Abstract:
A release agent composition for molding a polyurethane foam is disclosed. The agent is obtained by blending a cationic surfactant having an amino acid salt of alkyl amine, a predetermined substance having release characteristic and a film forming agent. Furthermore, it is preferable that a polyethylene glycol type non-ionic surfactant with an additional number of ethylene oxide in the range from 1 to 15 moles, preferably, in the range from 5 to 10 moles is used in combination.

Description:
BACKGROUND OF THE INVENTION  
         [0001]    1. Field of the Invention  
           [0002]    The present invention relates to an aqueous release agent composition for molding polyurethane foam.  
           [0003]    2. Description of Related Art  
           [0004]    As a release agent for molding polyurethane foam, solvent based release agents have been used for a long time, however, an aqueous release agent has been proposed as a substitute for the above-described solvent based release agents from the viewpoints of problems such as flammability of an organic solvent, working environment and the like (see Japanese Unexamined Patent Publication No.H09-141671 gazette).  
           [0005]    In the invention disclosed in the above-described patent publication gazette, in an aqueous release agent their attention has been exclusively turned to, a film forming agent comprising naphthenic hydrocarbon compounds or paraffin based hydrocarbon compounds, and its improvement has been contemplated, thereby providing a release agent which is soluble in water and provides excellent release performance and work performance.  
         SUMMARY OF THE INVENTION  
         [0006]    When the present inventors made every effort to consider an aqueous release agent, the present inventors were aware of being insufficiencies for the consideration of surfactants used for this release agent.  
           [0007]    As far as the present inventors know, it is general that as a surfactant agent contained in a release agent for molding polyurethane foam, a volatile aliphatic amine salt such as morpholine stearate or the like has been used. However, in the case of a surfactant comprising such morpholine stearate, large amounts have been used for the purpose of stabilizing the release agent. For example, 20-50 weight portions of morpholine stearate has been required with respect to 100 weight portions of the release component. However, if the usage amount of a surfactant becomes large, a negative influence upon the release performance of the release agent is feared  
           [0008]    On the other hand, as a cationic surfactant, an inorganic acid salts (hydrochloride or the like) of alkyl amine or a lower carbon salt (acetic acid salt or the like) are known. However, when the former is used as a release agent for molding polyurethane foam, the corrosiveness against the mold becomes a problem. In the case of the latter, that has a stimulating smell, a problem arises from the viewpoint of the work environment.  
           [0009]    It should be noted it is feared that a problem of the work environment might also occur in the case where a large amount of morpholine stearate is comprised in the agent composition since that morpholine stearate is volatile.  
           [0010]    Furthermore, since a film forming agent comprising the naphthenic hydrocarbon compound or paraffin based hydrocarbon compound, in general, also has volatility, it is feared that the problem of the work environment may occur from the viewpoint of this, also.  
           [0011]    The present invention has been made so as to solve at least one of the above-described problems and is described as follows:  
           [0012]    aqueous release agent composition for molding polyurethane foam comprises,  
           [0013]    an amino acid salt of alkyl amine,  
           [0014]    a release substance, and  
           [0015]    a forming film agent.  
           [0016]    Hereinafter, the present invention will be described in detail.  
           [0017]    (Amino Acid Salt of Alkyl Amine)  
           [0018]    It is preferable that the blending amount of amino acid salt of alkyl amine with respect to 100 weight portions of a release component (substance having release nature: wax or the like, the detail of this will be described later) is made in the range of 1-50 weight portions. If the blending amount of amino acid salt of alkyl amine is less than one weight portion, the emulsified matter is not capable of being formed and if the blending amount of it exceeds over 50 weight portions, the release performance of the release agent is lowered, therefore neither of these are preferred.  
           [0019]    A further preferred blending amount of amino acid salt of alkyl amine with respect to 100 weight portions of a release component is in the range of 1-20 weight portions, and a still further preferred blending amount of amino acid salt of alkyl amine with respect to 100 weight portions of the release component is in the range of 3-10 weight portions.  
           [0020]    In this way, when the amino acid salt of alkyl amine of the present invention is utilized as a surfactant, the usage amount of it is capable of being reduced compared to morpholine stearate used in the conventional examples. According to the considerations of the present inventors, the release agent could be stabilized with the usage amount of approximately ⅓-⅕ (weight ratio) of morpholine stearate used in the conventional example according to cationic surfactant of the present invention.  
           [0021]    It is preferable that the number of carbons of an alkyl group of alkyl amine in the range from 12 to 24. If the number of carbons of alkyl group is less than 12, the emulsification becomes unstable and the stability of the release agent is lowered. On the other hand, if the number of carbons of the alkyl group exceeds over 24, the emulsification is insufficient, and it is feared that the components of the release agent may separate.  
           [0022]    The alkyl group may be available if it is straight chain or branched.  
           [0023]    In general, amino acid is a solid weak acid, and it seldom corrodes the metal of the mold or the like. Moreover, since amino acid has no irritating smell as acetic acid does, it does not adversely affect the work environment.  
           [0024]    According to the considerations by the present inventors, amino acid having two carboxyl groups is preferable among amino acids, in particular, it is preferable that one of or both of aspartic acid and glutamic acid, which are acidic amino acids, is employed.  
           [0025]    By the existence of this amino acid, a surfactant of this present invention becomes a cationic surfactant.  
           [0026]    When a surfactant comprising such an amino acid salt of alkyl amine has been blended in an aqueous release agent composition for molding polyurethane foam, as shown in Example 1 (see Tables 1-3) or Example 7 (see Tables 4-6), excellent release performances (in release characteristic, cell opening characteristic, surface roughening, drying characteristic) and excellent workabilities (in odor and corrosiveness) were obtained.  
           [0027]    On the other hand, in the case where morpholine stearate conventionally and universally has been utilized as a surfactant, in order to stabilize the release agent, it is required that the amount of the surfactant to be used should be over 3 times (weight ratio) more than that in the case of Example 1 (or Example 7) as shown in Comparative Example 1 (or Comparative Example 4). As a result, the release performance becomes inferior to that of Example 1 (or Example 7). Moreover, since morpholine, which is a volatile amine, is used in a large amount, the work environment is also inferior.  
           [0028]    The drying characteristic which is particularly inferior in its performance in Comparative Example 1 (or Comparative Example 4) is, in general, capable of being resolved by adding a leveling agent and by preventing the release agent from forming droplets on a mold surface.  
           [0029]    According to findings of the present inventors, even among non-ionic surfactants, some of them have a leveling performance, for example, the use of polyethylene glycol type non-ionic surfactant is preferable. Hence, the relevant non-ionic surfactant has been added in Examples 2-4 (or Examples 8-10), the leveling characteristic was enhanced, thereby the enhancement of the drying characteristic being observed.  
           [0030]    By further considerations of the present inventors, in the polyethylene glycol type non-ionic surfactant, it is preferable that the additional number of ethylene oxide in the range from 1 to 15 moles and it is further preferable that it is in the range from 5 to 10 moles. If the additional number of ethylene oxide exceeds 15 moles, since ethylene oxide group is reacted with isocyanate and the release characteristic is made worse, it is not preferable (see Comparative Example 3 or Comparative Example 6).  
           [0031]    Moreover, when the additional number of ethylene oxide becomes 5 moles or more, it was understood that it largely contributes to the enhancement of the leveling characteristic.  
           [0032]    It is preferable that the polyethylene glycol type non-ionic surfactant is blended in combination with amino acid salt of alkyl amine in total in the range from 1 to 100 weight portions with respect to 100 weight portions of the release component. It is more preferable that the total in the range from 5 to 50 weight portions of them is blended. It is still more preferable that the total in the range from 5 to 40 weight portions is blended. It is preferable that the blending ratio of amino acid salt of alkyl amine and polyethylene glycol type non-ionic surfactant is made in the range from 1:0 to 1:10. It is more preferable that it is in the range from 1:1 to 1:5.  
           [0033]    As the polyethylene glycol type non-ionic surfactant, ethylene oxide adducts such as alkyl amine, higher alcohol, alkyl phenol, alphatic amide, polypropylene glycol, fats and fatty oils, polyvalent alcohol aliphatic ester, fatty acid and the like are listed.  
           [0034]    In the polyethylene glycol type non-ionic surfactant, in the case of ethylene oxide adduct of alkyl amine, when the additional number of ethylene oxide is small, the large difference with alkyl amine (without ethylene oxide adduct) does not occur from the viewpoint of the reactivity with amino acid (generation of salt). For example, as shown in Example 5 (or Example 11), when alkyl amine whose additional number of ethylene oxide is one mole was used, almost the same performance as Example 1 (or Example 7) was obtained.  
           [0035]    According to the considerations of the present inventors, when the additional amount of ethylene oxide with respect to alkyl amine is less than 5 moles, more preferably one mole or less, it is considered that although the relevant ethylene oxide is added, amino acid salt is formed and it is effective as a cationic surfactant.  
           [0036]    From the description described above, if the present invention is observed from another viewpoint, the present invention is described in that amino acid is selected as its acid component when a cationic surfactant is employed in an aqueous release agent composition for molding polyurethane foam.  
           [0037]    As already described above, amino acid is preferable from the viewpoint of the work environment since its corrosiveness with respect to the metal such as the mold or the like is slight and it has no irritating smell.  
           [0038]    As such an amino acid, an amino acid having two carboxyl groups is preferable, and among these, glutamic acid and/or asparaginic acid, which are acidic amino acids, are preferable.  
           [0039]    In a cationic surfactant, it is preferable that the basic side is made alkyl amine, and it is preferable that the number of carbon atoms of alkyl group is in the range from 12 to 24. If the number of carbons of the alkyl group is less than 12, the emulsification becomes unstable and the stability of the release agent is lowered. On the other hand, if the number of carbon atoms exceeds 24, the emulsification is insufficient, and it is feared that components of the release agent may become separated.  
           [0040]    The alkyl group may be available if it is straight chain or branched.  
           [0041]    Less than 5 moles of ethylene oxide, more preferably one mole or less of ethylene oxide may be added to this alkyl amine.  
           [0042]    The following components are blended in an aqueous release agent for molding polyurethane foam.  
           [0043]    (Release Substance)  
           [0044]    A release substance referred to in the present invention is, for example, as a straight chain wax, a straight chain polyethylene wax, a highly pure purified paraffin wax, fishertropsch and the like are listed. It is preferable that the average molecular amount of a straight chain wax is in the range from 500 to 1000. Moreover, it is more preferable that it contains 50% or more with respect to the total release characteristic substance. Carnauba wax, montan wax, microcrystalline wax, branched polyethylene wax, silicon and the like is capable of being used, however, it is preferable that the blending ratio of these is less than 50%.  
           [0045]    (Film Forming Agent)  
           [0046]    A film forming agent is referred to as a substance for resolving one portion of or the whole of the release component by the temperature of the mold surface and making it in a uniform film shape after the release agent is coated on the mold. If the relevant film forming agent is not added, the release agent film is in a state where powder is attached, when the urethane raw material is injected, the film cannot be maintained due to that impact, and it causes cell roughening and voids. In a urethane molding, since urethane raw material is injected immediately after the release agent was applied, it is necessary to swiftly form the release agent film. Therefore, it is preferable that the film forming agent is a substance in a liquid at 40-80° C. or less which is the temperature of mold at the time when a urethane is generally molded and it is more preferable that it is a substance in a liquid state at 20° C.  
           [0047]    Moreover, in order to function as a film forming agent, in this case, the resolvability with the release component is important, hydrocarbon compound containing hydrophilic group having a hydroxyl group, carboxyl group or the like is not suitable for a film forming agent of the present invention. Hence, similarly to the release component, a hydrophobic hydrocarbon compound is available, and it is preferably a hydrocarbon compound in a liquid state at 20° C.  
           [0048]    According to the first aspect of the present invention, a solvent based film forming agent is capable of being used. Such a film forming agent comprises naphthen based hydrocarbon compounds and paraffin based hydrocarbon compounds. The additional amount of such a film forming agent is preferably in the range from 50 to 500 weight portions with respect to 100 weight portions of substance having the release characteristic. In the case where the additional amount is less than 50 weight portions, regular molecular sequence of the substance having release characteristic is not sufficiently performed, and cell opening characteristic of the molded product becomes worse. If the additional amount exceeds 500 weight portions, the emulsion necessary for emulsification is required even more and the bad influence of the emulsion appears and the cell opening characteristic of the molded product is lowered.  
           [0049]    For a solvent based film forming agent, an organic compound whose boiling point is in the range from 150 to 250° C. is suitable. For example, (a) as hydrocarbons, nonan, decane, unbenzene, tetralin, isopropylbenzene, cyclohexylbenzene, paraffin based hydrocarbon mixture (number of carbon atoms 10-13), naphthenic hydrocarbon mixture (number of carbon atoms 11-13) and the like are listed, (b) as a halide, p-chlorotoluene, hexachloroethane, trichlorobenzene, bromobenzene, octyl bromide and the like are listed, and (c) as an ether, anisole, phenetole, cresylmethyl ether, ethylbenzyl ether, butylphenyl ether and the like are listed. Moreover, these compounds may be used in a mixture. It is more preferable that (a) these are hydrocarbons, among these, naphthenic hydrocarbon, paraffin based hydrocarbon and the mixture of paraffin based and naphthenic hydrocarbons are more preferable from the viewpoints of the safety to the human body and environment.  
           [0050]    According to another aspect of the present invention, a non-solvent based film forming agent is capable of being used. As such a film forming agent, an organic compound whose vapor pressure at 20° C. is less than 0.01 kPa is preferable. Since such a film forming agent is sufficiently low in its vapor pressure, it hardly volatilizes under the conditions of molding work of urethane foam.  
           [0051]    As such a film forming agent, for example, as hydrocarbons, (a) aromatic hydrocarbon mixture, (b) polycyclic aromatic hydrocarbon mixture, (c) paraffin based hydrocarbon mixture, (d) naphthenic hydrocarbon mixture and the like, and (e) halogenation hydrocarbon and the like are listed. Preferably, (a) aromatic hydrocarbon mixture, (b) polycyclic aromatic hydrocarbon mixture, (c) paraffin based hydrocarbon mixture, and (d) naphthenic hydrocarbon mixture are listed, and these compounds may be used in a mixture. Moreover, these and some other than hydrocarbons may be mixed.  
           [0052]    It is preferable that the additional amount of non-solvent based film forming agent is in the range from 5 weight portions or more to less than 100 weight portions with respect to 100 weight portions of the substance having release characteristic. If the additional amount is less than 5 weight portions, the film forming of the substance having release characteristic is not sufficiently performed (see Comparative Example 5), and the cell opening characteristic of the molded product becomes worse. If the additional amount is 100 weight portions or more, the surface of the molded body is not capable of forming an open cell structure, and causes cell roughening and voids, thereby worsening the release characteristic (see Comparative Example 6). A more preferable blending amount of a film forming agent is in the range from 10 to 80 weight portions with respect to 100 weight portions of the substance having release characteristic. It is still more preferable that it is in the range from 20 to 50 weight portions.  
           [0053]    (Additive)  
           [0054]    Furthermore, an aqueous release agent according to the present invention may contain an insecticide, a foam stabilizer, a wetting agent, a leveling agent, an antifoaming agent and the like as an additive of conventional small amount.  
           [0055]    (Method of Manufacture)  
           [0056]    Next, an example of a method for manufacturing an aqueous emulsion of the present invention will be described below. First, a material having release characteristic, solvent, and further the other components are added and heated, melted and mixed at 110-120° C. Then this is gradually added to an aqueous solution of surfactant at 90° C. or more and simultaneously mixed by a homomixer to make an emulsion. Subsequently, a fine emulsion composition is made by treatment with a homogenizer. A stable emulsion composition is made by cooling the obtained emulsion to room temperature. It should be noted that in the above-described method, a substance having the release characteristic, solvent, other components may be mixed after each of these is separately emulsified.  
           [0057]    (Application to Polyurethane Foam Manufacture Step)  
           [0058]    A release agent composition of the present invention, which is similar to general purpose release agent composition, is coated on the interior of the metal mold by spraying or other methods, and the film is formed within the interior of the relevant metal mold. Subsequently, urethane material is injected into the metal mold, and the molding steps are carried out.  
           [0059]    As described above, in the present invention, as a cationic surfactant of an aqueous release agent composition for molding polyurethane foam, an amino acid salt of alkyl amine is employed. By using this, a release agent composition emulsion is capable of being stabilized with a small usage amount compared to anionic morpholine stearate which has been conventionally and generally used. Then, on the basis of the usage amount of the surfactant being suppressed, the release performance (release characteristic, cell-opening characteristic and the like) originally required for a release agent is to be enhanced.  
           [0060]    It should be noted that as for alkyl amine, a small amount of ethylene oxide may be added to that.  
           [0061]    Furthermore, when a non-solvent based one which is low in vapor pressure as a film forming agent has been employed, vaporization of organic materials from the release agent composition in the molding work of polyurethane foam are capable of being prevented, and the work environment is capable of being enhanced.  
           [0062]    Moreover, according to the present invention, since a surfactant containing a volatile substance like morpholine stearate is not used, therefore, the work environment is also enhanced. 
       
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS  
       [0063]    Hereinafter, Examples and Comparative Examples are shown in order to make the present invention clearer.  
         [0064]    In Examples and Comparative Examples listed in Table 1-Table 3, a solvent based film forming agent has been blended.  
         [0065]    In Examples and Comparative Examples listed in Table 4-Table 6, a non-solvent based film forming agent has been blended.  
                                                                                                   TABLE 1                           Examples and Comparative Examples                                        Comparative   Comparative   Comparative           Example 1   Example 2   Example 3   Example 4   Example 5   Example 6   Example 1   Example 2   Example 3                        Wax A (note 1)   2.0   2.0   2.0   2.0   2.0   2.0   2.0   2.5   2.0       Wax B (note 2)   2.0   2.0   1.5   1.5   2.0   1.5   2.0   1.0   1.5       Wax C (note 3)                               0.5       Wax D (note 4)           0.5   0.5       0.5           0.5       Hydrocarbon based   10.0   5.0       10.0   10.0   10.0   10.0       solvent E (note 5)       Hydrocarbon based           5.0                   5.0   5.0       solvent F (note 6)       Alkyl amine G (note   0.3   0.2   0.2                   0.3   0.3       7)       Alkyl amine N (note               0.2       8)       Glutamic acid (note   0.1       0.1       0.1               0.1       9)       Asparaginic acid       0.1       0.1       0.1       (note 10)       Acetic acid (note                               0.1       11)       Alkyl amine ethyl-                   0.3   0.3       ene       Oxide adduct (note       12)       Alkyl amine ethyl-       0.1   0.1   0.1       0.1       ene       Oxide adduct (note       13       Higher alcohol           0.5       ethylene oxide       adduct (note 14)       Higher alcohol               0.5       0.5       0.5       ethylene oxide       adduct (note 15)       High alcohol                                   0.5       ethylene oxide       adduct (note 16)       Alkylphenol       0.5       ethylene oxide       adduct (note 17)       Morpholine stearate                           1.5       Water   85.6   90.1   90.1   85.1   85.6   85.0   84.5   90.1   90.1                  
 
         [0066]    [0066]                         TABLE 2                       Description of blending components on table 1                                Wax A (note 1)   Petrolite: “POLYWAX           500”       Wax B (note 2)   Petrolite: “POLYWAX           655”       Wax C (note 3)   Petrolite: “POLYWAX           850”       Wax D (note 4)   Petrolite: “BE           SQUARE 195A”       Hydrocarbon based solvent E (note 5)   Exxon Mobile: “EX-           XOL D-40”       Hydrocarbon based solvent F (note 6)   Shell Japan: “Shell-           zole D-70”       Alkyl amine G (note 7)   Kaoh: “Farmin 86T”       Alkyl amine H (note 8)   Kaoh: “Farmin 80”       Glutamic acid (note 9)   Ajinomoto: “L-glut-           amic acid”       Asparaginic acid (note 10)   Ajinomoto: “aspara-           ginic acid”       Acetic acid (note 11)   Kanto Chemical: “re-           agent chemical; acetic           acid”       Alkyl amine ethylene Oxide adduct (note 12)   Aoki Fats and Fatty           Oils: “Brownon S-           201” (EO = 1) * 1       Alkyl amine ethylene Oxide adduct (note 13)   Aoki Fats and Fatty           Oils: “Brownon S-           207” (EO = 7)       Higher alcohol ethylene oxide adduct (note 14)   Aoki Fats and Fatty           Oils: “Brownon SR-           707” (EO = 7)       Higher alcohol ethylene oxide adduct (note 15)   Kaoh: “Emulgen 108”           (EO = 8)       Higher alcohol ethylene oxide adduct (note 16)   Kaoh: “Emulgen           130K” (EO = 30)       Alkylphenol ethylene oxide adduct (note 17)   Aoki Fats and Fatty           Oils: “Brownon N-           510” (EO = 10)                            
         [0067]    [0067]                                                                                                 TABLE 3                                                           Comparative   Comparative   Comparative           Example 1   Example 2   Example 3   Example 4   Example 5   Example 6   Example 1   Example 2   Example 3                                    release char-   ⊚   ⊚   ⊚   ⊚   ⊚   ⊚   ⊚   ⊚   X       acteristic (kg)       cell-opening char-   ⊚   ⊚   ⊚   ⊚   ⊚   ⊚   ⊚   ⊚   X       acteristics       surface roughening   ◯   ◯   ◯   ◯   ◯   ◯   Δ   ◯   ◯       drying characteristic   Δ   ◯   ◯   ◯   Δ   ◯   X   ◯   ◯       smell   ◯   ◯   ◯   ◯   ◯   ◯   ◯   X   ◯       corrosiveness   ◯   ◯   ◯   ◯   ◯   ◯   ◯   X   ◯                    
         [0068]    [0068]                                                                                                                           TABLE 4                           Examples and Comparative Examples                                        Com-   Com-   Com-   Com-   Com-   Com-                                   para-   para-   para-   para-   para-   para-                                   tive   tive   tive   tive   tive   tive           Exam-   Exam-   Exam-   Exam-   Exam-   Exam-   Exam-   Exam-   Exam-   Exam-   Exam-   Exam-           ple 7   ple 8   ple 9   ple 10   ple 11   ple 12   ple 4   ple 5   ple 6   ple 7   ple 8   ple 9                        Wax A (note 1)   2.5   2.0   2.0   2.0       2.0   3.0   3.0   3.0   3.0   2.0   2.0       Wax B (note 2)   2.0   2.0   1.5   1.5   2.0   2.0   2.0   1.0   1.5   2.0   2.0   2.0       Wax C (note 3)                   2.0           0.5       Wax D (note 4)           0.5   0.5       0.5           0.5       0.5   0.5       Film forming agent F (note 5)   3.0               3.0       Film forming agent F (note 6)       2.0               2.0   2.0       Film forming agent G (note 7)           1.0       Film forming agent H (note 8)               0.5                               10.0       Hydrocarbon based solvent I (note                               2.0       9)       Hydrocarbon based solvent J (note                                   2.0   2.0       10)       Alkyl amine K (note 11)   0.3   0.2   0.2                   0.3   0.3   0.3   0.2   0.2       Alkyl amine L (note 12)               0.2       Glutamic acid (note 13)   0.1       0.1       0.1               0.1   0.1   0.1   0.1       Asparaginic acid (note 14)       0.1       0.1       0.1       Acetic acid (note 15)                               0.1       Alkyl amine ethylene                   0.3   0.3       Oxide adduct (note 16)       Alkyl amine ethylene       0.1   0.1   0.1       0.1               0.1   0.1   0.1       Oxide adduct (note 17)       Higher alcohol ethylene           0.5                               0.5   0.5       oxide adduct (note 18)       Higher alcohol ethylene               0.5       0.5       0.5       0.5       oxide adduct (note 19)       Higher alcohol ethylene                                   0.5       oxide adduct (note 20)       Alkylphenol ethylene oxide adduct       0.5       (note 21)       Morpholine stearate                           1.5       Water   92.1   94.1   94.1   94.6   92.6   92.5   91.5   92.6   92.1   92.0   94.6   84.6                    
         [0069]    [0069]                         TABLE 5                       Description of blending components on table 4                                Wax A (note 1)   Petrolite: “POLYWAX           500”       Wax B (note 2)   Petrolite: “POLYWAX           655       Wax C (note 3)   Petrolite: “POLYWAX           850”       Wax D (note 4)   Petrolite: “BE           SQUARE 195A”       Film forming agent E (note 5)   Exxon Mobile: “EX-           XOL D-110” vapor           pressure (/20° C.):           less than 0.01 kPa       Film forming agent F (note 6)   Exxon Mobile: “EX-           XOL D-130” vapor           pressure (/20° C.):           less than 0.01 kPa       Film forming agent G (note 7)   Nihon Seikyu           Chemical{ }“Hizol           SAS-296” vapor           pressure (/20° C.):           less than 0.01 kPa       Film forming agent H (note 8)   Exxon Mobile: “CRY-           STOL 70” vapor           pressure (/20° C.):           less than 0.01 kPa       Hydrocarbon based solvent I (note 9)   Exxon Mobile: “EX-           XOL D-40” vapor           pressure (/20° C.):           0.183 kPa       Hydrocarbon based solvent J (note 10)   Exxon Mobile: “Iso-           par L” vapor           pressure (/20° C.):           0.03 kPa       Alkyl amine K (note 11)   Kaoh: “Farmin 86T”       Alkyl amine L (note 12)   Kaoh: “Farmin 80”       Glutamic acid (note 13)   Ajinomoto: “L-gluta-           mic acid”       Asparaginic acid (note 14)   Ajinomoto: “asp-           araginic acid”       Acetic acid (note 15)   Kanto Chemical: “re-           agent chemical; acetic           acid”       Alkyl amine ethylene Oxide adduct (note 16)   Aoki Fats and Fatty           Oils: “Brownon S-           201” (EO = 1)*1       Alkyl amine ethylene Oxide adduct (note 17)   Aoki Fats and Fatty           Oils: “Brownon S-           207” (EO = 7)       Higher alcohol ethylene oxide adduct (note 18)   Aoki Fats and Fatty           Oils: “Brownon SR-           707” (EO = 7)       Higher alcohol ethylene oxide adduct (note 19)   Kaoh: “Emulgen           108” (EO = 8)       Higher alcohol ethylene oxide adduct (note 20)   Kaoh: “Emulgen           130K” (EO = 30)       Alkylphenol ethylene oxide adduct (21)   Aoki Fats and Fatty           Oils: “Brownon N-           510” (EO = 10)                            
         [0070]    [0070]                                                                                                                         TABLE 6                                                           Com-   Com-   Com-   Com-   Com-   Com-                                   para-   para-   para-   para-   para-   para-                                   tive   tive   tive   tive   tive   tice           Exam-   Exam-   Exam-   Exam-   Exam-   Exam-   Exam-   Exam-   Exam-   Exam-   Exam-   Exam-           ple 7   ple 8   ple 9   ple 10   ple 11   ple 12   ple 4   ple 5   ple 6   ple 7   ple 8   ple 9                                    release characteristic (kg)   ⊚   ⊚   ⊚   ⊚   ⊚   ⊚   Δ   ⊚   X   ⊚   X   Δ       cell-opening characteristics   ⊚   ⊚   ⊚   ⊚   ⊚   ⊚   ⊚   ⊚   X   ⊚   X   Δ       surface roughening   ◯   ◯   ◯   ◯   ◯   ◯   Δ   ◯   ◯   ◯   Δ   X       drying characteristic   Δ   ◯   ◯   ◯   Δ   ◯   X   ◯   ◯   ◯   ◯   ◯       smell   ◯   ◯   ◯   ◯   ◯   ◯   ◯   X   ◯   ◯   ◯   ◯       corrosiveness   ◯   ◯   ◯   ◯   ◯   ◯   ◯   X   ◯   ◯   ◯   ◯       work environment   ◯   ◯   ◯   ◯   ◯   ◯   X   X   X   X   ◯   ◯                    
         [0071]    Performance Test Method  
         [0072]    In order to clarify the performance effects of the present invention, the performance test has been carried out on Examples and Comparative Examples as shown below.  
         [0073]    (1) Coating of release agent: metal mold in core-box made of iron (interior size: vertical; 15 cm, horizontal; 20 cm, depth; 5 cm, with lid having a carrying handle) was heated to 50-55° C., the release agent composition was uniformly sprayed (about 30 g per 1 m 2 ) by an air-gun and drying for 2 minutes.  
         [0074]    (2) Molding of polyurethane foam: 40 weight portions of polyol (MS-300; made by Mitsui Toatsu Chemical, Co., Ltd.) and 20 weight portions of TDI/MDI=1/1 as raw material were mixed and agitated for 5 seconds at 2000 rpm, and immediately after that, injected into the metal mold, and reacted at 50-55° C. with the lid closed. The metal mold was put into the thermostat at 50-50° C. and left for 10 minutes including the curing time.  
         [0075]    (3) Evaluation of the release characteristic: a spring balance was set at the carrying handle of the above-described mold, and the lid was opened. The applied load was measured.  
         [0076]    Evaluation standard: ⊚; 5-10 kg or less, ◯; 10-15 kg; Δ; 15-20 kg, and X; 20 kg or more.  
         [0077]    (4) Evaluation for cell-opening characteristic of molding foam: the number of the entire cells within the square of 5 cm ×5 cm on the surface of the molded urethane foam and whether there are foam breakings of cells or not were visually observed and measured. The cell-opening ratio was made as a ratio of the number of foam breaking cells occupying in the total cell number. The cell-opening characteristic is preferably 60% or more. Evaluation standard: for cell-opening ratio: ⊚; 80% or more, ◯; 60-80%; Δ; 40-60%, and X; 40% or less or not cell-opened.  
         [0078]    (5) Dry characteristic: The duration from the time when the release agent was sprayed in the mold at the above-described temperature to the time when it was dried was measured. Evaluation standard: ⊚; within about 30 seconds, ◯; within about 60 seconds, X; 60 seconds or more.  
         [0079]    (6) Smell: the smell at the time when the release agent was sprayed on the mold at the above-described temperature was determined by a human. Evaluation standard: ◯; no uncomfortable smell, X; uncomfortable smell.  
         [0080]    (7) Corrosiveness: the moiety of the release agent was put in the sample bottle, in which the degreased iron was immersed. The bottle stood in the thermostat at 65° C. for 4 hours, and the possible occurrence of rust was observed. Evaluation standard: ◯; no occurrence of rust, X; occurrence of rust.  
         [0081]    (8) Work environmental characteristic: The vapor pressure at 20° C. as the whole composition which was less than 0.01 kPa was represented by ◯, and the vapor pressure at 20° C. as the whole composition which was 0.01 kPa or more was represented by X. It should be noted that the composition evaluated as ◯ clears the standard of EU conference (COUNCIL DIRECTIVE, 1999/13/EC) concerning with volatile organic solvents. It should be noted that the following URL can be referred to for the relevant standard.  
         [0082]    http://europa.eu.int/eur-lex/en/consleg/pdf/1999/en — 1999L0 013_do — 001.pdf  
         [0083]    See B-17 of pp.5.  
         [0084]    The present invention is not limited by the description of Embodiments and Examples at all. A variety of modified Embodiments are also included within the scope in which those skilled in the art can easily conceive without departing from the scope of the description of the claims.