NO117963B - - Google Patents

Description

Reconstituted tobacco product.

The present invention relates to a reconstituted tobacco product. More specifically, the invention relates to a preferred reconstituted tobacco product using materials that previously had little commercial value.

It has long been known that light tobacco leaves, even without the addition of any flavoring, give a good smoke when used in tobacco products. They have a naturally sweet taste which is desirable in smoking tobacco. They have become commonly accepted as a good type of tobacco and are therefore in demand both for use alone and in tobacco mixtures.

More light tobacco than any other is produced by tobacco growers in the United States and many other parts of the world. Light tobacco stalks and other parts of light tobacco, such as waste and dust from light tobacco have therefore formed a major part of the tobacco products that have not been able to be fully utilized by tobacco manufacturers. Although methods are known for the production of reconstituted tobacco from such light tobacco stalks, no such method has been found to be completely satisfactory, and no way is known to convert light tobacco stalks, tobacco waste and the like into a product having the same beneficial properties as light tobacco leaves.

The present invention provides a tobacco product which can have substantially the same beneficial smoking properties as light tobacco leaves. The present invention also allows the production of a tobacco product in such a way that many of the less desirable elements which are usually given off in tobacco smoke are reduced or removed. The invention thus comprises a "tailor-made" smoking product which contains mostly only those components which result in good burning properties, and which produces the satisfaction expected when smoking the best tobacco varieties.

The invention permits the manufacture of a tobacco product from light tobacco stalks by treating the tobacco stalks to remove the calcium cross-links and magnesium cross-links from the pectin-containing material contained therein without adversely affecting the fibrous nature of the cellulose and hemi-cellulose in the tobacco being treated. .

The invention allows the manufacture of a product from light tobacco stalks or other tobacco sources that is substantially free of magnesium cross-links and calcium cross-links. This cross-link-free product is preferably pressed or ground at a time when it contains substantially all of the cellulose, hemi-cellulose and pectin-containing material originally present in the stalks or other tobacco parts being processed. will be described more fully hereinafter, the resulting product or stalk pulp is then used by forming a slurry thereof with water and adding organic or inorganic ingredients to the slurry to impart the desired tobacco characteristics to the slurry. The resulting slurry was then shaped by by a conventional molding technique or otherwise into a reconstituted tobacco product which can be incorporated as the sole tobacco ingredient or as part of the tobacco ingredient in a smoking product, for example a cigarette, a cigar or a pipe

tobacco.

The method for removing the calcium and magnesium cross-links from the pectin-containing materials found in tobacco is to wash the tobacco parts, which may be whole stems, torn or chopped stems, tobacco particles and tobacco waste or the like, with an aqueous treatment solution with a pH value from 0.5 to 3.0 and preferably from 1.0 to 2.5.

It is preferable to wash the tobacco parts first with water.

In order to imitate a light tobacco product, the tobacco parts should preferably be light tobacco parts. However, other types of tobacco, such as burley tobacco, can be processed and used accordingly.

The aqueous treatment solution can be suitably acidified by adding an inorganic acid, such as hydrochloric acid, to the water to bring the pH to the preferred level. However, the water is preferably passed through an ion exchanger resin of an acidic type, such as a sulfate resin in acidic form. If a sulphate resin in acidic form is used for this purpose, it may be necessary to add small amounts of a chloride, nitrate or similar ion to give the water an initial acidity which can be maintained by the resin. Other precautions to bring the pH to the desired level include the use of any organic or inorganic acid with which a pH of 3 or lower can be achieved. These acids include sulfuric acid, nitric acid, orthophosphoric acid, pyrophosphoric acid and the like. The acid treatment is continued until the removal of the desired amount of calcium and/or magnesium has been carried out. This can take from 10 minutes to 50 hours, depending on the acidity of the solution, the temperature and the mechanical capacity of the equipment used. The acidic water in the ion exchange column should generally be in contact with the tobacco parts for a period of from 1 hour to 8 hours and preferably from 3 to 4 hours at a temperature of from 25°C to 50°C, and preferably from 25 °C to 35°C. The water used to treat the tobacco can then be brought back into contact with new tobacco.

The treated stems may then be pressed or otherwise treated to remove the treatment solution, air-dried or dried in an oven or the like, and ground to a substantially uniform size, usually from -50 to -200 mesh size and preferably from -80 to -120 mesh size to form a pulp.

The resulting pulp was then mixed with from 10 to 25 parts of water per part pulp, at a temperature of from 0°C to 60°C, preferably from 20°C to 40°C and the resulting mixture was brought to a pH value of from 5 to 10, preferably from 7.5 to 8, 6 by adding aqueous potassium hydroxide or similar. The following ingredients, which are essential for a good product, are added in the following quantities: 1) calcium, added as a calcium salt or as calcium hydroxide or the like, for example Ca(OH)2, CaCl2 or CaHPO^ to give the following percentage of calcium (elemental ) in the final product: 2.0-37°2) potassium, added as a potassium salt or as potassium hydroxide or the like, for example KOH,<K>2<S0>4,K2HP04 or KC1 to give the following percentage of potassium (elemental) in the final product

ducted 0.19-5.0$

3) maleic acid or a salt thereof, for example calcium maleate 5.0-20.0$ 4) citric acid or a salt thereof, for example calcium citrate *s 0.75-10.0$ 5) a humectant, for example glycerol, triethylene glycol, butylene glycol or

propylene glycol 1.6-6.0%

damn

6) a sugar, for example invert sugar,

dextrose, fructose or sucrose 5.0-20.0$

Then the following components can be added if desired, 7) magnesium, added as a magnesium salt or as magnesium hydroxide or similar,

for example, Mg(OH)2, MgSO^, or MgCl2 to give the following percentage elementally

magnesium 0.3-1.4$

8) nicotine, for example pure nicotine or as a salt such as maleate, citrate or hydrochloride 1.0-3.0$

9)' a phosphate (P2O5), for example CaHPO^

or K2HP040.8-1.0$

Other ingredients can be added to adjust the taste or smoking properties of the product.

The selection of the organic and inorganic components to be added to the slurry mainly comprises the addition of the desirable components (or their equivalents) found in the naturally occurring tobacco leaves to the slurry.

The following examples are illustrative of the invention:

Example 1.

The components which, by chemical analysis, were found to be present in the filling mass of a completely light cigarette without additives, were added to the base material. This base material was 1.78 kg of ground fibers produced from light tobacco stalks which had been decalcified by passing slightly acidic water back over the washed light tobacco stalks and through a column of "Dowex" sulphate resin in acidic form. The ground fibers were dispersed in 34.2 kg of distilled water and the mixture was brought to a pH value of 8.2 by the addition of 0.62 kg of 17% aqueous potassium hydroxide. This mixture can be called the base mixture in component group 1.

Maleic acid (0.23 kg), calcium hydroxide (0.06 kg) and nicotine (0.34 kg 20% aqueous solution) were added to 2.15 kg of distilled water. This mixture, which will be referred to as component group II, was then added to the base mixture

(group 1)

The following groups of materials were also mixed together separately and added to the base mixture in the sequence indicated below:

This production, which formed 45.3 kg of slurry with a solids content of 7% and a pH value of 5.2, was passed through a homogenizer and then cast onto an endless steel casting belt. The cast plate was partially dried with electric heating devices, removed from the belt when it had a moisture content of approx. 20$ and further dried to approx. 15$ humidity. The resulting plate weighed approx. 95 g/m . It was torn up without difficulty into a filler for cigarettes, and cigarettes were made from this in the usual way. The plate and the torn-up filling material were very easy to process in the various production steps.

The inhalation resistance of the resulting cigarette was determined. Resistance to inhalation is defined as the pressure drop across a cigarette, expressed in mm of water column, when air flows through the cigarette at a rate of 1050 ml/min. To determine this pressure difference, one end of the cigarette was inserted into a specially designed tube through which air was sucked. The pressure difference between the open and the closed end of the cigarette was measured. Resistance to inhalation was 51 - 61 mm water column.

The cigarettes weighed 1.14 grams each. Niognitti cigarettes were made from 120 grams of filler.

The cigarettes were smoked in a constant volume smoking machine which took a 35 ml inhalation of 2 second duration once every 60 seconds. The smoke was captured in a "Cambridge" filter insert that retained particles larger than 0.3 microns. The pill array was weighed before and after the smoking of four cigarettes to determine the accumulated amount of total particulate matter. This was 10.2 mg/cigarette.

The number of inhalations was determined by smoking four cigarettes, counting the number of inhalations needed to bring the burn line up to the JO mm mark on the cigarettes, and then averaging the number of inhalations as the number for the individual cigarettes. The number of inhalations was 5.5-

Steam distillation of the filler in the cigarette removed the volatile alkaloids present. Comparison of the ultraviolet absorption spectrum of the distillate with suitable standards formed the basis for a quantitative estimate of the total alkaloid content. The nicotine content expressed as total alkaloid was 0.84 mg/cigarette.

The static burn rate, which was measured by determining the time required to statically burn a 40 mm stick of tobacco, was 6.6 minutes.

Example 2.

The ingredients similar to those used in example 1 were put together as in example 1, with the exception that 0.064 kg of citric acid monohydrate (twice as much as in the amount prescribed in example 1) was used. The final slurry was adjusted to a pH value of 5.2 by adding 17% aqueous potassium hydroxide as needed. A plate was cast, dried and torn up very well. Cigarettes made from this filler had much the same physical and burning properties as the material prescribed in Example 1 as shown in the following table.

A judging panel of five experts compared these cigarettes to those produced in Example 1. They found that the sample cigarette had a less sharp taste than the cigarette in Example 1, that it had a fuller aroma, and that it was preferable to the cigarettes in Example 1 out of four group (one had no preference).

Example 3-

Ground tobacco fibers (1.78 kg) from light tobacco stalks were washed with water passed back through a column of "Dowex" sulfate resin in acid form and dispersed in 3^.30 kg of distilled water. The mixture was brought to a pH of 8.2 by adding 0.064 kg of concentrated aqueous ammonium hydroxide, 0.34 kg of 20% aqueous nicotine and 0.09 kg of calcium hydroxide slurried in 0.453 kg of distilled water.

The following groups of ingredients were added to the resulting mixture in the order indicated:

The resulting slurry weighed 4-5.3 kg and had a pH of 6.0. It was made into plates :jg r--i vet opp as before. The plates had a high calcium content and a very low potassium content. The cigarettes stopped burning under static foHiold, and it u-s changed certain smoking characteristics as shown in the following tables (more tail rings, higher total yield).

Example 4.

Ingredients and method of putting them together were the same as in example 1, with the exception that no invert sugar was added. A plate was cast which was dried and torn up as before. A low sugar content meant a high ash content in the plate, and the change in the plate produced a light, fast-burning cigarette which consequently had a low number of tails and a low yield of both nicotine and particulate matter.

The results of the different assessments from examples 1-5 are presented in tables I and II.

As elsewhere in the presentation, all percentages are calculated by weight.

Claims (2)

1. Reconstituted tobacco product, characterized in that it comprises from 5.0 to 90.0 weight percent of a fiber chewy tobacco material containing tobacco pectins substantially without calcium cross-links and magnesium cross-links, a calcium compound in an amount sufficient to provide from 2.0 to 3.0 percent by weight elemental calcium, a potassium compound in an amount sufficient to provide from 0.19 to 5.0% by weight of elemental potassium, from 5.0 to 20.0% by weight of maleic acid or a salt thereof, from 0.75 to 10.0% by weight of citric acid or a salt thereof, from 1.0 to 6.0% by weight of a humectant and from 5.0 to 20.0 weight percent of a sugar. 2. Reconstituted tobacco product in accordance with claim 1, characterized in that it comprises a magnesium compound in an amount sufficient to provide from 0.3 to 1.4 weight percent elemental magnesium, from 1.0 to 3.0 weight percent pure nicotine or a nicotine salt, as well as from 0.3 to 1.0 weight percent of a phosphate.