JP6106090B2 - Cheese and method for producing the same - Google Patents

Description

  The present invention relates to an aerated natural cheese having a novel texture. Specifically, after pulverizing at least one or more types of hard and / or semi-hard natural cheese, the resulting cheese is kneaded without heating and without melting, so that it melts well in the mouth and swallows It is based on the fact that a new natural cheese product having a light texture that is not a problem is obtained.

  Cheese is an excellent food in terms of nutrition because it contains abundant milk-derived proteins and calcium. In particular, it is effective for nutritional supplementation for growing children and calcium supplementation for women and elderly people who are concerned about osteoporosis. Cheese is made by coagulating milk, cream, buttermilk or a mixture of these, partially excluding whey from the curd, and ripening natural cheese as needed, and natural cheese with molten salt and as needed In addition, it is roughly classified into processed cheeses obtained by adding auxiliary materials, heating and melting and emulsifying.

  In general, natural cheese is roughly divided into hard cheese, semi-hard cheese, soft cheese, etc., and further classified into 2000 types in the world when classified according to differences in the composition of raw milk, types of lactic acid bacteria and fermentation conditions, ripening conditions, etc. The above cheese is manufactured. Although these natural cheeses are preferred for their specific flavors, the texture is particularly hard and semi-hard cheeses, with many varieties that have a stiff and battered hard texture, and have good melt-dissolving physical properties. It is often unfavorable by consumers who tend to be oriented. Moreover, although it is satisfying in terms of nutrition for the elderly and those who have difficulty swallowing, it is a food texture that is difficult to chew and swallow, and is a food that is avoided to eat. For this reason, natural cheeses with good melting properties suitable for those who have difficulty swallowing are often desired. Rather than converting hard cheese and semi-hard cheese into processed cheese using molten salt, the demand for natural cheese is expected to increase significantly if it is easily melted in the mouth and eaten as it is. It is done.

  Processed cheeses, on the other hand, convert the insoluble calcium paracaseinate in natural cheese into soluble sodium paracaseinate by the action of molten salt, and when cooled, the texture is smoother and softer than natural cheese. However, many consumers dislike this point because it is sticky in the mouth and has a texture that easily adheres to teeth. In addition, with the recent increase in health consciousness, preference is shifting to low sodium and low phosphorylation, and there is a tendency to restrict the use of molten salts mainly composed of sodium salts and phosphates.

  In hard cheese, semi-hard cheese, without changing the composition of ingredients by adding water or cream, etc., as a technology to adjust the texture so that it is easy to eat, by the applicant, the cheese is crushed and pressed A manufacturing method of cheese to be reshaped has been proposed (Patent Document 1). In this method, a tissue that is easily crushed in the mouth was obtained as it is, but it has not yet been possible to obtain a mouth melt that does not cause trouble in swallowing. Moreover, in patent document 1, the binder was added in the process of pressing and solidifying, and the deliciousness which natural cheese originally had could not be tasted as it was.

On the other hand, after the present applicant grinds hard and hard-to-eat natural cheese such as special hard cheese, hard cheese, and semi-hard cheese with a meat chopper or the like, the flexibility is 7.5 mm or less and the adhesiveness is 4.0. A cheese having a new and improved texture that is easy to crush in the mouth and has a texture that is not sticky in the mouth by press-reforming so as to have physical properties of × 10 ⁻³ N · m or less and its production A method has been proposed (Patent Document 2). In this method, as in Patent Document 1, even if the component composition is not greatly changed by increasing moisture or fat, a mouthfeel that is easy to break in the mouth and is not sticky in the mouth is obtained. A rough texture remained in the mouth, which was not satisfactory in terms of melting in the mouth.
In addition, a method has been proposed in which cheese and nitrogen gas are mixed, kneaded, cooled and compressed to be extruded to obtain a soft texture cheese (Patent Document 3). Until now, there is no description of pulverization and kneading.

  Furthermore, a method for obtaining aerated cheese by adding alkali metal lactalbumin phosphate to agglomerated cheese while stirring while aeration of gas under high pressure and then cooling by releasing under normal pressure. (Patent Document 4), a method in which an inert gas is passed through a heated and melted cheese to make it foam, and after adjusting to a predetermined viscosity, the volume is expanded by holding under vacuum (Patent Document 5). And a method of obtaining processed cheese in which minute bubbles are dispersed by adding native gellan gum and heating and melting with stirring (patent document 6), by melting and solidifying cheese added with carbonates and the like In addition, a method for forcibly aeration of cheese, such as a method of foaming carbonates to obtain aerated cheese (Patent Document 7) has also been proposed. Problems such as the need to highly control the amount of gas to be added and the pressure difference (Patent Documents 4 and 5), and the natural flavor of natural cheese will change because special additives are required. The problem (Patent Documents 6 and 7) is inevitable.

International Publication WO2010 / 008056 International publication WO2011 / 087086 Japanese Laid-Open Patent Publication No. 1-291748 JP 50-95452 A JP 58-175437 A JP 2003-47403 A JP-A-62-138137

  The present invention has been made to solve the above-mentioned problems found by the present inventors. Therefore, the problem to be solved by the present invention is to maintain the flavor of natural cheese in a simpler manner. An object of the present invention is to provide a new natural cheese or processed cheese food with a new texture that improves the meltability of the mouth by eliminating the rough texture and is easy to eat even by those who have difficulty swallowing.

  The inventors of the present invention have sought to solve the problem by repeated kneading with a meat chopper while solving the above problems, but the rough texture is eliminated, but there is much stickiness and the mouth melts. The knowledge that it cannot be improved was obtained. However, when further kneading was continued until further whitening with a meat chopper or the like in further research, we encountered an unexpected fact that the stickiness disappeared and a mouthfeel good texture was obtained. Based on this fact, hard and / or semi-hard natural cheese is forced to contain gas and uniformly dispersed to obtain a cheese with physical properties that are brittle and well melted without a rough texture. As a result of further research, the present invention has been completed.

Accordingly, the present invention relates to the following [1] to [8]:
[1] A method for producing an aerated natural cheese, wherein one or two or more hard and / or semi-hard natural cheeses are mechanically pulverized and kneaded until a white color is produced. Including said method.
[2] The method according to [1], further comprising molding.
[3] Air-containing natural cheese obtained by the method according to [1] or [2].
[4] The aerated natural cheese according to [3], which has a porosity of 5 to 60%.
[5] The aerated natural cheese according to [3] or [4], wherein the density is 1.0 g / cm ³ or less.
[6] The aerated natural cheese according to any one of [3] to [5], wherein an average particle size of the cheese structure is less than 200 μm.
[7] A method for producing a processed cheese food, the method comprising adding and mixing an auxiliary material to the method according to [1] 1.
[8] A processed cheese food obtained by the method according to [7].

The present invention also relates to the following [A1] to [A8]:
[A1] Aerated natural cheese in which at least one kind of hard and / or semi-hard natural cheese is forced to contain gas,
[A2] The aerated natural cheese according to [A1], wherein the porosity is 5 to 60%,
[A3] Aerated natural cheese according to [A1], wherein the density is 1.0 g / cm ³ or less,
[A4] The aerated natural cheese according to [A1], wherein an average particle size of the cheese structure is less than 200 μm,
[A5] The above [A1] to [A4], wherein at least one kind of hard and / or semi-hard natural cheese is mechanically pulverized and kneaded to contain gas. A method for producing aerated natural cheese containing bubbles,
[A6] The above-mentioned [A1] to [A5], wherein at least one kind of hard and / or semi-hard natural cheese is mechanically pulverized and kneaded to contain a gas forcibly, and is molded. ] The manufacturing method of the aerated natural cheese containing the bubble of description,
[A7] A cheese processed food produced using the aerated natural cheese according to [A1] to [A4] as a raw material.
[A8] A method for producing the cheese processed food according to [A7].

  The aerated natural cheese of the present invention loses the crunchy and tattered texture that traditional natural cheese had, and it collapses brittlely when put in the mouth, melts quickly, and the touch is very Natural cheese with a light texture and easy to eat even for those with difficulty swallowing. Further, the aerated natural cheese of the present invention can be produced without using special equipment and additives peculiar to the present invention and without undergoing a heating and melting step. Furthermore, it can confirm that the aerated natural cheese of this invention has the above preferable food texture by confirming the change of the color tone of cheese, without making a special measurement.

  Hereinafter, the present invention will be described in detail, but the present invention is not limited to the individual forms described below.

The raw material for producing the “aerated natural cheese” of the present invention contains at least one selected from the group consisting of hard and / or semi-hard natural cheese.
As an example of hard cheese, although this invention is not limited to this, Emmental cheese, Gruyere cheese, Parmesan cheese, Gouda cheese, Cheddar cheese, Edam cheese, Conte cheese, Mimolette cheese, etc. are mentioned. Examples of semi-hard cheeses include, but are not limited to, maribo cheese, samso cheese, raclette cheese, mozzarella (mozzarella) cheese, string cheese, skim cheese, and the like. These may use a single natural cheese, or may combine a plurality of natural cheeses as a raw material.

  As a raw material for producing the “aerated natural cheese” of the present invention, soft natural cheese may be used when a plurality of natural cheeses are used in combination. Examples of soft natural cheese include, but are not limited to, feta cheese, cream cheese, fromage blanc, mascarpone, and the like.

  The hard and / or semi-hard natural cheese that is a raw material for producing the “aerated natural cheese” of the present invention has a moisture content of 25% or more and 55% or less for the hard cheese and semi-hard cheese as the composition of the raw cheese. The protein in the solid content is preferably 5% or more and less than 80%, more preferably the water content is 30% or more and 55% or less, and the protein in the solid content is 10% or more and less than 70%. In the case of skim cheese having a solid content of 80% or more, casein in the cheese thickens by kneading to form a bowl-shaped cheese structure, and the physical properties as in the present invention cannot be produced. Moreover, when the water | moisture content in raw material cheese exceeds 55%, since it contains many water | moisture contents, it becomes sticky and does not become a brittle physical property which collapses easily in the mouth.

  “Whitening” in the present invention means that the color of the hard and / or semi-hard natural cheese that is the raw material is closer to white from the conventional colors such as orange, yellow, milky white, etc. Changes can be confirmed. For example, whitening can also be determined by the L value, and the difference between the L value of the hard and / or semi-hard natural cheese that is the raw material and the L value of the aerated natural cheese is preferably 3.0 or more, More preferably 4.0 or more, still more preferably 5.0 or more, and even more preferably 6.0 or more can be recognized as whitening.

  The “aerated natural cheese” of the present invention has a porosity of 5 to 60%, preferably 7 to 55%, more preferably 15 to 55%. By having such a porosity, it is possible to have features such as being brittle when it is put in the mouth, melting in the mouth quickly, and being very light to the touch. If the porosity of the “aerated natural cheese” of the present invention is lower than 5%, it is not possible to obtain a feature that is brittle even when put in the mouth. If the porosity is higher than 60%, the shape can be maintained during refrigerated distribution. It will disappear.

The “aerated natural cheese” of the present invention has a density of 1.0 g / cm ³ or less, preferably 0.5 to 1.0 g / cm ³ , more preferably 0.6 to 0.9 g / cm ³ . When the density of the “aerated natural cheese” of the present invention is less than 0.5 g / cm ³ , the structure becomes brittle and easily collapsed, and after discharging the aerated natural cheese from meat choppers, extruders, pasta machines, etc., the shape is not impaired. It becomes difficult to cut and wrap. On the other hand, when the density exceeds 1.0 g / cm ³ , the characteristics of the present invention such as quick melting in the mouth and very light touch cannot be obtained.

  The “aerated natural cheese” of the present invention is a state in which a hard and / or semi-hard natural cheese as a raw material is cut into a dice shape or kneaded using a meat chopper or the like to have a gap between the cheeses. By mechanically pulverizing and kneading, the natural cheese structure is finely pulverized and gas is forcibly included. At this time, cheese particles in the cheese structure are destroyed, and the average particle size of fat globules and proteins is reduced. Therefore, the “aerated natural cheese” of the present invention has an average particle size of cheese tissue of less than 200 μm, preferably less than 100 μm, more preferably less than 60 μm.

  When the average particle size of the cheese structure of the “aerated natural cheese” of the present invention is 200 μm or more, the rugged and tattered texture of conventional natural cheese cannot be lost. The average particle diameter is measured with a diffraction particle size distribution meter using laser light for the homogenized mixed raw material, and the average particle diameter is a value calculated from the particle size distribution (specifically Specifically, the regression equation is obtained from the logarithm of the particle diameter and the cumulative number, and the cumulative particle number is 50% on the regression equation).

  The “aerated natural cheese” of the present invention mechanically pulverizes and kneads hard and / or semi-hard natural cheese as a raw material to finely pulverize the structure of natural cheese and forcibly emit gas. Contain.

The method of forcibly containing gas of the “aerated natural cheese” of the present invention is not particularly limited as long as the gas is uniformly dispersed as bubbles. As the means, for example, a gas is forcibly contained by kneading with a meat chopper, an extruder, a pasta machine or the like.
For example, a gas is forcibly contained until the natural cheese is whitened by repeating pulverization and kneading a plurality of times with a meat chopper, preferably 3 times or more, more preferably 5 times or more, and even more preferably 8 times or more. Can do. Further, natural cheese is obtained by pulverizing and kneading using an extruder at a high rotational speed, preferably higher than 100 rpm, more preferably higher than 110 rpm, and even more preferably higher than 120 rpm. The gas can be forcibly contained until whitening occurs.

  Although the conditions of pulverization and kneading depend on the type of raw material natural cheese used and the combination thereof, the texture of the aerated natural cheese can be estimated by evaluating the color tone. Therefore, even if the type of raw natural cheese and the combination thereof are changed, it is possible to easily obtain a preferable texture by checking the color tone (visually) without measuring the density and the average particle diameter of the cheese structure each time. It can confirm that the aeration natural cheese which has is obtained.

  The gas in the “aerated natural cheese” of the present invention is characterized by being contained as fine bubbles in the cheese. It is preferable that a plurality of bubbles exist in the natural cheese, and it is particularly preferable that the bubbles are uniformly dispersed in the natural cheese. Most preferably, the bubbles are uniformly dispersed among the cheese particles of the natural cheese. is there. As a result, the mouthfeel is good and it can have a light texture.

  The gas in the “aerated natural cheese” of the present invention is not particularly limited as long as it does not deteriorate the flavor and quality of the hard and / or semi-hard natural cheese used as a raw material, but may be intended for long-term storage. For example, it is preferable to use aseptic air, inert gas such as nitrogen gas, carbon dioxide gas or the like in terms of suppressing oxidation during storage and propagation of mold and the like and not easily absorbed into cheese.

  The “aerated natural cheese” of the present invention is obtained by finely crushing the structure of natural cheese and bringing it into an aerated state, and the degree of aeration may be small.

  The “aerated natural cheese” of the present invention is a soft physical property that is easy to mold when the process of forcibly containing gas by mechanically pulverizing and kneading hard and / or semi-hard natural cheese is completed. Have Thereby, it can be processed into a desired shape or by adding other foods or seasonings.

The “aerated natural cheese” of the present invention does not substantially require an additive such as a molten salt. Here, “substantially no additives” means that in the present invention, a hard and / or semi-hard natural material is basically used as a raw material in order to obtain a texture that melts in the mouth and does not bother swallowing. Means that only cheese is needed. However, it is possible to add additives such as soft cheese and / or a stabilizer in order to adjust the melting, shape retention, moldability, and the like. In addition, in this invention, it is preferable to use only hard and / or semi-hard natural cheese as a raw material, and not to use additives other than hard and / or semi-hard natural cheese.

  A cheese processed food can be obtained by adding and mixing auxiliary materials as necessary to the “aerated natural cheese” of the present invention. Examples of the auxiliary materials to be added and mixed include foods and nutrition enhancers for imparting flavor and nutritional functions. Here, examples of the food as an auxiliary material include seasonings, spices, kneaded products such as herbs, nuts and strawberries, and other foods, but the present invention is not limited to the following examples. . Specific examples of seasonings include sugar, salt, soy sauce, miso, sauce, and vinegar. Specific examples of spices include cumin seed, caraway seed, pepper, and paprika. Specific examples of herbs include basil and parsley. Specific examples of nuts include almond, cashew nut, hazelnut, pistachio, peanut and the like. Examples of other foods include processed meat products such as bacon chips, dried vegetables, dried fruits, concentrated vegetables such as concentrated tomatoes and concentrated lemon juice, concentrated fruit juices, foods such as yogurt, jam and paste, curry powder, etc. Examples include seasoning. Examples of nutrient enhancers include mineral enhancers such as calcium and iron, vitamins, intestinal agents such as oligosaccharides and dietary fibers, and the like.

  EXAMPLES Hereinafter, although an Example is given and this invention is demonstrated, this invention is not limited by this. In addition, in this specification,% display shows the mass%, when not specifying clearly.

[Example 1]
Cheddar cheese (raw wood cheddar cheese (20 kg block cheese for raw material)) was pulverized using a meat chopper (manufactured by NANTUNE Co., Ltd.). The pulverized cheddar cheese was again pulverized and kneaded with a meat chopper (manufactured by Nantsune Corporation, meat chopper MD-22K), and this operation was performed nine times in total. (Along with the initial crushing process, the mechanical crushing and kneading process by a meat chopper was repeated 10 times.) It was observed that the resulting cheese had a white color change and was aerated. This sample was filled into a rectangular parallelepiped molding frame, refrigerated at 5 ° C. or lower and stored overnight to obtain cheese.
The obtained cheese had a texture that was brittle and easy to break, and had a light texture that quickly melted in the mouth. In addition, the air content of the cheese was about 14% in terms of porosity, and the specific gravity was below 1.0 g / cm ³ .

  Prepare a sample in a cylindrical shape with a diameter of 17 mm and a height of 11 mm, and use a rheometer (NRM-2002J manufactured by Fudo Kogyo Co., Ltd.) to grind it once with cheddar cheese and meat chopper before processing, or grind 10 times with meat chopper -About the kneaded cheddar cheese, the stress at break and brittleness were measured.

The method of measuring stress at break and brittleness is as follows.
Each temperature of the cheese obtained in Example 1 (cheddar cheese crushed and kneaded 10 times), cheddar cheese before processing, and cheddar cheese crushed only once with a meat chopper was adjusted to 10 ° C. and used for the test. did. Each cheese (sample) is fixed to the sample table, and a φ10 mm spherical stainless steel plunger is used. The sample table is raised at a speed of 15 cm / min. The plunger comes into contact with the sample and is pushed into the sample. After the sample collapsed and the stress from the sample started to decrease, it was measured until the stress from the sample increased again. The stress applied to the plunger from the sample when the sample collapsed is the stress at break (g). After the sample collapses, the difference between the stress when the stress applied to the plunger is relaxed and minimized and the stress at break Was a brittle stress (g), and a value obtained by dividing the brittle stress by the stress at break was regarded as brittle.

  As shown in Table 1, by pulverizing with a meat chopper, the value of the stress at break expressed as the work amount was reduced, and the crisp texture was improved. Furthermore, it was confirmed that by pulverizing and kneading, the brittleness value increased and the physical properties were easily broken in the mouth.

[Example 2]
Cheddar cheese (raw wood cheddar cheese (20 kg block cheese for raw materials)) is made into a 3 mm dice shape, and this is used as a starting material, and crushed and kneaded using a meat chopper (manufactured by Natsune Corporation, meat chopper MD-22K), Changes in color tone, physical properties and texture according to the number of kneading were examined. The color tone was evaluated visually. The physical properties were evaluated in the same manner as in Example 1 by adjusting the sample to a cylindrical shape having a diameter of 17 mm and a height of 11 mm, and using a rheometer (manufactured by Fudo Kogyo Co., Ltd.) at a product temperature of 10 ° C. Evaluation items of physical properties are stress at break (g), brittle stress (g), brittleness, and work (g · s). Stress at break, brittle stress, and brittleness are described in Example 1. Measured by the method. Regarding the work amount, the total amount of stress applied from when the sample began to be stressed to the plunger until the sample broke was calculated as the work amount. In the evaluation of the texture, the sticky texture was evaluated as C, the stickiness decreased, the light texture as B, the brittle, the light texture that was quick and good as the mouth was evaluated as A.

  As shown in Table 2, in cheddar cheese, the color tone changed from yellow to white as the number of kneading by the meat chopper was increased. In the third kneading, a slightly light texture was obtained due to air content, but the brittleness was insufficient and stickiness was felt. In the fifth kneading, the stickiness became weak and it approached a light texture, and in the eighth and more times, the mouth melted well, so that the mouth melted well. The average particle size of the cheese kneaded for the 10th time was 19.9 μm.

[Example 3]
Gouda cheese (raw wood Gouda cheese (20 kg block cheese for raw materials)) is made into a 3 mm dice shape, and this is used as a starting material, and crushed and kneaded using a meat chopper (manufactured by Natsune Corporation, meat chopper MD-22K), Changes in color tone, physical properties and texture according to the number of kneading were examined. The evaluation method was the same as in Example 2.

  As shown in Table 3, with Gouda cheese, the color tone changed from yellow to white as the number of kneading by the meat chopper was increased. Although it was fragile by the 5th kneading and good mouth melting that did not adhere in the oral cavity was felt, the light texture due to air content was insufficient. A light texture was obtained by the 8th and 10th kneading, and the mouth melted well so that it melted immediately.

[Example 4]
Mozzarella cheese (raw wood mozzarella (20kg block cheese for raw materials)) is made into a 3mm die, and this is used as a starting material, pulverized and kneaded using a meat chopper, and changes in color, physical properties, and texture according to the number of kneading are examined. did. The evaluation method was the same as in Example 2.

  As shown in Table 4, in the mozzarella cheese, the color tone changed from yellow to white as the number of kneading by the meat chopper was increased. In the fifth kneading, a brittle texture was felt, but a light mouth melt due to air content could not be obtained. In the 8th and 10th kneading, the melting of the mouth was improved. The average particle size of the cheese kneaded for the 10th time was 51.5 μm.

[Example 5]
Parmesan cheese (raw parmesan cheese (20 kg block cheese for raw materials)) is made into a 3 mm dice shape, and this is used as a starting material, and crushed and kneaded using a meat chopper (manufactured by Natsune Corporation, meat chopper MD-22K), Changes in color tone, physical properties and texture according to the number of kneading were examined. The evaluation method was the same as in Example 2.

  As shown in Table 5, in Parmesan cheese, the color tone changed from yellow to white as the number of kneading by the meat chopper was increased. Due to the unique properties of Parmesan cheese, even if the number of kneading times was small, it was brittle, but the texture was felt heavy until the third kneading. The 5th kneading reduced the texture, and the 8th and 10th kneading had brittleness that collapsed in the mouth, and a light texture was obtained.

[Example 6]
Cheddar cheese (raw wood cheddar cheese (20 kg block cheese for raw materials)) is made into a 3 mm dice shape, and this is used as a starting material, and an extruder (KEX-50, KEX-50) is used to supply tap water to the jacket. While being fed, the body temperature was maintained at around 10 ° C., pulverized and kneaded, and discharged from a φ22 mm nozzle to produce cheese. The brittleness, work volume, density, and texture were evaluated when the rotational speed was changed. The texture was evaluated in the same manner as in Example 2.

  The results are shown in Table 6. The cheese obtained from the extruder outlet of the sample (b) produced by increasing the number of revolutions of the extruder changed to white. In the texture (a), physical properties with good mouth melting that do not adhere in the oral cavity were obtained, and (b) had even better physical properties.

[Example 7]
Mozzarella cheese (raw wood mozzarella (20kg block cheese for raw materials)) is made into 3mm dice, and this is used as a starting material to supply tap water to the jacket using an extruder (manufactured by Kurimoto Steel Works, KEX-50) Then, while maintaining the body temperature at around 10 ° C., the mixture was pulverized and kneaded and discharged from a φ22 mm nozzle to produce cheese. We examined the differences in brittleness, work load, density, and texture when the rotation speed was changed.

  The results are shown in Table 7. The cheese obtained from the extruder outlet of the sample (b) produced by increasing the number of revolutions of the extruder changed to white. In the texture (a), physical properties with good mouth melting that do not adhere in the oral cavity were obtained, and (b) had even better physical properties.

[Example 8]
Cheddar cheese (raw wood cheddar cheese (20 kg block cheese for raw materials)) is made into a 3 mm dice shape, and this is used as a starting material, and an extruder (KEX-50, KEX-50) is used to supply tap water to the jacket. The cheese was produced by supplying and maintaining the body temperature at around 10 ° C., pulverizing and kneading, and discharging from a φ17 mm nozzle. The brittleness, work volume, density, and texture were evaluated when the rotational speed was changed. Fat and protein particle sizes of the obtained cheese tissue were measured with a particle size distribution measuring device (SALD-2200, manufactured by Shimadzu Corporation).

  As shown in Table 8, the cheese obtained from the extruder outlet of the sample (b) produced by increasing the number of revolutions of the extruder was changed to white. In the texture (a), physical properties with good mouth melting that do not adhere in the oral cavity were obtained, and (b) had even better physical properties. Further, these cheese particles (a) and (b) were 100 μm or less, and the average particle size was smaller in (b) where the rotational speed was increased. The mozzarella cheese was also carried out at the same rotational speed, but the mozzarella cheese also had good emulsification stability, and as the extruder rotational speed increased, the density decreased and the average particle diameter of the particles in the cheese structure decreased. We have knowledge.

[Example 9]
The mozzarella cheese cut into 3 mm dice was blended with the auxiliary ingredients shown in Table 9 and kneaded 10 times with a meat chopper (manufactured by Natsune Corporation, meat chopper MD-22K) to produce cheese. The resulting cheese was filled into a cubic mold and stored refrigerated at 5 ° C or lower. All of the prototypes had good meltability in the mouth and were mixed without heating, so that the original flavor of cheese was not deteriorated and was good.

[Example 10]
Cheddar cheese (raw wood cheddar cheese (20 kg block cheese for raw materials)) is made into a 3 mm dice shape, and this is used as a starting material, and an extruder (KEX-50, KEX-50) is used to supply tap water to the jacket. The cheese was produced by supplying and maintaining the body temperature at around 10 ° C., pulverizing and kneading, and discharging from a φ17 mm nozzle. The color tone, density, and texture when the rotation speed was changed were evaluated. The results are shown in Table 10.

  From the results in Table 10, it can be seen that increasing the number of revolutions of the extruder (paddle) reduces the density and improves the evaluation (feeling of mouthfeel) of the texture. On the other hand, in the evaluation of flexibility / adhesiveness based on the description of International Publication No. WO2011 / 087086, no significant difference was observed for each rotation speed.

[Example 11]
Mozzarella cheese (raw wood mozzarella cheese (20 kg block cheese for raw materials)) is made into a 3 mm dice shape, and this is used as a starting material, and using an extruder (KEX-50, KEX-50), tap water is supplied to the jacket. The cheese was produced by supplying and maintaining the body temperature at around 10 ° C., pulverizing and kneading, and discharging from a φ17 mm nozzle. The density, flexibility, and adhesion when the rotation speed was changed were evaluated. The evaluation of flexibility and adhesion was performed based on the description of International Publication No. WO2011 / 087086. The results are shown in Table 11.

  From the results in Table 11, it can be seen that increasing the number of revolutions of the extruder (paddle) results in more whitening, lower density, and better texture evaluation.

[Example 12]
Cheddar cheese (raw wood cheddar cheese (20 kg block cheese for raw material)) is made into a 3 mm die, and this is used as a starting material, and a meat chopper (manufactured by Natsune, meat chopper MD-22K) is used as in Example 2. Using SPECTRO PHOTOMETER (manufactured by KONICA MINOLTA), the light source: C (auxiliary illuminant for colorimetry), field of view: 2 °, specular reflection processing: SCE ( (Exclude specular reflection light). The results are shown in Table 12.
In Example 2, it was confirmed by visual observation that the color tone changed from yellow to white depending on the number of kneading by the meat chopper, but the L value representing the white tone increased by the color difference measurement, and accordingly, E * ab The value also increased. Note that the L value of the raw wood cheddar cheese (corresponding to 0 kneading times) was used as a control, and the L value of the kneading frequency of 8 times was obtained in Example 2 where the visual color tone was “white” and the texture evaluation was A. The difference in the L value was 5.83, and the difference in the L value was 10.72 when the number of kneading was 10 in which the result of Example 2 was that the visual color tone was “white” and the texture evaluation was A.

[Example 13]
Cheddar cheese (raw wood cheddar cheese (20 kg block cheese for raw materials)) is made into a 3 mm die, and this is used as a starting material, and an extruder (KEX-50, manufactured by Kurimoto Ironworks Co., Ltd.) is used as in Example 10. Then, tap water was supplied to the jacket and crushed and kneaded while maintaining the body temperature at around 10 ° C., and then discharged from a φ17 mm nozzle to produce cheese. Evaluation of the change in color tone when the rotation speed was changed was performed in the same manner as in Example 12. The results are shown in Table 13.
In Example 10, it was visually confirmed that the color tone changed from yellow to white depending on the extruder paddle rotation speed, but the L value representing the white color tone was increased by measuring the color difference. In addition, the difference of L value of the paddle rotation speed of 120 rpm with which the color tone by visual observation was white and the food texture evaluation was A in Example 10 was compared with the L value of the raw wood cheddar cheese (corresponding to paddle rotation speed of 0 rpm). 5.89, the difference in L value at a paddle rotation speed of 300 rpm, in which the result of Example 10 was that the visual color tone was white and the texture evaluation was A, was 6.19.

  According to the present invention, a cheese which is uniformly aerated only by a mechanical process can be obtained without heating and melting the natural cheese of the present invention or adding a special additive. In addition, the cheese obtained in this way loses the crunchy and tattered texture that the original cheese had, and when it is put into the mouth, it collapses brittlely, melts quickly, and people with difficulty swallowing It has a very good light texture even when eating. Furthermore, the cheese of the present invention has soft physical properties when it is kneaded, and can be molded into a desired shape.

Claims (7)

One or two or more hard and / or semi-hard raw natural cheeses are mechanically pulverized and kneaded to forcibly contain gas until the density is 1.0 g / cm ³ or less and whiten. The manufacturing method of the aerated natural cheese or aerated cheese processed food including the thing . By mechanically pulverizing and kneading one or more hard and / or semi-hard raw material natural cheeses, the difference between the L value of the raw natural cheese and the L value of the aerated natural cheese is 3.0. A method for producing an aerated natural cheese or an aerated cheese processed food comprising forcibly containing a gas and whitening until it is as described above. Including further molding method according to claim 1 or 2. The method as described in any one of Claims 1-3 including adding and mixing an auxiliary material before and / or after the grinding | pulverization of raw material natural cheese, and / or kneading | mixing. Aerated natural cheese or aerated cheese processed food obtained by the method according to any one of claims 1 to 4 . Porosity of 5% to 60%, aerated natural cheese or aerated cheese processed food according to claim 5. The aerated natural cheese or aerated cheese processed food according to claim 5 or 6 , wherein the average particle size of the cheese tissue is less than 200 µm.