JP6749537B2 - Moisture analyzer and grain dryer - Google Patents

Description

The present invention relates to a moisture measuring device for measuring moisture contained in grains and a grain dryer.

Conventionally, this type of moisture measuring device is provided in, for example, a grain dryer for drying grains, and is included in some grains of the accommodated grains in order to confirm the degree of drying of the grains. A device for measuring water content is known (for example, see Patent Document 1).

The moisture measuring apparatus includes a moisture measuring mechanism including a pair of rollers and a measuring unit that measures an electric resistance between the pair of rollers. The moisture measuring device, in the moisture measuring mechanism, crush the grains between the outer peripheral surface of the pair of rollers, by measuring the electrical resistance between the pair of rollers by the measuring unit, in the crushed grain The water content is measured electrically.

In the moisture measuring device, since the moisture contained in the grain is measured by sandwiching and crushing the grain between the outer peripheral surfaces of the pair of rollers, the moisture content is measured according to the size of the grain to be measured. It is necessary to set the distance between the outer peripheral surfaces of the rollers forming the. Therefore, for example, when measuring the moisture contained in small grains such as paddy and wheat, the interval between the outer peripheral surfaces of the paired rollers is set to be small, and the moisture contained in large grains such as soybeans and corn is adjusted. When measuring, it is necessary to set a large interval between the paired rollers.

In the moisture measuring device, a hopper into which grains for measuring moisture are put, a plurality of moisture measuring units in which intervals between rollers forming pairs according to the size of grains for measuring moisture are different from each other, and a plurality of hoppers. Other than the end of one of the plurality of communication passages, which communicates with each of the moisture measurement portions of, and supplies the grains that have been put into the hopper to each of the moisture measurement portions, Is provided with a communication passage closing member that closes the end of the communication passage and a holding opening that holds the grain, and the grain held in the holding opening by rotating in the hopper is the end of the one communication passage. And a grain moving plate for moving the grain. The water content measuring device can measure the water content of a plurality of types of grains having different grain sizes.

JP, 2014-169885, A

In the water content measuring device, when the size of the grain changes due to a change in the type of grain whose water content is measured, the work of switching the communication passage to be closed by the communication passage closing member and a size suitable for the size of the grain. There are two switching operations, one is a switching operation for switching to the grain moving plate having the holding opening.

An object of the present invention is to provide a moisture measuring device and a grain dryer that can easily perform a switching operation even when the grain size changes due to a change in the grain type for moisture measurement. It is in.

The moisture measuring device of the present invention is a moisture measuring device having a plurality of moisture measuring units for measuring moisture contained in grains having mutually different sizes in order to achieve the above-mentioned object, and measures moisture. A hopper into which the grains are put, a plurality of communication passages that connect each of the hopper and each of the plurality of moisture measuring units are provided, and a communicating member that supplies the grains that have been put into the hopper to the respective moisture measuring units, Each is detachably attached to the hopper, and is formed in a plate shape with a holding opening for holding the grains put into the hopper, and is held in the holding opening by performing a predetermined operation in the hopper. A plurality of grain moving members for moving the grain, and a plurality of communication holes for communicating the plurality of communication passages with the spaces in the hopper are provided on the inner surface of the hopper, and the plurality of grain moving members are provided. Each of the holding openings is formed to have a different size depending on the size of the grain to be held, and first passes over different communication holes during a predetermined operation.

As a result, when changing the size of the grain for measuring the water content, the grain introduced into the hopper is supplied to the corresponding moisture measuring unit by changing only the grain moving member.

According to the moisture measuring device of the present invention, when changing the size of the grain for measuring the contained moisture, by changing only the grain moving member, the moisture measured corresponding to the grain put into the hopper. Since it can be supplied to the parts, it is possible to reduce the number of parts and prevent erroneous setting when measuring the water content of the grain.

It is a schematic block diagram of the grain dryer which shows one Embodiment of this invention. It is the whole moisture measuring device perspective view. It is a side sectional view of a moisture measuring device. It is a front sectional view of a moisture measuring device. It is a figure explaining a some moisture measuring part. It is a front view of a hopper. It is a front view of a 1st grain moving board. It is a front view of a 2nd grain moving board. It is a figure explaining operation which moves a small grain to the 1st communicating hole. It is a figure explaining operation which moves a large grain to a 2nd communicating hole.

1 to 10 show one embodiment of the present invention.

As shown in FIG. 1, the grain dryer 1 of the present invention includes a storage unit 2 for storing grains, a drying unit 3 for drying grains, and a collecting unit for collecting grains falling from the drying unit 3. The grain section 4 and the fried grain section 5 for returning the grain collected in the grain collection section 4 to the storage section 2 are provided.

The storage unit 2 is located on the upper side and stores grains.

The drying unit 3 is provided below the storage unit 2 and heats the grain falling from the storage unit 2 by the circulation operation by, for example, far-infrared rays or hot air to reduce moisture contained in the grain.

The grain collecting unit 4 is provided below the drying unit 3 and collects grains falling from the drying unit 3 by a circulation operation.

The fried grain unit 5 is provided so as to extend vertically on the side surfaces of the storage unit 2, the drying unit 3, and the grain collection unit 4, conveys the grain collected in the grain collection unit 4 upward, and Release to the top. Further, at the lower part of the fried grain section 5, an input port 6 for inputting grains to be dried by the grain dryer 1 is provided. The grain input from the input port 6 is conveyed upward by the fried grain unit 5 and discharged to the upper part of the storage unit 2. Further, at the upper part of the fried grain section 5, a carry-out section for carrying out the grain contained therein is provided.

The grain dryer 1 configured in this way circulates grains in the order of the storage unit 2, the drying unit 3, the grain collecting unit 4, and the fried grain unit 5.

As shown in FIG. 1, the moisture measuring device 10 of the present invention is provided below the side surface of the fried portion 5. The water content measuring device 10 measures the water content contained in a part of the grain of the grain that is conveyed upward in the fried grain unit 5 every predetermined time. The grain dryer 1 detects that the moisture content of the grain measured by the moisture measuring device 10 has reached the set moisture content or moisture percentage during the grain drying operation, and the drying unit 3 and the grain collecting unit It is possible to stop the operations of 4 and the fried portion 5.

As shown in FIG. 2 to FIG. 4, the moisture measuring device 10 is provided in the housing 20 so as to project from the side surface of the fried portion 5, and is provided in the housing 20 to measure moisture contained in the grain. And a grain supply mechanism 40 for supplying grains to the moisture measurement mechanism 30.

As shown in FIG. 2, the housing 20 has a box shape extending in the vertical direction. As shown in FIG. 3, the housing 20 is attached to the side wall of the fried portion 5 with the first side surface 21 facing the fried portion 5. The bottom surface 22 of the housing 20 is inclined downward from the second side surface 23 facing the first side surface 21 toward the first side surface 21. The third side surface 24 adjacent to the first side surface 21 of the housing 20 is provided with a peep window 24a for allowing the inside of the housing 20 to be visually recognized from the outside. As shown in FIG. 4, the interior of the housing 20 is divided into a first space 20a on the third side face 24 side and a second space 20b on the fourth side face 25 side facing the third side face 24 by the partition wall 26. It is partitioned. An inlet 21a for taking in grain is provided in an upper portion of the first side surface 21 of the housing 20 on the first space 20a side. Further, a discharge port 21b for discharging the grain of which moisture is measured by the moisture measuring mechanism 30 is provided in the lower portion of the first side surface 21 of the housing 20 on the first space 20a side.

The moisture measuring mechanism 30 is provided for each grain size for measuring moisture, and has a plurality of moisture measuring units 31 for crushing the grains and an electric motor 32 as a power source for driving the plurality of moisture measuring units 31. And a driving force transmission mechanism 33 for transmitting the driving force of the electric motor 32 to the plurality of moisture measuring units 31.

The plurality of moisture measuring units 31 receives the driving force of the electric motor 32 and is driven by a first rotating shaft 31a.
And the second rotating shaft 31b, the first roller 31c supported by the first rotating shaft 31a, the second roller 31d and the third roller 31e supported by the second rotating shaft 31b, the first roller 31c and the second roller 31c. The measuring unit 31f that measures the electric resistance between the roller 31d and the first roller 31c and the third roller 31e.

The first rotating shaft 31a and the second rotating shaft 31b are each made of metal, and are arranged so that their central axes are parallel to each other in the horizontal direction in the first space 20a. One end side of each of the first rotating shaft 31a and the second rotating shaft 31b is rotatably supported by the partition wall 26.

The first roller 31c is a metal cylindrical member fixed to the outer peripheral portion of the first rotating shaft 31a. The outer peripheral portion of the first roller 31c is subjected to, for example, rolling knurling such as crocheting. Further, a rotating brush 31c1 and a scraper 31c2 are provided near the first roller 31c for removing debris of the grain adhering to the outer peripheral surface of the first roller 31c.

The second roller 31d is a metallic cylindrical member fixed to the outer peripheral portion of the second rotating shaft 31b. The axial dimension of the second roller 31d is approximately half the axial dimension of the first roller 31c. As shown in FIG. 5, a groove 31d1 is formed on the outer peripheral portion of the second roller 31d by, for example, rolling knurling such as slanting or flat stitching. The groove 31d1 is formed with a depth dimension capable of crushing small grains such as paddy and wheat between the outer peripheral portion of the first roller 31c and the outer peripheral portion of the second roller 31d.

The third roller 31e is a metallic cylindrical member fixed to the outer peripheral portion of the second rotating shaft 31b. The axial dimension of the third roller 31e is approximately half the axial dimension of the first roller 31c, and is substantially the same as the axial dimension of the second roller 31d. As shown in FIG. 5, a groove 31e1 is formed on the outer peripheral portion of the third roller 31e by, for example, cutting knurling such as slanting or flattening. The groove 31e1 is deeper than the groove 31d1 of the second roller 31d, which is capable of crushing large grains such as soybeans and corn between the outer circumference of the first roller 31c and the outer circumference of the third roller 31e. It is formed to a size.

The second roller 31d and the third roller 31e are arranged in the axial direction of the second rotating shaft 31b, as shown in FIG. In the present embodiment, the plurality of moisture measuring units 31 define a first moisture measuring unit 31A between the outer peripheral portion of the first roller 31c and the outer peripheral portion of the second roller 31d, and the outer peripheral portion of the first roller 31c and the third roller 31c. A portion between the outer peripheral portion of 31e and the outer peripheral portion is formed as a second moisture measuring portion 31B.

Further, near the second roller 31d and the third roller 31e, a fixed brush 31d2 and a scraper 31d3 for removing the debris of the grain adhering to the outer peripheral surface of the first roller 31c are provided.

Further, each of the plurality of moisture measuring units 31 has a foreign matter removing structure for removing the foreign matter when a foreign matter such as a stone or a metal piece different from the grain is supplied. The foreign matter removing structure is configured such that a part of the outer peripheral portion of the first roller 31c, a part of the outer peripheral portion of the second roller 31d and the third roller 31e, or an outer periphery of the first roller 31c, the second roller 31d and the third roller 31e. It is formed by subjecting a part of the portion to a flat surface, which is so-called D-cut processing.

In the plurality of moisture measuring units 31, when the foreign matter is supplied while the first rotary shaft 31a and the second rotary shaft 31b are driven to measure the moisture of the grain, the foreign matter is transferred to the rollers 31c, 31d, 31e. The rotation of the first rotating shaft 31a and the second rotating shaft 31b is restricted by being bitten. In the plurality of moisture measuring units 31, the rotation of the first rotating shaft 31a and the second rotating shaft 31b is detected when the rotation of the first rotating shaft 31a and the second rotating shaft 31b is restricted and the rotation of the first rotating shaft 31a and the second rotating shaft 31b is measured. The first rotating shaft 31a and the second rotating shaft 31b are rotated in the opposite direction. As a result, the foreign matter put into the moisture measuring unit 31 has a gap formed by D-cut between the first roller 31c and the second roller 31d or between the first roller 31c and the third roller 31e. Is dropped and removed from the moisture measuring unit 31.

The measurement unit 31f measures the electric resistance between the first measurement point 31f1 connected to the first rotation shaft 31a and the second measurement point 31f2 connected to the second rotation shaft 31b. The measurement unit 31f is arranged between the first measurement point 31f1 and the first measurement point 31f1 while the grain is sandwiched between the first roller 31c and the second roller 31d or between the first roller 31c and the third roller 31e. An electric circuit is formed between the two measurement points 31f2. The measurement unit 31f measures the amount of water contained in the grain or the water content by detecting the resistance value of the electric resistance between the first measurement point 31f1 and the second measurement point 31f2.

As shown in FIGS. 3 and 4, the electric motor 32 is provided in the upper part of the first space 20a and is fixed to the partition wall 26.

The driving force transmission mechanism 33 is composed of a plurality of gears, and the rotating shaft of the electric motor 32 is connected to the first rotating shaft 31a and the second rotating shaft 31b. The driving force transmission mechanism 33 is provided in the second space 20b and fixed to the partition wall 26.

As shown in FIG. 3, the grain supply mechanism 40 is provided with a hopper 41 into which the grain is charged, and a plurality of communication passages 42a and 42b that communicate the inside of the hopper 41 with each of the plurality of moisture measuring units 31. The communication member 42 and the grain moving plate 43 as a plurality of grain moving members for moving the grain thrown into the hopper 41 to a predetermined communicating path in the hopper 41 are provided.

The hopper 41 is provided on the upper side of the housing 20 on the side of the fried grain portion 5. The hopper 41 has a tubular shape with one end closed and the other end open. A part of the hopper 41 protrudes toward the fried grain portion 5 side through the intake port 21a, and one end side of the tubular shape is directed obliquely downward. The opening on the other end side of the hopper 41 is directed obliquely upward in the fried grain portion 5. The hopper 41 is provided with a closing plate 41a that closes a part of the opening on the other end side in order to suppress the amount of grain input from the fried grain section 5 into the hopper 41.

The communication member 42 is a member in which a passage that connects one end of the hopper 41 and the upper part of the plurality of moisture measuring units 31 is formed. Specifically, when viewed from the first side surface 21 side of the housing 20, a first communication passage 42a that communicates the hopper 41 and the first moisture measuring unit 31A is formed on the right side, and the hopper 41 and the second moisture measuring unit are on the left side. A second communication passage 42b that communicates with 31B is formed. Further, the end portion of the communication member 42 on the hopper 41 side is connected to the upper side of one end surface of the hopper 41, and as shown in FIG. The first communication hole 42a1 is formed, and the second communication hole 42b1 of the second communication passage 42b is formed on the left side of the first communication hole 42a1. On one end surface of the hopper 41, the second communication hole 42b1 is opened to the inside in the radial direction with respect to the radial arrangement of the first communication hole 42a1.

As shown in FIGS. 7 and 8, the plurality of grain moving plates 43 are disk-shaped members having an outer diameter dimension that is substantially the same as the inner diameter dimension on one end side of the hopper 41, and are centered on the radial center portion. Is rotatably supported by the hopper 41 in a detachable manner. The grain moving plate 43 can rotate in the forward and reverse directions by transmitting the power of the electric motor 32. The grain moving plate 43 is provided with a holding opening 43a for holding the grains put into the hopper 41 and moving the grains along one end surface inside the hopper 41 by a rotating operation. The holding opening 43a is formed by cutting out the outer peripheral portion of the grain moving plate 43 or punching a predetermined radial position. In the grain moving plate 43, the size and the position of the holding opening 43a are determined according to the size of the grain to be moved and the positions of the communication holes 42a1 and 42b1 on the one end surface in the hopper 41. The holding opening 43a is formed in a size capable of holding one grain.

In the present embodiment, the grain moving plate 43 includes a first grain moving plate 43-1 for moving a small grain such as paddy or wheat to the first communication hole 42a1 and a large grain such as soybean or corn. The second grain moving plate 43-2 for moving the grain to the second communication hole 42b1 is used. The 1st grain moving board 43-1 and the 2nd grain moving board 43-2 are replaced with respect to the hopper 41 according to the size of the grain which measures the moisture contained.

The first grain moving plate 43-1 has a holding opening 43a formed by cutting out the outer peripheral portion. The first grain moving plate 43-1 is formed with a plurality of holding openings 43a at predetermined intervals in the circumferential direction.

The second grain moving plate 43-2 has a holding opening 43a formed radially inward of the holding opening 43a of the first grain moving plate 43-1. The second grain moving plate 43-2 has one holding opening 43a formed in the circumferential direction. The holding opening 43a of the second grain moving plate 43-2 is larger than the holding opening 43a of the first grain moving plate 43-1.

In the moisture measuring apparatus 10 configured as described above, when the operation of drying the grain by the grain dryer 1 is performed, the grain moving plate 43 is attached to the hopper 41 according to the type of grain to be dried. When the grain to be dried is a small grain such as paddy or wheat, the first grain moving plate 43-1 is attached to the hopper 41. When the grain to be dried is a large grain such as soybean or corn, the second grain moving plate 43-2 is attached to the hopper 41.

During the drying operation of the grain by the grain dryer 1, in the moisture measuring device 10, the grain moving plate 43 is rotated and the moisture measuring mechanism 30 is driven in a state where the grain is put in the hopper 41. , Measure the water content in the grain.

When the grain moving plate 43 is rotated counterclockwise in the hopper 41 into which the grains are put, the holding opening 43a of the grain moving plate 43 passes under the hopper 41, so that the inside of the hopper 41 One grain is in a state of being held in the holding opening 43a.

One grain held in the holding opening 43a moves upward along the one end face in the hopper 41 by the rotation of the grain moving plate 43. The grain held in the holding opening 43a that moves along the one end face in the hopper 41 has a communication passage 42a when the position of the holding opening 43a matches the positions of the communication holes 42a1 and 42b1 on the one end face in the hopper 41. , 42b to be supplied to the moisture measuring mechanism 30, and the moisture is measured in any of the moisture measuring units 31A and 31B.

Here, when the 1st grain moving board 43-1 is attached in the hopper 41, since the holding opening 43a is provided in the outer peripheral part, it is counterclockwise from the lower side in the hopper 41. When it moves, it first passes over the first communication hole 42a1 as shown in FIG. Therefore, the grain S held in the holding opening 43a is supplied to the first moisture measuring unit 31A through the first communication hole 42a1 and the first communication passage 42a. The grain S supplied to the first moisture measuring unit 31A measures the electrical resistance in a crushed state between the first roller 31c and the second roller 31d to measure the moisture contained therein. The grain S crushed between the first roller 31c and the second roller 31d is discharged to the outside of the housing 20 through the discharge port 21b.

In addition, when the second grain moving plate 43-2 is attached inside the hopper 41, the holding opening 43a is provided radially inside the holding opening 43a of the first grain moving plate 43-1. Therefore, when it moves counterclockwise from the lower side of the hopper 41, it first passes over the second communication hole 42b1 as shown in FIG. Therefore, the grain L held in the holding opening 43a passes through the first communication passage 42b via the second communication hole 42b1 and is supplied to the second moisture measuring unit 31B. The grain L supplied to the second moisture measuring unit 31B measures the electrical resistance in a state of being crushed between the first roller 31c and the third roller 31e, and thereby the moisture contained therein is measured. The grain L crushed between the first roller 31c and the third roller 31e is discharged from the discharge port 21b to the outside of the housing 20.

As described above, according to the moisture measuring apparatus of the present embodiment, the holding openings 43a of the plurality of grain moving plates 43 are formed in different sizes according to the size of the grains to be held, and have a predetermined size. During operation, it first passes over the mutually different communication holes 42a1 and 42b1.

Thereby, when changing the size of the grain which measures the water content, only the grain moving plate 43 is changed and the grain thrown into the hopper 41 is supplied to the corresponding moisture measuring unit 31. Therefore, it is possible to reduce the number of parts, and it is possible to prevent erroneous setting when measuring the water content of the grain.

Each of the plurality of grain moving plates 43 is formed in a disc shape, and as a predetermined operation, performs a rotating operation centering on the radial center in the hopper 41, and positions different from each other in the radial direction. And a plurality of communication holes 42a1 and 42b1 are provided at positions corresponding to the respective holding openings 43a of the plurality of grain moving plates 43.

As a result, since the grain moving plate 43 that performs the rotating operation can move the grains in the hopper toward the communication holes 42a1 and 42b1, a large operation space during operation of the grain moving plate 43 can be obtained. Since it is not necessary, the device can be downsized.

In addition, the plurality of moisture measuring units 31 each include rollers 31c, 31d, and 31e that form a pair to crush the grain.

This makes it possible to change the size of the grain whose moisture is to be measured by using rollers having different outer peripheral shapes, which facilitates the setting change.

In addition, in the said embodiment, although the grain moving plate 43 which moves the grain thrown into the hopper 41 by a rotation operation was shown, it is not restricted to this. A grain moving plate that can reciprocate in a predetermined direction in the hopper may be used as long as it can move the grains put into the hopper 41.

Further, in the above-described embodiment, the plurality of moisture measurement units 31 are configured by the first roller 31c and the second roller 31d, and the first roller 31c and the third roller 31e, which form a pair, but the present invention is not limited to this. It is not something that can be done. It is not limited to the moisture measuring unit having a pair of rollers as long as the member for measuring moisture is changed according to the grain size.

Moreover, in the said embodiment, the water|moisture content of two types of grain is measured by two moisture measuring parts 31A and 31B, two communicating paths 42a and 42b, and two grain moving plates 43-1 and 43-2. However, the present invention is not limited to this. It is also possible to measure the moisture content of grains of three or more sizes by providing three or more moisture measuring units, three or more communication passages, and three or more grain moving plates.

DESCRIPTION OF SYMBOLS 1... Grain dryer, 10... Moisture measuring device, 31... Moisture measuring part, 31A... 1st moisture measuring part, 31B... 2nd moisture measuring part, 41... Hopper, 42... Communication member, 42a... 1st communicating path, 42a1... 1st communicating hole, 42b... 2nd communicating path, 42b1... 2nd communicating hole, 43... Grain moving plate, 43a... Holding opening, 43-1... 1st grain moving plate, 43-2... 2nd Grain transfer board.

Claims (4)

A moisture measuring device comprising a plurality of moisture measuring units for measuring moisture contained in grains of mutually different sizes,
A hopper into which the grains for measuring water content are added,
A plurality of communication passages that connect each of the hopper and each of the plurality of moisture measurement units are provided, and a communication member that supplies the grain put into the hopper to each of the moisture measurement units,
Each is detachably attached to the hopper, and is formed in a plate shape with a holding opening for holding the grains put into the hopper, and is held in the holding opening by performing a predetermined operation in the hopper. A plurality of grain moving members for moving the selected grains,
The inner surface of the hopper is provided with a plurality of communication holes that respectively communicate a plurality of communication passages with the space inside the hopper,
A moisture measuring device in which the holding openings of the plurality of grain moving members are formed to have different sizes according to the size of the grains to be held and first pass over different communication holes during a predetermined operation. Each of the plurality of grain moving members is formed in a disc shape, and as a predetermined operation, performs a rotating operation about a radial center in the hopper, and holding openings are provided at different positions in the radial direction. Formed,
The moisture measuring device according to claim 1, wherein the plurality of communication holes are provided at positions corresponding to respective holding openings of the plurality of grain moving members. The moisture measuring device according to claim 1 or 2, wherein the plurality of moisture measuring units each have a pair of rollers that crush the grain. A grain dryer for accommodating and drying grains,
A moisture measuring device according to any one of claims 1 to 3 is provided,
A grain dryer that measures the moisture content of grains stored by a moisture measuring device.

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