glass plates us covered halfway with a black tape having a known emissivity of 0.96. The emissivity of the different samples is calculated with a help of an industrial grade FLIR thermal camera by manually setting the emissivity at 0.96 in the thermal camera. Then the temperature reading of the taped area is measured. Then the emissivity setting on the camera is manually adjusted until the temperature reading of the coated sample at a specific emissivity setting matches the already measured temperature reading of the black taped area. The glass plates is heated and maintained at a constant temperature with a help of a water bath set at 45 degrees Celsius.
[0068] Table 5:
Emissivity Test
Sample Temperature Temperature Emissivity
Black Body Sample
Example 1 43.6 43.7 92
Example 2 43.3 43.3 91
Example 3 43.5 43.4 87
Example 4 43.6 4.5 84

[0069] In yet another embodiment, slurry of 90% of the energy retaining composition is mixed with 3.5 % of jadeite and 2.5% of Silver micro particles PVDF/Urethane and 4% of Binder in water at 1:1 ratio. Then the mixture of the energy retaining composition is heated at 150 degrees Celsius for 1 hour, and then cooled overnight.
[0070] The foregoing description of the specific embodiments will so fully reveal the general nature of the embodiments herein that others can, by applying current knowledge, readily modify and/or adapt for various applications such specific embodiments without departing from the generic concept, and, therefore, such adaptations and modifications should and are intended to be comprehended within the meaning and range of equivalents of employed herein is for the purpose of description and not of limitation. Therefore, while the embodiments herein have been described in terms of preferred embodiments, those skilled in the art will recognize that the embodiments herein can be practiced with modification within the sprit and scope.
,CLAIMS:I/We Claim:

1. An energy retaining composition that is coated in a garment (104) for enabling the garment (104) to maintain an optimal energy recovery without affecting the breathability, characterized in that said energy retaining composition comprising:
(a) from 36 % to 45 % of cyclosilicate, wherein said cyclosilicate comprises tourmaline wherein said tourmaline comprises at least one of schorl tourmaline, dravite tourmaline or elbaite tourmaline;
(b) from 30 % to 35 % of phyllosilicate, wherein said phyllosilicate comprises from 27 % to 30 % of kaolinite and from 3 % to 5 % of montmorillonite;
(c) from 10 % to 15 % of metal oxide, wherein said metal oxide comprises at least one of aluminum oxide (Al2O3), zinc oxide (ZnO), titanium dioxide (TiO2) or zirconium oxide (ZrO2);
(d) from 6 % to 10 % of tectosilicate, wherein said tectosilicate comprises quartz; and
(e) from 0.5 % to 1.5 % of adhesive polymer, wherein said adhesive polymer comprises polyacrylic Acid.


2. The energy retaining composition as claimed in claim 1, wherein said energy retaining composition comprises from 5 % to 10 % of mineral oxide, wherein said mineral oxide comprises silicon dioxide (SiO2).

3. The energy retaining composition as claimed in claim 1, wherein said energy retaining composition comprises at least one of (a) from 1 % to 2.5 % of silver, and (b) from 3.5 % to 5 % of Jade.

4. The energy retaining composition as claimed in claim 1, wherein said energy retaining composition comprises (a) from 5 % to 15 % of at least one of Polyvinyl fluoride (PVF), Poly urethane (PU), or an epoxy compound as a binding agent, and (b) from 0.5 % to 11 % of wetting agent, wherein wetting agent comprises Iso propyl alcohol.

5. The energy retaining composition as claimed in claim 1, wherein said energy retaining composition comprises from 0.02 % to 10.02 % of conducting polymer, wherein said conducting polymer comprises polypyrrole.

6. The energy retaining composition as claimed in claim 3, wherein the jade crystal comprises aluminum content for increasing efficiency of the energy retaining and energy recovery.

7. An energy retaining composition that is coated in a garment (104) for enabling the garment (104) to maintain an optimal energy recovery without affecting the breathability, characterized in that said energy retaining composition comprising:
(a) 36 % of cyclosilicate, wherein said cyclosilicate comprises tourmaline, wherein said tourmaline comprises schorl tourmaline;
(b) 32 % of phyllosilicate, wherein said phyllosilicate comprises 29 % of Kaolinite and 3 % of montmorillonite;
(c) 15 % of metal oxide, wherein said metal oxide comprises titanium dioxide (TiO2);
(d) 10 % of mineral oxide, wherein said mineral oxide comprises silicon dioxide (SiO2);
(e) 6 % of tectosilicate, wherein said tectosilicate comprises quartz; and
(f) 1 % of adhesive polymer, wherein said adhesive polymer comprises polyacrylic Acid.

8. An energy retaining composition that is coated in a garment (104) for enabling the garment (104) to maintain an optimal energy recovery without affecting the breathability, characterized in that said energy retaining composition comprising:
(a) 20 % of cyclosilicate, wherein said cyclosilicate comprises tourmaline, wherein said tourmaline comprises schorl tourmaline;
(b) 25 % of phyllosilicate, wherein said phyllosilicate comprises 20 % of Kaolinite and 5 % of montmorillonite;
(c) 45 % of metal oxide, wherein said metal oxide comprises 20 % of zinc oxide (ZnO) and 25 % of titanium dioxide (TiO2);
(d) 5 % of mineral oxide, wherein said mineral oxide comprises silicon dioxide (SiO2);
(e) 5 % of tectosilicate, wherein said tectosilicate comprises quartz; and

(f) 1 % of adhesive polymer, wherein said adhesive polymer comprises polyacrylic Acid.

9. A process of preparing a breathable energy retaining textile article (104), characterized in that said process comprising:
(a) preparing a slurry of energy retaining composition comprising: mixing (i) from 36 % to 45 % of cyclosilicate, wherein said cyclosilicate comprises tourmaline wherein said tourmaline comprises at least one of schorl tourmaline, dravite tourmaline or elbaite tourmaline; (ii) from 30 % to 35 % of phyllosilicate, wherein said phyllosilicate comprises from 27 % to 30 % of kaolinite and from 3 % to 5 % of montmorillonite; (iii) from 10 % to 15 % of metal oxide, wherein said metal oxide comprises at least one of aluminum oxide (Al2O3), zinc oxide (ZnO), titanium dioxide (TiO2) or zirconium oxide (ZrO2); (iv) from 6 % to 10 % of tectosilicate, wherein said tectosilicate comprises quartz; and(v) from 0.5 % to 1.5 % of adhesive polymer, wherein said adhesive polymer comprises polyacrylic Acid;
(b) heating the energy retaining composition at 120-150 degrees Celsius and cooling at room temperature overnight;
(c) mixing the energy retaining composition with at least one binder, an antimicrobial agent comprises silver and a cooling agent comprises Jade in water at a ratio of 1:1;
(d) heating the energy retaining composition comprising the binder, the antimicrobial agent and the cooling agent at 120-150 degree Celsius and cooling at room temperature overnight; and
(e) coating the energy retaining composition on the textile article (104) in a reiki healing pattern (202) using a screen printing to obtain patterned energy retaining textile article, which enables the patterned energy retaining textile article to maintain an optimal energy recovery without affecting the breathability.

10. The process as claimed in claim 9, wherein the reiki healing pattern (202) comprises a layer which is built inside the energy retaining textile article (104) to enable the patterned energy retaining textile article as breathable.