CA1142020A - Aromatized soluble coffee - Google Patents
Aromatized soluble coffeeInfo
- Publication number
- CA1142020A CA1142020A CA000339558A CA339558A CA1142020A CA 1142020 A CA1142020 A CA 1142020A CA 000339558 A CA000339558 A CA 000339558A CA 339558 A CA339558 A CA 339558A CA 1142020 A CA1142020 A CA 1142020A
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- Prior art keywords
- soluble coffee
- coffee
- solids
- soluble
- pores
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Abstract
ABSTRACT
Soluble coffee solids are processed to have a unique microporosity such that 3 to 30 microliters of the pore space per gram of solids are comprised of pores having a radius of 150 .ANG. or less. The microporous soluble coffee solids act as an excellent sorbent for roasted and ground coffee aromas and, when admixed in small quantity with conventional soluble coffees, enhance the product with in-jar aroma.
Soluble coffee solids are processed to have a unique microporosity such that 3 to 30 microliters of the pore space per gram of solids are comprised of pores having a radius of 150 .ANG. or less. The microporous soluble coffee solids act as an excellent sorbent for roasted and ground coffee aromas and, when admixed in small quantity with conventional soluble coffees, enhance the product with in-jar aroma.
Description
Descr~ tion AROMATIZE~ SOLUBLE COFFEE
Technical Field The present inven~ion p~rtains to soluble 05 coffee and, more particulaxly, is directed to freeze-dried soluble coffee solids. Specifically, the invention is related to soluble coffee granules having a unique porosity which provides these granules with the capability of sorbing and retain-ing roasted and ground coffee aromatics and control-lably releasing these aromatic volatiles.
Background Art ~
Compared with roasted and ground coffee, the source material, soluble coffee has very little aroma.
Prior to the present invention, virtually all commercial soluble coffee products have been Pn-hanced with aromas by combining the soluble coffee with pure coffee oil or aroma-enriched coffee oil in an endeavor to provide the soluble coffee product with an aromatic quality more akin to roasted and ground coffee (cf. U.S.A. Patent No. 3,148,070).
Aromatizing soluble coffee solids with coffee oil has several drawbacks. Many processing problems are encountered in recovering the oil from the roasted and ground coffee and, once obtained, the glyceride has a tendency to become rancid. ALso, ~t~
Technical Field The present inven~ion p~rtains to soluble 05 coffee and, more particulaxly, is directed to freeze-dried soluble coffee solids. Specifically, the invention is related to soluble coffee granules having a unique porosity which provides these granules with the capability of sorbing and retain-ing roasted and ground coffee aromatics and control-lably releasing these aromatic volatiles.
Background Art ~
Compared with roasted and ground coffee, the source material, soluble coffee has very little aroma.
Prior to the present invention, virtually all commercial soluble coffee products have been Pn-hanced with aromas by combining the soluble coffee with pure coffee oil or aroma-enriched coffee oil in an endeavor to provide the soluble coffee product with an aromatic quality more akin to roasted and ground coffee (cf. U.S.A. Patent No. 3,148,070).
Aromatizing soluble coffee solids with coffee oil has several drawbacks. Many processing problems are encountered in recovering the oil from the roasted and ground coffee and, once obtained, the glyceride has a tendency to become rancid. ALso, ~t~
- 2 ~
coffee oil, even in small amounts, adversely affects the flowability of soluble coffee granules and undesirable droplets of -the oil can, and do, appear on the surface of the liquid beverages prepared from 05 the oil-containing soluble coffèe solids.
Prior suggestions, trials and other efforts directed toward aromatizing soluble coffee solids without the use of coffee oil as the aroma carrier have not, within present knowledge, met with com-mercial success. These attempts have been less thansuccessful, for the most part, because of the in-herent lack of sufficient affinity of conventionally produced soluble coffee solids for sorbing and retaining volatile coffee aromatics.
Disclosure of the Invention The thrust of the invention is the aromatization of soluble coffee products wi~hout the use of coffee oil. Surprisingly, it has been discovered that soluble coffee solids, produced under a condition which provides them with a unique porous structure, have an affinity of heretofore unrealized large magnitude for roasted and ground coffee aromas.
The porous soluble coffee particles of this invention not only have the capacity to sorb large quantities of volatile aromatics of roasted and ground coffee, but also have the capability to retain the aromatics for extended periods of time and subsequently, to release the aromatics under controlled conditions.
These highly aromatized soluble coffee particles, when added in small amounts, and uniformly admixed with typical unaromatized soluble coffee solids, provide the composite product with the desirable fragrant aroma of freshly roasted and ground coffee.
The aromatized soluble coffee particles ind their greatest utility as sor~ent for roasted and ground coffee aromas which are to be released upon opening a jar of aroma-enhanced soluble co~fee ? When 05 the jar is recapped, the uniquely porous particles controllably release additional aromas which perm-eate the contained remaining bulk product and void spaces. On reopening the jar, the aromas are further released to the a-tmosphere foretelling the consumer of an enjoyable beverage.
The essence of the invention resides in the discovery of a uni~ue microporous structure which not only provides soluble coffee particles with available exposed internal surface areas for solid surface to vapor molecular attraction (adsorption of the roasted and ground coffee aroma vapors) but also the structure manifests micropores within a range of sizes which extensively sorb and retain roasted and ground coffee aromatics via capillary condensation.
The molecular structures of the aromas "fit" and cooperate with the micropores to the extent the aromatics are releasably retained within the micropores substantially by capillary condensation forces and by some surface contact attracting forces.
Condensation of the aromas affords the micropores the capability of sorbing significant quantities of aromatics which are, subsequently, controllably released as vapors.
For purposes of this invention, the term "micropore" is intended to mean a pore having a radius of 1000 A or less.
In order to produce a satisfactory and success ful result within the precepts of the invention, it has been determined that the particles of soluble coffee to be initially aromatized with roasted and ~round coffee aromas must have a porosity such that from 3 to 30 microliters per gram of the dry soluble coffee solids is comprised of micropores which have 05 a radius of 150 A or less. That is, the soluble coffee solids must have 0.3 to 3% (v/w) of useful pore space comprised of pores having a radius of 150 A or less.
Inherently, when the soluble coffee solids are prepared so as to have from 0.3 to 3% (v/w) of the pore space comprised of pores having a radius of lS0 A or less (useful pore space for purposes of the invention), a gradation of pore sizes results with those pores having a radius of less than 30 A most frequently occurring and contributing to the useful pore space.
The fact the useful pore space is comprised of pores of gradual sizes adds to the overall capability of the useful pore space to sorb and retain aromas associated with roasted and ground coffee. The aromas are a mixture of compounds of various molecular size and structure, each of which is preferentially sorbed and retained by capillary condensation in pores of a size most suitable for this purpose.
Those pores in the soluble coffee solids having a radius greater than 150 A have been determined to be substantially incapable of sorbing any of the components of roasted and ground coffee aromas by capillary condensation and are, therefore, considered to be outside the useful range.
It has now been determined that from 0.05 to 20 milligrams of roasted and ground cof~ee aromas can be sorbed by capillary condensatlon per gram of dry coffee solids having a useful pore space of 0.3 to 3% (v/w).
The specific amount of aromas sorbed is primarily a factor of the type aroma, the magnitude of the useful pore space, and the pore size distribution within the useful pore space.
05 Further, for those soluble coffee solids having a useful pore space of 30 microliters/~ram of solids, when sorbing within each gram of soluble solids as much as 10 milligrams of dry aromas from roasted and ground coffee via capillary condensation, it has been determined that only 30-35% of the useful pore space is filled with aroma components.
The capillary condensation forces which sorb and retain the aromas have been determined to be less than the aroma vapor pressure forces strivin~
to release the aroma from the useful pore spa~e.
Thus, upon confining a small quantity of the aromatized soluble coffee solids within a closed container, the aroma will be driven from the solids in vapor form until an equilibrium partial vapor pressure is attained within the container. Upon opening the container the vaporized aroma is further released to the proximate atmosphere. Reclosing the container brings about a second equilibrium condition.
Thus it can be appreciated that a readily calculated small amount of aromatized microporous sol-lble coffee solids of the invention can be admixed and jarred with unaromatized conventional soluble coffee to provide sufficient roasted and ~xound aroma to pass from the aromatized solids into the headspace of the jar and be released each time the jar is uncapped.
Measurement of Pore Size and Useful Pore Space The porosity of a material is the ratio of the volume of the interstices of -the material to the volume of its mass. To extend this definition to include the number of interstices (pores), their shape and size (particularly micropores), requires sophisticated measurement and calculation techniques.
The characteristics of the porosity of the dry 05 soluble coffee solids for the present invention have been calculated from responses from model systems employing C02 and N2 gases according to the well recognized and authoritative methods of S. Brunauer, "The Adsorption of Gases and Vapors" Vol. 1 Princeton University Press, 1945 and ~arre-tt, E.P., et al. Journal American Chemical Society 73 373 1951.
Best Mode for Carryin~ Out_the Invention The microporous particles of soluble coffee of the invention are prepared by shock freezing a concentrated coffee extract followed by freeze-drying the resultant frozen particles of extract.
Spraying an aqueous coffee extract, preferably, but not necessarily, having a soluble solids content less than 40% by weight, typically 25% to 35% by weight, into a cryogenic fluid having a temperature below -100C, preferably liquid nitrogen, and subsequently freeze-drying the frozen particles of solution produces dry microporous soluble coffee solids having the required useful pore space whereof from 3 to 30 microliters per gram of the solids is comprised of micropores which have a radius of 150 A
or less.
The spray should preferably produce particles having an average particle size of below about 200 microns diameter so that the entire particle will be instantaneously frozen on contact with the cryogenic fluid.
It is not strictly essential the particle be formed from a spray or the particle size be below 200~ --what is essential is the rapidity at which all of the moisture within ~he particle freezes.
05 It is believed that rapid freezing, approaching instantaneous, forms minute ice crystals exclusively throughout the particle. To assure this condition, the cryogenic fluid should have a temperature of -100C or below.
The moisture content of the shock frozen particles of concentrated coffee extract which is in the form of minute ice crystals is sublimed from the particles to yield solid coffee granules with the microporous structure of the invention. It is essential that moisture removal be accomplished substantially completely by sublimation (no liquid water present) to produce the desirable pore structure. Also, freeze-drying processing conditions must be carefully controlled to insure there is insignificantly little, or no melting of the ice crystals during dehydration of the frozen coffee extract particles.
The aromas associated with roasted and ground coffee, whether natural or synthetic, may be derived from many sources well-known to those skilled in the art. Depending on the method of contact to be employed, the aromas may be present as a component of a gas, a liquid condensate or a condensed frost.
The method of contacting the microporous particles with roasted ground coffee aromatics for the purpose of sorbing aroma within the particles can also be many and varied. The use of high pressure and/or low particle temperatures may be employed in order to maximize the quantity of aroma sorbed or to shorten the period of -time required to achieve a desired level of aromatization; however, such conditions are not usually required.
Among the techniques useful to date for the 05 sorption of aromatics by the porous solu~le coffee particles, the most preferable is to contact the microporous particles of soluble coffee with grinder gas frost (frozen roasted and ground aromatics plus frozen C02 obtained during the grinding of the roasted coffee).
This is accomplished by placing both the porous particles and condensed CO2 aroma frost well mixed in a vented vessel, preferably above -40C, and permitting the CO2 portion of the frost to sublime.
The microporous coffee granules of the in-vention have the capability of sorbing as much as 2%
(w/w) of roasted and ground coffee aroma. This is, in general, in excess of that which is required and, depending on how the aromatized soluble coffee solids axe utilized, the aromatized particles will contain aromatics at a level of from 0.05 to 20 milligrams per gram of solids.
When the level of aromatics sorbed is 1 milli-gram/gram of aromatized solids, it requires about 5 grams of aromatized solids to be admixed with 95 grams of conventional soluble coffee -to provide sufficient headspace aroma in the jar for release each time the jar is uncapped throughout the average periodic use of the beverage-making product.
Since it has been determined to be more prefer~
able to admix 2% or less of aromatized microporous soluble coffee solids with the conventional soluble coffee, the aromatized mixture should preferably contain aromatics at a level of 0.2 to 0.5% (w/w).
~z~
If the aromatized rnicroporous soluble coffee granules are present in the product of the invention in excess quantity, they provide desirable flavor effects to the liquid beverage upon reconstitution 05 of the granules with hot water.
As stated before, during storage of the aromatized soluble coffee granules admixed with the bulk unaromatized materials, the sorbed aromatics exert a vapor pressure which overcomes the porosity binding forces and a small quantity of aroma is released until a partial vapor pressure equilibrium condition exists within the jar. Upon opening the jar, the aroma is further released to the atmosphere foretelling the consumer of an enjoyable beverage.
Upon capping the jar, the aroma-retention and releasing processes are repeated. Thus, the inven-tive granules are capable of sorbing, retaining, and releasing roasted and ground coffee aromas to pro-duce desirable soluble coffee jar package "head-space" aroma.
EXAMPLE
An aqueous coffee extract having a soluble solids content of 33% by weight was prepared by reconstitu-ting spray dried coffee solids. This extract was sprayed into an open vessel containing liquid nitrogen whereupon the particles of extract immediately froze and were dispersed. The extract was sprayed by means of a two-fluid, glass atomizing nozzle (a chromatographic nozzle obtained from SGA
Scientific, Inc., Fullerton, California) using air as the pressurizing fluid. The liquid nitrogen and particle mixture was poured into freeze drier trays, and the liquid nitrogen was allowed to boil off leaving behind a flat bed of frozen particles about 1.16 to 3.2 mm. in thickness. The trays were placed in a freeze drier and subjected to a vacuum of 10 microns of Hg. and a plate temperature of 50C for a period of 18 hours. The vacuum on the freeze drier 05 was broken with dry CO~ and the dry particles having a moisture content of helow about 1.5% were remo~ed from the freeæe drier and kept out of contact of moisture. The dry particles were found to have a microporous structure such that 30 microliters per gram of coffee solids of the pore space were com-prised o pores having a radius of 150 A or less with the most frequently occurring pore size within the useable pore space being less than 30 A.
The dry particles were subse~uently chilled in dry ice under a dry atmosphere and mixed with coffee grinder gas frost, having a moisture content between 10 and 15% by weight, at a weight ratio of 0.2 parts frost per part particle. The mixture was trans-ferred to a prechilled jar having a pinhole vent, and the jar was stored at-18~overnight during which time CO2 was evolved. The chilled particles, having a moisture content of below 6% by weight, were then packaged in glass jars with unplated, agglomerated spray-drled coffee solids at the level of 0.75~ by weight of spray-dried solids. The resulting jars were then stored at 35c for periods of eight weeks. Upon initial opening and during a standard 7-day, in-use cycle, a pleasing headspace aroma was found which was rated as being at least as good as the headspace aroma possessed by jars of comparably stored, aromatized, agglomerated spray-dried coffee which coffee had been plated with grinder gas-enriched coffee oil. This oil-plated sample was prepared in accordance with U.S. Patent No.
4,119,736 using an amount of grinder gas frost for each weight unit of soluble product comparable to that employed in the inventive sample.
As previously noted, jar aroma has been provided 05 to commercial soluble coffee products by means of oil plating an aroma-bearing glyceride (e.g. coffee oil onto soluble powder). -Lt has also been con-templated to absorb coffee aromatics onto oil-plated soluble coffee, and this technique is expressly disclosed in U.S. Patent No. 3,823,241 to Patel et al. It has, however, not previously been thought possible to sorb high levels of aromatics directly onto soluble coffee solids such that the aromatics would be retained. The Patel et al. patent notes the criticality of the oil so that upon successive openings of the soluble coffee package (i.e., in~use cycle), the consumer will continue to perceive a jar aroma. This is in fact the situation for the con-ventional spray-dried, foam~dried and freeze-dried products dealt with in the Patel et al. patent.
However, the same deficiency does not exist with microporous soluble coffee particles having a use-able pore space as described for this invention. As previously noted, conventional spray-dried coffee does not possess a microporous structure; while in conventional freeze-dried coffee, most of the pore radii are on the order of 10,000 A and the useable pore space (pores having a radius of 150 A or less) is insignificantly small or entirely absent.
Indus_rlal Applicability The microporous soluble coffee granules of the invention find their greatest utility as sorbent for roasted and ground coffee aromas which are to be released upon opening a jar of soluble coffee. The inventive product has no coffee oil as the aroma sorbent and thereby avoids the processing difficulties encountered with the z~
~ 12 -glyceride. In this respect alone, the inventive soluble coffee product comprising packaged low or no aroma-containing soluble coffee admixed with a small amount of highly aroma-enhanced microporous soluble 05 co~fee granules represents a major technical advance in the art of soluble coffee manufacturing, part-icularly in view of the fact the aromas sorbed by the microporous granules have excellent stability during prolonged storage under inert conditions such as those which normally exist in packaged soluble coffee products.
coffee oil, even in small amounts, adversely affects the flowability of soluble coffee granules and undesirable droplets of -the oil can, and do, appear on the surface of the liquid beverages prepared from 05 the oil-containing soluble coffèe solids.
Prior suggestions, trials and other efforts directed toward aromatizing soluble coffee solids without the use of coffee oil as the aroma carrier have not, within present knowledge, met with com-mercial success. These attempts have been less thansuccessful, for the most part, because of the in-herent lack of sufficient affinity of conventionally produced soluble coffee solids for sorbing and retaining volatile coffee aromatics.
Disclosure of the Invention The thrust of the invention is the aromatization of soluble coffee products wi~hout the use of coffee oil. Surprisingly, it has been discovered that soluble coffee solids, produced under a condition which provides them with a unique porous structure, have an affinity of heretofore unrealized large magnitude for roasted and ground coffee aromas.
The porous soluble coffee particles of this invention not only have the capacity to sorb large quantities of volatile aromatics of roasted and ground coffee, but also have the capability to retain the aromatics for extended periods of time and subsequently, to release the aromatics under controlled conditions.
These highly aromatized soluble coffee particles, when added in small amounts, and uniformly admixed with typical unaromatized soluble coffee solids, provide the composite product with the desirable fragrant aroma of freshly roasted and ground coffee.
The aromatized soluble coffee particles ind their greatest utility as sor~ent for roasted and ground coffee aromas which are to be released upon opening a jar of aroma-enhanced soluble co~fee ? When 05 the jar is recapped, the uniquely porous particles controllably release additional aromas which perm-eate the contained remaining bulk product and void spaces. On reopening the jar, the aromas are further released to the a-tmosphere foretelling the consumer of an enjoyable beverage.
The essence of the invention resides in the discovery of a uni~ue microporous structure which not only provides soluble coffee particles with available exposed internal surface areas for solid surface to vapor molecular attraction (adsorption of the roasted and ground coffee aroma vapors) but also the structure manifests micropores within a range of sizes which extensively sorb and retain roasted and ground coffee aromatics via capillary condensation.
The molecular structures of the aromas "fit" and cooperate with the micropores to the extent the aromatics are releasably retained within the micropores substantially by capillary condensation forces and by some surface contact attracting forces.
Condensation of the aromas affords the micropores the capability of sorbing significant quantities of aromatics which are, subsequently, controllably released as vapors.
For purposes of this invention, the term "micropore" is intended to mean a pore having a radius of 1000 A or less.
In order to produce a satisfactory and success ful result within the precepts of the invention, it has been determined that the particles of soluble coffee to be initially aromatized with roasted and ~round coffee aromas must have a porosity such that from 3 to 30 microliters per gram of the dry soluble coffee solids is comprised of micropores which have 05 a radius of 150 A or less. That is, the soluble coffee solids must have 0.3 to 3% (v/w) of useful pore space comprised of pores having a radius of 150 A or less.
Inherently, when the soluble coffee solids are prepared so as to have from 0.3 to 3% (v/w) of the pore space comprised of pores having a radius of lS0 A or less (useful pore space for purposes of the invention), a gradation of pore sizes results with those pores having a radius of less than 30 A most frequently occurring and contributing to the useful pore space.
The fact the useful pore space is comprised of pores of gradual sizes adds to the overall capability of the useful pore space to sorb and retain aromas associated with roasted and ground coffee. The aromas are a mixture of compounds of various molecular size and structure, each of which is preferentially sorbed and retained by capillary condensation in pores of a size most suitable for this purpose.
Those pores in the soluble coffee solids having a radius greater than 150 A have been determined to be substantially incapable of sorbing any of the components of roasted and ground coffee aromas by capillary condensation and are, therefore, considered to be outside the useful range.
It has now been determined that from 0.05 to 20 milligrams of roasted and ground cof~ee aromas can be sorbed by capillary condensatlon per gram of dry coffee solids having a useful pore space of 0.3 to 3% (v/w).
The specific amount of aromas sorbed is primarily a factor of the type aroma, the magnitude of the useful pore space, and the pore size distribution within the useful pore space.
05 Further, for those soluble coffee solids having a useful pore space of 30 microliters/~ram of solids, when sorbing within each gram of soluble solids as much as 10 milligrams of dry aromas from roasted and ground coffee via capillary condensation, it has been determined that only 30-35% of the useful pore space is filled with aroma components.
The capillary condensation forces which sorb and retain the aromas have been determined to be less than the aroma vapor pressure forces strivin~
to release the aroma from the useful pore spa~e.
Thus, upon confining a small quantity of the aromatized soluble coffee solids within a closed container, the aroma will be driven from the solids in vapor form until an equilibrium partial vapor pressure is attained within the container. Upon opening the container the vaporized aroma is further released to the proximate atmosphere. Reclosing the container brings about a second equilibrium condition.
Thus it can be appreciated that a readily calculated small amount of aromatized microporous sol-lble coffee solids of the invention can be admixed and jarred with unaromatized conventional soluble coffee to provide sufficient roasted and ~xound aroma to pass from the aromatized solids into the headspace of the jar and be released each time the jar is uncapped.
Measurement of Pore Size and Useful Pore Space The porosity of a material is the ratio of the volume of the interstices of -the material to the volume of its mass. To extend this definition to include the number of interstices (pores), their shape and size (particularly micropores), requires sophisticated measurement and calculation techniques.
The characteristics of the porosity of the dry 05 soluble coffee solids for the present invention have been calculated from responses from model systems employing C02 and N2 gases according to the well recognized and authoritative methods of S. Brunauer, "The Adsorption of Gases and Vapors" Vol. 1 Princeton University Press, 1945 and ~arre-tt, E.P., et al. Journal American Chemical Society 73 373 1951.
Best Mode for Carryin~ Out_the Invention The microporous particles of soluble coffee of the invention are prepared by shock freezing a concentrated coffee extract followed by freeze-drying the resultant frozen particles of extract.
Spraying an aqueous coffee extract, preferably, but not necessarily, having a soluble solids content less than 40% by weight, typically 25% to 35% by weight, into a cryogenic fluid having a temperature below -100C, preferably liquid nitrogen, and subsequently freeze-drying the frozen particles of solution produces dry microporous soluble coffee solids having the required useful pore space whereof from 3 to 30 microliters per gram of the solids is comprised of micropores which have a radius of 150 A
or less.
The spray should preferably produce particles having an average particle size of below about 200 microns diameter so that the entire particle will be instantaneously frozen on contact with the cryogenic fluid.
It is not strictly essential the particle be formed from a spray or the particle size be below 200~ --what is essential is the rapidity at which all of the moisture within ~he particle freezes.
05 It is believed that rapid freezing, approaching instantaneous, forms minute ice crystals exclusively throughout the particle. To assure this condition, the cryogenic fluid should have a temperature of -100C or below.
The moisture content of the shock frozen particles of concentrated coffee extract which is in the form of minute ice crystals is sublimed from the particles to yield solid coffee granules with the microporous structure of the invention. It is essential that moisture removal be accomplished substantially completely by sublimation (no liquid water present) to produce the desirable pore structure. Also, freeze-drying processing conditions must be carefully controlled to insure there is insignificantly little, or no melting of the ice crystals during dehydration of the frozen coffee extract particles.
The aromas associated with roasted and ground coffee, whether natural or synthetic, may be derived from many sources well-known to those skilled in the art. Depending on the method of contact to be employed, the aromas may be present as a component of a gas, a liquid condensate or a condensed frost.
The method of contacting the microporous particles with roasted ground coffee aromatics for the purpose of sorbing aroma within the particles can also be many and varied. The use of high pressure and/or low particle temperatures may be employed in order to maximize the quantity of aroma sorbed or to shorten the period of -time required to achieve a desired level of aromatization; however, such conditions are not usually required.
Among the techniques useful to date for the 05 sorption of aromatics by the porous solu~le coffee particles, the most preferable is to contact the microporous particles of soluble coffee with grinder gas frost (frozen roasted and ground aromatics plus frozen C02 obtained during the grinding of the roasted coffee).
This is accomplished by placing both the porous particles and condensed CO2 aroma frost well mixed in a vented vessel, preferably above -40C, and permitting the CO2 portion of the frost to sublime.
The microporous coffee granules of the in-vention have the capability of sorbing as much as 2%
(w/w) of roasted and ground coffee aroma. This is, in general, in excess of that which is required and, depending on how the aromatized soluble coffee solids axe utilized, the aromatized particles will contain aromatics at a level of from 0.05 to 20 milligrams per gram of solids.
When the level of aromatics sorbed is 1 milli-gram/gram of aromatized solids, it requires about 5 grams of aromatized solids to be admixed with 95 grams of conventional soluble coffee -to provide sufficient headspace aroma in the jar for release each time the jar is uncapped throughout the average periodic use of the beverage-making product.
Since it has been determined to be more prefer~
able to admix 2% or less of aromatized microporous soluble coffee solids with the conventional soluble coffee, the aromatized mixture should preferably contain aromatics at a level of 0.2 to 0.5% (w/w).
~z~
If the aromatized rnicroporous soluble coffee granules are present in the product of the invention in excess quantity, they provide desirable flavor effects to the liquid beverage upon reconstitution 05 of the granules with hot water.
As stated before, during storage of the aromatized soluble coffee granules admixed with the bulk unaromatized materials, the sorbed aromatics exert a vapor pressure which overcomes the porosity binding forces and a small quantity of aroma is released until a partial vapor pressure equilibrium condition exists within the jar. Upon opening the jar, the aroma is further released to the atmosphere foretelling the consumer of an enjoyable beverage.
Upon capping the jar, the aroma-retention and releasing processes are repeated. Thus, the inven-tive granules are capable of sorbing, retaining, and releasing roasted and ground coffee aromas to pro-duce desirable soluble coffee jar package "head-space" aroma.
EXAMPLE
An aqueous coffee extract having a soluble solids content of 33% by weight was prepared by reconstitu-ting spray dried coffee solids. This extract was sprayed into an open vessel containing liquid nitrogen whereupon the particles of extract immediately froze and were dispersed. The extract was sprayed by means of a two-fluid, glass atomizing nozzle (a chromatographic nozzle obtained from SGA
Scientific, Inc., Fullerton, California) using air as the pressurizing fluid. The liquid nitrogen and particle mixture was poured into freeze drier trays, and the liquid nitrogen was allowed to boil off leaving behind a flat bed of frozen particles about 1.16 to 3.2 mm. in thickness. The trays were placed in a freeze drier and subjected to a vacuum of 10 microns of Hg. and a plate temperature of 50C for a period of 18 hours. The vacuum on the freeze drier 05 was broken with dry CO~ and the dry particles having a moisture content of helow about 1.5% were remo~ed from the freeæe drier and kept out of contact of moisture. The dry particles were found to have a microporous structure such that 30 microliters per gram of coffee solids of the pore space were com-prised o pores having a radius of 150 A or less with the most frequently occurring pore size within the useable pore space being less than 30 A.
The dry particles were subse~uently chilled in dry ice under a dry atmosphere and mixed with coffee grinder gas frost, having a moisture content between 10 and 15% by weight, at a weight ratio of 0.2 parts frost per part particle. The mixture was trans-ferred to a prechilled jar having a pinhole vent, and the jar was stored at-18~overnight during which time CO2 was evolved. The chilled particles, having a moisture content of below 6% by weight, were then packaged in glass jars with unplated, agglomerated spray-drled coffee solids at the level of 0.75~ by weight of spray-dried solids. The resulting jars were then stored at 35c for periods of eight weeks. Upon initial opening and during a standard 7-day, in-use cycle, a pleasing headspace aroma was found which was rated as being at least as good as the headspace aroma possessed by jars of comparably stored, aromatized, agglomerated spray-dried coffee which coffee had been plated with grinder gas-enriched coffee oil. This oil-plated sample was prepared in accordance with U.S. Patent No.
4,119,736 using an amount of grinder gas frost for each weight unit of soluble product comparable to that employed in the inventive sample.
As previously noted, jar aroma has been provided 05 to commercial soluble coffee products by means of oil plating an aroma-bearing glyceride (e.g. coffee oil onto soluble powder). -Lt has also been con-templated to absorb coffee aromatics onto oil-plated soluble coffee, and this technique is expressly disclosed in U.S. Patent No. 3,823,241 to Patel et al. It has, however, not previously been thought possible to sorb high levels of aromatics directly onto soluble coffee solids such that the aromatics would be retained. The Patel et al. patent notes the criticality of the oil so that upon successive openings of the soluble coffee package (i.e., in~use cycle), the consumer will continue to perceive a jar aroma. This is in fact the situation for the con-ventional spray-dried, foam~dried and freeze-dried products dealt with in the Patel et al. patent.
However, the same deficiency does not exist with microporous soluble coffee particles having a use-able pore space as described for this invention. As previously noted, conventional spray-dried coffee does not possess a microporous structure; while in conventional freeze-dried coffee, most of the pore radii are on the order of 10,000 A and the useable pore space (pores having a radius of 150 A or less) is insignificantly small or entirely absent.
Indus_rlal Applicability The microporous soluble coffee granules of the invention find their greatest utility as sorbent for roasted and ground coffee aromas which are to be released upon opening a jar of soluble coffee. The inventive product has no coffee oil as the aroma sorbent and thereby avoids the processing difficulties encountered with the z~
~ 12 -glyceride. In this respect alone, the inventive soluble coffee product comprising packaged low or no aroma-containing soluble coffee admixed with a small amount of highly aroma-enhanced microporous soluble 05 co~fee granules represents a major technical advance in the art of soluble coffee manufacturing, part-icularly in view of the fact the aromas sorbed by the microporous granules have excellent stability during prolonged storage under inert conditions such as those which normally exist in packaged soluble coffee products.
Claims (12)
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:
1. Freeze-dried microporous soluble coffee solids characterized by having from 3 to 30 microliters of pore space per gram of solids composed of pores having a radius of 150 .ANG.
or less.
or less.
2. The microporous soluble coffee solids of claim 1, wherein the most frequently occurring pores composing the 3 to 30 microliters of pore space are pores having a radius of less than 30 .ANG..
3. The microporous soluble coffee solids of claim 1 or 2 having from 0.1 to 2% (w/w) of capillary condensed aromas releasably contained in the pores having a radius of 150 .ANG. or less which constitute from 3 to 30 microliters of pore space per gram of solids.
4. A soluble coffee powder enhanced with roasted and ground coffee aromas,the soluble coffee powder having admixed therewith in amount of from 0.1 to 5% by weight of the soluble coffee powder, an aroma-enriched microporous soluble coffee sorb-ent having from 3 to 30 microliters of pore space per gram of sorbent consisting of pores having a radius of 150 .ANG. or less.
5. A soluble coffee powder according to claim 4, wherein the most frequently occurring pores composing the 3 to 30 microliters of pore space are pores having a radius of less than 30 .ANG..
6. A soluble coffee powder according to claim 4 or 5 wherein the sorbent has from 0.2% to 1% by weight sorbed roasted and ground coffee aromas.
7. A soluble coffee powder according to claim 4 or 5 packaged within a reclosable container.
8. Method of preparing freeze-dried soluble coffee solids having from 3 to 30 microliters of pore space per gram of solids composed of pores having a radius of 150 .ANG. or less, the method comprising spraying an aqueous coffee extract into a cryogenic fluid having a temperature of -100°C., and below, and freeze-drying the frozen particles.
9. Method according to claim 8, wherein droplets of the sprayed aqueous coffee extract have an average size of below about 200 microns diameter.
10. Method according to claim 8 or 9 wherein the aqueous coffee extract has a soluble solids content less than 40% by weight.
11. Method according to claim 8, wherein the cryogenic fluid is liquid nitrogen.
12. Method of providing a headspace aroma to a pack-age of soluble coffee powder, comprising mixing the soluble coffee powder with an amount of from 0.1 to 5% by weight of the soluble coffee powder,
12. Method of providing a headspace aroma to a pack-age of soluble coffee powder, comprising mixing the soluble coffee powder with an amount of from 0.1 to 5% by weight of the soluble coffee powder,
Claim 12 - continued of an aroma-enriched microporous soluble coffee sorbent having from 3 to 30 microliters of pore space per gram of sorbent con-sisting of pores having a radius of 150 .ANG. or less which is enriched with from 0.2% to 1% by weight sorbed roasted and ground coffee aromas, and packaging the soluble coffee powder and the admixed sorbent, the roasted and ground coffee aromas passing gradually from the sorbent to the headspace whereby upon opening of the package coffee aroma volatiles released from the headspace are detected.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CA000339558A CA1142020A (en) | 1979-11-09 | 1979-11-09 | Aromatized soluble coffee |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CA000339558A CA1142020A (en) | 1979-11-09 | 1979-11-09 | Aromatized soluble coffee |
Publications (1)
Publication Number | Publication Date |
---|---|
CA1142020A true CA1142020A (en) | 1983-03-01 |
Family
ID=4115579
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CA000339558A Expired CA1142020A (en) | 1979-11-09 | 1979-11-09 | Aromatized soluble coffee |
Country Status (1)
Country | Link |
---|---|
CA (1) | CA1142020A (en) |
-
1979
- 1979-11-09 CA CA000339558A patent/CA1142020A/en not_active Expired
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