JP2015188849A - Lowly phosphorus rice producing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a producing apparatus enabled to produce lowly phosphorous rice by applying a vertical shaft type grain cleaning machine of high versatility, and a method for producing lowly phosphorus rice by using said apparatus.SOLUTION: A grain cleaning apparatus is characterized by comprising: a vertical shaft type grain cleaning machine 1 including a grinding type milling part 2 and a friction type milling part 3 for processing the rice R discharged from below the grinding type milling part 2; and a grain cleaning circuit 4 for returning the rice R discharged from said friction type milling part 3, to said grinding type milling part 2. At this time, it is preferred that two or more said grain cleaning circuits are disposed in parallel, and that at least one grain cleaning circuit is equipped with a cooling tank 5.

Description

  The present invention relates to an apparatus for producing low-phosphorus rice and low-phosphorus rice produced by this apparatus.

  According to presentations by the Ministry of Health, Labor and Welfare and the Japan Osteoporosis Society, there are 13 million osteoporosis patients nationwide. One of the risk factors for osteoporosis is excessive phosphorus intake. In addition to osteoporosis patients, about 300,000 dialysis patients who need to remove blood phosphorus through dialysis are recognized nationwide. Under such circumstances, development of foods with a reduced phosphorus content is required. Among foods, rice is a staple food, and if you eat two rices, you will consume half of them against the 700mg / day phosphorus intake limit for dialysis patients. Therefore, among foods, low phosphorous rice is required. Currently, low-phosphorus rice that is commercially available is manufactured using a special grain mill for chemical processing or sake rice, so it has poor versatility and is expensive.

According to the knowledge so far, most of the phosphorus in the rice is present near the surface, so that the phosphorus content can be reduced by further grinding the surface of the polished rice.
However, the friction-type rice mill used by rice mill wholesalers cannot cut the rice to the target part, so it is necessary to use a grinding-type rice mill for sake rice or a rice mill with a special roll structure. there were.
Technological development for producing low phosphorus rice has been carried out by scraping the surface of rice (Patent Documents 1 to 3). Among these, Patent Document 1 relates to a technique for preparing low protein / low phosphorus rice by either friction milling or grinding rice milling, and Patent Document 2 and Patent Document 3 describe low phosphorus special polished rice by grinding rice polishing. It relates to the technique of preparation.

Japanese Patent Laid-Open No. 11-9203 JP 2002-45128 A JP-A-11-243879 JP-A-9-57121

However, no satisfactory apparatus has been known for producing low-phosphorus rice in large quantities and at low cost.
The present invention has been made in view of the above-described circumstances, and its purpose is to apply a highly versatile pestle-type grain mill (Patent Document 4) to enable the production of low-phosphorus rice. It is providing the manufacturing method of a low phosphorus rice using an apparatus and the said cereal apparatus.

As a conventional grain refiner, (1) grinding type grain refiner, (2) friction type grain refiner, and (3) vertical axis type mill equipped with a grinding type grain part and a friction type grain part in the vertical direction A grain machine was known. Among them, the circulation type grinding-type grain milling apparatus can mill while determining the degree of grain milling. There was the feature that became high. This device is used for processing rice to produce Ginjo-shu, which can be converted even if it is expensive. Friction type grain milling devices are widely used as staple rice rice grain milling devices because they can be continuously processed. In addition, the cocoon-type grain refiner has been developed relatively recently and is in the process of spreading.
The inventor of the present invention has succeeded in achieving the object of the present invention by paying attention to the above-described miller-type grain mill as a grain refiner capable of producing low-phosphorus rice in a large amount and at a low cost.

  That is, the grain refiner according to the invention for achieving the above object includes a ground mill provided with a grinding type grain part and a friction type grain part that processes rice discharged from below the grinding type grain part. And a cereal circulation path for returning the rice discharged from the friction-type cereal part to the grinding-type cereal part, and there are two or more cereal circulation paths provided The at least one cereal circulation path is provided with a cooling tank capable of controlling the temperature of rice in the cereal. At this time, it is preferable to provide each cereal circulation path in parallel.

During the cerealing operation using the vertical mill, the temperature of the rice rises due to grinding and friction. As the temperature rises, the rate of broken rice increases, and quality degradation and yield decrease. For this reason, in the said structure, it was decided to reduce the temperature of rice by leaving still in the tank provided in the cereal circulation path. According to this structure, since the temperature of rice falls and a broken rice cracking rate can be reduced, a yield improvement and high quality can be maintained.
In the above-mentioned invention, it is preferable that a circulation path switching device that circulates rice by selecting any one of the plurality of cereal circulation paths is provided in the cereal circulation path. At this time, examples of the cereal state of the rice include a method of manually confirming the cereal state and a method of providing a sensor for detecting the cereal state of the rice in the cereal circulation path. With these methods, if the cereal state has advanced to a predetermined stage, the circulatory path switching device can be operated to change the cereal circulation path.
Further, a method for producing a polished rice according to another invention is a method of using the above-described grain refiner, and when the measurement result by the sensor becomes a predetermined value, the circuit switching device is switched, It is characterized by switching so that rice is cerealed through the cereal circulation path without the cooling tank. At this time, it is preferable that the processing speed of the cereal apparatus is set higher when passing through the cereal circulation path having no cooling tank than when passing through the cereal circulation path having the cooling tank.
Moreover, it is preferable that the said grain refiner is provided with the control apparatus which receives the measured value from the said sensor and controls the said circuit switching device. At this time, the sensor is preferably provided in front of the position where the rice discharged from the friction-type cereal part branches the cereal circulation path with the cooling tank and the uncooled cereal circulation path. .

Further, another invention is a method for producing a polished rice using the above-described cerealing device, wherein the control device refines the rice through a cereal circulation path with a cooling tank at an early stage of the cerealing. On the other hand, when the measured value from the sensor reaches a predetermined value, the circulation path switching device is controlled to switch the rice to grain through a cereal circulation path without a cooling tank. And
According to the study of the present inventor, it was found that the occurrence rate of cracked rice is reduced by using a cereal circulation path with a cooling tank. However, in order to provide low-phosphorus rice as a product, in the final stage of cereals, it is possible to achieve the desired cereal ratio by using a cereal circulation path without a cooling tank and increasing the cereal flow rate. found. For this reason, in the above configuration, when the cereal reaches the final stage according to the measured value of the sensor, the circulation path switching device is controlled and the cereal is passed through the cereal circulation path that is not the cereal circulation path with the cooling tank. We decided to do the work.

Moreover, the low phosphorus rice which concerns on another invention was manufactured using the said grain refiner.
According to the said structure, low phosphorus rice can be provided in large quantities and cheaply.
In the present invention, the sensor means an apparatus capable of measuring or estimating the phosphorus content of rice, and includes those that are measured manually and those that are mechanically measured. However, in order to provide low-phosphorus rice in a larger amount and at a lower cost, it is preferable to use a sensor that measures mechanically. As such a sensor, for example, a near infrared sensor or a whiteness sensor can be used. In addition, the low-phosphorus rice produced is manufactured by combining frictional and ground cereals, so the surface structure is different from the low-phosphorus rice produced by existing methods and has a high water absorption rate. Therefore, the water absorption time can be shortened.

  According to the present invention, it is possible to mass-produce low-phosphorus rice whose phosphorus content is reduced to about half that of normal cereals at a low cost. This low-phosphorus rice can be suitably used as a staple food particularly for osteoporosis patients or renal dialysis patients and their families.

It is a schematic diagram of a grain refiner of a 1st embodiment. It is a schematic diagram of the grain refiner of 2nd Embodiment. It is a schematic diagram of the grain refiner of 3rd Embodiment. It is a schematic diagram of the grain refiner of 4th Embodiment. It is a flowchart when performing grain refinement | working with a computer. It is a graph which shows the relationship between the rice polishing ratio and phosphorus content when pulverized by the conventional method and this invention method. It is a graph which shows the relationship between the presence or absence of a cooling tank (cooling tank) and the broken rice rate. It is a graph which shows the relationship between polished rice whiteness and phosphorus content. It is the photograph which compared the morphological characteristic of the low phosphorus rice manufactured with the method of this embodiment, and the conventional method. (A) The low phosphorus rice manufactured by the method of this embodiment, (b) The low phosphorus rice manufactured by the conventional method is shown, respectively. It is the photograph which compared the water absorption characteristic of the low phosphorus rice. (A) is low-phosphorus rice produced by the method of the present embodiment, 10 minutes after water absorption, (b) is low-phosphorus rice produced by a conventional method, 10 minutes after water absorption, ( c) Low-phosphorus rice produced by the method of this embodiment, and as a result of NMG staining after water absorption for 10 minutes, (d) is low-phosphorus rice produced by the conventional method, and NMG staining after water absorption for 10 minutes. Each result is shown.

Next, embodiments of the present invention will be described with reference to the drawings. However, the technical scope of the present invention is not limited by these embodiments, and various forms can be made without changing the gist of the invention. Can be implemented.
<First Embodiment>
In FIG. 1, the outline | summary of the grain refiner which concerns on 1st Embodiment of this invention was shown. This milling device is provided with a vertical mill 1. In the vertical mill 1, a grinding cereal part 2 having a rotary grindstone at the center and a friction cereal part for processing rice R discharged from below the grinding cereal part 2. 3 is provided. Further, the cerealing device 4 is provided with a cereal circulation path 4 for returning the rice R discharged from the frictional cerealing unit 3 back to the inlet 6 of the grinding-type cerealing unit 2. Rice R is transferred in the direction of arrow A.
According to the said structure, the rice R processed by the vertical type grain refiner 1 provided with the grinding-type grain refiner 2 and the friction-type grain refiner 3 is again ground via the grain circulation path 4. 2 is returned to the inlet 6 and cerealed. For this reason, efficient graining work can be performed.
Second Embodiment
Next, a second embodiment of the present invention will be described with reference to FIG. In FIGS. 1 and 2, the same reference numerals are given to configurations having the same actions, and descriptions thereof are omitted.
The difference between the present embodiment and the first embodiment is the presence or absence of the cooling tank 5. A cooling tank 5 for reducing the temperature of the rice R in the cereal is provided in the middle of the cereal circulation path 4.

  According to the said structure, the rice R processed by the vertical type grain refiner 1 provided with the grinding-type grain refiner 2 and the friction-type grain refiner 3 is again ground via the grain circulation path 4. 2 is returned to the inlet 6 and cerealed. During the cerealing operation using the vertical type grain mill 1, the temperature of the rice R rises due to grinding and friction (in the test using the actual machine, the milled rice is used at 30 ° C., but the milled rice is not used. Rice temperature above 45 ° C was observed). As the temperature rises, the rate of broken rice increases, and quality degradation and yield decrease. Therefore, in this embodiment, the cooling tank 5 is provided in the cereal circulation path 4, and the temperature of the rice R is adjusted by providing a fixed time (about 5 minutes) in the cooling tank 5 for the cereal. It is decreasing. For this reason, since the rate of broken rice during the cereal operation is reduced, it is possible to improve yield and maintain high quality.

<Third Embodiment>
Next, a third embodiment of the present invention will be described with reference to FIG. 1 and 2 and FIG. 3, the same reference numerals are given to configurations that exhibit the same action, and description thereof is omitted.
In the third embodiment, a cereal circulation path 12 without a cooling tank is provided in parallel with the cereal circulation path 4 with the cooling tank 5. The rice R passing through the cereal circulation path 12 is returned to the inlet 6 of the grinding-type cereal part 2 without the rice temperature being controlled.
In addition, a circulation path switching device 11 is provided at a place where both the cereal circulation paths 4 and 12 intersect. By operating this circulation path switching device 11, it is possible to designate which of the cereal circulation paths 4 and 12 the rice R selects and circulates.
As described above, it is preferable to control the temperature rise of the rice R in order to reduce the rate of crushed rice during milling. However, in order to provide low-phosphorus rice as a product, in the final stage of the cereal operation, the cereal circulation path 12 is passed through the cereal circulation path 12 without passing through the cereal circulation path 4 provided with the cooling tank 5. It became clear that it was better to use the flow rate increased than the flow rate of the rice R set in the vertical mill 1 when using 4. For this reason, according to the configuration of the present embodiment, at the initial stage of the cereal operation, the rice R passes through the cooled cereal circulation path 4 (that is, the rice R passes through the arrows S-A-T). ) Set the circulation path switching device 11 to suppress the increase of the broken rice rate and perform the cereal. When the cereal operation reaches the final stage, the circuit switching device 11 is operated so that the rice R passes through the uncooled cereal circulation path 12 (that is, the rice R passes through the arrows S-B-T). ). In this way, since the rice R is refined while the temperature rises, a good low-phosphorus rice can be provided.

<Fourth embodiment>
Next, a fourth embodiment of the present invention will be described with reference to FIGS. 4 and 5. 1-3 and FIG. 4, about the structure which show | plays the same effect | action, the same code | symbol is attached | subjected and description is abbreviate | omitted.
In 4th Embodiment, the sensor 20 which measures the rice mill whiteness in order to detect the cereal state of the rice R is provided in the front position of the circulation path switching device 11 in the cereal circulation path. A measured value by the sensor 20 is transmitted to a computer 21 (corresponding to a control device in the present invention). The computer 21 is connected to the circulation path switching device 11 and operates the circulation path switching device 11 by issuing a predetermined signal so that the circulation path of the rice R becomes the cereal circulation path 4 or the refinement. It is possible to control whether to use the cereal circulation path 12. In addition, the computer 21 is also connected to the cocoon-type grain refiner 1 and the cooling tank 5 and can control them.

According to the present embodiment configured as described above, low-phosphorus rice can be provided by performing the rice milling operation by the same cerealing method as in the second embodiment. However, the designation operation of the cereal circulation paths 4 and 12 is performed by software preset by the computer 21.
The flowchart of the software is as shown in FIG. That is, first, the cereal circulation path 4 is designated by the initial setting, and the circulation path is switched so that the rice R passes through the cereal circulation path 4 with the cooling tank 5 (through the arrow S-A-T). The apparatus 11 is set (S100) and set so that the broken rice rate is reduced.
Next, the cerealing work is started by the vertical axis type grain mill 1 (S110). The measured value V from the sensor 20 is received during the cerealing operation, and is compared with a predetermined whiteness W for switching (S120). When the measured value V is smaller than the switching whiteness W (when V <W, “NO”), the graining operation is in the initial stage, so the process directly returns to S110 to continue the graining operation. On the other hand, when the measured value V is equal to or higher than the switching whiteness W with the progress of the grain work (when V ≧ W, “YES”), the grain work has reached the end stage. A predetermined switching signal is output to the circulation path switching device 11 so that the rice R passes through the cereal circulation path 12 (arrow S-B-T. S130). In this state, the cereal operation is continued, and the measured value V is compared with the predetermined cereal end whiteness X (S140). When the measured value V is smaller than the finished grain whiteness X (when V <X, “NO”), the process returns to S110 as it is and continues the grain work. On the other hand, when the measured value V is equal to or higher than the cereal end whiteness X as VW progresses (when V ≧ X, “YES”), it is determined that the production of low-phosphorus rice is completed. Then, the circulation path switching device 11 is operated to designate the cereal circulation path 4 (S150). Then, the rice R is guided to the cooling tank 5 in the cereal circulation path 4 to finish the cereal operation. The low-phosphorus rice produced is discharged using the conventional product shipping line of the vertical mill.
As described above, according to the present embodiment, in addition to the same effects as those of the above-described embodiment, the switching of the cereal circulation paths 4 and 12 can be performed by the automatic control of the computer 21, so that the work efficiency is improved.

<Test to obtain low phosphorus rice>
Next, the test method for obtaining a good low-phosphorus rice and the results will be described.
1. Examination of the relationship between rice polishing ratio and phosphorus content It is known that phosphorus in rice is contained more outside than inside. However, the quantitative relationship has not been examined in detail. Therefore, in order to estimate how much the outside of the rice should be cut, the relationship between the rice milling rate and the phosphorus content was examined.
The results are shown in Table 1.

  In general polished rice (milled rice ratio 89.7), the content of phosphorus, potassium and magnesium was 102.5, 93.5 and 28.8 (mg), respectively, for 100 g edible part. On the other hand, for the rice milling ratio up to 83.1, the contents of phosphorus, potassium and magnesium were 56.1, 64.4 and 7.1 (mg) for 100 g edible part, respectively. . Thus, although the rate of reduction differs depending on the type of mineral, it was found that the amount of mineral can be greatly reduced by slightly shaving the outer portion of the rice. In particular, it has been found that phosphorus can be reduced to about half by further refinement by about 7% compared to ordinary polished rice. Based on this result, the goal was to provide low-phosphorus rice that had been milled to about 83.1 rice polishing ratio.

2. Comparison test of rice milling ratio between conventional milling method and milling method of the present invention Phosphorus content reduction between conventional rice milling method and rice milling method of the present invention The difference in speed was compared. As a conventional cerealing method, cerealing work was performed using a grinding cerealing device. Moreover, as a cereal method of the present invention, a cereal operation using the cereal apparatus described in Embodiment 3 was performed.
The test results are shown in FIG. According to this test, as compared with the case where the conventional method is used, when the cereal method of the present invention is used, the reduction of phosphorus accompanying the reduction of the rice polishing rate proceeds more quickly, and the phosphatization is reduced to some extent even at a high yield. Was found to be possible.

3. Next, it was examined how much the rice cracking rate when the cooling tank was provided compared to the case where the cooling tank was not provided.
As a cerealing method that does not provide a cooling tank, in the cerealing apparatus described in the first embodiment, only the cereal circulation path 4 is designated to perform the cerealing operation. On the other hand, the grain refinement | working operation | work by the grain refinement method of Embodiment 3 was performed, and the broken rice rate was investigated.
The test results are shown in FIG. In the case where no cooling tank was provided (the graph of “no cooling” in the figure), the rate of broken rice was 14.36%. On the other hand, when the standing time in the cooling tank is provided (the graph of the cooling tank “present” in the figure), the 10th pass (using the vertical type grain mill 1) is repeated 10 times. Even when cereal work was performed), the broken rice rate was 6.15%. Thus, it was found that the rate of broken rice can be greatly reduced by using the apparatus of the present embodiment.

4). Test for Examining Relationship between Polished Whiteness and Phosphorus Content Next, the relationship between polished rice whiteness and phosphorus content was examined. In general, it is known that the whiteness of polished rice increases as cereal work progresses. However, there was no known data that investigated the relationship between rice mill whiteness and phosphorus content. In this invention, it is set as the structure which estimates the phosphorus content of rice with the measured value of a sensor. For this reason, the correlation with the phosphorus content when a rice mill whiteness meter was employed as a sensor was examined.
The test results are shown in FIG. According to this graph, it was found that the phosphorus content can be evaluated very accurately with a contribution ratio (R ² ) of 0.9051 when the whiteness of polished rice is in the range of 43.6 to 54.8. For this reason, when using a whiteness meter as a sensor, it was found that low phosphorus rice having an appropriate phosphorus content can be provided by utilizing the above linearity (for example, the lower limit value of milled rice whiteness is set to 53). By doing so, it is possible to provide low-phosphorus rice having an edible portion of phosphorus 54 mg / 100 g or less).

5. Evaluation test of the taste of low-phosphorus rice Next, the taste of low-phosphorus rice provided by this embodiment and the taste of low-phosphorus rice already on the market (due to chemical processing) are cultivated in Iga Agricultural Research Institute, Mie Prefecture. A taste sensory test of the former Food Agency method using Koshihikari as a standard rice was evaluated.
The results are shown in Table 2. “Test-processed low-phosphorus rice” is a rice milled by the milling apparatus described in the third embodiment.

As shown in the table, commercially available chemically-processed low-phosphorus rice has extremely low values for all six items, and it was difficult to say that foods can be eaten appropriately.
On the other hand, the low phosphorus rice (test processed low phosphorus rice) of this embodiment showed a numerical value close to Koshihikari. From this, it was found that the low-phosphorus rice provided by the present embodiment exhibits a significantly superior taste compared to conventional low-phosphorus rice.

6). Morphological characteristic evaluation of low-phosphorus rice produced by this technique According to the study of the present inventors, low-phosphorus rice refined by the technique described in Embodiment 3 has a surface structure different from conventional low-phosphorus rice. I found out. Compared with conventional low-phosphorus rice, which increases the polishing ratio by grinding-type rice milling, new low-phosphorus rice milled with a combination of friction-type and grinding-type rice mills showed fine scratches and numerous irregularities on the surface. (FIG. 9). The difference in surface structure has a great effect on water absorption.
Therefore, when a water absorption test was performed by immersing 5 g of low-phosphorus rice in 10 ml of distilled water for 10 minutes, the low-phosphorus rice produced completed water absorption in 10 minutes, and the water absorption rate was faster than conventional low-phosphorus rice. It was revealed. In addition, when each sample 10 minutes after water absorption is stained with the NMG reagent, the water absorption completion part and the non-water absorption part can be clearly distinguished, and the manufactured low phosphorous rice absorbs water from the fine irregularities present on the surface to the whole grain. On the other hand, it has been clarified that conventional low-phosphorus rice has different appearance after water absorption because water absorption stays at the outer part (FIG. 10). The part that has absorbed water has turned white. As a result, it was speculated that conventional low-phosphorus rice and new low-phosphorus rice could be distinguished by a water absorption test. Since the water absorption speed is higher than that of conventional low-phosphorus rice, it is possible to save labor in the water absorption process.
As described above, according to the present embodiment, it was possible to produce rice with a phosphorus content reduced to about half that of normal cereal at low cost. This low-phosphorus rice can be suitably used as a staple food particularly for osteoporosis patients or renal dialysis patients.

DESCRIPTION OF SYMBOLS 1 ... Shaft type | mold grain machine, 2 ... Grinding-type grain part, 3 ... Friction-type grain part, 4,12 ... Grain circulation path, 5 ... Cooling tank, 11 ... Circulation path switching device, 20 ... Sensor, 21 ... Computer (control device), R ... Polished rice (low phosphorus rice)

Claims (7)

A rice-shaft-type grain mill provided with a grinding-type grain portion and a friction-type grain portion that processes rice discharged from below the grinding-type grain portion, and the rice discharged from the friction-type grain portion A cereal circulation path for returning
Two or more of the cereal circulation paths are provided, and at least one cereal circulation path is provided with a cooling tank capable of controlling the rice temperature in the cereal grains. Cereal machine to do. 2. The cereal apparatus according to claim 1, wherein a circulatory path switching device that circulates rice by selecting any of the plurality of circulatory paths is provided in the cereal circulation path. 3. The refinement according to claim 2, further comprising: a sensor for detecting a cereal state of the rice and a control device for receiving the measurement value from the sensor and controlling the route switching device. Grain equipment. A method for producing a polished rice using the milling apparatus according to claim 2, wherein in the initial stage of the milled grain, the grain is refined through a grain circulation path provided with a cooling tank, while the grain ratio is predetermined. When the value reaches the value, the circuit is switched so that the circulatory path switching device is switched so as to cereal through the cereal circulation path without the cooling tank. 4. A method for producing a polished rice using the milling apparatus according to claim 3, wherein the control apparatus mills the rice through a milling circuit having a cooling tank at an early stage of the milling. On the other hand, when the measured value from the sensor reaches a predetermined value, the circulation path switching device is controlled to switch to cereal rice through the cereal circulation path without the cooling tank. A method for producing polished rice. Low-phosphorus rice produced using the grain refiner according to any one of claims 1 to 3. Low-phosphorus rice produced by the production method according to claim 4 or 5.