JP2018021861A - Physical property measuring apparatus of formulation - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a physical property measuring apparatus of formulations capable of appropriately evaluating the adhesiveness of a dry film of liquid formulations.SOLUTION: A physical property measuring apparatus 10 of formulations supplies face lotion and emulsion as cosmetics, for example, as liquid or semi-solid formulations 15, to a nip portion 14 formed of a drive roll 11 and a free rotation roll 12 disposed in parallel with each other, and measures a tack value of these formulations 15. The free rotation roll 12 is formed using an elastic material such as rubber. The surface of the free rotation roll 12 is coated with a non-elastic material such as an inorganic solid, preferably metal, metal oxide, carbon, silicon compound, or fluorocarbons.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a device for measuring physical properties of a preparation.

  The inventors of the present invention first supplied the foundation or mascara to the nip formed by the two rolls of the driving roll and the free rotating roll, and the supplied foundation or mascara was split on the outlet side of the nip. Invented a method for evaluating the performance of cosmetics, which measures the force in the direction perpendicular to the plane including the two roll axes, and evaluates the tack value of the foundation or mascara (for example, patents) References 1 and 2).

  In Patent Documents 1 and 2, the measurement results of the tack value of the foundation or mascara measured by the methods described in these Patent Documents 1 and 2, and the sensory evaluation of stickiness in actual use of the foundation or mascara by a specialized panelist It has been reported that there is a high correlation with the evaluation results, and according to the cosmetic performance evaluation methods described in Patent Documents 1 and 2, the stickiness of cosmetics (formulations) that was difficult to evaluate The feeling can be objectively evaluated.

  Moreover, in the cosmetics performance evaluation methods described in Patent Documents 1 and 2, the measuring device including the two rolls of the driving roll and the free rotating roll forming the nip portion is a preparation that does not contain solid particles such as pigments. For example, when lotion is supplied to the nip portion, slipping easily occurs in the nip portion due to its configuration. When slip occurs in the nip portion, the preparation is not divided on the outlet side of the nip portion, and the tack value of the preparation cannot be measured. On the other hand, the inventors of the present invention have provided a mechanism for preventing slipping at the nip portion, whereby the physical properties of the cosmetics that enable measurement of the tack value even for a preparation that does not contain solid particles. A measuring device was developed (see, for example, Patent Document 3).

JP 2005-106731 A JP 2008-70382 A Japanese Patent Laying-Open No. 2015-166713

"Tacking test machine" TAC-2 "" Nobuhiro Sasaki, Convertec 28 (3), 63-65 (2000)

  In the above-described cosmetic performance evaluation method and physical property measuring apparatus, the tack value of a liquid preparation such as lotion when wet is measured. In particular, in liquid preparations such as skin lotions, it has been elucidated that stickiness is most strongly expressed when drying after a certain period of time has passed since the liquid preparation was applied on the skin. That is, liquid preparations such as skin lotions do not become sticky immediately after being applied, and stickiness is most strongly expressed after a certain amount of time has elapsed, and further, the stickiness is reduced by further drying. Become. In addition, the sensory evaluation of stickiness when actually using a liquid preparation such as skin lotion is, for example, the maximum of the tack values that change in the drying process measured using the physical property measuring apparatus for cosmetics of Patent Document 3. It shows a particularly good correlation with the tack value.

  On the other hand, in the case of liquid preparations such as lotions, the stickiness (stickiness) due to dry residual components remaining after drying has progressed, in addition to the stickiness when wet during the drying process, is also possible when using liquid preparations such as lotions. It is known to become an important factor in the sticky feel. For example, it is clear from experience that moist skin has a slight adsorptivity, but conversely, by applying a slightly sticky oil to the bulky skin surface, the skin is moist. A feeling may be produced. On the other hand, if the surface of the skin is excessively tacky (stickiness), it is disliked as stickiness after application. For this reason, controlling the dry residual component to have an appropriate strength of adhesiveness is a point for adjusting so that a moist skin feel can be obtained.

  After applying a liquid preparation such as lotion, as a method for measuring the tackiness when the applied liquid preparation is dried, for example, after applying the liquid preparation to a silicone rubber plate and the applied liquid preparation is dried A method has been developed for measuring the force required to press a probe with a constant pressure and peel it off (see, for example, Non-Patent Document 1).

  In addition, as another method capable of performing measurement equivalent to the method described in Non-Patent Document 1, a liquid preparation is preferably formed on a roll using the physical property measuring apparatus described in Patent Documents 1 to 3 described above. A method of measuring the tack value (plateau value) after drying is conceivable. By using the physical property measuring apparatus described in Patent Documents 1 to 3, in addition to the change in the tack value and the maximum value in the drying process of the liquid formulation when wet, the dry coating by the dry residual components after the liquid formulation is dried Since the tack value (adhesiveness) of the film can also be measured, it is considered that the tack value of the liquid preparation can be efficiently measured.

  However, using the physical property measuring apparatus described in Patent Documents 1 to 3, when trying to evaluate the tackiness of the dried coating film after the liquid preparation has been dried by a method equivalent to the measuring method of Non-Patent Document 1, it is particularly liquid. When the preparation is a preparation that does not contain solid particles such as lotion and emulsion, at least one of a drive roll and a free rotating roll arranged in parallel to each other is formed using an elastic material such as a rubber roll. In the case of a rolled roll, there is a problem that measurement of the tack value of the dried coating film after the liquid preparation is dried is hindered by the adhesiveness of the roll surface by the elastic material.

  That is, in the physical property measuring apparatus described in Patent Documents 1 to 3, for example, a nip portion formed between two rolls, a drive roll made of a metal roll and a free rotating roll made of a rubber roll. In this case, the force applied to the peeling between rolls (division of the coating film formed on the roll surface) is measured to evaluate the tackiness of the dried coating film. Depending on the surface condition of the roll and the ingredients of the preparation, strong stickiness may be produced on the surface of the rubber roll, and the tack value of the dried coating film can be measured by the stickiness produced on the roll surface. It becomes easy to be disturbed.

  The reason why stickiness is generated on the surface of a roll formed using an elastic material such as a rubber roll as described above has not been elucidated, and the tack value of a dry coating film of a preparation containing solid particles is measured. In some cases, such stickiness does not occur. Moreover, even if it is the roll of rubber | gum of the same kind, the thing which does not produce such adhesiveness in what passed many years after creating the roll. In fact, in the case of rubber rolls that have undergone aging, even when using preparations that do not contain solid particles such as lotion, measure the tack value of the dry coating film of the preparation applied to the surface of the roll, It was possible to evaluate the tackiness. However, this is thought to be mainly due to the secular change of rubber rolls, and it is only necessary to always prepare a rubber roll with such physical properties after the secular change. It is difficult to create. In addition, what kind of rubber roll is unclear as to whether it becomes a roll that can be used when measuring and evaluating the tack value of a dry coating film of a preparation that does not contain solid particles after aging, The evaluation result may be inappropriate or unstable.

  The present invention does not depend on the physical properties of a roll formed using an elastic material such as a rubber roll after aging, and the tack value of a dry coating film of a formulation that does not contain solid particles such as lotion and emulsion. It is an object of the present invention to provide a device for measuring physical properties of a preparation that enables appropriate and stable measurement and can evaluate the adhesiveness of a dry coating film of a liquid preparation appropriately and stably.

  The present invention is an apparatus for measuring physical properties of a preparation, which supplies a liquid or semi-solid preparation to a nip formed by a drive roll and a free rotating roll arranged in parallel to each other, and measures the tack value of the preparation. And at least any one of the said drive roll and the said free rotation roll is formed using the elastic material, The surface of the roll formed using this elastic material is an inelastic material, or to-be-measured object An apparatus for measuring physical properties of a preparation coated with a non-swellable elastic material having non-swelling property with respect to a dry residue of the preparation is provided.

  According to the apparatus for measuring physical properties of the preparation of the present invention, the preparation does not contain solid particles such as lotion and emulsion without depending on the physical properties of the roll formed using an elastic material such as a rubber roll after aging. It is possible to appropriately and stably measure the tack value of the dried coating film, and it is possible to appropriately and stably evaluate the adhesiveness of the dried coating film of the liquid preparation.

FIG. 1 (a) is a conceptual diagram of a main part for explaining a state before measurement of a physical property measuring apparatus for a preparation according to a preferred embodiment of the present invention, and FIG. 1 (b) is a main part for explaining a state at the time of measurement. It is a conceptual diagram. FIG. 2 (a) is a perspective view of a main part for explaining the configuration of a preparation physical property measuring apparatus according to a preferred embodiment of the present invention, and FIG. 2 (b) shows a physical property measuring apparatus for another form of the preparation. It is a principal part perspective view to explain. Fig.3 (a)-FIG.3 (c) are principal part perspective views of the physical property measuring apparatus of the formulation which concerns on other embodiment of this invention. It is a figure which shows the relationship between the tack value of a dry residue, and the sensory evaluation value by a specialized panel. It is a figure which shows the change of the tack value in the drying process of the sample by the apparatus of Example 2 and Comparative Example 1. FIG.

  Hereinafter, an apparatus for measuring physical properties of a preparation of the present invention will be described with reference to FIGS. 1 (a), 1 (b) and 2 (a) based on preferred embodiments thereof. 1 (a), 1 (b) and FIG. 2 (a), a physical property measuring apparatus 10 for a preparation according to a preferred embodiment of the present invention is used as a physical property of the preparation, for example, cosmetics such as foundations and mascaras, especially cosmetics It is preferably used as an apparatus for measuring and evaluating the stickiness of cosmetics that do not contain solid particles such as water and emulsion. The physical property measuring apparatus 10 of the present embodiment is a liquid or semi-solid preparation 15 (see FIG. 1B) in a nip portion 14 formed by two rolls of a drive roll 11 and a free rotating roll 12. Specifically, for example, cosmetics, hair styling agents, hair growth agents, skin external preparations, body lotions, sunscreen agents, after shave lotions, moisturizers for lips, massage agents, skin and hair cleaning agents, hair conditioners, treatments, etc. The tack value obtained by measuring the force generated when the supplied preparation 15 is split at the nip portion 14 can be measured with high accuracy, and the stickiness of the preparation 15 can be evaluated more appropriately. It is used as a device for Here, it is reported that there is a high correlation between the tack value and the sensory evaluation of the stickiness of the preparation 15 as described above. The physical property measuring apparatus 10 of the present embodiment has a tack value (adhesiveness) of a dry coating film due to a dry residual component after the liquid formulation is dried, in addition to the change or maximum value of the tack value in the drying process of the formulation when wet. ) Is also provided with a function that enables appropriate and stable measurement. In addition, the physical property measuring apparatus 10 of the present embodiment can be used by appropriately improving an incometer, which is known as an apparatus used for, for example, evaluation of adhesiveness of printing ink.

  Then, the physical property measuring apparatus 10 for the preparation of the present embodiment has a liquid or semi-solid preparation 15 as a liquid or semi-solid preparation 15 in a nip portion 14 formed by a drive roll 11 and a free rotating roll 12 arranged in parallel with each other. This is a measuring device for supplying the skin lotion or emulsion and measuring the tack value of these preparations 15. At least one of the drive roll 11 and the free rotation roll 12 (in this embodiment, the free rotation roll 12) is formed using an elastic material such as rubber, and the roll (free free roll) is formed using an elastic material. The surface of the rotating roll 12) is coated with, for example, an inorganic solid, preferably a metal, a metal oxide, carbon, a silicon compound, or fluorocarbons as an inelastic material. When the polar oil agent is contained in the object to be measured, this polar oil agent causes the above-mentioned problem that the measurement of the tack value of the dry coating film due to the dry residual component after the liquid preparation is dried occurs. The surface of the roll (free rotating roll 12) formed using an elastic material is a material having non-swelling property with respect to the dry residue of the preparation 15 as the object to be measured, preferably a silicone resin or You may coat | cover with the non-swelling elastic material which has non-swelling property with respect to polar oil agents, such as a fluororesin.

  Moreover, in this embodiment, you may have the film thickness control roll 13 for adjoining the drive roll 12 and spreading the supplied cosmetics (formulation) 15 thinly.

  In the preparation physical property measuring apparatus 10 of the present embodiment, as shown in FIGS. 1A and 1B, the drive roll 11 and the free rotating roll 12 have their respective rotating shafts 11a and 12a via hinges or arms. The measuring device 10 is rotatably attached to a frame (not shown). As shown in FIG. 2A, the driving roll 11 and the free rotating roll 12 have their rotating shafts 11a and 12a arranged in parallel to each other, and the driving roll 11 and the free rotating roll 12 are in contact with each other. Thus, the structure is such that a load from above by the free rotating roll 12 is added to the nip portion 14, which is a portion that sandwiches the supplied cosmetic material 15. The free rotating roll 12 rotates with the rotation of the driving roll 11 by the action of frictional force caused by contact with the driving roll 11 at the nip portion 14.

  Moreover, in this embodiment, as described above, the physical property measuring apparatus 10 of the preparation is preferably a third roll other than the drive roll 11 and the free rotation roll 12, and the cosmetic 5 is evenly distributed on the drive roll 11. It has a film thickness control roll (vibration roll) 13 that spreads thinly. As shown in FIG. 2A, the film thickness control roll 13 has a rotation shaft 13 a arranged in parallel with the rotation shaft 12 a of the drive roll 11, and is caused by the action of frictional force caused by contact with the drive roll 11. The drive roll 11 rotates with the rotation. The film thickness control roll 13 preferably includes a mechanism that enables reciprocal driving in the axial direction (left-right direction in FIG. 2A).

  Here, the load applied to the nip portion 14 can be adjusted so that a load more than the weight of the free rotating roll 12 is applied by applying a load to the rotating shaft 12a of the free rotating roll 12, for example. Further, by applying a load from the lateral direction by using, for example, a pressing mechanism by a spring member such as a spring, the positional relationship between the drive roll 11 and the free rotating roll 12 includes, for example, the rotating shafts 11a and 12a. It can also be arranged such that the plane is horizontal.

  In this embodiment, the drive roll 11 is a metal roll, and a motor (not shown) is attached to the rotary shaft 11a so as to be rotated at a predetermined speed. Further, the drive roll 11 has a temperature adjusting device (not shown) for keeping the roll at a constant temperature. As for the magnitude | size of the drive roll 11, as shown to Fig.2 (a), it is preferable that the diameter D1 is about 50 mm-120 mm, for example, and the length L1 of the rotating shaft 11a direction is about 50 mm-250 mm. preferable.

  In this embodiment, the free rotating roll 12 is a rubber roll made of, for example, nitrile butadiene rubber (NBR) as an elastic material such as rubber, and is shown in FIGS. 1 (a), 1 (b), and 2 (a). Thus, it is arranged above the drive roll 11 so as to come into contact with the drive roll 11. As shown in FIGS. 1A and 1B, a rotating arm 22 is attached to the free rotating roll 12 at both ends of a rotating shaft 12 a. A weight 21 is disposed at the lower end of the rotating arm 22 opposite to the free rotating roll 12. A sensor (not shown) that detects a change in the angle around the rotation shaft 22 a of the rotation arm 22 (coaxial with the rotation shaft 11 a of the drive roll 11) is attached to the rotation arm 22. The angle of the rotating arm 22 detected by the sensor (not shown) is the torque generated when the force generated in the free rotating roll 12 as a drag force caused by the division of the cosmetic 15 is applied to the rotating shaft 22 a via the rotating arm 22. This corresponds to the inclination angle of the rotating arm 22 at a position balanced with the torque due to the weight of the weight 21 applied to the rotary shaft 22a by lifting the weight. That is, if this angle is large, it indicates that the force applied to the free rotating roll 12 is increased due to the division of the cosmetic 15. The sensor (not shown) detects this angle and outputs a detection result to a control device (not shown).

  Based on the detection result of the sensor, the control device (not shown) applies a force (tackiness due to stickiness) applied in a direction perpendicular to the plane including the rotation shaft 12a of the free rotation roll 12 and the rotation shaft 11a of the drive roll 11. The tack value (relative value) of the cosmetic 15 that is a force) can be calculated as a measurement target. The tack value is measured by measuring the position of the weight 21 that is lifted via the rotating arm 22 by the tack force shown in FIGS. 1A and 1B, as well as the free rotating roll 12. It is also possible to use a method of directly measuring the force applied to the load using a force gauge or the like.

  As for the magnitude | size of the free rotation roll 12, as shown to Fig.2 (a), it is preferable that the diameter D2 is about 50 mm-120 mm, for example, and the length L2 of the rotating shaft 12a direction is comparable as the drive roll 11, For example, it is preferably about 50 mm to 120 mm. In FIG. 1B, the swing of the rotating arm 22 is drawn large so that the movement can be easily understood. However, in actual measurement, the swing is not so large. In addition to the method of measuring the angle at which the weight 21 is lifted, the force applied to the free rotating roll 12 is a force perpendicular to the rotating shaft 12a of the free rotating roll 12 using a force gauge as described above. A detection method may be used.

  The free rotating roll 12 is preferably a rubber roll having a rubber hardness (hereinafter simply referred to as “hardness”) of 40 ° to 95 °, and is a rubber roll having a hardness of 40 ° to 85 °. More preferably.

  Further, the free rotating roll 12 made of an elastic material such as rubber has a direct contact between the metal driving roll 11 and the free rotating roll 12 made of an elastic material when the cosmetic 15 is interposed in the nip portion 14. For the purpose of avoiding general contact, the surface is coated with an inorganic solid (for example, an inelastic material). For example, metals, metal oxides, carbon, silicon compounds, and fluorocarbons can be used as the inorganic solid (inelastic material). From the viewpoint of the wettability of the product (cosmetic material 15) (ease of fitting to the surface of the free rotating roll 12), etc., it is preferable to use carbon, particularly diamond like carbon.

  As a coating method of the inorganic solid (non-elastic material) on the surface of the free rotating roll 12 in the present embodiment, an appropriate method is selected according to the type of inorganic solid (non-elastic material) to be coated, such as a CVD method or a dipping method. be able to. For example, when the inorganic solid (inelastic material) to be coated is a carbon material, for example, a film formation technique by plasma ion implantation or the like (Japan Rubber Association magazine published by Japan Rubber Association, 2009 Volume 82, “Plasma It is preferable to use DLC film formation technology by ion implantation and film formation and industrial application to rubber and resin (see Yasuo Suzuki, p252-257). By using this method, it is possible to form a coating of an inelastic material on the surface of the free rotating roll 12 at a relatively low cost, preferably by forming diamond-like carbon on the surface of the free rotating roll 12. . Since the diamond-like carbon film is strongly adhered to the rubber surface, it is excellent in mechanical durability against the wiping operation of the surface of the free rotating roll 12 after the sample measurement. That is, it is most preferable from various viewpoints that the surface of the free rotating roll 12 is covered with diamond-like carbon.

  As shown in FIGS. 1A, 1 </ b> B, and 2 </ b> A, the film thickness control roll 13 is disposed in front of the drive roll 11 and in contact with the drive roll 11. As described above, the film thickness control roll 13 rotates in synchronization with the drive roll 11 as the drive roll 11 rotates due to the action of frictional force caused by contact with the drive roll 11. As with the free rotating roll 12, the film thickness control roll 15 can be formed as a rubber roll made of an elastic material such as rubber, for example, and can be formed by selecting a wide range of materials from, for example, nylon and other various resins. The film thickness control roll 13 preferably has a diameter smaller than the diameter D1 of the drive roll 11, for example, about 35 to 80 mm. When the film thickness control roll 13 performs reciprocal driving (vibration operation) in the axial direction, the film thickness control roll 13 is longer than the lengths L1 and L2 of the driving roll 11 and the free rotating roll 12 by the driving width. Is preferred.

  In the present invention, the cosmetic (formulation) 15 whose physical properties such as stickiness are evaluated by measuring the tack value after the coating film is dried using the physical property measuring apparatus 10 is not only the foundation and the mascara but also the lotion. , Milky lotion, cream, essence, UV care agent, antiperspirant coating, aftershave lotion and other skin cosmetics, nail enamel and other nail cosmetics, hair cosmetics and hair restorer, lip moisturizer, skin care Other various cosmetics in liquid or semi-solid form such as preparations can be mentioned. The physical property measuring devices 10, 10A, 10B, and 10C of the present invention can also be preferably used when measuring the tack value after drying the coating film of the cosmetic 15 that easily causes the nip portion 14 to slip. Examples of the cosmetic 15 that easily causes slippage in the nip portion 14 include cosmetics that contain little or no solid particles such as pigments. Here, the solid particles such as pigments are specifically organic pigments, inorganic pigments, glitter pigments, etc. Among these, examples of organic pigments include azo pigments and polyazo pigments. it can. Examples of inorganic pigments include carbon powders such as acetyl carbon and graphite, synthetic silica, iron oxide, titanium oxide, cobalt oxide, manganese oxide, copper oxide, zinc oxide, and clay minerals such as mica. Examples of glitter pigments include pearl pigments.

  Further, the supply amount of the cosmetic 15 supplied to the nip portion 14 is preferably such that the thickness of the cosmetic 15 spread evenly and thinly on the drive roll 11 is 1 μm or more and 30 μm or less. The supply amount is more preferably 5 μm or more and 20 μm or less.

  Using the physical property measuring apparatus 10 of the preparation of the present embodiment having the above-described configuration, as a physical property of the cosmetic (preparation) 15, for example, a tack value for evaluating the sticky feeling in the drying process of the preparation 15 when wet In order to measure the tack value for evaluating the sticky feeling after the coating film is dried, first, as shown in FIG. 1 (a), for example, the state before supplying lotion or emulsion as the cosmetic 15, In a state before measuring the tack value of the cosmetic 15, the driving roll 11, the free rotating roll 12, and the film thickness control roll 13 (when using the film thickness control roll) are rotated at a predetermined initial rotation speed. The temperature is maintained at a predetermined temperature. Specifically, a motor (not shown) attached to the rotation shaft 11a of the drive roll 11 is driven to rotate the drive roll 11. Along with the rotation of the drive roll 11, the free rotation roll 12 and the film thickness control roll 13 that are in contact with the drive roll 11 are rotated together with the drive roll 11 by the action of frictional force due to contact with the drive roll 11.

  With the drive roll 11, the free rotating roll 12, and the film thickness control roll 13 rotated (when using the film thickness control roll), next, for example, using a pipette (not shown) or the like, In addition, as the cosmetic 15 whose tack value is to be measured, for example, a predetermined amount of emulsion or lotion is supplied. Alternatively, the film thickness control roll 13 is brought into a non-contact state with respect to the driving roll 11, and the other two rolls (the driving roll 11 and the free rotating roll 12) are rotated. In FIG. 3, the entire region of the film thickness control roll 13 facing the head 11 is opposed to the portion corresponding to the physical property measurement region 14 c of the nip portion 14 in the drive roll 11 in FIGS. 3A and 3B described later. After the cosmetic material 15 as a sample is placed evenly in the axial direction on the region of the film thickness control roll 13, preferably the film thickness control roll 13 is gently brought into contact with the drive roll 11, The cosmetic 15 is supplied evenly to the surface of the measurement area. The supplied cosmetic material 15 is preferably thinly spread evenly in the tack value measurement region of the drive roll 11 by the action of the film thickness control roll 13 which is or is not vibrating. Go.

  When the cosmetic 15 supplied onto these rolls and spread to the tack value measurement region in the drive roll 11 reaches the nip portion 14 between the drive roll 11 and the free rotation roll 12, FIG. As shown in FIG. 4, by passing through the nip portion 14, a force required for splitting the cosmetic material is generated on the outlet side of the nip portion 14. The force required for the splitting is transmitted from the free rotating roll 12 through the rotating arm 22 to the weight 21 side as a torque that rotates around the rotating shaft 22a and lifts the weight 21, and when the weight 21 is lifted, The torque due to the weight of the weight 21 thus obtained is balanced, and an equilibrium state is obtained. The angle of the rotating arm 22 in the equilibrium position is detected by a sensor (not shown), and the detected angle of the rotating arm 22 is output to a control device (not shown), thereby controlling the control device (not shown). In the figure, the tack value that is the measurement target is calculated. Such a tack value is calculated for a dry coating film with a dry residual component after the cosmetic 15 is dried through the drying process from the wet cosmetic 15 immediately after the cosmetic 15 is supplied. In addition to the change and maximum value of the tack value in the drying process of the cosmetic 15 when wet, the tack value (adhesiveness) of the dry coating film due to the dry residual component after the liquid preparation has been dried is also obtained. It becomes possible to measure efficiently using the physical property measuring apparatus 10.

  And according to the physical property measuring apparatus 10 of the formulation of the present embodiment having the above-described configuration, lotion, emulsion, without depending on physical properties of a roll formed using an elastic material such as a rubber roll after aging. It is possible to appropriately and stably measure the tack value of a dry coating film of a formulation that does not contain solid particles such as the above, and to appropriately and stably evaluate the tackiness of the dry coating film of a liquid formulation It becomes possible.

  That is, according to the physical property measuring apparatus 10 of the preparation of the present embodiment, the surface of the rubber free rotating roll 12 is covered with, for example, an inorganic solid (non-elastic material). When a non-elastic material is interposed in the nip portion 14 between the free rotating roll 12 and the rubber free rotating roll 12, strong adhesiveness derived from the rubber material is expressed on the surface of the rubber free rotating roll 12. In addition, the tack value after drying the coating film can be measured appropriately and stably.

  In addition, in the physical property measuring apparatus 10 of the formulation of the above-described embodiment, the surface of the rubber free rotating roll 12 is covered with an inelastic material such as an inorganic solid, so that the metal driving roll 11 and the elastic member are used. The direct contact with the free rotating roll 12 is avoided. For example, when a polar oil agent is contained in the measurement object, the polar oil agent causes the dry coating by dry residual components after the liquid preparation is dried. When the problem that measurement of the tack value of the film is hindered occurs, the surface of the free rotating roll 12 is a material that has non-swelling property with respect to the dry residue of the cosmetic 15 that is the object to be measured. It can also coat | cover with the non-swelling elastic material which has non-swelling property to polar oil agents, such as a silicone resin or a fluororesin. That is, by directly coating the surface of the free rotating roll 12 with a non-swellable elastic material, direct contact between the metal driving roll 11 and the free rotating roll 12 made of an elastic material may be avoided. Even when the surface of the object to be measured is coated with a non-swellable elastic material, the same effects as when the surface is covered with a non-elastic material can be obtained.

  Hereinafter, the physical property measuring apparatus for pharmaceutical preparations according to another embodiment of the present invention shown in FIGS. 3 (a) to 3 (c) will be described in more detail.

  3A is a groove 11b for dividing the nip portion 14 into a physical property measurement region 14c and a driving force transmission region 14d on the peripheral surfaces of the end portions on both sides of the drive roll 11A. Is provided with substantially the same configuration as the physical property measuring apparatus 10 described above. And the physical-property measuring apparatus 10A of the formulation shown in FIG. 3A has a groove 11b extending along the surface perpendicular to the rotation shaft 11a on the peripheral surface of the drive roll 11A. Yes.

  According to the physical property measuring apparatus 10A shown in FIG. 3A, since the grooves 11b are formed on the peripheral surfaces of the end portions on both sides of the drive roll 11A, the cosmetic 15 is supplied to the surface of the drive roll 11A. The cosmetic 15 that has been pushed and spread on the peripheral surface of the drive roll 11A does not extend beyond the groove 11b of the drive roll 11A.

  Accordingly, in the physical property measuring apparatus for the preparation shown in FIG. 3A, the cosmetic 15 covers the entire length only inside the grooves 11b on both sides of the drive roll 11A (the physical property measuring region 14c in the nip portion 14). Will be spread evenly and thinly. Therefore, even when the supplied cosmetic 15 is a slippery cosmetic that does not contain particles, for example, the outer side of the grooves 11b on both sides of the drive roll 11A (the driving force transmission region 14d in the nip portion 14). Thus, the frictional force can be reliably ensured. Accordingly, the free rotating roll 12 can be rotated in synchronization with the rotation of the driving roll 11A, and the tack value of the cosmetic 15 can be measured with higher accuracy. In addition, the film thickness control roll 13 can be rotated in synchronization with the rotation of the drive roll 11A, and a uniform film thickness can be stably formed.

  The physical property measuring apparatus 10B for the preparation shown in FIG. 3 (b) is the above-mentioned except that the grooves 12b and 13b are provided on the peripheral surfaces of both end portions of the free rotation roll 12B and the film thickness control roll 13B. The device has substantially the same configuration as that of the physical property measuring apparatus 10 for pharmaceutical preparations of the embodiment. And the physical-property measuring apparatus 10B of the formulation shown in FIG. 3 (b) has grooves 12b extending along the surface perpendicular to the rotating shaft 12a on the peripheral surface of the free rotating roll 12 over the entire periphery. On the circumferential surface of the film thickness control roll 13, a groove 13 b extending along a plane perpendicular to the rotation shaft 13 a is entirely located at a position corresponding to the groove 12 b formed on the circumferential surface of the free rotation roll 12. It is formed over the circumference.

  According to the physical property measuring apparatus 10B shown in FIG. 3B, the free rotating roll 12B is rotated in synchronization with the rotation of the drive roll 11, as in the physical property measuring apparatus 10A shown in FIG. Thus, the tack value of the cosmetic 15 can be measured with higher accuracy. Further, the film thickness control roll 13B can be rotated in synchronization with the rotation of the drive roll 11, and a uniform film thickness can be stably formed.

  3C of the preparation physical property measuring apparatus 10C shown in FIG. 3 (c) is provided with grooves 11b and 12b on the peripheral surfaces of both ends of the drive roll 11C and the free rotating roll 12C, and the film thickness control roll 13C. Except that the groove 13b is provided also in the peripheral surface of the edge part of both sides, it has the structure substantially the same as the physical property measuring apparatus 10 of the formulation of said embodiment. And the physical property measuring apparatus 10C of the formulation shown in FIG. 3 (c) has a groove 11b extending along the surface perpendicular to the rotating shaft 11a on the peripheral surface of the drive roll 11C, and is freely formed. A groove 12b extending along a surface perpendicular to the rotation shaft 12a is formed on the circumferential surface of the rotation roll 12C over the entire circumference, and a surface perpendicular to the rotation shaft 13a is formed on the circumferential surface of the film thickness control roll 13C. A groove 13b extending along the circumference of the drive roll 11C and the free rotation roll 12C is formed over the entire circumference at a position corresponding to the grooves 11b and 12b formed on the peripheral surfaces of the free rotation roll 12C.

  According to the physical property measuring apparatus 10C shown in FIG. 3C, the free rotating roll 12C is rotated in synchronization with the rotation of the drive roll 11C, similarly to the physical property measuring apparatus 10A shown in FIG. Thus, the tack value of the cosmetic 15 can be measured with higher accuracy than the physical property measuring apparatus 10 regardless of the type of cosmetic used as a sample. In addition, the film thickness control roll 13C can be rotated in synchronization with the rotation of the drive roll 11C, and a uniform film thickness can be stably formed regardless of the type of cosmetic material used as a sample. Is possible.

  The present invention is not limited to the above-described embodiment, and various modifications can be made. For example, the device for measuring physical properties of the preparations shown in FIGS. 3A to 3C does not necessarily need to be provided with a film thickness control roll for spreading the supplied preparation thinly adjacent to the drive roll. Similarly to 2 (b), it can also be configured as an apparatus not provided with a film thickness control roll. Further, the concave grooves are not necessarily provided in pairs on the peripheral surfaces of both ends of the drive roll, the free rotating roll, and the film thickness control roll. For example, the concave grooves are provided only on one side of these peripheral surfaces. May be. Three or more concave grooves can be provided on these peripheral surfaces.

  In addition to the cosmetics described above, the apparatus for measuring physical properties of the preparation of the present invention is a hair styling agent, a hair restorer, an external preparation for skin, a lotion for body, a sunscreen agent, an after shave lotion, a moisturizer for lips, a massage agent, and skin. -Hair washing agents, hair conditioners, treatments, and the like can be suitably used as objects to be measured.

  Moreover, the physical property measuring apparatus for the preparation of the present invention may be a roll in which at least one of the drive roll 11 and the free rotation roll 12 is formed using an elastic material, and at least any one of the drive roll 11 and the free rotation roll 12. It is only necessary that the surface of the roll formed using an elastic material is covered with a non-elastic material or a non-swelling elastic material.

  EXAMPLES Hereinafter, although an Example demonstrates this invention further in detail, this invention is not restrict | limited to a following example.

[Example 1]
As a device having the same configuration as the physical property measuring device 10 having the configuration of FIG. 2A, a commercially available incometer (Digital Incometer D type, manufactured by Toyo Seiki Seisakusho Co., Ltd.) was used. The material of the top roll (corresponding to the free rotating roll 12 in the physical property measuring apparatus 10) of this apparatus was nitrile butadiene rubber (NBR), and the drive roll was made of brass. The surface of the top roll was coated with a carbon material (DLC-diamond-like carbon-coating treatment, manufactured by Metropolitan Roller Industries, Ltd.) having a thickness of about 1 μm as an inelastic material.

  About 27 samples of commercially available and prototype emulsion samples, each emulsion sample was developed so as to reach the entire roll surface of the drive roll and top roll, and when the emulsion sample was dried on the roll (dry residue) The tack value was measured. The tack value of each dry residue obtained (the tack value after drying the coating solution) and the sensory evaluation value of “stickiness after application” by a specialized panel for each emulsion sample (indicating that the larger the value, the more sticky) 4 is plotted in FIG.

  As shown in FIG. 4, when a top roll (free rotating roll) coated with a carbon material as an inelastic material is used, the tack value of the dry residue of the emulsion sample and the application of the emulsion sample by a specialized panel A high correlation was found between the evaluation value of “after (of skin) stickiness”.

[Example 2]
Using the apparatus having the configuration shown in FIG. 3 (c), the commercial lotion A is spread over the entire measurement surface of the drive roll and the top roll (free rotating roll), and each measurement is performed. The change of the tack value in the drying process of the sample appearing in the value was measured. The measurement results are shown in FIG.

[Comparative Example 1]
Using a device having the same configuration as the device of Example 2 except that the surface of the top roll is not coated with a carbon material as an inelastic material, a commercial roll lotion A is driven as in Example 2. And it extended | deployed so that it might spread over the whole roll surface of a top roll, and when the same measurement as Example 2 was performed, the change of the tack value in the drying process of the sample which appears in each measured value was measured. The measurement results are shown in FIG.

  According to the measurement results shown in FIG. 5, in the apparatus of Example 2, the tack value takes a peak and attenuates to reach a plateau value after drying, whereas in the apparatus of Comparative Example 1, after showing a peak, It turns out that it dries further and shows an abnormal increase in tack value. As mentioned at the beginning, the feeling when applying lotion is generally strong stickiness when dry, and then the stickiness is reduced if it is further dried. It can be said that the measurement result obtained by the apparatus of Example 2 appropriately explains the change in the feel (it decreases with a peak and settles to a constant value as it dries). On the other hand, the device of Comparative Example 1 showed a higher tack value as it dries, and it was not recognized that the result was consistent with the transition of the feeling of use when applying lotion.

10, 10A, 10B, 10C Formulation physical property measuring apparatus 11, 11A, 11C Drive roll 11a Rotating shaft 11b Groove (concave groove)
12, 12B, 12C Free rotating roll 12a Rotating shaft 12b Groove (concave groove)
13, 13B, 13C Film thickness control roll 13a Rotating shaft 13b Groove (concave groove)
14 Nip part 14c Physical property measurement area 14d Driving force transmission area 15 Formulation (cosmetics)

Claims (7)

A device for measuring physical properties of a preparation for supplying a liquid or semi-solid preparation to a nip formed by a drive roll and a free rotating roll arranged in parallel to each other, and measuring the tack value of the preparation,
At least one of the drive roll and the free rotating roll is formed using an elastic material, and the surface of the roll formed using the elastic material is a non-elastic material or a preparation to be measured A device for measuring physical properties of a preparation coated with a non-swelling elastic material having non-swelling property to a dry residue.   The device for measuring physical properties of a preparation according to claim 1, wherein the inelastic material is a metal, a metal oxide, carbon, a silicon compound, or a fluorocarbon.   The apparatus for measuring physical properties of a preparation according to claim 1, wherein the non-swelling elastic material having non-swelling property with respect to the dry residue of the preparation is a silicone resin or a fluororesin.   The physical property measuring apparatus for a preparation according to any one of claims 1 to 3, further comprising a film thickness control roll for thinly spreading the supplied preparation adjacent to the drive roll. A groove extending along a plane perpendicular to the rotation axis is formed on the circumferential surface of at least one of the drive roll and the free rotating roll,
The peripheral surface of at least one of the drive roll and the free rotating roll has a physical property measuring region for measuring a tack value of the preparation supplied by the groove in the nip portion, and the free rotation on the driving roll. The physical property measuring device for a pharmaceutical preparation according to any one of claims 1 to 4, wherein the device is divided into a driving force transmission region in which the free rotating roll is rotated by contact with the roll. The drive roll and the free rotating roll have substantially the same length in the rotation axis direction,
A pair of the grooves is formed on at least one of the drive roll and the free rotating roll,
The physical property measurement region in the nip portion is formed between the pair of grooves formed in the driving roll and / or the free rotating roll,
The device for measuring physical properties of a preparation according to claim 5, wherein the driving force transmission region in the nip part is formed outside a pair of the grooves formed in the driving roll and / or the free rotating roll.   The liquid or semi-solid preparation is a cosmetic, hair styling agent, hair restorer, skin external preparation, body lotion, sunscreen agent, after shave lotion, moisturizer for lips, massage agent, skin / hair cleansing agent, hair. The device for measuring physical properties of a preparation according to any one of claims 1 to 6, wherein the device is a conditioner or a treatment.