[0001] This invention relates to the perfuming of rinse conditioner compositions.
[0002] Rinse conditioners are products which are designed to be added to water used for
the rinsing of laundry after washing with a detergent composition. Such conditioners
contain a material whose function is to confer a benefit to the laundry after the
laundry has been rinsed and dried. One of the main benefits delivered by such products
is softness.
[0003] It is normal to include perfume in such rinse conditioners, firstly to enhance the
attractiveness of the product to a user, and secondly to deliver the perfume to the
laundry itself.
[0004] It is known to incorporate perfume into a porous carrier to reduce the rate at which
the perfume evaporates and hence extend the time during which the perfume fragrance
remains perceptible.
[0005] US-A-4446032 discloses rinse conditioner compositions which contain perfume trapped
within carrier particles which may be porous or alternatively may be closed capsules
with an impervious layer surrounding the perfume. This document teaches that a suspending
agent should be included in the composition.
[0006] JP-A-63/122796 discloses the addition of a polymer latex which contains cationic
or tertiary amino groups to a detergent composition, for the purpose of enhancing
perfume deposition.
[0007] WO98/28396 (Quest) discloses perfume absorbed within organic polymer particles and
which have a further polymer at their exterior. The polymer particles disclosed desirably
have an average particle size of at least 10 µm.
[0008] WO 98/28339 (Quest) discloses polymer particles comprising a hydrophobic organic
matrix and located at the exterior free cationic groups and a further polymer which
comprises free hydroxy groups. The polymer particles disclosed desirably have an average
particle size of at least 10 µm.
[0009] EP 397 246 (Minnesota Mining) discloses perfume particles comprising perfume dispersed
within certain water-insoluble polymeric materials and encapsulated in a protective
shell by coating with a friable coating material.
[0010] EP 617 051 (Allied Colloids) discloses that the controlled release of a fragrance
can be provided by incorporating it during emulsion polymerisation of water insoluble
monomeric material in which it is dissolved, and by controlling the monomer blend
composition and the Tg of the resultant polymer.
[0011] The present invention provides a composition for use in the rinsing of laundry, containing
particles with perfume located or absorbed in or on the particles, wherein the particles
are formed of cross-linked organic polymeric material and have a mean particle size
not greater than 1 micron, wherein there is cross-linking between at least 0.5% by
number of the total number of monomer residues present in the polymer.
[0012] Preferably the polymeric material is a latex.
[0013] We have found that cross-linked latices give superior delivery of perfume to fabrics
and better physical stability to the product
[0014] In preferred forms, this invention is concerned with rinse conditioner compositions
which incorporate a material effective to soften fabrics.
[0015] Incorporating perfume in this way can lead to an increase in the amount of perfume
which remains with the fabric after drying, especially when the fabric is dried in
a heated tumble dryer.
[0016] Additionally particles of this small, colloidal size remain suspended in an aqueous
liquid and there is no need to incorporate a separate suspending agent.
[0017] A method of treating laundry comprising contacting said laundry with a composition
as herein described is also provided.
[0018] Furthermore, this invention provides a method of making a rinse conditioner which
comprises mixing.(i) a fabric softening material and (ii) particles of cross-linked
organic polymeric material wherein there is cross-linking between at least 0.5% by
number of the total number of monomer residues present in the polymer, the particles
having a mean particle size not greater than 1 micron and with perfume located or
absorbed therein or thereon.
[0019] In this aspect, the invention can provide a way to incorporate perfume into a rinse
conditioner composition while avoiding or mitigating adverse effects on viscosity.
We have found that perfume can produce adverse changes to the viscosity of rinse conditioner
compositions, especially when these contain a substantial percentage of fabric softener.
In extreme cases the addition of perfume to a concentrated rinse conditioner composition
can cause it to gel and become immobile.
[0020] Incorporation of perfume in a latex can avoid or mitigate this. This feature of the
invention has been found to be applicable in particular to compositions which contain
at least 8%, more especially at least 12% by weight of fabric softening material.
The amount of fabric softening material may lie in a range from 12% to 40% by weight
or may be even greater up to 80% or 90% by weight of the composition.
[0021] It is here envisaged in particular that the fabric softening material may be cationic
fabric softening material in an amount which is at least half of the total quantity
of fabric softening material present and in addition is at least 8% by weight of the
composition, especially at least 12% by weight of the composition.
[0022] In certain preferred forms, this invention is particularly concerned with cross-linked
polymer lactices whose particles have the perfume trapped therein. We have found that
cross-linked latices give superior delivery of perfume to fabrics and better physical
stability to the product.
[0023] Compositions in which this invention may be applied and materials used, will now
be discussed in more detail.
Fabric Softening Rinse Conditioners
[0024] A variety of materials are effective to soften fabrics and can be delivered to fabric
from an aqueous composition.
[0025] A fabric-softening agent functions to give fabric a softer handle. Frequently such
agents also provide an anti-static benefit.
[0026] Fabric softening agents used in rinse conditioner compositions are usually materials
with low solubility in water. Typically the solubility in acidified water at pH 2.5
and 20°C is less than 10g/litre, preferably less than 1g/litre. When added to rinse
water such materials form a dispersed phase which is then able to deposit on fabrics
which are being rinsed in the water.
[0027] Many fabric softening materials fall within the categories of amphoteric, zwitterionic,
cationic and nonionic compounds.
[0028] Amphoteric, zwitterionic and cationic fabric softening materials include a polar
group and usually one or more hydrophobic aliphatic chains such as alkyl or alkenyl
groups each of which contains at least 6 carbon atoms, e.g. a range from 6 to 50 carbon
atoms in a continuous hydrocarbon chain or a hydrocarbon chain interrupted by a hereoatom.
In many such materials there are either a single aliphatic chain containing 12 to
50 carbon atoms, or a plurality of aliphatic chains each containing 6 to 30 carbon
atoms. Such aliphatic chains many be interrupted by a heteroatom as for instance in
an

linkage. Generally it is preferred that a hydrophobic aliphatic chain does not incorporate
more than one interrupting heteroatom.
[0029] A nonionic fabric softening material will generally include a polar group and an
aliphatic hydrocarbon chain of 6 to 30 carbon atoms, optionally interrupted by a heteroatom
as mentioned above, although hydrocarbon chains of 6 to 18, carbon atoms especially
6 to 11 carbon atoms are preferably without any interruption.
[0030] Cationic fabric softeners are of special commercial importance and are a preferred
type of softener according to the invention. Preferred forms of this invention include
cationic fabric softener, optionally with nonionic, amphoteric or zwitterionic fabric
softener present in addition. Thus the amount of cationic fabric softening agent may
be equal to, or greater than, the amount of any softening agent or surfactant which
is not cationic.
[0031] Many commercially important fabric softening agents are organic compounds containing
nitrogen, and at least one hydrocarbon chain of 6 to 50 carbon atoms. The nitrogen
atom may well be quaternary, but need not be, as for example in amines and imidazolines
which protonate to a quaternary form in acidic solution.
[0032] Some specific instances of fabric softening agents are:
1) Acyclic quaternary ammonium compounds.
[0033] These compounds are of the general formula (I)

wherein each Q
1 is a hydrocarbyl group containing from 15 to 22 carbon atoms. Q
2 is a saturated alkyl or hydroxy alkyl group containing from 1 to 4 carbon atoms.
Q
3 may be as defined for Q
1 or Q
2 or may be phenyl, Q
4 may be defined as for Q
1 or Q
2, and X
- is an anion preferably selected from halide, acetate, methyl sulphate and ethyl sulphate
radicals.
[0034] Throughout this discussion of fabric softening agents the expression hydrocarbyl
group refers to alkyl or alkenyl groups optionally substituted or interrupted by functional
groups such as -OH, -O-, CONH, -COO-, etc.
[0035] Representative examples of these quaternary softeners include tallow trimethyl ammonium
methyl sulphate or chloride; ditallow dimethyl ammonium chloride; ditallow dimethyl
ammonium methyl sulphate; dihexadecyl dimethyl ammonium chloride; di(hydrogenated
tallow) dimethyl ammonium methyl sulphate or chloride; di (coconut) dimethyl ammonium
chloride dihexadecyl diethyl ammonium chloride; dibehenyl dimethyl ammonium chloride.
[0036] Preferred among these are ditallow dimethyl ammonium chloride, di (hydrogenated tallow)
dimethyl ammonium chloride, di(coconut) dimethyl ammonium chloride and di(coconut)
dimethyl ammonium methosulphate.
[0037] Examples of commercially available materials in this class are ARQUAD 2C, ARQUAD
2HT, ARQUAD 2T (all ex Akzo), PRAPAGEN WK, PRAPAGEN WKT, DODIGEN 1829 (all ex Clariant),
QUERTON 4BG, QUERTON 442 (all ex Akzo), AMMONYX KP, AMMONYX SKD (all ex Millchem),
SYNPROLAM FS ( ex Unichema). The product names are believed to be trademarks.
2) Alkoxylated Polyamines
[0038] Alkoxylated polyamines of general formula (II) are known

[0039] Each Q
4 is a hydrocarbyl group containing from 10 to 30 carbon atoms. The Q
5 groups may be the same or different each representing hydrogen, (-C
2H
4O)
pH, (C
3H
6O)
qH, (C
2H
4O)
p, (C
3H
6O)Q,H, and alkyl group containing from 1 to 3 carbon atoms or the group (CH
2)
n, N(Q
5)
2; n and n' are each an integer from 2 to 6, m is an integer from 1 to 5 and p, q and
(p' + q') may be numbers such that (p + q + p' + q') does not exceed 25. X- is an
anion.
[0040] Alkoxylated polyamines suitable for use herein include N-tallowyl, NN'N'-tris (2
hydroxethyl)-1,3- propane diamine di-hydro chloride; N-cocyl N,N,N',N' pentamethyl-1,3
propane diammonium dichloride or dimethosulphate; N-stearyl N,N',N' tris (2-hydroxyethyl)
N,N1'dimethyl-1,3 propanediammonium dimethyl sulphate; N-palmityl N,N',N'tris (3-hydroxyprolyl)-1,3-propanediammonium
dihydrobromide; N-tallowyl N-(3 aminopropyl)-1,3-propanediamine trihydrochloride.
3. Diamido Quaternary Ammonium Salts
[0041] Diamido quaternary salts of general formula (III) are also known to be useful as
fabric softening agents.

[0042] Q
6 is a divalent alkylene group containing from 1 to 3 carbon atoms. Q
1, Q
2, Q
5 and X
- are as defined previously. Examples of suitable materials are methylbis (tallowamidoethyl)(2-hydroxyethyl)
ammonium methyl sulphate and methyl bis (hydrogenated tallowamido ethyl) (2-hydroxyethyl)
ammonium methyl sulphate. These materials are available from Goldschmidt under trade
names VARISOFT 222 and VARISOFT 110 respectively and under the trade name ACCOSOFT
from Stepan.
4. Ester Quaternary Ammonium Salts
[0043] A number of ester group containing quaternary ammonium salts, including those disclosed
in EP 345842 A2 (Procter & Gamble), EP 239910 (Procter & Gamble) and US 4137180 (Lever)
and incorporated herein by reference, are known to be particularly useful as softening
materials. These materials can be represented by generic formulae (IV) and (V) below.

[0044] In formula (IV) Q
7 is a hydrocarbyl group containing 1 to 4 carbon atoms, Q
8 is (CH
2)
n-Z-Q
10 where n is an integer from 1 to 4 or -Q
10. Q
9 is an alkyl or hydroxyalkyl group of 1 to 4 carbon atoms, or is as defined for Q
8. Q
10 is a hydrocarbyl group containing from 12 to 22 carbon atoms and Y can be -CH(OH)-CH
2- or Q
5, as previously defined. Z can be -O-C(O)-O, C(O)-O or -O-C(O)- and X
- is an anion.
[0045] In formula (V) the symbols Q
2, Q
10, Z and X
- have the meanings defined previously.
[0046] Examples of suitable materials based on formula IV are methyl bis-[ethyl(tallowyl)]-2-hydroxyethyl
ammonium methyl sulphate (or its olelyl equivalent), N,N-di(tallowyloxyethyl)-N,N-dimethyl
ammonium chloride; N,N-di(2-tallowyloxy-2-oxo-ethyl)-N,N-dimethyl ammonium chloride;
N,N-di(2-tallowyloxyethylcarbonyl oxyethyl)-N,N-dimethyl ammonium chloride; N-(2-tallowloxy-2-ethyl)-N-(2-tallowyl
oxo-2-oxyethyl)-N, N-dimethyl ammonium chloride; N,N,N-tri(tallowyl-oxyethyl)-N-methyl
ammonium chloride; N-(2-tallowyloxy-2-oxyethyl)-N-(tallowyl-N,N-dimethyl)-ammonium
chloride. Tallowyl may be replaced with cocoyl, palmoyl, lauryl, oleyl, stearyl and
palmityl groups. An illustrative example of a formula V material is 1,2-(hardened)
ditallowyloxy-3-trimethyl ammonium propane chloride.
[0047] Examples of commercially available materials can be obtained under the trade name
STEPANTEX VRH 90 (ex Stepan) AKYPOQUAT (ex Kao) and as mixtures of mono and ditallow
esters of 2,3-dihydroxy propane trimethyl ammonium chlorid (ex Clarient).
5. Quaternary Imidazolinium Salts
[0048] A further class of cationic softener materials is the imidazolinium salts of generic
formula (VI).

[0049] Wherein Q
11 is a hydrocarbyl group containing from 6 to 24 carbon atoms, G is -N(H)-, or -O-,
or NQ
2, n is an integer between 1 and 4, and Q
7 is as defined above.
[0050] Preferred imidazolinium salts include 1-methyl-1-(tallowylamido) ethyl-2tallowyl-4,5
dihydro imidazolinium methosulphate and 1-methyl-1-(palmitoylamido) ethyl-2-octadecyl-4,5-dihydroimidazolinium
chloride. Other useful imidazolinium materials are 2-heptadecyl-1-methyl-1-(2 stearylamido)
ethyl imidazolinium chloride and 2- lauryl-1-hydroxyethyl-1-olayl imidazolinium chloride.
Also suitable are the imidazolinium fabric softening components of US 4127489 incorporated
here by reference.
Representative commercially available materials are VARISOFT 475 (ex Goldschmidt)
and REWOQUAT W7500 (ex Rewo).
[0051] A particular aspect of the invention relates to compositions wherein the amount of
fabric softening material which is cationic is a majority of the fabric softening
material present.
6. Primary Secondary and Tertiary Amines
[0052] Primary, secondary and tertiary amines of general formula (VII) are useful as softening
agents.

wherein Q
11 is a hydrocarbyl group containing form 6 to 24 carbon atoms, Q
12 is hydrogen or a hydrocarbyl group containing from 1 to 22 carbon atoms and Q
13 can be hydrogen or Q
7. Preferably amines are protonated with hydrochloric acid, orthophosphoric acid or
citric acid or any other similar acids for use in fabric conditioning compositions
of this invention.
7. Alkoxylated Amines
[0053] Alkoxylated amines of general formula (VIII) are also useful as components of this
invention.

wherein Q
14 is (C
2H
4O)
xH, Q
15 is (C
2H
4O)
yH and Q
16 is (C
2H
4O)
zH and x+y is within the range 2 to 15 and x+y+z is within the range 3 to 15, m can
be 0, 1 or 2 and Q
1 is as previously defined.
[0054] Examples of these materials are monotallowdipolyethoxyamine containing from 2 to
30 ethylene oxide units, tallow N, N', N' tris (2-hydroxythyl)-1,3 propylene diamine
or C
10 to C
18 alkyl-N-bis(2-hydroxyethyl) amines.
Examples of commercially available materials are available under the trade names ETHOMEEN
and ETHODUOMEEN (ex Akzo).
8. Cyclic Amines
[0055] Other useful materials are dialkyl cyclic amines represented by formula (IX).

wherein the groups Q
17 are independently selected from hydrocarbyl groups containing from 3 to 30 carbon
atoms and A can be oxygen (-O-) or nitrogen (-N-), preferably nitrogen; B is selected
from Q
5 as defined earlier or the group -Q
13-T-C(O) - where Q
18 is either Q5 or (-C
2H
4O-)
m with m being an integer from 1 to 8 and T being selected from oxygen or NQ
13. The broken line shows a possible double bond between A and C. If absent, it is replaced
by bond(s) to additional hydrogen(s).
[0056] Illustrative materials are 12-stearyl oxyethyl-2-stearyl imidazoline, 1-stearyl oxyethyl-2-palmityl
imidazoline, 1-stearyl oxyethyl myristyl imidazoline, 1-palmityl oxyethyl-2-palmityl
imidazoline, 1-palmityl oxyethyl-2-myristyl imidazoline, 1-stearyl oxyethyl-2-tallow
imidazoline, 1-myristyl oxyethyl-2-tallow imidazoline, 1-palmityl oxyethyl-2-tallow
imidazoline, 1-coconut oxyethyl-2-coconut imidazoline, 1-tallow oxyethyl-2-tallow
imidazoline and mixtures thereof. Also useful is stearyl hydroxyethyl imidazoline,
available commercially as MONAZOLINE S (ex Unichema), 1-tallow amido ethyl-2-tallow
imidazoline and Methyl-1-tallow amidoethyl-2-tallow imidazoline.
[0057] Yet another class of suitable fabric softening materials are the condensation products
formed from the reaction of fatty acids with a polyamine selected from the group consisting
of hydroxyalkyl, alkylene diamines and dialkylenetriamines and mixtures thereof. Suitable
materials are disclosed in EP-A-199382 (Procter). Preferred among these are mixtures
of molecules of the generic formula X and corresponding salts obtained by partial
protonation.

[0058] W is selected from hydrogen and the group -C(O)-Q
1 and other symbols are as previously defined. Commercially available materials of
this class can be obtained from Clariant as Ceranine HC39, HCA and HCPA.
9. Zwitterionic Fabric Softeners
[0059] Other useful ingredients of softening systems include zwitterionic quaternary ammonium
compounds such as those disclosed in EP 332270 A2 (Unilever) incorporated herein by
reference. Representative materials in this class are illustrated by general formula
(XI) and (XII).

wherein the groups Q
19 are selected independently from Q
7, Q
11 and Q
14; Q
20 is a divalent alkylene group containing 1 to 3 carbon atoms and may be interrupted
by -O-, -CONH, -C(O)O-, etc; and Z- is an anionic water solubilising group (e.g. carboxy,
sulphate, sulpho or phosphonium).
[0060] Examples of commercially available materials are the EMPIGEN CD and BS series (ex
Albright & Wilson), the REWOTERIC AM series (ex Goldschmidt) and the Tegobetaine F,
H, L and N series (ex GOLDSCHMIDT).
[0061] In all of the aforementioned fabric softening compounds where an alkyl chain name
is given, the hardened equivalent may also be used, for example tallow or hardened
tallow.
10. Nonionic Ingredients
[0062] It is well known to blend nonionic material with cationic, amphoteric or zwitterionic
softening materials as a means of improving dispersion of the product in rinse waters
and enhancing the fabric softening properties of the softener blend.
[0063] Suitable nonionic adjuncts include lanolin and lanolin derivatives, fatty acids containing
from 10 to 18 carbon atoms, esters of fatty acids containing from 8 to 24 carbon atoms
with monohydric alcohols containing from 1 to 3 carbon atoms, and polyhydric alcohols
containing 2 to 14 carbon atoms eg 2 to 12 carbon atoms such as sucrose, sorbitan,
together with alkoxylated fatty acids, alcohols and lanolins containing an average
of not more than 7 alkylene oxide groups per molecule. Suitable materials have been
disclosed in EP-A-88520 (Unilever), EP-A-122141 (Unilever), GB 2157728A (Unilever),
GB 8410321 (Unilever), EP-A-159918 (Unilever), EP-A-159922 (Unilever) and EP-A-79746
(Procter).
[0064] The composition may additionally or alternatively comprise, as a fabric softening
agent, an oily sugar derivative which is a liquid or soft solid derivative of a cyclic
polyol or of a reduced saccharide, said derivative resulting from 35 to 100% of the
hydroxyl groups in said polyol or in said saccharide being esterified or etherified.
The derivative has two or more ester or ether groups independently attached to a C
8-C
22 alkyl or alkenyl chain. Preferably the oily sugar derivative contains 35% by weight
tri or higher esters, eg at least 40%. WO98/16538 (Unilever) discloses such derivatives
and is incorporated herein by reference.
[0065] Preferably 35 to 85% most preferably 45 to 70% of the hydroxyl groups in said cyclic
polyol or reduced saccharide are esterified or etherified to produce the derivative.
[0066] The tetra etc prefixes used refer to the average degrees of esterification or etherification;
the compounds exist as a mixture comprising the monoester to fully esterified ester.
[0067] The derivatives do not have substantial crystalline character at 20°C. The starting
material is esterified or etherified with said alkyl or alkenyl chains to an extent
so as to produce the derivatives as a liquid or soft solid.
[0068] Typically the derivative has 3 or more, preferably 4 or more, eg 3 to 5, ester or
ether groups or mixtures thereof.
[0069] The derivative may be obtained from a saccharide, e.g. monosaccharides including
xylose, arabinose, galactose, fructose, sorbose and especially glucose, or, disaccharides
including maltose, lactose, cellobiose and especially sucrose.
[0070] An example of a reduced saccharide is sorbitan. If based on a disaccharide it is
preferred if the disaccharide has 3 or more ester or ether groups attached to it e.g.
include sucrose tri, tetra and penta esters.
[0071] Examples of suitable derivatives include esters of alkyl(poly)glucosides, in particular
alkyl glucoside esters having a degree of polymerisation from 1 to 2.
[0072] The derivative may have branched or linear alkyl or alkenyl chains (of varying degrees
of branching), mixed chain lengths and/or unsaturation. Those having unsaturated and/or
mixed alkyl chain lengths are preferred.
For example, predominantly unsaturated fatty chains may be attached to the ester/ether
groups, e.g. those derived from rape oil, cotton seed oil, soybean oil, oleic, tallow,
palmitoleic, linoleic, erucic or other sources of unsaturated vegetable fatty acids.
[0073] Examples of suitable oily sugar derivatives include sucrose tetratallowate, sucrose
tetrarapeate, sucrose tetraoleate, sucrose tetraesters of soybean oil or cotton seed
oil, cellobiose tetraoleate, sucrose trioleate, sucrose triapeate, sucrose pentaoleate,
sucrose pentarapeate, sucrose hexaoleate, sucrose hexarapeate, sucrose triesters,
pentaesters and hexaesters of soybean oil or cotton seed oil, glucose trioleate, glucose
tetraoleate, xylose trioleate, sucrose tetralinoleate or sucrose tetra-,tri-, penta-
or hexa- esters with any mixture of predominantly unsaturated fatty acid chains.
[0074] Other oily sugar derivatives suitable include sucrose pentalaurate, sucrose pentaerucate,
sucrose tetraerucate. Suitable materials include some of the Ryoto series available
from Mitsubishi Kagaku Foods Corporation.
[0075] The liquid or soft solid derivatives are characterised as materials having a solid:liquid
ratio of between 50:50 and 0:100 at 20°C as determined by T
2 relaxation time NMR, preferably between 43:57 and 0:100, most preferably between
40:60 and 0:100, such as, 20:80 and 0:100. The T
2 NMR relaxation time is commonly used for characterising solid:liquid ratios in soft
solid products such as fats and margarines. For the purpose of the present invention,
any component of the NMR signal with a T
2 of less than 100 microsecond is considered to be a solid component and any component
with T
2 greater than 100 microseconds is considered to be a liquid component.
[0076] The oily sugar derivatives can be prepared by a variety of methods well known to
those skilled in the art. Typical preparations of these materials are disclosed in
US 4 386 213 and AU 14416/88 (Procter and Gamble).
[0077] Fabric softening compositions generally do not contain anionic detergent active nor
bleach, nor detergency builder. It is desirable that the amounts (of any) of anionic
detergent active, bleach and detergency builder are all less than the amount of the
fabric softening agent. The amount of each one of these may well be less than 5% by
weight of the whole composition.
[0078] A rinse conditioner composition according to this invention will usually contain
from 0.5% to 90% by weight of the fabric softening material, for example 0.5-40%.
More specifically, so called dilute compositions generally contain from 1% to about
8% by weight of fabric softening agent while compositions containing from about 8%
up to 20% by weight of the fabric softening material have been classed as "concentrated".
Higher concentrations, in the range of at least 8%, at least 12% or up to 40% by weight
are also possible, but even this is not the upper limit. Still higher concentrations
from 40% up to 80% or even 90% by weight are possible in a very concentrated product.
As mentioned above, either nonionic or cationic fabric softening agents may be used.
Perfume
[0079] The term "perfume" as used herein denotes materials which are used in perfumery and
mixtures of such materials.
Frequently the perfume will be a mixture of perfumery materials. Examples of suitable
perfumes are to be found in "Perfume and flavour Chemicals" by Steffen Erctander (Library
of Congress Catalogue Card no. 75-91398).
[0080] The perfume may function solely to impart fragrance. However, perfumes can perform
other functions, such as to reduce the onset of body malodour as disclosed in US-A-4134838
and EP-A-545556. Such deodorant perfumes are within the scope of this invention and
may or may not impart fragrance. Deodorant perfumes with low perceptible odour are
disclosed in EP-A-404470.
[0081] Preferably the cross-linked organic polymer particles have the perfume trapped therein.
Polymers
[0082] It is a feature of this invention that the particles are composed of cross-linked
organic polymeric material. Such particles may be made from a variety of organic monomers,
although in general these are olefinically unsaturated materials. Preparation may
be by an emulsion polymerisation process, as will be explained further below.
[0083] It is also a feature of this invention that the particles have a mean diameter which
is not more than lum. Particles of such small size can remain in colloidal suspension.
As is known, particles of colloidal dimensions are kept in suspension by Brownian
motion and by the effect of charges on the particles surfaces, which cause the particles
to repel each other and stay apart. Also, because the particles size is small in relation
to the wavelength of light, they are generally not visible although they give an appearance
of turbidity. Hence, a rinse conditioner composition containing them can appear translucent.
[0084] There are three preferred techniques for the production of a polymer with perfume
absorbed therein as herein described. These are as follows:
[0085] Method A, is to synthesise a polymer latex by emulsion polymerisation in the presence of the
perfume. The monomers used may include some polyfunctional monomer so as to produce
cross-linking in the polymer. This enhances the strength and rigidity of the polymer.
A low level of cross-linking provides the ability of particles to hold perfume. Thus,
there should desirably be cross linking between at least 0.5%, and 15% by number,
of the total number of monomer residues present in the polymer and more preferably
between 1% and 10%, eg. between 1 and 5%, of the monomer residues. The polymer particle
size range is preferably between 50 and 200 nanometres.
[0086] Techniques for the production of a latex of small particles by emulsion polymerisation
are well known. The polymerisation is normally carried out in the presence of a surfactant
which functions as an emulsifier. Raising the concentration of surfactant leads to
smaller particle sizes, but does not generally lead to particle sizes smaller than
50 nanometres unless a special method, e.g. a microemulsion process, is used. Particle
size is also affected by temperature and hence rate of reaction, stirring speed and
monomer/initiator ratio. Fast rates of polymerisation and higher stirring speeds lead
to small particles. High proportions of monomer and low proportions of initiator favour
the production of bigger particles.
[0087] After carrying out emulsion polymerisation it will generally be necessary to remove
unreacted monomer. This will often be done by steam distillation, leading to some
loss of perfume, although we have found that such losses of perfume are acceptably
small. Some monomers may be removed by chemical reaction to yield harmless or volatile
products.
[0088] Method B: which is particularly preferred, is to commence with a pre-formed cross-linked polymer
latex as a dispersion in liquid, e.g. water. The perfume is dissolved in a low boiling
organic solvent which is able to swell the polymer particles. The solution is brought
into contact with the polymer latex, causing the polymer particles to swell and absorb
the perfume. The solvent is then evaporated, leaving the perfume trapped in latex
particles. There is the same amount of cross-linking between of the monomer residues
as in method A.
[0089] For method B, residual monomer can be removed from the polymer before the polymer
comes into contact with the perfume.
[0090] For either of these procedures the polymer should be capable of forming a colloidal
emulsion in water. A latex of colloidal polymer particles will generally contain from
3% to 50% polymer, usually from 3% to 40%. Various polymerisation methods may be used
for making polymers. Natural or modified natural polymers might also be used, e.g.
a natural rubber latex.
[0091] Suitable monomers for radical addition polymerisation are those containing polymerisable
olefinic unsaturation. Monomers which may be used include styrene, vinyl acetate,
ethylene, propylene, vinyl pyrrolidone, vinyl chloride, acylonitrile, methyl methacrylate,
and other acrylates and methacrylates. The monomers may be used either singly or in
combination. Examples of polyfunctional monomers which may be used to effect cross-linking
include divinyl benzene, divinyl ether, ethyleneglycol dimethacrylate, pentaerythritol
triacrylate and polyallyl sucrose. Suitable radical initiators include sodium or potassium
persulphate, 2,2'-azobis-isobutyronitrile (AIBN) and 4,4'-azobis (4-cyanovaleric acid).
A water soluble initiator is preferable. Polymerisation temperature is preferentially
in the range 40-90°C.
[0092] For Method B, it is possible to use natural and modified natural polymers, e.g. cellulose,
modified cellulose, cellulose acetate, cellulose butyrate and hydroxy ethyl cellulose,
as well as synthetic latices made from the polymers referred to above.
[0093] When Method A is used, the perfume should preferably be soluble in the monomer and
compatible with the polymer. For Method B, the perfume should also be compatible with
the polymer itself. This prevents phase separations which may cause problems.
[0094] The absorptions of perfume by polymer may be by absorption into open pores through
capillary action, or by encapsulation or dissolution in the polymer so that release
of perfume is by diffusion through the polymer, or it may be adsorption onto the hydrophobic
polymer material. More than one of these modes of absorption may occur at the same
time.
[0095] A polymer with absorbed perfume may have the polymer and the perfume in a weight
ratio lying in the range from 25:1 to 2:1, especially 20:1 to 3:1.
[0096] The amount of polymer particles with absorbed perfume included in a rinse conditioning
composition is preferably such an amount that the perfume is present in an amount
from 0.1 to 10% by weight of the composition.
[0097] In many instances, the amount of polymer with absorbed perfume is likely to be such
that its perfume amounts to 0.1% to 3%, or even 0.1% to 2% by weight of the composition.
[0098] A composition according to this invention may incorporate additional perfume which
is not located or absorbed in or on the particles (i.e. it is outside the particles
and not absorbed thereon) in addition to the perfume which is absorbed onto or into
such particles.
[0099] References herein to the amount of absorbed perfume in the particles is to be construed
as the amount of perfume located in or on the particles, but not perfume separately
added to the composition.
[0100] If this is done, it can be arranged by choice of the amounts and nature of the perfumes
which respectively are and are not absorbed onto the particles that the fragrance
on the fabrics after rinsing and drying will come principally from the perfume which
was absorbed onto the porous particles whereas the apparent fragrance of the rinse
conditioner composition will be principally attributable to the perfume which is not
so absorbed. This can enable the producer to control a difference in fragrance between
the rinse conditioner composition and the fragrance of the fabrics after rinsing and
drying.
[0101] It may therefore be desirable that the perfume which is not absorbed onto particles,
which principally provides the fragrance of the rinse conditioner composition itself,
does not exhibit high substantivity towards the fabrics. It may also be desirable
that the weight ratio of perfume which is and respectively is not absorbed or included
in or on particles lies in a range from 10:1 to 1:4, especially from 10:1 or 4:1 to
1:1.
[0102] It may be arranged that the polymer melts when heated to ironing temperatures so
that perfume which is absorbed onto the polymer particles is released and provides
a perceptible fragrance during ironing. If this is desired it will be appropriate
for the organic polymer of the porous polymer particles to soften and flow at a temperature
in the range from 100°C to 220°C (that is, to have a melting temperature lying in
the range 100°C-220°C).
[0103] Choice of polymer characteristics can affect the ease with which perfume is released.
Using monomers which give a more crystalline polymer, and incorporating cross-linking
will both inhibit the release of the perfume, so that the perfume may be released
more slowly over a longer period or may be released when ironing melts the polymer.
[0104] There is cross-linking between at least 0.5% by number of the total number of monomer
residues present. There may be cross-linking between up to 10% by number of the monomer
residues, or possibly even more eg. up to 15% by number. Preferred is a range of 0.5%
or 1% up to 5% or 8% by number of the monomer residues in the polymer.
Other ingredients
[0105] Rinse conditioner compositions may contain a number of materials in addition to the
fabric softening material, the porous particles and perfume. Materials which may be
present include optical brightening agents, colourants, opacifiers, hydrotropes, viscosity
control agents such as electrolyte, stabilisers such as guar gum and polyethyleneglycol,
anti-static agents and ironing aids. Silicones may be used for the latter purpose.
[0106] These various optional ingredients, if present in a rinse conditioner, will generally
not be present in amounts exceeding 5% by weight of the composition and they may well
total not more than 10% by weight of the composition.
[0107] Rinse conditioner compositions in accordance with the invention preferably have a
pH of less than 6.0, more preferably a pH ranging from 2.0 to 5.0. Rinse conditioning
compositions may contain pH-buffering agents such as weak acids and salts thereof,
e.g. phosphoric, benzoic or citric acids and salts of these acids. The amount of buffering
material included in a composition may lie in the range from 0.5-10% by weight, preferably
not more than 5% by weight.
[0108] Rinse conditioner compositions of this invention are generally in the form of aqueous
liquids which will generally contain at least 10%, usually at least 20% by weight
water and often from 50% or 60% to 97% by weight of water. Other product forms may
be envisaged, however, including powders, creams, pastes, blocks or tablets. Suitable
types of blocks and tablets are disclosed in European Patent Specification No. EP-A-255
779 (UNILEVER). The ability of colloidal particles to remain in suspension is of course
most relevant to products in liquid form.
[0109] In use compositions according to this invention are preferably added to a much larger
volume of water to form a liquor which is than used to contact the fabrics to be treated.
Notably, such liquor can be formed by adding a composition by hand or by way of an
automatic dispensing device to water in a washing machine.
[0110] One ingredient which is normally not included in rinse conditioning compositions
is detergency builder. Generally speaking, rinse conditioning compositions in accordance
with this invention will not contain ion exchange aluminosilicate builder, nor any
other water-insoluble inorganic material nor sodium tripolyphosphate nor any other
water-soluble electrolyte in quantities greater than the quantity of the rinse conditioner
material. It is likely that the compositions will be entirely free of tripolyphosphate
and of any water-insoluble inorganic materials.
[0111] The invention will now be further explained and illustrated by the following examples
in which all amounts and percentages are by weight unless otherwise indicated.
Example 1
[0112] A cross-linked polystrene latex with perfume absorbed therein was prepared by method
A referred to above.
[0113] Polymerisation was carried out in a reaction vessel which was a round bottomed flask
fitted with stirrer, nitrogen inlet tube and reflux condenser. The materials employed
were:
styrene 8.8 gram
divinylbenzene (55% concentration) 0.17 gram
perfume 1 gram
cetyl trimethylammonium bromide (CTAB) 0.4 gram
polymerisation initiator 0.25 gram
water 100 ml.
[0114] The CTAB was dissolved in most of the water (90ml) and the solution degassed. The
perfume was dissolved in the styrene divinylbenzene mixture and the resulting solution
was added to the surfactant solution in the flask. After 10 minutes the initiator
in the remaining water was added and the polymerisation reaction allowed to proceed
for 6-8 hours while the contents of the flask were heated to 70°C. Emulsion polymerisation
took place during this time giving a latex consisting of a colloidal suspension of
polymer particles in the water. The mean particle size was approximately 0.1µm. Unreacted
monomer was removed by steam distillation. This led to some loss of perfume, but about
90% of the perfume remained in the polymer latex.
[0115] A higher quantity of perfume could be incorporated into the latex particles by increasing
the quantity of perfume, up to about 2.5 gram.
Example 2
[0116] In this example perfume was incorporated into performed latex in accordance with
method B above.
[0117] A latex of cross-linked polystyrene particles of mean size approximately 0.1µm was
prepared using the following materials:
styrene 21.85 gram
divinylbenzene (55%) 4.85 gram
CTAB 0.13 gram
polymerisation initiator 0.33 gram
water 100 gram
[0118] The procedure was as given in Example 1 above and after the removal of excess monomer
by steam distillation the solids content of the colloidal suspension was determined
and found to be 7.8%.
[0119] A second stage used:
perfume 1 gram
CTAB 0.3 gram
dichloromethane 27 gram.
[0120] The perfume was dissolved in the dichloromethane solvent. This was then mixed with
the CTAB and 50 grams of the latex prepared as above. The heavy organic layer was
dispersed throughout the mixture by shaking and then by application of ulta-sound.
This produced an opaque emulsion from which the solvent was removed using a rotary
evaporator.
Example 3
[0121] A typical conditioner composition contains:
| |
wt% |
| Dimethyl di-hardened tallow ammonium chloride |
5% |
| Cross-linked Polymer latex particles according to any of the preceding examples |
sufficient to provide up to 0.4% perfume |
| Demineralised water |
balance to 100% |
[0122] A chemical preservative could well be included, e.g. 0.02% by weight of 2-brom-2-nitropropane-1,
3-diol available under the Registered Trade Mark "Bronopol".
[0123] An additional amount of the same perfume, or different, perfume as used in the latex
particles can be included in conventional amounts.
[0124] To provide further examples the dimethyl di-hardened tallow ammonium chloride can
be partially, or totally, replaced by 1,2-(hardened) ditallowyloxy-3-trimethyl ammonium
propane chloride or a nonionic oily sugar derivative as described in the text above
under nonionic compounds.
Example 4
[0125] Several cross linked polymers latices with perfume incorporated in the latex particles
were prepared using the methods A and B disclosed above and exemplified by Examples
1 and 2. Details of these various latices are given in the following Table 1 where
percent solids denotes the percentage by weight of polymer in the aqueous latex; percent
perfume denotes the quantity of perfume by weight as a percentage of the total weight
of polymer and perfume.
[0126] Each latex was used to deliver perfume to fabric in accordance with the following
procedure which used three fabrics namely 70-30 polyester/cotton, a bulked acrylic
fabric and cotton terry towelling.
[0127] Six examples of each of the three fabrics were washed at 50°C using an unperfumed
detergent composition containing anionic detergent, phosphate builder and other conventional
detergent ingredients.
[0128] The wash load was rinsed twice with water only and spun dry. At this point the wash
load was divided into two halves each containing three pieces of each fabric. One
half of the wash load serving as a control was rinsed using a rinse conditioning composition
containing the same perfume as that used to make the latices. The other half of the
wash load was rinsed using unperfumed rinse conditioning composition mixed with an
amount of latex calculated to contain the same quantity of perfume. Each of the halves
of the wash load was spun dry, line dried, stored overnight and then assessed as follows.
[0129] The perfume intensity assessment was carried out by a panel of assessors trained
to recognise the perfume and score the perfume intensity on a 0-5 scale as extending
from 0 = no perfume perceptible through 5 - extremely strong perfume perceived. The
panellist's results were averaged and are set out in Table 1 below where "Δ intensity"
denotes the amount by which the panellists' mean score exceeded their mean score for
the control composition. The results are given in Table 1 below.
[0130] The two non-cross linked styrene monomer only examples are comparative.
Table 1
| Monomers |
Method |
%Solids |
%Perfume |
ΔIntensity |
Fabric |
| STY |
B |
9.6 |
20 |
0.9 |
Terry |
| 0.9 |
Polycotton |
| 0.6 |
Acrylic |
| |
| STY/5% DVB |
B |
6.5 |
10 |
0.7 |
Terry |
| 0.8 |
Acrylic |
| |
| STY/10% DVB |
B |
5.3 |
10 |
1.7 |
Terry |
| 0.9 |
Polycotton |
| 1.2 |
Acrylic |
| |
| STY |
A |
12.3 |
10 |
0.4 |
Terry |
| 0.5 |
Acrylic |
[0131] From the above results it is demonstrated that the greater the level of DVB, the
greater the level of cross-linking and the greater is the perfume substantivity/intensity.
Example 5
[0132] Several cross-linked polymer latices with perfume incorporated therein were prepared
by the Method B above, exemplified in Example 2. Details are given in the following
Table 3.
Table 2
| Latex No. |
Monomers % |
Solids % |
Perfume |
Avge Particle size (µm) |
| I |
Styrene/DVB |
22 |
20 |
0.10 |
| II |
Styrene/DVB |
10 |
20 |
0.11 |
| III |
Styrene/DVB |
23.3 |
10 |
0.10 |
[0133] These latices were used to deliver perfume to fabric, either terry towelling or polyester
cotton mixtures, using a similar procedure to that in the previous Example, or a variant
procedure in which the fabric pieces were tumble dried at 70-75°C. The rinse conditioner
contained 5% by weight cationic fabric softener (which was dimethyldistearyl ammonium
chloride). In some experiments the rinse conditioner contained sufficient latex to
provide 0.25% by weight perfume. In other experiments the quantity of latex was halved,
but compared with a control containing 0.25% by weight perfume. In other experiments
the quantity of latex was halved, but compared with a control containing 0.25% by
weight of perfume.
[0134] Assessment of the dried fabric pieces was carried out as in Example 4 above, except
that the results are exprassed as mean perfume scores, and not as Δ relative to a
control as in the previous tables.
[0135] Details of these experiments and the results obtained are given in the following
Table 3.
Table 3
| Mean Perfume Intensity Scores (0-5 Scale) On Dry Fabric |
| Latex No: |
Perfume Level in Composition |
Fabric Type |
Drying Regime |
Mean Scores |
| a) |
|
|
|
|
| III |
0.25% |
Terry |
Line |
2.2 |
| II |
0.25% |
Terry |
Line |
1.9 |
| I |
0.25% |
Terry |
Line |
2.0 |
| None (perfumed control) |
0.25% |
Terry |
Line |
1.1 |
| |
| b) |
|
|
|
|
| II |
0.25% |
Polycotton |
Line |
1.8 |
| I |
0.25% |
Polycotton |
Line |
1.6 |
| None (perfumed control) |
0.25% |
Polycotton |
Line |
1.1 |
| |
| c) |
|
|
|
|
| III |
0.125% |
Terry |
Line |
1.2 |
| I |
0.125% |
Terry |
Line |
1.2 |
| None (perfumed control) |
0.25% |
Terry |
Line |
1.2 |
| III |
0.125% |
Terry |
Tumbled |
1.8 |
| I |
0.125% |
Terry |
Tumbled |
1.2 |
| None (perfumed control) |
0.25% |
Terry |
Tumbled |
1.2 |
[0136] The results in the above table show that when the perfume levels are equal (at 0.25%)
the perfume intensity retained on the fabric after line drying is greater when the
perfume is carried by polymer particles.
[0137] The experiments in which the latex provided 0.125% perfume achieved a retention of
perfume which was approximately equal to a control using double the quantity of perfume
without latex.
Example 6
[0138] A fabric softening composition was prepared containing 20% by weight of 1, 2-ditallowyloxy-3-trimethyl
ammonium propane chloride.
[0139] The suspension was a mobile white emulsion.
[0140] 0.5% by weight of perfume was added to this composition. It thickened to such an
extent as to become an immobile solid.
[0141] The same emulsion was mixed with a latex which was the cross-linked latex I of Example
5. The amount was sufficient to provide 1% by weight perfume in the composition. The
emulsion remained very mobile.
[0142] The same emulsion was mixed with (1) the same latex in an amount sufficient to provide
0.5% by weight of perfume plus (ii) 0.5% by weight of perfume which was not included
in a latex. Again the emulsion thickened dramatically to an immobile solid.
Example 7
[0143] A linear polymeric latex was prepared in the presence of perfume as a comparative
example (7A). The materials employed were:
| n-butyl acrylate |
140g |
| N,N'-dimethylaminoethyl acrylate |
4.3g |
| polyoxyethylene (30) nonylphenyl ether |
38.0g |
| perfume |
36.1g |
| polymerisation initiator |
1.2g |
| deionised water |
500 ml |
[0144] Polymerisation was carried out in a similar apparatus to that of Example 1. The nonionic
surfactant and the polymerisation initiator were dissolved in the water which was
then degassed, after which it was stirred and heated to 62°C. The two acrylate monomers
were mixed with the perfume and the resulting solution was added drop-wise to the
water over a period of two hours. The polymerisation reaction was allowed to continue
for a further 7 hours while the contents of the flask were stirred at the same temperature
of 62°C. After this the mixture was stem distilled to remove most of the residual
monomer. The resulting latex was than concentrated on a rotary evaporator reducing
its volume by about 50% and in doing so removing remaining monomer to provide an odourless
latex which was filtered through glass wool. 503g of a latex of 37 wt% solids content
and 0.11µm average particle size was obtained.
[0145] A cross-linked polymeric latex was prepared using the following materials (example
7B):
| n-butyl acrylate |
140 g |
| N,N'-dimethylaminoethyl acrylate |
4.3 g |
| ethylene glycol di(methylacrylate) (EGDMA) |
6.0 g |
| cetyl trimethyl ammonium bromide (CTAB) |
30 g |
| Polymerisation initiator |
1.2 g |
| deionised water |
500 ml |
[0146] Polymerisation was carried out in a similar manner to that above. The CTAB was dissolved
in the water, along with the initiator. The three acrylate monomers were mixed together
before addition. The EGDMA then functioned as a cross-linking agent. The latex obtained
had a particle size of approximately 0.1µm.
[0147] 36.1 grams perfume was incorporated into the resulting latex in accordance with the
procedure described in Example 2 above.
[0148] The linear and cross-linked latices prepared above (Examples 7A and 7B respectively)
were used to incorporate perfume into a rinse conditioner composition containing 5%
by weight of dimethyl distearyl ammonium chloride as in Example 6. The amount of each
latex was calculated so as to introduce 0.25% perfume in the rinse conditioner composition
assuming that all perfume used in the preparation of the latex has been retained in
the latex. The resulting rinse conditioner compositions were compared with a composition
containing the same fabric softener and 0.25% by weight perfume without latex.
[0149] Terry cotton test pieces were agitated in 1 litre of water containing 2 grams of
the rinse conditioner under test. After agitation for 5 minutes the cloths were hand
wring, rinsed in a further litre of plain water for two minutes, then wrung again
and line dried overnight. As in Example 4 a panel of assessors scored the perfume
intensity on the dried cloths on a scale extending from
- 0 =
- no perfume perceptible through to
- 5 =
- extremely strong perfume perceived
[0150] The results of this comparison and a subsequent repetition of it are set out in the
following Table 4.
TABLE 4
| COMPARISON OF LINEAR AND CROSSLINKED POLYMER LATICES AS PERFUME CARRIERS |
| SAMPLE |
EXPT 1 |
EXPT 2 |
| Free perfume (control) |
0.5 |
0.7 |
| perfume I cross-linked latex (Example 7B) |
1.4 |
1.2 |
| perfume in linear latex (Example 7A) |
1.0 |
0.9 |
[0151] As can be seen from the results above, the perfume incorporated in the cross-linked
latex was more perceptible than either of the free perfume control or the perfume
incorporated in the linear latex. These results are statistically significant at a
95% confidence level.
[0152] Using the same test procedure, a comparison was made between latex III of Example
5, the above cross-linked latex based on butyl acrylate (Example 7B) and perfume without
latex. As before, the amount of each latex added to the rinse conditioner composition
was calculated so as to introduce 0.25% perfume. Some of the test cloths were ironed
before assessment. The results are set out in the following Table 5.
TABLE 5
| SAMPLE |
EXPT 1 |
EXPT 1 IRONED |
EXPT 2 |
EXPT 2 IRONED |
| free perfume (control |
1.0 |
0.8 |
0.7 |
0.6 |
| cross-linked styrene latex (Example 5 III) |
2.2 |
3.1 |
1.6 |
2.8 |
| cross-linked butyl acrylate latex (Example 7B) |
1.5 |
1.3 |
1.3 |
1.6 |
[0153] As can be seen from this Table, both cross-linked latices provided an increase in
the perceptibility of the perfume delivered to the fabric. This was particularly apparent
with the cross-linked styrene latex after the test cloths had been ironed.
1. Zusammensetzung zur Verwendung beim Spülen von Wäsche, enthaltend Teilchen mit Parfum,
das in oder auf den Teilchen angeordnet oder absorbiert ist, dadurch gekennzeichnet, dass die Teilchen aus vernetztem organischem polymerem Material gebildet sind und eine
mittlere Teilchengröße nicht größer als 1 Mikrometer aufweisen, wobei es Vernetzung
zwischen mindestens 0,5%, zahlenmäßig, von der Gesamtzahl an in dem Polymer vorliegenden
Monomerresten gibt.
2. Zusammensetzung nach Anspruch 1, worin das Polymermaterial und das Parfum in einem
Gewichtsverhältnis, das im Bereich von 25:1 bis 2:1 liegt, vorliegen.
3. Zusammensetzung nach Anspruch 1 oder Anspruch 2, die eine Spülkonditioniererzusammensetzung
darstellt, die ein zum Weichmachen von Textilien wirksames Material enthält.
4. Zusammensetzung nach Anspruch 3, die 0,5 bis 90 Gewichtsprozent des Textil weichmachenden
Materials enthält und die Teilchen in einer derartigen Menge enthält, dass das Parfum
darin oder darauf 0,1 bis 10 Gewichtsprozent der Zusammensetzung beträgt.
5. Zusammensetzung nach einem beliebigen vorangehenden Anspruch, die in Form einer wässrigen
Flüssigkeit vorliegt.
6. Zusammensetzung nach Anspruch 4, die 0,5 bis 40 Gewichtsprozent des Textil weichmachenden
Materials enthält und die Teilchen in einer derartigen Menge enthält, dass das Parfum
darin oder darauf 0,1 bis 3 Gewichtsprozent der Zusammensetzung beträgt.
7. Zusammensetzung nach Anspruch 6, die eine flüssige Zusammensetzung darstellt, die
mindestens 50 Gewichtsprozent Wasser enthält.
8. Zusammensetzung nach einem beliebigen der Ansprüche 3 bis 7, die mindestens 12 Gewichtsprozent
des Textil weichmachenden Materials enthält.
9. Zusammensetzung nach einem beliebigen der Ansprüche 3 bis 8, worin das Textil weichmachende
Material kationisch ist und eine organische Verbindung darstellt, die Stickstoff und
mindestens eine Kohlenwasserstoffkette mit 6 bis 50 Kohlenstoffatomen enthält.
10. Zusammensetzung nach einem beliebigen der Ansprüche 3 bis 9, die 0,5 bis 90 Gewichtsprozent
Textil weichmachendes Material enthält, das kationisch ist.
11. Zusammensetzung nach einem beliebigen der Ansprüche 3 bis 10, worin die Menge an Textil
weichmachendem Material, die kationisch ist, eine Mehrheit des vorliegenden Textil
weichmachenden Materials darstellt.
12. Zusammensetzung nach einem beliebigen der vorangehenden Ansprüche, worin die Teilchen
das darin eingefangene Parfum aufweisen.
13. Zusammensetzung nach einem beliebigen der vorangehenden Ansprüche, die zusätzliches
Parfum enthält, das außerhalb der Teilchen vorliegt, wobei die Mengen an Parfum, die
in oder auf den Teilchen eingeschlossen sind und nicht eingeschlossen sind, in einem
Gewichtsverhältnis von 10:1 bis 1:4 vorliegen.
14. Zusammensetzung nach einem beliebigen der vorangehenden Ansprüche, worin die Teilchen
aus organischem Polymer mit einer Schmelztemperatur, die im Bereich von 100°C bis
220°C liegt, zusammengesetzt sind.
15. Verfahren zum Behandeln von Wäsche, umfassend In-Kontakt-Bringen der Wäsche mit einer
wie in einem beliebigen der Ansprüche 1 bis 14 definierten Zusammensetzung.
16. Verfahren zur Herstellung eines Spülkonditionierers, umfassend Vermischen
(i) eines Textil weichmachenden Materials und
(ii) Teilchen von vernetztem organischem Polymermaterial, worin es Vernetzen zwischen
mindestens 0,5%, zahlenmäßig, von der Gesamtzahl an in dem Polymer vorliegenden Monomerresten
gibt, wobei die Teilchen eine mittlere Teilchengröße von nicht größer als 1 Mikrometer
und mit darin oder darauf angeordnetem oder absorbiertem Parfum aufweisen.