JP2020012018A - Coolant composition - Google Patents

Abstract

To provide a cooling liquid composition capable of showing sufficiently a function as brine, even in a low temperature range of -30°C or lower, or even in a lower temperature range (about -40°C to -50°C), when adjusting properly the content ratio of each component in the composition.SOLUTION: A cooling liquid composition is constituted by using, as essential components, ethanol as a first component, water as a second component, and potassium sorbate as a third component.SELECTED DRAWING: None

Description

  The present invention relates to a coolant composition, and more particularly to a coolant composition that can be advantageously used as brine in a refrigeration facility.

  As brine (secondary refrigerant, indirect cooling liquid) in refrigeration equipment, aqueous solutions of various compositions have been conventionally proposed and used. In recent years, there has been a demand for a refrigeration facility that exhibits a higher refrigeration capacity than before, and an aqueous solution (cooling liquid composition) that can sufficiently exhibit the function of brine even in a low temperature range of about -30 to -50 ° C. ) Is required.

  For example, an aqueous solution of calcium chloride has a relatively low viscosity even in a low temperature range of −30 ° C. or less, and therefore has been conventionally used as brine, but corrodes the inside of a brine circuit (equipment for circulating brine). In addition, there is a problem that a pump (a pump for circulating the brine in the circuit) in the brine circuit is worn by scale (sediment) caused by calcium chloride or the like.

  In contrast, aqueous solutions of ethylene glycol and propylene glycol have lower corrosiveness and abrasion to the brine circuit than calcium chloride aqueous solution, and have excellent lubricity in the brine circuit. Widely used.

  However, when the ethylene glycol aqueous solution and the propylene glycol aqueous solution are used in a low temperature range of −30 ° C. or lower, there is a problem that the viscosity sharply increases. Specifically, when used at −40 ° C., the viscosity of the aqueous ethylene glycol solution is about 150 to 450 mPa · s, and the viscosity of the propylene glycol aqueous solution is about 650 to 10,000 mPa · s. As described above, in particular, a propylene glycol aqueous solution widely used in a refrigeration facility of a food factory has a remarkable increase in viscosity in a low temperature range of −30 ° C. or less. When used as a brine in a low temperature range, the pressure loss of the liquid sent in the brine circuit becomes very large, and the practical use of the refrigeration equipment becomes difficult, or a very high output pump is required. However, there is a problem that the total energy efficiency deteriorates depending on conditions. Also, there is a concern about the ethylene glycol aqueous solution and the propylene glycol aqueous solution that the refrigerant capacity decreases due to an increase in viscosity in a low temperature range of −30 ° C. or lower.

  On the other hand, an aqueous solution of a lower alcohol that maintains a low viscosity even in a low temperature range of −30 ° C. or less has been conventionally used as various cooling liquids and brine (see Patent Documents 1 to 4). .

JP-B-51-38105 JP-A-64-24880 JP-A-8-183950 JP-A-10-183109

  By the way, in recent years, brine (cooling liquid composition) used in the refrigeration equipment has been increased in size with the increase in size of the refrigeration equipment. However, an aqueous solution of a saturated monohydric alcohol having one to three carbon atoms constituting one molecule may be a dangerous substance under the Fire Service Law depending on its composition (particularly the alcohol concentration) and the type of additive added. (Alcohols, petroleums). Although the storage method and transportation method of the dangerous materials under the Fire Service Act are strictly defined, the use of alcohol aqueous solution corresponding to the dangerous materials under the Fire Service Act as brine (coolant composition) is not permitted. The large amount also puts a heavy burden on the user of the refrigeration equipment.

  Specifically, Patent Document 1 (Japanese Patent Publication No. 51-38105) discloses a dipping method characterized in that a predetermined amount of salt is added to an aqueous ethanol solution so that the freezing point is kept at approximately −30 ° C. or lower. A frozen liquid is disclosed. However, according to the description of the document, the immersion frozen liquid disclosed therein has a risk that it becomes easy to catch fire when the ethanol concentration is increased. It is very difficult in practice to be able to use at a temperature lower than −40 ° C. in an ethanol concentration range that does not correspond to dangerous substances (alcohols). In addition, since the salt is added to the immersion frozen liquid, the inside of the brine circuit may be corroded.

  Further, Patent Document 2 (Japanese Patent Application Laid-Open No. 64-24880) discloses that an object to be frozen is reduced from approximately -72 ° C by adding a citric acid derivative as a freezing point depressant to an aqueous solution having an ethanol concentration of 60% or less. A low-temperature brine that can be kept at -40 ° C. is disclosed. However, citric acid derivatives are dangerous substances under the Fire Service Law, and low-temperature brine composed of the composition disclosed in the same document is a fire safety law. There is a problem of being regulated as dangerous goods.

  Further, Patent Document 3 (Japanese Patent Application Laid-Open No. 8-183950) and Patent Document 4 (Japanese Patent Application Laid-Open No. 10-183109) disclose a cooling liquid composition and a brine composition that maintain fluidity even at a low temperature. An aqueous solution containing a lower alcohol and a glycol has been proposed. However, glycols are also classified as dangerous substances under the Fire Service Law, and even if the coolant composition or the brine composition is composed of the composition disclosed in each of those documents, it is a dangerous substance under the Fire Service Law. There is an inherent problem of being regulated.

  Here, in the Fire Defense Law, an aqueous solution having an ethanol concentration of less than 60% by weight (an aqueous solution containing no other components other than ethanol. Hereinafter, the ethanol aqueous solution referred to in this paragraph does not contain other added components. ) Is considered a non-dangerous substance, but the freezing temperature in an aqueous solution having an ethanol concentration of less than 60% by weight is at least -43 ° C. More specifically, the freezing temperature in a 50% by weight aqueous ethanol solution is -38 ° C, and the freezing temperature in a 40% by weight aqueous ethanol solution is -30 ° C. Therefore, an aqueous solution containing only ethanol, which is not regulated as a dangerous substance under the Fire Service Law (non-dangerous substance), is a coolant composition used in a low temperature range of about -30 ° C to -50 ° C. Are extremely difficult to use or cannot be used.

  The present invention has been made in view of such circumstances, and a problem to be solved is that a coolant capable of sufficiently exhibiting a function as a brine even in a low temperature range of −30 ° C. or less. It is to provide a composition.

  The present invention provides a cooling liquid composition characterized by containing, as a third component, potassium sorbate, together with ethanol, a first component, and water, a second component, in order to solve such problems. It is assumed that.

  In addition, the cooling liquid composition according to the present invention preferably further contains sodium acetate as the third component.

  In addition, in the cooling liquid composition according to the present invention, the content of the ethanol as the first component is preferably 40% by weight or more and less than 60% by weight, and the content of the third component is preferably less than 10% by weight. It is.

  Furthermore, in the coolant composition of the present invention, more preferably, the weight ratio of the third component, potassium sorbate and sodium acetate, is potassium sorbate: sodium acetate = 1: 8 to 8: 1. .

  Thus, in the cooling liquid composition according to the present invention, together with ethanol as the first component and water as the second component, potassium sorbate is contained as the third component, and the freezing point of potassium sorbate is lowered. By the action, even in a low temperature range of −30 ° C. or less, a low viscosity state is maintained without freezing, so that it can function as a cooling liquid.

  By the way, the cooling liquid composition according to the present invention (hereinafter, also simply referred to as a composition) contains ethanol as one of the essential components. In the present invention, the higher the content of ethanol, the better the function as a coolant composition (the freezing temperature of the composition decreases). Alcohols). If the content of ethanol is small, the function as a cooling liquid may not be sufficiently exhibited. Therefore, in the coolant composition according to the present invention, the content of ethanol is preferably 40% by weight or more and less than 60% by weight, more preferably 42.5% by weight or more and 55% by weight or less. Most preferably, it is 42.5% by weight or more and 50% by weight or less.

  In the present invention, water that functions as a solvent is the second essential component. In preparing the coolant composition according to the present invention, deionized water, distilled water, and the like, which have been conventionally used for preparing the coolant composition, can be used in the same manner as in the related art.

  In the present invention, a great technical feature resides in that potassium sorbate is contained as a third component together with ethanol as a first component and water as a second component. That is, the addition of potassium sorbate effectively lowers the freezing point of the cooling liquid composition, and thus, even in a low temperature range of -30 ° C or lower, the content ratio of each component in the composition When appropriately adjusted, even in a low temperature range of about −40 ° C. to −50 ° C., the coolant composition according to the present invention does not solidify (freeze), and is sufficiently used as a brine in a refrigeration facility. It can work.

  Further, it is preferable that the cooling liquid composition of the present invention contains sodium acetate in addition to the above-mentioned potassium sorbate as the third component. By adding sodium acetate together with potassium sorbate, it is possible to enjoy the same or higher freezing point lowering action as when potassium sorbate is used alone, and appropriately adjust the content ratio of each component in the composition. In this case, it can be used as brine even in a low temperature range of about -40 ° C to -50 ° C.

  Here, the content ratio of the third component in the present invention, more specifically, 1) when potassium sorbate alone is used, 2) the content ratio of potassium sorbate in the entire composition, and 2) potassium sorbate and sodium acetate When used in combination, the content of the two compounds in the total composition is preferably less than 10% by weight. In the present invention, assuming that the content of the third component is 10% by weight or more, the Fire Service Law, the regulations on dangerous goods regulations, and the Fire Defense Law No. 57 of 1990, "Restrictions on alcohols" (prefectural fire departments) If the information is compared with the Director of Dangerous Goods Regulations Section, it is classified as dangerous goods (petroleum) and may be subject to regulation. In the present specification, the dangerous goods under the Fire Service Law refer to the Fire Service Law, the rules for dangerous goods regulations, and the Fire Defense Law No. 57, dated May 22, 1990, “Restrictions on Alcohols”. (Dangerous goods such as alcohols and petroleums, etc., which are determined in accordance with the Dangerous Goods Regulations Section of the Prefectural Fire Department.)

  When potassium sorbate and sodium acetate are used in combination as the third component of the present invention, the use ratio of these components is potassium sorbate: sodium acetate = 1: 8 to 8: 1 by weight. And more preferably potassium sorbate: sodium acetate = 4: 5 to 6: 3. By using potassium sorbate and sodium acetate together in such a ratio, the freezing point of the coolant composition can be reduced more effectively, and the coolant composition that can be used as brine even in a lower temperature region. It is possible to get things.

  The cooling liquid composition according to the present invention may contain various additives conventionally used in the cooling liquid composition, in addition to the components described above, as long as the object of the present invention is not impaired. It is possible.

  As such an additive, first, a compound having a freezing point lowering ability can be exemplified as an auxiliary component of the third component (potassium sorbate, sodium acetate) which is a freezing point depressant. Specifically, organic solvents such as ethylene glycol, propylene glycol and citric acid derivatives, salts of carboxylic acids such as formic acid, acetic acid, lactic acid and propionic acid, alkaline agents such as potassium hydroxide and sodium hydroxide, nitric acid, sulfuric acid and the like. Salts of inorganic acids such as phosphoric acid can be exemplified, and one or more of these compounds can be selected and used as necessary.

  Further, the cooling liquid composition of the present invention can also contain a pH adjuster. Examples of the pH adjuster that can be used in the present invention include organic acids such as benzoic acid and salts thereof, inorganic acids such as phosphoric acid and salts thereof, in addition to sodium hydroxide and potassium hydroxide.

  Further, a rust preventive may be added as necessary. Specifically, rust inhibitors for copper such as 1H-1,2,3-benzotriazole, methylbenzotriazole, and thiabendazole; rust inhibitors for iron such as sodium benzoate, sodium nitrite, potassium nitrate, and potassium phosphate; From among various kinds of rust preventives for aluminum, it is possible to select and use one or more kinds as necessary.

  When various additives such as those described above are used in the present invention, the content ratio of the total amount obtained by adding the amount of the third component (potassium sorbate, sodium acetate) to the amount of the additive used Is preferably less than 10% by weight of the coolant composition. If the content of the total amount is 10% by weight or more, it may fall under the Fire Service Act dangerous substances (petroleum) depending on the flash point of the entire coolant composition, etc. If it falls under), it will be subject to the regulations of the Fire Service Law.

  Further, the coolant composition according to the present invention is preferably prepared so that the amount of the flammable liquid contained therein is less than 60% by weight. This is because a coolant composition having a flammable liquid amount of 60% by weight or more corresponds to dangerous substances (alcohols) under the Fire Service Law and is regulated by the Fire Service Law. The amount of the flammable liquid contained in the coolant composition can be measured in accordance with Fire Danger No. 64, "Measurement of Amount of Flammable Liquid", dated July 4, 1989.

  Further, when a compound corresponding to a dangerous substance under the Fire Service Act is used as an additive, the content of the compound is preferably less than 10% by weight of the amount of ethanol contained in the coolant composition. If the content ratio is 10% by weight or more, the coolant composition may fall under dangerous goods (petroleum) under the Fire Service Law, depending on the type of compound, and may be classified as dangerous goods (petroleum) under the Fire Service Law. If this is the case, it will be subject to regulations under the Fire Service Law.

  The coolant composition according to the present invention containing the above-described components can be prepared and manufactured according to the same method as in the related art. For example, ethanol and a third component (potassium sorbate alone or potassium sorbate and sodium acetate) and, if necessary, other components are added to water as a solvent in such an amount that each has a desired composition. Then, the desired cooling liquid composition can be obtained by mixing.

  And in the cooling liquid composition obtained in this way, from the place containing potassium sorbate (and sodium acetate) as the third component together with the first component ethanol and the second component water. The solidification point of the cooling liquid composition is effectively lowered by the third component, and thus, even in a low temperature range of -30 ° C or lower, the content ratio of each component in the composition was appropriately adjusted. In this case, even in a low temperature range of about −40 ° C. to −50 ° C., the coolant composition according to the present invention can sufficiently function as a brine in a refrigeration facility without freezing (freezing). .

  Hereinafter, some examples of the present invention will be shown to clarify the present invention more specifically. However, the present invention is not limited by the description of such examples. Needless to say. Further, in addition to the following examples, the present invention may further include various changes and modifications based on the knowledge of those skilled in the art without departing from the spirit of the present invention, in addition to the specific description described above. , Improvements and the like can be added.

First, cooling liquid compositions (test liquid, comparative liquid, and reference liquid) having the respective compositions shown in Tables 1 to 5 below were prepared, and 100 mL of the prepared cooling liquid composition was placed in a glass container (volume: 140 mL). . The glass container containing the cooling liquid composition is stored for 4 weeks in a freezer set at -30 ° C, -40 ° C, -45 ° C, and -50 ° C, and the glass container after the storage. The state of the cooling liquid composition inside was visually observed and evaluated according to the following criteria. As a freezer, Sanyo Blast Freezer (product number: MDF-U460BR, cooling performance: -50 ° C, temperature control range: -15 ° C to -95 ° C) manufactured by Sanyo Electric Co., Ltd. was used. The evaluation results for each cooling liquid composition are also shown in Tables 1 to 5 below.
-Evaluation criteria-
A: No freezing in appearance is observed.
B: Thin crystals or freezing are observed on the liquid surface in appearance.
C: Crystals or freezing are observed on the liquid surface and in the liquid in appearance.
D: Some degree of freezing is observed in the entire appearance.
E: In appearance, freezing is clearly observed throughout.

  The following summarizes the evaluation of the cooling liquid composition for each storage temperature.

-Storage temperature: appearance evaluation at -50 ° C-
1) The ethanol concentration is 50% by weight, the concentration of the third component is 9% by weight, that is, the total content of both components is less than 60% by weight, and potassium sorbate and sodium acetate as the third components are The test solution containing potassium sorbate: sodium acetate in a ratio of 4: 5 to 7: 2 in terms of weight ratio, and further containing thiabendazole, which is a rust preventive agent, in a ratio of 0.01% by weight, has an appearance. The above freezing was not recognized (test solution No. 4 to 7. See Table 1).
2) The ethanol concentration is 47.5% by weight, the concentration of the third component is 9% by weight, that is, the total content of both components is less than 60% by weight, and the third components potassium sorbate and acetic acid are used. In a test solution containing sodium in a weight ratio of potassium sorbate: sodium acetate = 4: 5 to 6: 3, and a rust preventive thiabendazole in a ratio of 0.01% by weight, No freezing on the appearance was observed (test liquid Nos. 13 to 15. See Table 2).

-Storage temperature: -45 ° C appearance evaluation-
1) The ethanol concentration is 50% by weight, the concentration of the third component is 9% by weight, that is, the total content of both components is less than 60% by weight, and potassium sorbate and sodium acetate as the third components are In terms of weight ratio, potassium sorbate: sodium acetate = 1: 8 to 8: 1, or only potassium sorbate as the third component, and thiazendazole, a rust preventive agent, of 0.01%. In the test solution contained at a ratio of% by weight, freezing in appearance was not observed (test solution Nos. 1 to 9; see Table 1).
2) The concentration of ethanol is 47.5% by weight and the concentration of the third component is 9% by weight, that is, the total content of both components is less than 57.5% by weight, and the third component is potassium sorbate. And sodium acetate in a weight ratio of potassium sorbate: sodium acetate = 1: 8 to 8: 1 or only potassium sorbate as the third component, and furthermore, a rust inhibitor In the test solution containing 0.01% by weight of thiabendazole, freezing in appearance was not observed (test solutions Nos. 10 to 18; see Table 2).
3) The ethanol concentration is 45% by weight and the concentration of the third component is 9% by weight, that is, the total content of both components is less than 55% by weight, and potassium sorbate and sodium acetate as the third components are In a test solution containing a weight ratio of potassium sorbate: sodium acetate = 4: 5 to 5: 4 and further containing thiabendazole, which is a rust preventive agent, in a ratio of 0.01% by weight, the appearance is as follows. The above freezing was not observed (test solution No. 22, 23; see Table 3).
4) The concentration of ethanol is 42.5% by weight and the concentration of the third component is 9% by weight, that is, the total content of both components is less than 52.5% by weight, and the third component is potassium sorbate. And sodium acetate in a weight ratio of potassium sorbate: sodium acetate = 4: 5, and a test solution containing thiabendazole as a rust inhibitor in a ratio of 0.01% by weight, No freezing on the appearance was observed (test solution No. 31; see Table 4).

-Storage temperature: Appearance evaluation at -40 ° C-
1) The ethanol concentration is 50% by weight, the concentration of the third component is 9% by weight, that is, the total content of both components is less than 60% by weight, and potassium sorbate and sodium acetate as the third components are In terms of weight ratio, potassium sorbate: sodium acetate = 1: 8 to 8: 1, or only potassium sorbate as the third component, and thiazendazole, a rust preventive agent, of 0.01%. In the test solution contained at a ratio of% by weight, freezing in appearance was not observed (test solution Nos. 1 to 9; see Table 1).
2) The concentration of ethanol is 47.5% by weight and the concentration of the third component is 9% by weight, that is, the total content of both components is less than 57.5% by weight, and the third component is potassium sorbate. And sodium acetate in a weight ratio of potassium sorbate: sodium acetate = 1: 8 to 8: 1 or only potassium sorbate as the third component, and furthermore, a rust inhibitor In the test solution containing 0.01% by weight of thiabendazole, freezing in appearance was not observed (test solutions Nos. 10 to 18; see Table 2).
3) The ethanol concentration is 45% by weight and the concentration of the third component is 9% by weight, that is, the total content of both components is less than 55% by weight, and potassium sorbate and sodium acetate as the third components are In terms of weight ratio, potassium sorbate: sodium acetate = 1: 8 to 8: 1, or only potassium sorbate as the third component, and thiazendazole, a rust preventive agent, of 0.01%. In the test liquid contained at a ratio of% by weight, freezing in appearance was not observed (test liquid Nos. 19 to 27; see Table 3).
4) The concentration of ethanol is 42.5% by weight and the concentration of the third component is 9% by weight, that is, the total content of both components is less than 52.5% by weight, and the third component is potassium sorbate. And sodium acetate in a weight ratio of potassium sorbate: sodium acetate = 1: 8 to 8: 1 or only potassium sorbate as the third component, and furthermore, a rust inhibitor In the test solution containing 0.01% by weight of thiabendazole, freezing in appearance was not observed (test solutions Nos. 28 to 36; see Table 4).
5) The concentration of ethanol is 40% by weight, the concentration of the third component is 9% by weight, that is, the total content of both components is less than 50% by weight, and potassium sorbate and sodium acetate as the third components are In terms of weight ratio, potassium sorbate: sodium acetate = 1: 8 to 8: 1, or only potassium sorbate as the third component, and thiazendazole, a rust preventive agent, of 0.01%. In the test solution contained at a ratio of% by weight, freezing in appearance was not observed (test solution Nos. 37 to 45; see Table 5).

-Storage temperature: Appearance evaluation at -30 ° C-
Test liquid No. No freezing in appearance was observed in all of Nos. 1 to 45, Comparative Solutions 1 to 10, and Reference Solution 1.

  Thus, in the cooling liquid composition according to the present invention, even in a low temperature range of −30 ° C. or less, or in a further low temperature range of −40 ° C. to −50 ° C. depending on the composition of the composition. , Freezing is not recognized, and it is recognized that it can function sufficiently as brine in the refrigeration facility.

  Next, the viscosity, flash point and combustion point of the seven types of cooling liquid compositions shown in Table 6 below were measured. The viscosity was measured using a B-type viscometer. The measurement of the flash point was performed using the test liquid No. Measurements of 5, 14, 23, 32 and Reference Liquid 1 were conducted using a tag-closed flash point measuring instrument, and Reference Liquid 2 and Reference Liquid 3 were conducted using a Cleveland open flash point measuring instrument. Was performed using an open tag flash point measuring device. At the same time, it was determined whether each of the cooling liquid compositions corresponded to dangerous goods under the Fire Service Law. The results are shown in Table 6 below.

  As is clear from the results in Table 6, the coolant composition (test solutions Nos. 5, 14, 23, and 32) according to the present invention has a low viscosity at −40 ° C. It was recognized that the substance did not fall under the category of dangerous goods. On the other hand, although Reference Liquid 1 consisting of an aqueous solution containing only ethanol had a low viscosity, it was classified as a dangerous substance under the Fire Service Law, and its handling was confirmed to be regulated by the Fire Service Law. The reference liquid 2 composed of an aqueous solution containing only ethylene glycol and the reference liquid 3 composed of an aqueous solution containing only propylene glycol have a viscosity at −40 ° C. It was very high, and it was confirmed that the composition was difficult to use as a cooling liquid composition at -40 ° C.

  Further, the following experiment was conducted to confirm the corrosiveness of the coolant composition according to the present invention to metals. In the following description, "JIS" means JIS-K-2234: 2006 "antifreeze".

  First, three types of cooling liquid compositions (test liquids No. 5a, 23a, 41a) were prepared. Test liquid No. 5a is prepared water (prepared water defined by JIS; 148 mg of sodium sulfate, 165 mg of sodium chloride and 138 mg of sodium hydrogen carbonate dissolved in 1 L of water) instead of deionized water. Except that the test liquid No. 5 (see Table 1). Similarly, test liquid No. 23a is the test liquid No. 23 (see Table 3) and test solution no. Test liquid No. 41a is test liquid No. 41a. 41, and each having the same composition, except that the above-prepared water was used in place of deionized water.

  In addition, test pieces made of aluminum casting, cast iron, steel, brass, solder, and copper were prepared as metal test pieces. The dimensions of the test piece were the size specified in JIS (length: about 50 mm × width: about 25 mm).

About 200 mL of the cooling liquid composition was placed in a beaker, and then a metal test piece was charged, and a metal corrosion test was performed at 25 ± 2 ° C. for 336 hours. The total surface area (cm ² ) of the metal test piece before the test and the weight (mg) of the metal test piece before and after the test were measured, and the mass change (mg / cm ² ) was calculated from the following equation. A metal corrosion test was performed using six types of metal test pieces, and the mass change in each test was determined. The results are shown in Table 7 below. The results of measuring the pH of the coolant composition before and after the metal corrosion test and the amount of change in pH before and after the test are also shown in Table 7 below.
C = (m ₂ −m ₁ ) / S (expression)
In the above formula, C is the mass change (mg / cm ² ), m ₁ is the mass (mg) of the test specimen before the test, m ₂ is the mass (mg) of the test specimen after the test, and S is the test mass. The total surface area (cm ² ) of the previous test specimen is indicated in each case.

  As is clear from the results in Table 7, it was confirmed that the coolant composition according to the present invention satisfies the JIS standard 1 type, and that the metal corrosiveness was low.

Claims (4)

  A cooling liquid composition comprising, as a third component, potassium sorbate together with ethanol as a first component and water as a second component.   The coolant composition according to claim 1, further comprising sodium acetate as the third component.   3. The cooling liquid composition according to claim 1, wherein the content of the ethanol as the first component is 40% by weight or more and less than 60% by weight, and the content of the third component is less than 10% by weight. . The cooling liquid composition according to claim 2 or 3, wherein the weight ratio of the third component, potassium sorbate and sodium acetate, is potassium sorbate: sodium acetate = 1: 8 to 8: 1.