Patent Description:
There are many categories of products in the personal wash market e.g. body wash, face wash, hand wash, soap bars, shampoos etc. Products which are marketed as body wash, face wash and shampoos are generally in liquid form and are made of synthetic anionic surfactants. They are sold in plastic bottles/ containers. Soap bars and hand wash products generally contain soaps. Soap bars do not need to be sold in plastic containers and are able to retain their own shape by virtue of being structured in the form of a rigid solid. Soaps bars are usually sold in cartons made of cardboard or in a plastic pack.

A known desire in cleansing bars is a rich and creamy lather formation. It is furthermore desired that the soap bar has sufficient hardness to be able to be manufactured on industrial scale. The risk of cracking of the bar upon storage/during usage should be as low as possible. Several soap bars are presently marketed which provide this attribute.

One of the predominant components in a soap bar is soap. Classic soap production involved the saponification of fat or oil into free fatty acid residues (monocarboxylic acids) and glycerol. The presence of alkali results in the formation of salt of the fatty acids, which is known as soap. Also, free fatty acids can be transformed into soap by treatment with alkali. Especially lauric acid soap is desired in soap bars, as it provides a rich lather.

However, the presence of lauric acid soap in the total soap mass comes with drawbacks. For example, the ingredient mixture becomes relatively soft when fatty C<NUM>-C<NUM> soap, such as C<NUM> fatty acid soap, is present. In addition, a soap bar with a high amount of lauric acid soap is relatively expensive. A soft ingredient mixture may give complications in manufacturing.

Soap bars are generally prepared through one of two routes. One is called the cast bar route while the other is called the milled and plodded route, also known as the `extruded route'. The cast bar route has inherently been very amenable in preparing low TFM (total fatty matter) bars. Total fatty matter is a common way of defining the quality of soap. It is defined as the total amount of fatty matter, mostly fatty acids, that can be separated from a sample of soap after splitting with a mineral acid, usually hydrochloric acid. In the cast bar soaps, the soap mixture is mixed with polyhydric alcohols and the hot/melted mixture is poured in casts and allowed to cool and then the soap bars are removed from the casts. The cast bar route is also the route typically used to prepare translucent bars. The cast bar route enables production at relatively lower throughput rates.

Conventionally, milled and plodded soaps are made by a process comprising saponification of fat and oils, forming the dried soap into noodles, mixing the various desired additives such as colorants, perfume, etc., into the soap noodles, passing the mixture formed through a mill or series of mills ("milling" the soap) thereby forming ribbons of soap, passing the milled soap mixture through a plodder to form billets of soap (i.e., "plodding" the soap, and cutting the billets into segments and stamping the segments into the desired shape.

A soap noodle with a high level of lauric fatty acid in the composition of the soap noodles does not allow an effective soap extrusion The mass of soap bar becomes very soft and does not allow extrusion in current process parameters/equipment. As a comparison, a conventional soap noodle comprises for example <NUM> wt% soap derived from palm oil (rich in C16 - C18) and <NUM> wt% soap derived from palm kernel oil (rich in C12), based on total soap noodle weight, and a C<NUM> soap level of about <NUM> -<NUM> wt%.

Therefore, there is a desire for a bar composition wherein the amount of lauric acid soap, is relatively low, but which still provides rich and creamy lather production upon use, preferably to the extend comparable to bar compositions comprising relatively high levels of lauric acid soap.

It is further desired, that such bar compositions can be prepared using conventional efficient industrial production machinery with high through-put that involves extrusion of a soap base ingredients mixture. Preferably the bars have a low risk on cracking upon storage/during usage.

<CIT> relates to an extruded personal washing bar with plate-like polymer inclusions.

<CIT> relates to a translucent soap bar composition that includes a soap mixture, a polyalkylene glycol, at least one of glycerin and sorbitol, water, and optionally, free fatty acid.

<CIT> relates to soap bar providing enhanced lather and water hardness including <NUM>-<NUM> wt% soap from <NUM>-<NUM> wt% palm oil and <NUM>-<NUM> wt% of palm kern oil, <NUM>-<NUM> wt% polyol consisting of glycerine and/or sorbitol and <NUM>-<NUM> wt% water.

Surprisingly, it was found that with the use of free fatty acids and glycerin in specific amounts, a soap bar composition could be prepared with abundant lather and hardness, and with a good production efficiency.

Accordingly, in a first aspect, the invention relates to a process to produce a soap bar composition, the process comprising the steps of:.

In a second aspect, the present invention relates to a soap bar comprising:.

In a third aspect, the invention relates to the use in a soap bar of.

to increase lather from the soap bar upon use thereof, the soap bar comprising.

These and other aspects, features and advantages will become apparent to those of ordinary skill in the art from a reading of the following detailed description and the appended claims. For the avoidance of doubt, any feature of one aspect of the present invention may be utilized in any other aspect of the invention. The word "comprising" is intended to mean "including" but not necessarily "consisting of" or "composed of. " In other words, the listed steps or options need not be exhaustive. It is noted that the examples given in the description below are intended to clarify the invention and are not intended to limit the invention to those examples per se. Similarly, all percentages are weight/weight percentages unless otherwise indicated. Except in the operating and comparative examples, or where otherwise explicitly indicated, all numbers in this description and claims indicating amounts of material or conditions of reaction, physical
properties of materials and/or use are to be understood as modified by the word "about". Numerical ranges expressed in the format "from x to y" are understood to include x and y. When for a specific feature multiple preferred ranges are described in the format "from x to y", it is understood that all ranges combining the different endpoints are also contemplated.

The invention relates to a soap bar composition comprising:.

It was a surprising finding of the present invention that the combination of <NUM> to <NUM> wt% of free fatty acids wherein <NUM> to <NUM> wt% thereof is lauric acid, and <NUM> to <NUM> wt% of glycerol, in a soap bar composition comprising <NUM> to <NUM> wt% C<NUM> to C<NUM> fatty acid soap (based on total soap weight in the bar) results in a bar with a desired hardness of the soap bar composition, and allowing stamping of the soap bar composition, thereby providing high-throughput production.

The term soap means salt of fatty acids. By a soap bar composition is meant a cleansing composition comprising soap which is in the form of a shaped solid. The soap content of the composition of the invention is from <NUM> to <NUM> wt%, preferably <NUM> to <NUM> wt% based on weight of the composition.

Preferably, the soap is soap of C<NUM> to C<NUM> fatty acids, more preferably of C<NUM> to C<NUM> fatty acids. According to the invention, the amount of C<NUM> to C<NUM> fatty acid soap (often referred to as "lauric portion") is of from <NUM> to <NUM> wt%, based on weight of total soap in the composition. The soap preferably contains C<NUM> fatty acid soap in an amount of from <NUM> to <NUM> wt%, preferably <NUM> to <NUM> wt%, based on the weight of the total fatty acid soap content. Preferably, the amount of non-lauric soap (soap not being C<NUM> to C<NUM> soap) is from <NUM> to <NUM> wt%, based on the total weight of the soap in the composition. Accordingly, it is preferred that the amount of C<NUM> to C<NUM> fatty acid soap (often referred to as "non-lauric portion") is from <NUM> to <NUM> wt%, based on the total weight of the soap in the composition.

The cation of the soap may be an alkali metal, alkaline earth metal or ammonium ion, preferably alkali metal cation. Preferably, the cation is selected from sodium or potassium, more preferably sodium. The soap may have saturated and/or unsaturated fatty acids. Soaps with higher content of saturated fatty acid soaps, preferably more than <NUM>% are preferred over soaps with higher content of unsaturated fatty acid soaps for stability. The oil or fatty acids may be of vegetable or animal origin.

The soap may be obtained by saponification of oils, fats or fatty acids. The fats or oils generally used to make the shaped solid cleansing compositions may be selected from tallow, tallow stearins, palm oil, palm stearins, soya bean oil, fish oil, castor oil, rice bran oil, sunflower oil, coconut oil, babassu oil, and palm kernel oil. The fatty acids may be from coconut, rice bran, groundnut, tallow, palm, palm kernel, cotton seed or soyabean. Preferably the fatty acid soap comprises soaps derived from palm oil and palm kernel oil. To obtain translucency typically is a problem in soaps derived from palm oil and palm kernel oil. It is preferred, that the fatty soap derived from palm kernel oil is <NUM> to <NUM> wt%, preferably <NUM>-<NUM> wt%, based on the weight of the total fatty acid soap. Preferably <NUM> to <NUM> wt%, more preferably <NUM> to <NUM> wt%, based on the weight of the total fatty acid soap content is soap derived from palm oil. The soaps may also be synthetically prepared (e.g. by the oxidation of petroleum or by the hydrogenation of carbon monoxide by the Fischer-Tropsch process). Resin acids, such as those present in tall oil, may also be used. Naphthenic acids may also be used.

The soap bar may additionally comprise synthetic surfactants selected from one or
more from the class of anionic, non-ionic, cationic or zwitterionic surfactants, preferably from anionic surfactants. These synthetic surfactants, as per the present invention, are included in less than <NUM>%, preferably less than <NUM>%, more preferably less than <NUM>% and optimally absent from the composition.

The soap bar composition generally comprises electrolyte and water. Electrolytes as per this invention include compounds that substantially dissociate into ions in water.

Electrolytes as per this invention are not an ionic surfactant. Suitable electrolytes for inclusion in the soap making process are alkali metal salts. Preferred alkali metal salts include sodium sulfate, sodium chloride, sodium acetate, sodium citrate, potassium chloride, potassium sulfate, sodium carbonate and other mono or di or tri salts of alkaline earth metals, more preferred electrolytes are sodium chloride, sodium sulfate, sodium citrate, potassium chloride and especially preferred electrolyte is sodium chloride sodium sulphate, sodium citrate or a combination thereof. For the avoidance of doubt, it is clarified that the electrolyte is a non-soap material. Electrolyte is preferably included in <NUM> to <NUM>%, preferably <NUM> to <NUM>% by weight of the composition.

Water is used as the slurrying medium for the soap and is preferably included in <NUM> to <NUM>% by weight of the bar composition.

It was surprisingly found, that the combination of free fatty acids and glycerol resulted in a significant increase in lather. An increase of FFA alone, with a glycerol level below the minimum amount as claimed, did not provide the effect on lather.

It had been found, that the weight ratio of glycerol to total free fatty acids in the bar is preferably below <NUM>, preferably higher than <NUM> and lower than <NUM>, preferably from <NUM> and <NUM>, more preferably of from <NUM> to <NUM>. These ratios are preferably used in the mixture of step a) of the process.

The glycerol in the composition ranges from <NUM> wt% to <NUM> wt%, based on the weight of the bar composition. These amounts are preferably used in the mixture of step a) of the process.

Glycerol is the only polyol present in the bar.

Free fatty acids (FFA) are present in an amount of from <NUM> to <NUM> wt%, preferably in an amount of from <NUM> to <NUM> wt%, even more preferably of from <NUM> to <NUM> wt% based on the weight of the bar composition. The bar composition comprises C<NUM> free fatty acid in an amount of from <NUM> to <NUM> wt%, more preferably <NUM> to <NUM> wt%, based on the weight of the free fatty acid. Most preferably, <NUM>% of the free fatty acid in the composition is C<NUM>.

Most preferably, the composition comprises C<NUM> free fatty acid in an amount of from <NUM> to <NUM> wt%, more preferably <NUM> to <NUM> wt% and most preferably <NUM> to <NUM> wt%, based on the weight of the composition. These are the preferred amounts that are added in step a) of the process.

Addition of FFA in combination with glycerol counterintuitively had an increasing effect on the hardness of the soap bars, as addition of FFA on its own does not have this effect or may even reduce the hardness of bars.

The composition includes <NUM> to <NUM> wt% water; more preferably <NUM> to <NUM>, even more preferably <NUM> to <NUM> wt% and most preferably <NUM> to <NUM> wt% water based on the weight of the bar composition. Water is added in step a) of the process in these amounts.

The total level of the adjuvant materials used in the bar composition preferably is in an amount not higher than <NUM>%, preferably <NUM> to <NUM>%, more preferably <NUM> to <NUM>% by weight of the soap bar composition.

It may be preferred, that if an adjuvant material is present, that starchy materials may be present in the bar composition. However, it is more preferred in the present invention, that the bar is free from starch.

It may be preferred, that the bar of the present invention is opaque. Especially in that situation, the bar composition may preferably comprise an opacifier. When opacifiers are present, the shaped solid cleansing composition is generally opaque, i.e. "opacification". Examples of preferred opacifiers include titanium dioxide, zinc oxide, ethylene glycol mono- or di-stearate or zinc stearate. A particularly preferred opacifier that can be employed when an opaque rather than a transparent soap composition is desired is ethylene glycol mono- or di-stearate, for example in the form of a <NUM>% solution in sodium lauryl ether sulphate. An alternative opacifying agent is zinc stearate.

It may however be more preferred, that the bar is a translucent bar. Even more preferred the translucent soap bar composition is a water-clear translucent solid cleansing composition. In case of a translucent soap bar composition, it will preferably not contain an opacifier It may be preferred that the bar composition is free from titanium dioxide, zinc oxide, ethylene glycol mono- or di-stearate or zinc stearate. Preferably, the bar is free from TiO<NUM>, polyox high molecular weight or mixture thereof. Even more preferably, the bar is free from talc, TiO<NUM>, polyox high molecular weight or mixture thereof. Preferably the bar is a translucent bar. Translucent allows some, but not all, light to pass through it. Preferably more than <NUM>%, even more preferably more than <NUM>%, even more preferably more than <NUM>% and even more preferably more than <NUM>% of light passes through. In an opaque bar, no light passes through.

It can be desired to use a filler in the soap composition, such as talc. If present, talc is preferably present in an amount of from <NUM> to <NUM> wt%, preferably of from <NUM> to <NUM> wt%.

The pH of preferred soaps bars of the invention is from <NUM> to <NUM>, more preferably <NUM> to <NUM>.

A preferred bar may additionally include up to <NUM> wt% benefit agents. Preferred benefit agents include moisturizers, emollients, sunscreens and anti-ageing compounds. The agents may be added at an appropriate step during the process of making the bars. Some benefit agents may be introduced as macro domains.

Other optional ingredients like anti-oxidants, perfumes, polymers, chelating agents, colourants, deodorants, dyes, emollients, moisturizers, enzymes, foam boosters, germicides, additional antimicrobials, lathering agents, pearlescers, skin conditioners,
stabilisers, superfatting agents, sunscreens may be added in suitable amounts in the process of the invention. Preferably, the ingredients are added after the saponification step. Sodium metabisulphite, ethylene diamine tetra acetic acid (EDTA), borax or ethylene hydroxy diphosphonic acid (EHDP) are preferably added to the formulation.

According to another aspect of the present invention, there is provided use of a
composition for providing enhanced perfume impact or enhanced deposition of actives.

The invention relates in a further aspect to a process to produce a soap bar composition according to the invention, the process comprising the steps of:.

In step a) of the process according to the invention fatty acid soap is used. The fatty acid soap used is in solid form. The fatty acid soap is conventionally added in particles comprising the fatty acid soap. Such particles are commonly referred to as 'soap noodles'. Accordingly, preferably the fatty acid soap is provided in the form of soap noodles. Preferably the fatty acid soap, such as preferably provided in the form of soap noodles, comprises soaps derived from palm oil and palm kernel oil. It is preferred, that the fatty soap derived from palm kernel oil is <NUM> to <NUM> wt%, preferably <NUM>-<NUM> wt%, based on the weight of the total fatty acid soap. Preferably <NUM> to <NUM> wt%, more preferably <NUM> to <NUM> wt%, based on the weight of the total fatty acid soap content is soap derived from palm oil. The amount of C<NUM> to C<NUM> fatty acid soap is between <NUM> and <NUM> wt%, the amount of soap not being C<NUM>-C<NUM>, preferably C<NUM>- C<NUM> soap, preferably is from <NUM> to <NUM> wt%, preferably of from <NUM> to <NUM> wt%, based on the weight of the total fatty acid soap. The fatty acid soap preferably contains C<NUM> fatty acid soap in an amount of from <NUM> to <NUM> wt%, preferably <NUM> to <NUM> wt%, based on the weight of the total fatty acid soap content. Soap noodles can be provided commercially or prepared by the skilled person. It is preferred, that in the process of the invention, the soap noodles, comprising the fatty acid soap, used in step a), comprise a low glycerol content. The glycerol level of the soap noodles is preferably less than <NUM> wt%, preferably the glycerol level is below <NUM> wt%, even more preferably it is of between <NUM> and <NUM> wt%, based on the weight of the soap noodles. This glycerol level in the soap noodles is achieved by removal of glycerol from the reaction mixture after formation of soap from fat. After the saponification, glycerol remains normally present in the soap mass and ends up in the soap noodle. In the present invention, preferably fatty acid soap is provided with soap noodles wherein glycerol has been removed to a significant extent. Low glycerol soap noodles can alternatively be prepared by saponification of fatty acids, rather than oil.

The soap noodles have preferably less than <NUM>, preferably less than <NUM> more preferably less than <NUM> wt% of FFA and are most preferably free from free fatty acids. It may be preferred hat the soap noodles are free from water.

Accordingly, it is preferred that the process according to the invention comprises the step of providing solid fatty acid soap noodles comprising less than <NUM> wt%, preferably less than <NUM> wt%, preferably from <NUM> to <NUM> wt% of glycerol. This preferred step is carried out before step a). Glycerol is then added in the next step, wherein a mixture is provided with the fatty acid soap, preferably comprised in soap granules, such as soap noodles, and further with free fatty acids, said glycerol, and water.

Accordingly, it is preferred, that the process of the invention comprises the steps of:.

The free fatty acids are added in an amount of from <NUM> to <NUM> wt% based on the weight of the mixture, i.e.based on the weight of the resulting soap bar. Preferred amounts are from <NUM> to <NUM> wt%. C<NUM> free fatty acid is preferably added in an amount of from <NUM> to <NUM> wt%, preferably of from <NUM> to <NUM> wt% based on the weight of the resulting soap bar. C<NUM> free fatty acid accordingly comprises preferably from <NUM> to <NUM> wt% of the weight of added free fatty acid. The free fatty acids are added as an ingredient as such and can be in the form of FFA flakes or liquid. Preferably, the FFA are added in the form of a liquid.

The water is added in an amount of preferably <NUM> to <NUM> wt%, more preferably of from <NUM> to <NUM> wt% and even more preferably of from <NUM> to <NUM> wt%, based on the weight of the mixture of step b). Accordingly, these amounts of water are also based on the weight of the resulting soap bar. The mixture is preferably prepared within a total mixing time of between <NUM>-<NUM> minutes, preferably <NUM>-<NUM> minutes, preferably <NUM> to <NUM> minutes, which is a conventional mixing time in the art. The temperature of the mixture is preferably of between <NUM> and <NUM>, and preferably of between <NUM> and <NUM> for optimal results. The higher temperatures resulted in higher translucency.

Glycerol is preferably added in the step of the process wherein the mixture is made comprising fatty acid soap, free fatty acids, glycerol and water, i.e. step a), in a total glycerol amount of from <NUM> to <NUM> wt%, based on the weight of the mixture of step b). Accordingly, such amounts represent the amounts of glycerol based on the weight of the resulting soap bar. The total amount of glycerol is from <NUM> to <NUM> wt%, based on the weight of the resulting soap bar. It may be preferred, that when preparing the ingredient mixture, glycerol is added after the fatty acid soap, preferably before the free fatty acids and water are added thereto. Adding the glycerol before the free fatty acids and water, preferably as the first ingredient after the fatty acid soap, typically added as soap noodles, surprisingly proved to have a beneficial effect on the appearance of the resulting soap bar, that appeared to be much more translucent. Translucent bars could now be produced in an efficient manner, e.g. compared to cast melt bars, in a high throughput process, within a similar time as used for opaque bars.

In step c) of the process of the invention, the mixture resulting from step b) is shaped into a bar. The shaping preferably comprises extrusion of the mixture, preferably followed by cutting the extruded material into individual soap bars. The soap composition may be made into a bar by a process that includes extruding the mixture in a conventional plodder. The bars preferably have a size of between <NUM> and <NUM>. They have preferably a weight of from <NUM> to <NUM> grams, preferably of from <NUM>-to <NUM> grams.

Alternatively, shaping takes place in the form of stamping the material in a desired shape, for example by stamping it in a mould.

The process may further include the step of stamping indicia onto the surface of the bar.

The invention further relates to a soap bar obtainable by, preferably obtained by the process of the present invention.

The invention further relates to the use of.

Lather and hardness of the bar respectively is increased compared to an equivalent soap bar wherein the FFA and glycerol are not added.

It was found that with the combination of free fatty acids and glycerol a bar composition could be provided that allowed for a reduction in C<NUM> to C<NUM> fatty acid soap including lauric acid soap while still providing a high lather. The bar of the invention shows the advantage that the bar is easy to extrude, despite its relatively low level of C<NUM> to C<NUM> fatty fatty acid soap of between <NUM> and <NUM> wt% based on the total weight of the fatty acid soap. By "easy to extrude" is meant that the hardness of the bar as it is extruded is high enough that it exits the extruder in a firm enough form that it can be called a rigid bar. The hardness of the bar as measured directly after extrusion is preferably higher than <NUM>, more preferably in the range of <NUM> to <NUM> and even more preferably of from <NUM> to <NUM> (at <NUM>). The hardness is preferably measured using the TA-XT Express apparatus available from Stable Micro Systems. The hardness is measured using this apparatus with a <NUM>° conical probe - Part #P/30c to a penetration of <NUM>. If the soap mass is too soft and is passed through the extruder it will not extrude out of the extruder in a cohesive enough mass to be called a bar. By "easy to stamp" is meant that the soap bar is of such a consistency and low enough stickiness that it does not stick to the die that is used to stamp any desired indicia on the bar. The soap bar prepared by the process of the invention therefore preferably comprises an indicium stamped thereupon.

The lather is preferably of from <NUM> to <NUM> and measured in mL of lather volume.

The invention will now be exemplified by the following non-limiting examples:.

The following soap bar compositions were prepared as shown in Table <NUM>:.

For examples <NUM>-<NUM>, fatty acid soap noodles were provided wherein the glycerol level was <NUM> wt%. An ingredient mixture was provided according to the table above. Ingredient mixtures where prepared by adding the glycerol as a first ingredient after the soap noodles in the mixing vessel. Mixing of the glycerol with soap oodles took <NUM>-<NUM> minutes. This was followed by the water and colorants and then the FFA and fragrances. Total preparation of the mixture, i.e. total mixing time was <NUM>-<NUM> minutes. The temperature of the mixture was <NUM>-<NUM>. The mixtures were extruded through a plodder and stamped to provide a bar. For comparative example <NUM>, soap noodles were used comprising <NUM> wt% glycerol, and no post addition of glycerol was done.

Comparative example <NUM> represents a prior art bar with <NUM>% PKO soap (high C<NUM> fatty acid soap). As expected, such a bar shows a high amount of lather (<NUM>), however the soap ingredient mixture is too soft, which resulted in problems with the equipment, requirements to adjust pressing parameters and a much lower throughput of bars. The bar is semi-translucent, almost opaque. It was found that in a bar with a significantly lower lauric acid soap content, (e.g. <NUM>% of total soap), the hardness could be restored, but the lather is reduced significantly (Comparative example <NUM>). When the combination was used of glycerol and free fatty acid in amounts according to the invention, the shortcomings of prior art bars were overcome: The examples <NUM>-<NUM> show significantly higher lather volume, a faster lather formation, and allow extrusion and stamping at efficient speed during production. Lather formation was improved without a negative impact on hardness, and the machinery didn't need to be changed. As a consequence of the production process, post-adding glycerol as the first ingredient after the noodles in the mixture, the bars were more translucent. Their translucency was better than that of comparative example <NUM> (opaque bar) and than that of the prior art bar (comparative example <NUM>).

The amount of lather generated by toilet bar is an important parameter affecting consumer preference. The lather volume test described here gives a quantitative measure of lather generation under standard conditions, thus allowing objective comparison of different soap formulations.

Lather is generated by trained technicians using a standardised method. The lather is collected in a beaker, and its volume measured.

This procedure may be conducted by trained and experienced technicians, capable to discriminate and reproduce results from a range of different formulation types, with replicates within variation ±<NUM>.

It is recommended <NUM>-<NUM> answers for each product tested. So, tests can be done by <NUM>-<NUM> technicians, each making duplicate or triplicate determinations. For each test made by each technician a different random order of testing the bars should be used.

Results are reported by data average and standard deviation. It is not recommended statistical analysis due to low amount of answers. But, based on deviation of analysis + correlation to consumers' data, differences higher than <NUM> among products can be considered significant.

Note: Gloves may be replaced when they show signs of permanent contamination or wear.

Bar Feel & Lather can be profiled by wider range of descriptors, used to emphasize special features on subjective assessments. These descriptors are useful on formulation and processing development, as well as on products quality checking. The bar feel and lather aspects are evaluated accordingly defined qualitative scales, by technicians trained on anchors for each assessment scale.

The bar feel attribute assessed by this protocol is:.

The lather attribute assessed by this protocol is:.

The assessments are conducted by trained technicians without gloves. Some attributes are assessed in two different water temperature: <NUM> and <NUM>, simulating the average for hand washing and bath. Depending on region under study, other temperatures can be also used on tests.

Usually samples are assessed by two technicians who may have a consensus on reporting the grade of the attribute. (Samples can be assessed by more evaluators).

a) Identify all samples on soap dishes with correct codes, accordingly to test form. b) It is recommended has a <NUM>rd person to record scores during assessments to avoid evaluators break procedures to take notes. c) Before start the assessments, wash well the hands with neutral soap (e.g. a cast melt product or SLS solution <NUM>%) and dry them. d) Start assessing Bar Hardness on dry bar (before use), for samples in study:.

• Hardness of the bar (Bar Firmness): hold the bar in one hand, and press the thumb on each bar corner. Assess the product by tactile feel, accordingly to scale:.

e) Set up water at <NUM> on adequate flow and hardness. g) Get one samples, wet the hand and wet the bar. Spin it <NUM> times* outside the water. During movements, assess Speed of Lathering visually, accordingly to scale below:.

A <NUM>° conical probe penetrates into a soap/syndet sample at a specified speed to a predetermined depth. The resistance generated at the specific depth is recorded. There is no size or weight requirement of the tested sample except that the bar/billet be bigger than the penetration of the cone (<NUM>) and have enough area. The recorded resistance number is also related to the yield stress and the stress can be calculated as noted below. The hardness (and/or calculated yield stress) can be measured by a variety of different penetrometer methods. In this invention, as noted above, we use probe which penetrates to depth of <NUM>.

This test can be applied to billets from a plodder, finished bars, or small pieces of soap/syndet (noodles, pellets, or bits). In the case of billets, pieces of a suitable size (<NUM>) for the TA-XT can be cut out from a larger sample. In the case of pellets or bits which are too small to be mounted in the TA-XT, the compression fixture is used to form several noodles into a single pastille large enough to be tested.

These settings need to be inserted in the system only once. They are saved and loaded whenever the instrument is turned on again. This ensures settings are constant and that all experimental results are readily reproducible.

Place the billet onto the test platform.

Place the probe close to the surface of the billet (without touching it) by pressing the UP or DOWN arrows.

Take the readings (g or kg) at the target distance (Fin).

After the run is performed, the probe returns to its original position.

Remove the sample from the platform and record its temperature.

The output from this test is the readout of the TA-XT as "force" (RT) in g or kg at the target penetration distance, combined with the sample temperature measurement. (In the subject invention, the force is measured in Kg at <NUM> at <NUM> distance).

The force reading can be converted to extensional stress, according to the equation below: The equation to convert the TX-XT readout to extensional stress is <MAT> where:.

For a <NUM>° cone at <NUM> penetration Equation <NUM> becomes <MAT>.

This stress is equivalent to the static yield stress as measured by penetrometer.

For a <NUM>° cone moving at <NUM>/s, έ = <NUM>-<NUM>.

The hardness (yield stress) of skin cleansing bar formulations is temperature-sensitive. For meaningful comparisons, the reading at the target distance (RT) should be corrected to a standard reference temperature (normally <NUM>), according to the following equation: <MAT> where.

The correction can be applied to the extensional stress.

Claim 1:
A process to produce a soap bar composition, the process comprising the steps of:
a) Providing a mixture comprising:
• Fatty acid soap in an amount of from <NUM> to <NUM> wt%, more preferably <NUM> to <NUM> wt%, based on the weight of the resulting soap bar,
wherein the amount of C8-C14 fatty acid soap is between <NUM> and <NUM> wt%, wherein the fatty acid soap comprises <NUM> to <NUM> wt% soap derived from palm kernel oil and <NUM> to <NUM> wt% soap derived from palm oil, based on the weight of the fatty acid soap,
• Free fatty acids in an amount of from <NUM> to <NUM> wt%, preferably from <NUM> to <NUM> wt%, based on the weight of the resulting soap bar, wherein the added free fatty acids comprise C<NUM> free fatty acid in an amount of from <NUM> to <NUM> wt%, preferably from <NUM> to <NUM> wt%, even more preferably from <NUM> to <NUM> wt%, most preferably <NUM>%, based on the weight of the added free fatty acids,
• Glycerol, in an amount of from <NUM> to <NUM> wt%, based on the weight of the resulting soap bar, wherein glycerol is the only polyol in the soap bar composition,
• from <NUM> to <NUM> wt%of water, based on the weight of the resulting soap bar,
b) shaping the mixture resulting from step a) into a soap bar.