JP2020139825A - Method and device for estimating dry matter density of silage and the like - Google Patents

Abstract

To provide a method for estimating dry matter density that can precisely and quickly estimate the dry matter density of silage and its raw material on-site.SOLUTION: The method for estimating dry matter density includes the steps of: inserting a shaft into silage and its raw material (silage and the like) that are piled on-site; measuring a friction resistance value between the silage and the like, and, the surface of the shaft; and obtaining the dry matter density of silage and the like that corresponds to the measured friction resistance value based on the correlation, between friction resistance values and the dry matter density of silage and the like, that has been obtained beforehand.SELECTED DRAWING: Figure 1

Description

The present invention relates to a silage density measuring technique, and more specifically, to a method and an apparatus for estimating the dry matter density of silage and its raw material using the frictional resistance value between the silage and its raw material and the shaft.

Roughage such as grass and feed corn, which are used as feed for livestock, can be stored for a long time by filling silos after harvesting and fermenting them with lactic acid bacteria. Roughage fermented with lactic acid bacteria is called silage. One of the main factors affecting the quality of silage is generally the density of the roughage filled in the silo. When the density of the filled roughage is low, the roughage contains a large amount of air, so that various bacteria other than lactic acid bacteria easily propagate in the fermentation process. Therefore, fermentation by lactic acid bacteria is suppressed, and there is a risk of spoilage or deterioration. In addition, silage with insufficient fermentation by lactic acid bacteria has unstable quality after opening the silo. Therefore, in order to prepare high quality silage, it is important to measure the silage density after opening the silo and feed back the result to the silo filling operation to realize an appropriate roughage density.

In the past, physical density has been used as an index to evaluate the fermentation quality of silage. The physical density is the density of silage measured in a water-containing state. However, the inventor of the present application proposed that it is more appropriate to use the dry matter density as an index for evaluating the fermentation quality of silage (Non-Patent Document 1), and as a result, the fermentation quality of silage was improved. Therefore, at present, dry matter density is mainly used as an index for evaluating the fermentation quality of silage. The dry matter density is the density of the residual solid matter after deducting the water content contained in the actual product, and is also the density of silage measured in a dried state.

Conventionally, a method mainly used as a method for measuring the dry matter density of silage is a core sampler method (for example, Non-Patent Document 2) using a core sampler (for example, Patent Document 1). In the core sampler method, for example, a silage cross section is perforated using a hole saw having a diameter of 5 to 10 cm and a length of about 20 cm, a silage sample is taken, and the collected sample is dried at a temperature of 105 ° C for 24 hours before drying. The dry matter density is calculated from the volume of the sample and the weight of the sample after drying. By using the weight and volume of the sample before drying, the actual density of silage can be obtained.

Japanese Unexamined Patent Publication No. 2008-116259

Ango Ogoshi, "Treading Method for Large Bunker Silo", Hokkaido Agricultural Test Results Conference Materials, Hokkaido Prefectural Agricultural Experiment Station, 2005, p.1-29 Tadashi Nakui et al., "Simple Density Measurement of Bunker Silo with Drill-type Core Sampler", NARO New Research Results, NARO, 1997, p.40-43

The core sampler method is the current density measurement method, but it has been confirmed that the value is low in the density measurement for grass silage. In addition, the actual density can be measured with relatively high accuracy, but the dry matter density has low measurement accuracy. For example, in grass silage, it has been confirmed that the dry matter density measured by this method is about 15 to 25% lower than the actual dry matter density. Further, in this method, it is necessary to dry the collected silage sample for 24 hours and measure the weight after drying, so that the dry matter density cannot be obtained quickly. Further, in this method, it is necessary to prepare equipment such as a dedicated hole saw, an electric drill, a generator, a dryer, and an electronic scale as a measuring device, so that the initial investment is high. Therefore, the core sampler method is used only by some research institutes and farming guidance organizations.

In view of the above problems, it is an object of the present invention to provide a dry matter density estimation method and a dry matter density estimation device capable of estimating the dry matter density of silage and its raw material in the field with high accuracy and speed.

Silage is an organism having water absorption and water retention, which is composed of plant fibers such as grass fibers or corn fibers for feed, water contained in the plant fibers or water adhering to the plant fibers, and voids. It is an elastic body whose volume greatly fluctuates depending on the pressure. This also applies to roughage such as grass or corn for feed, which is a raw material for silage. Therefore, silage and its raw material (hereinafter referred to as "silage, etc.") have weak properties as a rigid body / plastic body such as soil, and are pushed away by the rod-shaped object when it is inserted. A restoring force is generated, and the pressure due to this restoring force is applied to the entire peripheral surface of the rod-shaped object. The present inventor states that the frictional force generated between the surface of a rod-shaped object and fibers such as silage by this pressure has a high correlation with the density of dry matter such as silage, and that such a high correlation is established. The present invention has been completed based on the finding that it is important not to disturb the state of silage or the like when a rod-shaped object is penetrated into silage or the like. The present inventor has also found that, according to the estimation method of the present invention, the amount of water in silage or the like has almost no effect on the estimation result.

In one aspect, the present invention provides a method of estimating dry matter density such as silage. In this method, the step of penetrating the shaft into the silage or the like deposited at the site, the step of measuring the frictional resistance value between the silage or the like and the shaft, and the step of obtaining the frictional resistance value and the dry matter density of the silage or the like in advance are obtained. It includes a step of determining the dry matter density of silage or the like corresponding to the measured frictional resistance value based on the obtained correlation. The method can further include a step of preliminarily determining the correlation based on the frictional resistance value between the shaft and the silage or the like and the dry matter density of the silage or the like on which the frictional resistance value is measured. Here, the step of penetrating the shaft into the silage or the like deposited at the site and the step of measuring the frictional resistance value between the silage or the like and the shaft are performed at the same time, that is, the frictional resistance value is measured while penetrating (the step of penetrating the shaft). For example, it can be done separately (when the penetration resistance value is measured as the friction resistance value), that is, the friction resistance value is measured after the penetration is performed (the rotation resistance value or the pull-out resistance value is measured as the friction resistance value). If done) can also be done.

The steps to obtain the correlation in advance are to fill a predetermined container with silage or the like having a known water content, insert the shaft into the silage or the like filled in the container, and determine the frictional resistance value between the shaft and the silage or the like. The measurement, filling of silage, etc. in the container, and measurement of the frictional resistance value are repeated for silage, etc. with different water content and filling amount, and silage, etc. filled with different water content and filling amount, respectively. To calculate the dry matter density of, and to find the correlation between the frictional resistance value and the dry matter density such as silage by using the measured multiple frictional resistance values and the calculated dry matter densities. Can be included.

In one embodiment, the frictional resistance value between the deposited silage or the like and the shaft can be the rotational resistance value when the shaft penetrated into the silage or the like is rotated around the shaft. In another embodiment, the frictional resistance value can be a penetration resistance value when the shaft is penetrated into silage or the like. In yet another embodiment, the frictional resistance value can be the pullout resistance value when the shaft is pulled out from silage or the like. In yet another embodiment, the frictional resistance value may be a combination of two or all of the rotational resistance value, the penetration resistance value, and the pull-out resistance value. The shaft preferably has a circular cross section, and preferably has a conical tip.

In another aspect, the invention provides a device used to estimate dry matter densities such as silage. This device has a shaft that penetrates into silage, etc. deposited at the site, a measuring instrument that measures the frictional resistance value between the silage, etc. and the shaft, and a correlation for converting the frictional resistance value into the dry matter density of silage, etc. It is provided with a conversion unit including. The correlation can be determined in advance based on the frictional resistance value between the shaft or the like and the silage and the dry matter density of the silage or the like in the portion where the frictional resistance value is measured.

According to the method and apparatus for estimating the dry matter density according to the present invention, it is possible to estimate the dry matter density of silage or the like in the field more easily, in a short time and with high accuracy than the core sampler method which is a conventional density measurement method. Therefore, it contributes to the improvement of silage quality. By using the method and apparatus of the present invention, it is possible to appropriately give guidance on silage preparation conditions, and it is possible to solve problems such as insufficient treading pressure, excessive treading pressure, and uneven treading pressure, which are factors of deterioration of silage quality.

It is a flow chart which shows the method of estimating the dry matter density such as silage by this invention. It is a flow chart which shows the method of finding the correlation for estimating the dry matter density such as silage by this invention. It is a figure which shows the correlation between the dry matter density of a grass silage sample, a penetration resistance value, a pull-out resistance value, and a rotation resistance value. It is a figure which shows the correlation between the dry matter density of the corn silage sample for feed, and the penetration resistance value, the pull-out resistance value, and the rotation resistance value. It is a figure which shows the correlation between the density (density in the housing) of the grass silage sample and the corn silage sample for feed, and the density measured by the core sampler method. The coefficient of variation calculated from three measurements for each sample is shown for the dry matter density estimated by the dry matter density estimation method based on the penetration resistance value, the pull-out resistance value and the rotational resistance value, and the dry matter density measured by the core sampler method.

According to the inventor of the present invention, the optimum silage dry matter density to be used as an index for evaluating the fermentation quality of silage is that when a shaft having a predetermined shape penetrated into the silage is rotated, the shaft is placed on the silage. It was found that there is a high correlation with the frictional resistance between the shaft and the silage when the shaft is penetrated or when the shaft penetrated into the silage is pulled out. The present invention has been completed by using this finding. For example, by measuring the frictional resistance value at the silage opening site and examining the dry matter density corresponding to the frictional resistance value, the dry matter density of the silage can be determined at the site. It can be estimated easily, quickly and with high accuracy. In addition, the dry matter density can be estimated for the silage raw material by the same method.

In addition, the embodiment described below in this specification relates to an apparatus and a method for estimating the dry matter density of silage using timothy-based grass or feed corn as a roughage. The shape of the shaft of the device (thickness, length, size of tip angle, etc.) and the correlation between the frictional resistance value and the dry matter density described below are used for silage made from these roughages. It is applicable, and when estimating the dry matter density of silage using other forages, for example, other grass species such as orchardgrass, or the dry matter density of the raw material of silage, an appropriate shaft shape and correlation are separately applied. We need to seek a relationship. However, even when other roughages are used, an appropriate shaft shape and correlation can be determined by adopting the same method as that described in this embodiment.

[Device for estimating dry matter density]
The method of estimating the dry matter density of silage according to the present invention is by using a device having a shaft penetrating the deposited silage and a measuring instrument for measuring the frictional resistance value between the deposited silage and the surface of the shaft. Can be carried out. The frictional resistance value measured by the measuring instrument can be converted into a dry matter density based on the correlation between the frictional resistance value and the dry matter density of silage.

The correlation can be obtained in advance by using the method described later. When estimating the dry matter density based on the correlation obtained in advance, use it as a correlation diagram showing the correlation, use it as a calibration curve (correlation formula), or correspond to the frictional resistance value based on the calibration curve. It can be used as a conversion table showing the result of obtaining the dry matter density of the silage.

The numerical value of the dry matter density obtained by using the correlation diagram, the calibration curve or the conversion table is estimated to be the dry matter density of the silage whose frictional resistance value is measured. The frictional resistance value is the rotational resistance value (also called torque) when the shaft penetrated into the silage is rotated around the axis of the shaft, the penetration resistance value when the shaft is penetrated into the silage, or the shaft is pulled out from the silage. It can be any of the pull-out resistance values of the time, or a combination thereof.

The device used to estimate the dry matter density of silage according to one embodiment of the present invention comprises a shaft that penetrates the deposited silage. The shaft is preferably provided with a tip portion formed at the tip end of the rod so as not to disturb the silage when penetrating into the silage. The shaft is preferably one in which the rod and the tip portion are integrally formed, but may be one in which the separately formed rod and the tip portion are connected.

When measuring the rotational resistance value, the cross section of the shaft is preferably a circular shape or a polygonal shape close to a circular shape, and the tip portion is preferably a conical shape or a polygonal pyramid shape close to a conical shape. When measuring the penetration resistance value or the pull-out resistance value, the cross section does not necessarily have to be circular, and may be elliptical, polygonal or flat, and the tip is not conical but elliptical pyramid. It may have a polygonal cone shape or a plane cone shape. The shaft is preferably made of a material having high strength and excellent workability, and for example, it is preferable to use a metal such as steel, aluminum alloy, stainless steel, or duralumin.

By forming the tip of the shaft into a cone shape, the shaft can be penetrated into the silage without disturbing the silage. By penetrating the shaft without disturbing the silage, it becomes difficult for the silage near the surface of the shaft to be disturbed, and the frictional resistance can be measured accurately. Further, when the tip portion has a conical shape, the apex angle is preferably 30 ° or less, more preferably 15 °. If the apex angle is larger than 30 °, the resistance at the tip when the shaft penetrates the silage increases, the silage near the surface of the shaft is disturbed, and the frictional resistance cannot be measured accurately. Greater force will be required when the shaft penetrates.

The thickness of the shaft is not limited, but is preferably 10 to 14 mm when it is assumed that the operator manually penetrates or pulls out the shaft. If it is thicker than 14 mm, the resistance at the time of penetration becomes large, and it is considered that it becomes difficult for the operator to perform the penetration manually. If it is thinner than 10 mm, deformation may occur when the shaft is penetrated into the silage. The length of the shaft penetrating into the silage is not particularly limited, but it is preferable that the rod portion is about 250 mm in addition to the conical tip portion. As the penetration length becomes longer, the resistance during penetration, rotation or withdrawal increases, which may exceed the upper limit of measurement tolerance of the measuring instrument or increase the degree of dispersion of the repeatedly measured values. For example, when the silage is attached to a farming tool for taking out silage, the shaft may be subjected to a force more than human power, so it is preferable to change the thickness and length of the shaft. However, in this case, it is necessary to newly obtain the correlation between the frictional resistance value and the dry matter density by using the changed shaft.
The inventor of the present invention has sought a preferable shape of the shaft in the present embodiment by experiments, and for details of the experiments and the results, refer to Examples.

The device used to estimate the dry matter density of silage according to one embodiment of the present invention further comprises a measuring instrument capable of measuring the frictional resistance value between the deposited silage and the surface of the shaft. The frictional resistance value is the rotational resistance value when the shaft penetrated into the silage is rotated around the axis of the shaft, the penetration resistance value when the shaft is penetrated into the silage, or the withdrawal resistance value when the shaft is pulled out from the silage. Can be either. When measuring the rotational resistance value, for example, a torque driver or a torque wrench, which is a driver provided with a measuring unit capable of measuring rotational torque, can be used as the measuring instrument, although it is not limited. .. Further, when measuring the penetration resistance value or the pull-out resistance value, the measuring instrument is not limited, and for example, it is possible to measure a force applied to an object (for example, a pressing force, a tensile force, a peeling force, etc.). A force gauge, which is a measuring instrument, can be used.

The device used for estimating the dry matter density of silage according to one embodiment of the present invention further has a conversion unit for converting the measured frictional resistance value into the dry matter density of silage. The conversion unit may include a correlation diagram, a calibration curve (correlation formula), a conversion table, etc. showing the correlation between the measured frictional resistance value and the dry matter density. Alternatively, the conversion unit stores a correlation diagram, a calibration curve, or a conversion table showing the correlation as electronic data, and based on these correlations, the dry matter density corresponding to the frictional resistance value input by either method. It can also be a general-purpose personal computer equipped with software that is configured to automatically output. The conversion unit is a rotation resistance conversion unit that can be used when estimating the dry matter density using the rotation resistance value, a penetration resistance conversion unit that can be used when estimating the dry matter density using the penetration resistance value, and a extraction resistance. It can be any of the extraction resistance conversion units that can be used when estimating the dry matter density using the value.
For details of the experiments and results for obtaining the correlation in this embodiment, refer to Examples.

[Method of estimating dry matter density]
FIG. 1 is a flow 100 for estimating the dry matter density of silage. The method for estimating the dry matter density of silage by measuring the penetration resistance value or the withdrawal resistance value is as follows. First, a measuring instrument (for example, a force gauge) for measuring the penetration resistance is attached to the shaft (S102), and the indicated value of the measuring instrument is calibrated to zero (S103). When the silage is disturbed at the place where the dry matter density is estimated, it is preferable to adjust the disturbance or change it to another place when the internal disturbance is particularly large (S104). The estimation target location is not limited, but is preferably a location where the pressure from the surroundings acts substantially evenly, and thus is preferably the central portion of the measurement cross section of the opened silage. This method is usually used to estimate the dry matter density of silage after opening the silo, but if necessary, it can also be used to estimate the dry matter density of silage taken out from the roll bale silage. Can be used.

Next, the penetration of the shaft is started at any of the measurement positions of the estimation target points (S105). The penetration speed of the shaft is not particularly limited, and can be appropriately selected according to the specifications of the measuring instrument. In the examples described later, the penetration was performed at a speed of 10 cm / sec. After penetrating to a predetermined shaft length, the indicated value of the measuring instrument is read and the value is recorded (S106). This value becomes the penetration resistance value.

When measuring the withdrawal resistance value, after recording the penetration resistance value, the reading of the measuring instrument is calibrated to zero (S107), and the withdrawal of the shaft is started (S108). If the penetration resistance value is not measured and only the pull-out resistance value is measured, the shaft is penetrated to a predetermined length (S105), the measuring instrument is calibrated (S107), and the pull-out is started (S108). )be able to. The pull-out speed of the shaft is not particularly limited, and can be appropriately selected according to the specifications of the measuring instrument. In the examples described later, it was pulled out at a speed of 10 cm / sec. After pulling out a predetermined shaft length, the indicated value of the measuring instrument is read and the value is recorded (S109). This value becomes the pull-out resistance value.

The above-mentioned measurement of the penetration resistance value and / or the withdrawal resistance value is repeated a plurality of times at a position close to the first measurement position (S110), and the average value of the plurality of measurement values is calculated (S111). It is preferable to use the average value as the frictional resistance value of the estimation target location. The number of repetitions is not limited, and can be appropriately determined in consideration of the degree of variation in resistance value and the like. When the measurement is repeated, it is preferable that the measurement is performed at a position separated by about 10 to 15 cm in the left-right direction of the initial measurement position, although it is not limited. The measured penetration resistance value and / or extraction resistance value is converted into the dry matter density of silage by using the penetration resistance conversion unit and / or the extraction resistance value conversion unit (for example, conversion table) (S112).

The method for estimating the dry matter density by measuring the rotation resistance value is as follows. First, a measuring instrument (for example, a torque driver) for measuring the rotational resistance is attached to the shaft (S102), and the indicated value of the measuring instrument is calibrated to zero (S103). The estimation target location is the same as the above-mentioned measurement of the penetration resistance value.

Next, the penetration of the shaft is started at any of the measurement positions of the estimation target points (S105). The penetration speed of the shaft is not particularly limited, and can be appropriately selected according to the specifications of the measuring instrument. In the examples described below, the shaft was penetrated at a speed of 10 cm / sec. After penetrating to a predetermined shaft length, the torque driver is rotated (S113), the indicated value of the measuring instrument is read, and the value is recorded (S114). This value becomes the rotation resistance value. The rotation speed of the torque driver is not particularly limited, and can be appropriately selected according to the specifications of the measuring instrument. In the embodiments described below, the shaft was rotated at a speed of 90 ° / sec.

As in the case of the penetration resistance value, the resistance measurement is repeated a plurality of times at a position close to the first measurement position (S110), the average value of the multiple measurement values is calculated (S111), and this average value is calculated. It is preferable to use it as the rotation resistance value of the estimation target location. The measured rotation resistance value is converted into the dry matter density of silage using a rotation resistance conversion unit (for example, a conversion table) (S112).

[How to find the correlation]
The method for obtaining the correlation (correlation diagram, calibration curve or conversion table) between the rotation resistance, penetration resistance or pull-out resistance and the dry matter density is as follows. FIG. 2 is a flow 200 for obtaining a correlation. In the flow 200, first, a container having a predetermined internal dimension is prepared so that the true density of silage can be obtained (S202). In this embodiment, a rectangular parallelepiped wooden container having an internal dimension of 102 mm × 103 mm × 400 mm was used. The container was provided with a plurality of holes for inserting the shaft on the side surface of one end in the longitudinal direction.

When determining the correlation between the penetration resistance value and the withdrawal resistance value and the dry matter density, prepare a silage with a known water content (S203), fill the container with a predetermined amount of silage uniformly, and prepare the contents. The lid is fixed so that the amount does not change (S204). After calibration of the measuring instrument (S205), the shaft is penetrated into the silage from one of the plurality of holes provided in the container (S206), and the penetration resistance value is measured (S207). When determining the correlation between the pull-out resistance and the dry matter density as needed, after measuring the penetration resistance value, calibrate the measuring instrument (S208), pull out the shaft (S209), and measure the pull-out resistance value. (S210). The method for measuring the penetration resistance value and / or the withdrawal resistance value is as described above. Next, the shaft is penetrated and pulled out in another hole (preferably two other holes) among the plurality of holes, and the penetration resistance value and / or the pull-out resistance value are measured in the same manner (S211). .. The average value of the penetration resistance value and / or the withdrawal resistance value measured in the plurality of holes is obtained (S212).

Next, the silage is taken out of the container, the container is uniformly filled with an amount of silage different from the initial amount, the penetration resistance value and / or the withdrawal resistance value is obtained in the same manner, and the silage is taken out from the container. In this way, the silage filling and the measurement of the frictional resistance value are repeated for silages having different filling amounts (S204 to S212).

Further, the silage is taken out from the container, a silage having a known water content different from the initially measured water content is prepared (S203), and the container is uniformly filled with a predetermined amount of silage, and similarly, the penetration resistance value and the penetration resistance value and / Or find the pull-out resistance value and take out the silage from the container. Even with this amount of water, the filling and the measurement of the frictional resistance value are repeated for silages having different filling amounts (S204 to S212). In this way, the silage filling and the measurement of the frictional resistance value are repeated for silage having different water content and filling amount (S203 to S212).

The actual density of each amount of water filled in the container and the silage of the filling amount can be obtained from the weight of the filled silage and the internal volume of the container, and the dry matter density can be obtained from the actual density of the silage and the water content (S213). ). The plurality of values as the physical density and the dry matter density obtained in this way can be regarded as the true values of the silage density. By plotting the penetration resistance value and / or the extraction resistance value and the dry matter density of the silage as a scatter diagram, a correlation diagram between the penetration resistance value and / or the extraction resistance value and the dry matter density of the silage can be obtained. Further, an approximate expression of the correlation can be obtained from the penetration resistance value and / or the withdrawal resistance value and the dry matter density of the silage, and this approximate expression can be used as a calibration curve. Further, a conversion table can be obtained by displaying a specific penetration resistance value or extraction resistance value and a corresponding dry matter density in a table using a correlation diagram or a calibration curve (S214).

The case of obtaining the correlation between the rotation resistance value and the dry matter density is the same as that of the penetration resistance value and the pull-out resistance value. That is, a silage having a known amount of water contained is prepared (S203), a predetermined amount of silage is uniformly filled in the container (S204), the shaft is penetrated into the silage (S206), and then the rotational resistance value is measured (S206). S215, S216 and S211) to calculate the average value (S212). Repeat this process for silage with different water and filling amounts, determine the true dry matter density of the silage for each water and filling amount (S213), and plot the rotational resistance and the dry matter density of the silage as a scatter plot. Therefore, a correlation diagram between the rotation resistance value and the dry matter density of silage is obtained (S214). In addition, an approximate equation for the correlation can be obtained from the rotational resistance value and the dry matter density of the silage, and this approximate equation can be used as a calibration curve. Furthermore, a specific rotational resistance value and the corresponding dry matter density are shown in the table. A conversion table can be obtained.

[Other Embodiments]
In the above-described embodiment, the dry matter density of silage is estimated using any one of the rotational resistance value, the penetration resistance value, and the frictional resistance value. However, in another embodiment, the combination of rotational resistance, penetration resistance and withdrawal resistance can be used to estimate the dry matter density of silage. For example, after obtaining the dry matter density values using the correlation diagram, calibration line or conversion table corresponding to any two or all of the measured rotation resistance value, penetration resistance value and withdrawal resistance value, these Compare any two or all of the multiple values, namely the dry matter density value corresponding to the rotational resistance value, the dry matter density value corresponding to the penetration resistance value, and the dry matter density value corresponding to the withdrawal resistance value. The measurement error of the numerical values of these densities can be obtained, and the numerical value having the smaller measurement error (that is, more accurate) can be adopted as the estimated value of the dry matter density of the silage.

Alternatively, using any two or all of the rotation resistance value, the penetration resistance value, and the pull-out resistance value as explanatory variables, the dry matter density as the objective variable, and a plurality of frictional resistance values and the dry matter densities corresponding to those values in advance. The multiple regression equation (correlation) is obtained by performing multiple regression analysis, and any two or all of the rotation resistance value, penetration resistance value, and pull-out resistance value of the silage that is the actual measurement target are converted into the multiple regression equation. The numerical value of the dry matter density obtained by inputting can be used as an estimated value of the dry matter density of the silage.

Examples of the method of selecting the shaft shape and the method of obtaining the correlation (specifically, creating a correlation diagram and a calibration curve) and the results thereof are shown below. 3 and 4 are diagrams showing the correlation between the dry matter density of the silage sample and the penetration resistance value, the pull-out resistance value and the rotation resistance value, and FIG. 3 is a diagram showing the correlation of the first grass silage mainly composed of Timothy. FIG. 4 is a correlation diagram of silage of feed corn.

(1) Shaft manufacturing and selection <Shaft manufacturing>
The shaft can be used for measuring the penetration resistance value, the pull-out resistance value, and the rotational resistance value, and a duralumin round bar having high strength, light weight, and excellent machinability is adopted. To determine the preferred shape of the shaft, round bars with lengths of 350 mm, diameters of 5 mm, 8 mm, 10 mm, 12 mm and 15 mm are prepared and the apex angles of the tip cones are 15 °, 30 °, 60 ° and 90 °. And 25 shafts processed so as to be 120 ° were manufactured. Marks were provided every 50 mm on the shaft columnar portion starting from the end of the conical tip portion.

<Shaft selection>
In a bunker silo where Timothy-based silage No. 1 is stored, penetration resistance and rotation are applied to two undisturbed silage cross sections, low density (upper silo) and high density (lower center silo). The resistance and pull-out resistance were measured, and the appropriate shaft shape was determined from the range of various measured values, the linear shape drawn by the resistance values, and the situation at the time of measurement. In the measurement, after measuring the penetration resistance of the tip of the conical shape of the 25 shafts, the penetration resistance value and the rotation resistance value are measured every time the shaft is penetrated by 50 mm, and the shaft cylindrical portion is penetrated to 250 mm. After that, the shaft was pulled out, and the pull-out resistance value was measured every 50 mm. A high load digital force gauge (ZPH-5000N manufactured by IMADA) was used in the measurement of the penetration resistance value and the pull-out resistance value. A torque driver (Tohnichi FTD200CN2-S) was used in the rotation resistance measurement.

Table 1 shows the measurement results for shaft selection. First, when 25 shafts were manually penetrated into the high-density silage cross section, the shafts having diameters of 5 mm and 8 mm were confirmed to be bent at the time of penetration. With a shaft having a diameter of 15 mm, the penetration resistance value reached 500 N or more over the entire conical tip portion, and the penetration work was difficult. Similarly, when the tip angle of the conical tip is 60 ° or more in the case of a shaft with a diameter of 12 mm, and when the tip angle is 90 ° or more in the case of a shaft with a diameter of 10 mm, the penetration resistance value is 500 N or more. It reached, and the intrusion work was difficult. In addition, when the resistance value at the time of penetration is represented by a graph, a linear graph shape is generally shown when the tip angle is acute, but a logarithmic function graph shape is shown when the tip angle is obtuse. Since the graph shape of the logarithmic function was obtained when the tip angle was large for the shafts of any diameter, it was confirmed that the shaft with a large tip angle may disturb the penetration portion. When the tip angle was 30 ° or less, the error due to repeated measurement at the time of penetration was relatively small, and the error was the minimum when the tip angle was 15 °. Further, as the penetration length of the shaft became deeper, all of the penetration resistance value, the pull-out resistance value and the rotational resistance value increased. From the above results, it was judged that the appropriate shape of the shaft is a tip angle of 15 °, a diameter of 12 mm, and an effective penetration length of 250 mm (+ tip length).

(2) Derivation of the correlation between silage density and frictional resistance value, and comparison with the conventional method <Measurement method>
Using the shaft having the shape determined as described above, the Timothy-based No. 1 grass silage (hereinafter referred to as "grass") and the corn silage for feed (hereinafter referred to as "corn") collected from the bunker silo are respectively. Silage samples with different water contents were prepared by stepwise air-drying at a temperature of 30 to 35 degrees. The water content of the prepared grass was 23.9%, 45.3%, 63.3%, 70.4% and 80.3%, and the water content of the corn was 16.2% and 44. There were 5 levels of 8.8%, 59.2%, 66.1% and 70.0%. Each of these silage samples having different water contents was filled in a housing having an internal size of 102 mm × 103 mm × 400 mm and an effective internal capacity of 4202 ml by changing the filling amount in five stages. The shaft was penetrated through a hole provided on the side surface of the housing, and the penetration resistance value, the pull-out resistance value, and the rotation resistance value of the silage sample for each water content and filling amount were measured three times each. The penetration speed and pull-out speed of the shaft were 10 cm / sec, and the rotation speed was 90 ° / sec. Simultaneously with the measurement of these resistance values, the density measurement by the conventional method using an electric core sampler having an inner dimension of 66 mm, an outer dimension of 69 mm, and an effective depth of 200 mm was performed three times for each silage sample of the water content. From the weight and water content of the silage sample filled in the housing and the dimensions of the housing, the actual density and dry matter density of the silage sample were obtained and set as true values, and the penetration resistance value, pull-out resistance value, rotation resistance value and silage A correlation diagram between the actual density and the dry matter density of the sample was created, a calibration curve was obtained, and the estimation accuracy of the dry matter density by each resistance value was compared. At the same time, for the conventional method, a correlation diagram was created, a calibration curve was obtained, and the estimation accuracy of the dry matter density was compared.

<Result>
Although there was a certain tendency between the actual density of the silage sample and each frictional resistance value, there was no highly correlated approximation formula (not shown). However, an extremely high correlation was confirmed for each resistance value in the relationship between the dry matter density of the silage sample and each frictional resistance value, and a very accurate quadratic curve was obtained (FIGS. 3 and 4). ). The approximate expressions of FIGS. 3 and 4 and the correlation coefficients of the respective approximate expressions are shown below.

Approximate formula of Timothy-based, No. 1 grass silage (grass) (correlation coefficient (R ² ))
Penetration resistance y = 0.0005 x ^2.5343 (R ² = 0.9237)
^Pull -out resistance y = 9 x ^10-5 x ^2.7842 (R ² = 0.9409)
Rotation resistance y = 3 x ^10-5 x ^2.9087 (R ² = 0.9672)

Approximate formula of corn silage (corn) for feed (correlation coefficient (R ² ))
Penetration resistance y = 2 x ^10-7 x ^3.8928 (R ² = 0.9482)
^Pull -out resistance y = 2 x ^10-8 x ^4.2274 (R ² = 0.9332)
Rotational resistance y = 2 x ^10-8 x ^4.2275 (R ² = 0.962)

Therefore, by using this correlation, the dry matter density of silage can be estimated with high accuracy from the measured frictional resistance value. On the other hand, in the density measurement of silage samples by the conventional method using an electric core sampler, both grass and corn have a very high correlation with the actual density (correlation coefficients are 0.92 and 0.96, respectively). Although it was confirmed, the correlation was low for the dry matter density (correlation coefficients were 0.76 and 0.83, respectively), and the correlation for grass was particularly low. This is thought to be due to the elasticity of the material. FIG. 5 shows the correlation between the silage density in the housing and the silage density measured by the core sampler method.

FIG. 6 shows 3 for each sample for each method, namely, the dry matter density estimated by the dry matter density estimation method based on the penetration resistance value, the pull-out resistance value and the rotational resistance value, and the dry matter density measured by the core sampler method. The coefficient of variation calculated from the measurement of the times is shown. From FIG. 6, it can be seen that the accuracy is highest when the rotation resistance value is used. It is considered that the reason why the coefficient of variation becomes large when the penetration resistance value is used is that the resistance due to the conical tip is affected. Further, even if the shaft has a small tip angle, the silage is not a little disturbed at the time of penetration, so it is considered that the error due to the disturbance has an influence even when the pull-out resistance value is used.

From the above results, it can be seen that the frictional resistance value has an extremely high correlation with the dry matter density of silage, and the estimation based on the rotational resistance value is the most accurate. Further, in the method of determining the dry matter density using the frictional resistance value, it is considered that the frictional resistance value is highly related to the fiber portion of the silage and is not affected by the water content of the silage.

Claims (8)

A method for estimating the dry matter density of silage and its raw materials (hereinafter referred to as "silage, etc.").
The step of penetrating the shaft into the accumulated silage, etc.
The step of measuring the frictional resistance value between the silage and the like and the shaft,
A dry matter comprising a step of obtaining the dry matter density of the silage or the like corresponding to the measured frictional resistance value based on a predetermined correlation between the frictional resistance value and the dry matter density of the silage or the like. Density estimation method. The dry matter according to claim 1, further comprising a step of obtaining the correlation in advance based on the frictional resistance value between the shaft and the silage or the like and the dry matter density of the silage or the like in which the frictional resistance value is measured. Density estimation method. The step of obtaining the correlation in advance is
Filling a predetermined container with silage, etc. with a known water content,
Inserting the shaft into the silage or the like filled in the container
Measuring the frictional resistance value between the shaft and silage, etc.
Filling the container with silage, etc., inserting the shaft into the silage, etc., and measuring the frictional resistance value are repeated for silage, etc. with different water content and filling amount.
To calculate the density of each dry matter such as the amount of water filled in the container and the amount of silage with different filling amounts.
The second aspect of claim 2, wherein a plurality of measured frictional resistance values and a plurality of calculated dry matter densities are used to determine a correlation between the frictional resistance value and a dry matter density such as silage. Dry matter density estimation method. The frictional resistance value between the silage or the like and the shaft is the rotational resistance value when the shaft penetrated into the silage or the like is rotated around the axis of the shaft, or when the shaft is penetrated into the silage or the like. The dry matter density estimation method according to any one of claims 1 to 3, which is either the penetration resistance value of the above, the pull-out resistance value when the shaft is pulled out from the silage or the like, or a combination thereof. .. The dry matter density estimation method according to any one of claims 1 to 4, wherein the shaft has a circular cross section. The dry matter density estimation method according to claim 5, wherein the shaft has a conical tip portion. A device used to estimate the dry matter density of silage and its raw materials (hereinafter referred to as "silage, etc.").
A shaft that penetrates the accumulated silage, etc.
A measuring instrument that measures the frictional resistance value between the silage and the like and the shaft,
A conversion unit that includes a correlation for converting the frictional resistance value into dry matter density such as silage,
A dry matter density estimator comprising. The correlation is obtained in advance based on the frictional resistance value between the shaft and the silage or the like and the dry matter density of the silage or the like in the portion where the frictional resistance value is measured. The dry matter density estimator according to.

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