METHOD CONTROLLING EVAPORATION FOR LIQUID INGREDIENTS CONTAINED IN CONTAINER, AND GLASSWARE

Abstract

A method for controlling the evaporation of the liquid ingredients contained in the container by changing the composition of the glassware and glassware. Containing of the oxides effective for far-infrared radiation as the constituents in the glassware composed mainly by silica in following by contacting the liquids ingredients contained in the container with their glassware, controls the evaporation of liquids ingredients. The 5-40 mass % of the oxides effective for far-infrared radiation such as transparent oxides such as titanium oxide, zinc oxide, etc., or the 1-10 mass % of oxides of either transition metal oxides such as iron oxide, cobalt oxide, etc. or rare earth oxides such as neodymium oxide, cerium oxide, etc. for coloring, may be contained in said glassware.

Claims

1. A method for controlling the evaporation of a liquid ingredient contained. in a container is characterized in that stepwisely changing the contents of the oxides effective for far-infrared radiation in the multiple glasswares composed of mainly silica as its constituents by contacting each said glassware with the liquid ingredients contained in. the multiple containers, enables stepwisely to control the liquid ingredients in each said container.

2. (canceled)

3. (canceled)

4. (canceled)

5. (canceled)

6. (canceled)

7. Multiple glasswares used for controlling the evaporation of the liquid ingredients contained in the container according to claim 1, wherein the glasswares are constituted so that food and drink are stored or in contact with food and drink.

8. The glasswares according to claim 7, wherein the glasswares contain 5-40 mass % of said transparent oxides effective for far-infrared radiation, and furthermore contain 1-10 mass % of at least one kind of colored transition metal oxides absorbing the visible light or rare-earth oxides for coloring.

9. Glassware designed as storing foods and drinks, being composed of mainly silica as its constituents, wherein the glassware contains total mass of 10% of TiO.sub.2 and ZnO in a ratio of 1:1 as the oxides effective for far-infrared radiation, and controls the evaporation of the liquid ingredients contained in the container.

10. Glassware designed as storing foods and drinks, being composed of mainly silica as its constituents, wherein the glassware contains total mass of 20-30% of TiO.sub.2 and ZnO in a ratio of 1:1 as the oxides effective for far-infrared radiation, and controls the evaporation of the liquid ingredients contained in the container.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0019] FIG. 1 is a perspective view which shows the gas sampling method from the sample contained in the container for measuring the evaporation, in describing a method for controlling the evaporation of liquid ingredients contained in a container according to an embodiment of the present invention.

[0020] FIG. 2 is a graph which shows the total weight of gas shown as ion current/argon current with a molecular weight of 1-50 evaporated from the Japanese-sake contained in the glass sold in market and glasses with additives of oxides of 10 mass %, 20 mass % and 30 mass % which names as 10% glass, 20% glass, and 30% glass, respectively, according to an embodiment of the present invention.

[0021] FIG. 3 is a graph which shows the total weight of gas shown as ion current/argon current with a molecular mass of 50-100 evaporated from the Japanese-sake contained in the glass sold in market and glasses without or with additives of oxides of 10 mass %, 20 mass % and 30 mass % which names as 10% glass, 20% glass, and 30% glass, respectively, according to an embodiment of the present invention.

[0022] FIG. 4 is a graph which shows the normalized gas concentration per gram of poured Japanese-sake in the container versus the molecular mass of 1-50, after subtracting the constituents of air from the total gas concentration shown. in FIG. 2.

[0023] FIG. 5 is a graph which shows the normalized gas concentration per gram of poured Japanese-sake in the container versus the molecular mass of 51-100, after subtracting the constituents of air from the total gas concentration shown in FIG. 3.

[0024] FIG. 6 is a graph which shows the normalized gas concentration per gram of poured Japanese-sake in the container versus the molecular mass of 101-150, after subtracting the constituents of air from the total gas concentration obtained like FIG. 2, and FIG. 3.

[0025] FIG. 7 is a graph which shows the normalized gas concentration per gram of the poured Japanese-sake in the glass, after subtracting the amount of air from the total weight of gas having a molecular weight of 1-50 evaporated from the Japanese-sake contained in the glass sold in market and glasses with additives of oxides such as 10 mass %, 10 mass %+1 mass % of neodymium oxide, 1% of iron oxides, which names as 10% glass, Nd10% glass, and Fe1% Grglass, respectively, according to an embodiment of the present invention.

[0026] FIG. 8 is a graph which shows the normalized gas concentration per grain of the poured Japanese-sake in the glass, after subtracting the amount of air from the total weight of gas having a molecular weight of 51-100 evaporated from the Japanese-sake contained in the glass sold in market and glasses with additives of oxides such as 10 mass %, 10 mass %+1 mass % of neodymium oxide, 1% of iron oxides, which names as 10% glass, Nd10% glass, and Fe1% Grglass, respectively, according to an embodiment of the present invention.

DESCRIPTION OF EMBODIMENTS

[0027] Hereinafter, embodiments of the present invention will be described based on examples and the like. A method for controlling evaporation of liquid ingredients contained in the embodiment container is containing the oxides of far-infrared ray effects as its constituents in the glassware composed of mainly silica, in resulting in controlling the evaporation of liquid ingredients in the container.

[0028] Although the attempts to change the flavor of drinks by changing the shape of the container such as wine-glass or sake-vessels among the soda-glass containers widely sold in market are reported, there are no attempts to control the evaporation of liquid ingredients by containing more than 5 mass % of the oxides with far-infrared ray effects in a soda-glass.

[0029] This glassware consists of an amorphous structure when the content of oxides with far-infrared effects is small, but it forms a mixed microstructure consisted of two or more phases including a crystal phase when the content of oxides is large.

[0030] As the oxides with far-infrared ray effects, titanium oxide, zinc oxide, aluminum oxide, zirconium oxide, tin oxide, antimony oxide, etc. are desirable as a transparent oxide which presents white in the case of fine powder in order to maintain the transparency that is the characteristic of a glass.

[0031] As the oxides with far-infrared ray effects, the transition metal oxides such as iron oxide, cobalt oxide, copper oxide, nickel oxide, manganese oxide, chromium oxide, etc., are desirable for coloring a glass.

[0032] As the oxides with far-infrared ray effects, transparent oxides such as titanium oxide, zinc oxide, aluminum oxide, zirconium oxide, tin oxide, antimony oxide, etc, are desirable to be mainly used for maintaining their transparency, and the transition metal oxides such as iron oxide, cobalt oxide, copper oxide, nickel oxide, manganese oxide, chromium oxide, etc. and rare earth oxides such as neodymium oxide, cerium oxide, samarium oxide, etc., are desirably included in the glass for coloring.

[0033] As described in Patent Literature 1, it is reported that the line width of NMR spectrum of a water in the cups decreases with increasing with the adding amount of far-infrared radiation ceramics, by adding the specific composition of oxides to soda-glass, and then molecular motions of the water becomes active. But there is no disclosure of a specific example of a method of stepwisely controlling the evaporation of the liquid ingredients contained in the container, by containing the oxides of far-infrared ray effects in soda-glass and with increasing the adding amount of oxides

[0034] As the method to control the evaporation of liquids ingredients contained in the container by including the oxides of far-infrared ray effect in soda-glass, when the amount of far-infrared radiation oxides becomes large, for example, beverages such as wine and Japanese-sake may lose their flavor, so that the appropriate content of about 1-40% of content of the oxides is desirable.

[0035] In order to promote the evaporation of liquid ingredients contained in the container, increment of the content of far-infrared radiation oxides in the glassware is preferable. For an example, the increment of the content of titanium oxide, zinc oxide, aluminum oxide, zirconium oxide, tin oxide, antimony oxide, etc. causes the increment of melting point and viscosity of the glass, so that it becomes to be difficult to form an amorphous structure that is a glass structure. This recommends that the method for producing a transparent glass is preferably the rapid-quenching method such as a spin method.

[0036] On the other hand, even though the slow cooling such as air blowing may cause glass devitrification, it causes no significant effects on the evaporation control of the contained liquid ingredients. Then the slow cooling is desirable instead of rapid-cooling, as the manufacturing method to improve the beauty and design which appear on devitrification, as far as the glass has no crack or becomes brittle.

EXAMPLE 1

[0037] The experiments to measure the evaporation of liquid ingredients contained in the gas-made container were performed by selecting TiO.sub.2 and ZnO for an example as transparent oxides with far-infrared effects in order to study their adding effects, The compositions of the studied glass are based on the soda-glass cup of one hundred yen cup sold in market, and are shown in Table 1. The samples used in this investigation were the soda-gl.ass with the composite additives about one to one composition of transparent oxides such as TiO.sub.2 and ZnO which vary from 10 to 30 mass %, which are named as 10% glass, 20% glass, or 30% glass, respectively.

TABLE-US-00001 TABLE 1 Compounds SiO.sub.2 Na.sub.2O CaO SrO Al.sub.2O.sub.3 MgO Total % mass % 64 18.2 11 4.3 1.9 0.5 100.0

[0038] The evaporated gas from the liquids was measured by the high sensitivity gas analyzer for the breath gas analyzer manufactured by Nikken Flux The measurement procedure is shown in FIG. 1, The Japanese sake named Bodaimoto junmaishu which is sake made without added alcohol or sugar with 7 to 13 gram was poured into the sample container,and the container were wrapped by the cling film in following by leaving it for 5 minutes, Then, the syringe needle inserts into the cling film, and the evaporated gas from poured Japanese-sake is extracted to the syringe, which was connected with the gas analyzer, in following by analyzing the ingredients of evaporated gas. For the gas analyzer, the standardization of the evaporated gas was based on the amount of an argon gas of 9,300 ppm in the air, Then, the analysis of the air is always required to make the standardization The evaporated gas of aromas from Japanese-sake was standardized by the weight of Japanese-sake,

[0039] FIGS. 2 and 3 show the total weight of gas which is shown as ion current/ argon current versus the molecular mass evaporated from the Japanese-sake in the glass container, after the Japanese-sake poured into the container which was wrapping by the cling film and leaving it for 5 minutes, and the syringe needle inserts into the cling film, and the evaporated gas from poured Japanese-sake is extracted to the syringe. The measurement temperature was 23 C. FIGS. 4 to 6 show the normalized gas concentration per gram of poured Japanese-sake in the container versus the molecular mass, after subtracting the constituents of air from the total gas concentration shown in. FIGS. 2 and 3.

[0040] FIG. 2 exhibits the peaks from a water (molecular mass 18), nitrogen (28), oxygen (32), acetaldehyde (or CO.sub.2) (44), ethanol (46). In FIG. 3 iso-amyl alcohol (55), ethyl caproate (57), acetic acid (60), isoamyl acetate (70), succinic acid (74), furfural (96) were observed.

[0041] The works concerning the analysis of the ingredients of Japanese-sake reported (for examples, Haruo Ogawa, Tomokazu Nakajima, Nobutoshi Yoshihara, Yukako Ohhashi, Chemical analyses of ingredients in various types of alcoholic drinks of Sake, Bulletin of Tokyo Gakugei University. Natural Sciences, pp23-31, (2010). National research institute of brewing, Smell and its origin of Sake., [Translated from Japanese.], (2010), Atsuko Isoya, Aroma compounds during aging of Sake, Biotechnology, pp720-723 a (2010.) that the aromas are known as acetaldehyde (wood-like smell), ethanol (alcoholic smell), iso-amyl alcohol (whiskey-like smell), ethyl caprylate (pear-like smell (bitterness)), acetic acid, isoamyl acetate (banana-like smell, and Ginjo-ka (fruit, flower,floral, blossom-like smell)), succinic acid (tasty (umami)), furfural (Ginjo-ka which is contained in. I)aiginjo-shu made from highly-polished rice), ethyl caproate (apple-like smell (tart) and Ginjo-ka).

[0042] FIG. 4 exhibits that the water, acetaldehyde, ethanol are positive value, and that the nitrogen except of 20% glass, and oxygen are negative value, in the aroma gas after subtracting the components of air. These negative values mean that the contents of the nitrogen and the oxygen in the air are larger than those contained in the glass with Japanese-sake. The peak of molecular mass of 44 may correspond to CO.sub.2 or acetaldehyde, but it turns out that the peak will be acetaldehyde from the sake since the peak becomes positive value.

[0043] The difference due to the glass compositions in the aroma ingredients evaporated from the container turns out that the amount of the acetaldehyde evaporated from the sake in the container with the composite additives of TiO.sub.2 and ZnO, is larger than one without additives.

[0044] FIG. 5 also exhibits that the iso-amyl alcohol, the isoamyl acetate, and the succinic acid which were known as characteristic aromas of Japanese-sake have the concentrations of around 1.010.sup.6-6.810.sup.6. Since the concentration of these aromas from the glass container with the additives is larger than that from the one without additives, it can be said that the additives of the infrared emissive ceramics such as the transition metal oxides to the soda-glass will be effective on accelerating the evaporation of the aroma of Japanese-sake.

[0045] There will be the tendency that the evaporation of the aromas will be accelerated with increasing the amount of additives in the glass container although the amounts of evaporated aromas vary in depending on the molecular mass. In FIG. 6, the evaporated gas concentration of high molecular mass tends to decrease with increasing molecular mass in comparing with ones of low molecular mass, so that it will be difficult to judge the effects of the additives in the container to the evaporation of the aromas. But the evaporated amounts of the ethyl caprylate of molecular mass of 144 except of 57 and of 127 and the ethyl caproate of molecular mass of 172.6, which are the characteristic aromas of Japanese-sake, increase with increasing the additives in the glass container. It can be judged that the evaporation of the aromas of the Japanese-sake will be accelerated with increasing the amount of additives of the infrared emissive ceramics in the glass container.

EXAMPLE 2

[0046] The experiments to measure the evaporation of liquids ingredients contained in the glass-made container are performed by selecting neodymium oxide as an example of rare earth oxides for coloring, and iron oxide of transition metal oxides with far-infrared effects as well, in order to study their adding effects. The samples used in this investigation are the 10% added glass as shown in the embodiment of the invention 1 with 1 mass % of the neodyinium oxide, which colors the glass blue-purple, and the soda-glass as shown in Table 1 with the additives of 1 mass % of an iron oxide, which exhibits green colored glass. The glass samples with the composite additives of 10% of TiO.sub.2 and ZnO with 1 Mass % neodymium oxide, and 1 mass % iron oxide are named as Nd10% glass, Fe1% Grglass, respectively.

[0047] FIGS. 7 and 8 show the normalized gas concentration per gram of poured Japanese-sake in the container versus the molecular mass of 1-50 and 51-100, after subtracting the constituents of air from the total gas concentration as shown in FIGS. 4 and 5, respectively. The minus peaks of the nitrogen and the oxygen are interpreted as same as FIG. 4, and FIGS. 7 and 8 show the data of the glass sold in market and the 10% glass by comparison.

[0048] In FIG. 7, the amount of the acetaldehyde evaporated from the sake in the container of Nd10% glass and Fe1% Grglass which contains coloring oxides, is larger than that from the container of 10% glass and the glass sold in market.

[0049] In FIG. 8, the iso-amyl alcohol, the isoamyl acetate, and the succinic acid which were known as characteristic aromas of Japanese-sake are also observed, and it was found that their amount from the container of Nd10% glass and Fe1% Grglass with containing coloring oxides, is larger than that from the container of 10% glass and the glass sold in market. The effect of neodymium oxide as the far-infrared radiation has been unknown, but the present embodiment clarifies that neodymium oxide has the effect to promote the evaporation of Japanese-sake ingredients. This indicates that the neodymium oxide for coloring and the iron oxide for far-infrared effects have the effects to promote the evaporation of Japanese-sake ingredients.

[0050] Although it has been said that the taste and the flavor of the drinks will be changed by the shape of the glass-made container, the present embodiment clarifies that the glasses with the titanium dioxide, zinc oxide, alumina as the oxides of far-infrared radiation, and one with the neodymium oxide for coloring and the iron oxide for far-infrared effects, have the remarkable effects to promote the evaporation of aroma ingredients of the Japanese-sake, in comparison with the soda-glass sold in market. This leads to expect that it may be possible to change the tastes and flavors of other drinks such as wines, Japanese-vodkas, coffees, soft-drinks, vinegars, soy sauces.

[0051] Moreover, muddlers and ohajikis of Japanese glass-made tiddlywink, made with the composition shown in the embodiment of the invention 1 as the glassware, are dipped in the wine and Japanese-sake contained in the container of soda-glass and the ceramic ware sold in market, are confirmed to change their drinks such that their aroma becomes to be vivid or mellow as well as the glassware shown in the first embodiment of the invention. Therefore, it is judged that the glassware of the embodiment of the invention is not only effective to the glass-made container but also to other glassware.

INDUSTRIAL APPLICABILITY

[0052] The present embodiment suggests that the evaporation of the liquid ingredients contained in the container can be stepwisely controlled, so that their industrial applications could be tremendous. This can be applicable to stepwisely change the tastes and flavors of the drinks such as wines. Japanese-vodkas, coffees, soft-drinks, vinegars, soy sauces as well as Japanese-sake described in the present embodiment of the invention, For an example, the sommelier who was asked to use the present invented Mass-made container gives the comment that the wine with the strong acidity and astringency become to have the vivid aroma in resulting in the weak acidity and astringency, and as a result that the wine changes to be mellow. It is also confirmed that the taste of soy sauces in the present invented glass-made dishes change to be smooth, thus the present container are also applicable to the seasoning one. The present invented containers will become to be suitable as the coffee-cup with abundant flavor of coffee, and as the one that gives the week feeling of sourness of the vinegar for drinking.

[0053] It will become to be a suitable use for the perfume bottles and aroma diffusers since the present embodiment glassware can stepwisely control the evaporation of their ingredients in resulting in giving their strong fragrances. Especially in case of blending the various fragrances of perfumes, the glassware related to the present embodiment can control the evaporation of ingredients of perfumes, so that in may be possible what kind of the glass composition enables which ingredients of perfume to evaporate effectively, etc., and then the future applications of the present invented container are strongly expected.