JP6603244B2 - Automatic measuring device for crab noodles and method for producing subdivided crab noodles - Google Patents

Description

  BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic measuring device for strawberry noodles and potato noodles, and more particularly to a device for automatically separating potato noodles such as pasta, buckwheat noodles, udon, etc. into a certain amount, and strawberry noodles weighed by this device.

For example, Patent Document 1 discloses an apparatus that divides a large portion of noodles into a certain amount and then subdivides them into a certain amount. In this apparatus, the noodles thrown into the hopper are supplied into the measuring container from a slit-shaped supply port formed at the bottom of the hopper, filled into the measuring container, and the measuring container is slid to slide the measuring container. The noodles filled inside are discharged.
A rotating drum is arranged in the hopper to generate a water flow so that the noodles circulate around the outer peripheral surface of the drum, and the supply direction of the noodles from the inside of the slit-shaped supply port formed in the bottom of the hopper Prevents entanglement and clogging of crab noodles by generating a reverse water flow in the hopper.

JP 2012-50425 A

However, the accuracy of measuring the noodles is not sufficient, and there is a problem that the amount of the noodles divided into small amounts is large.
Moreover, if the opening area of the supply port formed in the bottom part of the hopper is made small in order to improve the measurement accuracy, the processing capacity of the apparatus is drastically lowered.

The present invention has been made to solve such a conventional problem, and provides an automatic measuring device for crab noodles that can accurately measure crab noodles while having high processing capacity. Objective.
Another object of the present invention is to provide crab noodles weighed by such an automatic weighing device.

According to the present invention, there is provided an automatic measuring apparatus for crab noodles, wherein the upper end and the lower end are opened, the hopper has at least one inclined inner side surface inclined with respect to a vertical surface, and stores stored water, and at least one inclined inner surface An input for injecting crab noodles into the stored water in the hopper from the upper end of the hopper along the one inclined inner side surface, extending upward from the upper end of the inclined inner side surface of one of the side surfaces. A chute, a funnel portion connected to the lower end of the hopper and having a plurality of through-holes formed in the peripheral wall and formed with a noodle discharge port at the lower end, a discharge port opening / closing unit for opening and closing the noodle discharge port, and the noodle A measuring bowl for volumetric measurement of the noodles by storing the noodles discharged together with the stored water from the noodle discharge port disposed below the discharge port and opened by the discharge opening / closing part and discharging only the stored water The hopper Reservoir water with has a pouring water supply unit for supplying poured water in the reservoir water in the hopper from one upper end of the hopper along the inclined inner side surface of a plurality of write bar swings reservoir water in the hopper With a squeezing part for feeding squeezed water into the funnel part and supplying a squeezed water supply part for supplying water to the stored water in the funnel part through a plurality of through holes. It is.
In this invention, the stored water is stored in the hopper, and the noodles thrown into the stored water reach the funnel, and then are discharged from the noodle discharge port together with the stored water to the measuring bowl, and only the stored water is measured. The noodles are evacuated from the bowl and volumetrically measured. Therefore, in order to improve weighing accuracy, it is important that the density of the noodles in the stored water, in particular, the density of the noodles in the stored water in the lower end of the hopper and the funnel near the noodle discharge port is constant. is there. Therefore, the pouring water is supplied by the pouring water supply section, the pushing water is supplied by the pouring section, and the plurality of pouring rods are swung, and the unwinding water is supplied by the unwinding water supply section. The noodle density is stabilized.

Preferably, the hopper has a drain arranged in the vicinity of the upper end of the hopper and for maintaining the water level of the stored water in the hopper at a constant height.
It is preferable that the inner surface of the funnel is coated with a fluororesin.
Further, the hopper preferably has a plurality of inner side surfaces including the inclined inner side surface, and the inner side surface facing the inclined inner side surface has a smaller inclination angle with respect to the vertical plane than the inclined inner side surface.

The pouring water supply unit can supply pouring water through a plurality of pouring water supply pipes arranged at the upper end of the inclined inner surface of the hopper toward the lower end of the hopper.
The biting portion extends substantially horizontally in the hopper and is rotatably arranged around the central axis thereof, and a support pipe to which a plurality of biting rods are connected, and the support pipe is connected to the central axis within a predetermined angle range. It can be configured to have a stir bar driving unit that swings around a plurality of stir bars by rotating around.
In this case, the plurality of stirring rods are connected to the support pipe in a state of being arranged in parallel to each other and perpendicular to the central axis of the support pipe, and a plurality of pushing water supply pipes whose inside communicates with the inside of the support pipe; A plurality of bar members that correspond to the plurality of push-in water supply pipes and are connected to the support pipe in a state of being arranged in parallel to each other so as to be perpendicular to the central axis of the support pipe and perpendicular to the corresponding push-in water supply pipe; It is preferable that the agitation part supplies pushing water into the stored water through the support pipe and the plurality of pushing water supply pipes.

The unraveling water supply part has an unraveling water supply container arranged outside the funnel part so that an annular unraveling water supply space is formed along the outer surface of the peripheral wall of the funnel part. Dissolving water can be supplied to the stored water in the funnel portion through the plurality of through holes by supplying the dissolving water into the space.
In addition, the upper ends of the pair of measuring rods are connected to each other by a connecting plate at a predetermined interval, and the measuring rod connecting body is opened at the upper and lower ends of each measuring rod. It has a measuring bowl driving unit that reciprocates the measuring bowl connecting body in the horizontal direction under the noodle outlet, and the connecting plate is positioned under the bowl noodle outlet as the measuring bowl connecting body reciprocates. It can be configured to open the strawberry noodle discharge port by closing the strawberry noodle discharge port and the upper end of one of the measuring jars located below the potato noodle discharge port.
In this case, with the reciprocating movement of the measuring bowl connecting body, the closing plate arranged under the bowl noodle outlet so as to close the lower end of the measuring bowl positioned below the bowl noodle outlet and the reciprocating of the measuring bowl connecting body. It is preferable to further include a collection chute for collecting the noodles falling from the lower end of the measuring bowl located on both sides of the closing plate along with the movement.
Moreover, it is preferable that a measuring rod is formed from a punching board.

The funnel portion has a truncated cone portion whose diameter decreases downward, and a cylindrical portion connected to the lower end of the truncated cone portion. Each of the through holes is formed in the peripheral wall of the frustoconical portion, and has a plurality of first through holes that are directed toward the central axis of the frustoconical portion and have a predetermined elevation angle with respect to the horizontal plane and are directed upward of the funnel portion, respectively. A plurality of second through holes formed in the peripheral wall of the cylindrical portion and inclined in the circumferential direction with respect to the direction toward the central axis of the cylindrical portion and having a predetermined depression angle with respect to the horizontal plane and directed downward of the funnel portion; It is preferable to have.
In addition, a plurality of funnels are juxtaposed at the lower end of the hopper, and equipped with a plurality of measuring rods corresponding to the plurality of funnels, and the unloading water supply unit supplies undissolved water to the stored water in the plurality of funnels. It can also be configured to.

The manufacturing method of the subboiled noodles according to the present invention is a method of manufacturing a subboiled noodles that has been weighed using the automatic measuring device.

  According to the present invention, the pouring water supply unit supplies the pouring water from the upper end of the hopper along the inclined inner side surface of the hopper into which the noodles are charged, and the stirring unit has a plurality of stirring rods. The water is pushed into the stored water while being swung in the stored water in the hopper, and the noodles in the stored water are stirred into the funnel, and the water supply unit is stored in the funnel through the plurality of through holes in the funnel. Since the water is dissolved and water is supplied, the density of the noodles in the stored water in the hopper is stabilized, and the noodles can be accurately measured while having a high processing capacity.

It is side surface sectional drawing which shows the structure of the automatic measuring device of crab noodles concerning Embodiment 1 of this invention. 1 is a front cross-sectional view showing a configuration of an automatic measuring device for crab noodles according to Embodiment 1. FIG. It is a fragmentary sectional view which shows the measuring method of crab noodles in Embodiment 1 in steps. It is a partial side sectional view showing an automatic measuring device for crab noodles according to a second embodiment. It is front sectional drawing which shows the structure of the automatic measuring device of crab noodles concerning Embodiment 3. It is a front view which shows the funnel part used for the automatic measuring device of the crab noodle which concerns on Embodiment 4. It is an AA line cutting | disconnection end elevation of FIG.

Hereinafter, the present invention will be described in detail based on a preferred embodiment shown in the drawings.
Embodiment 1
1 and 2 show the configuration of an automatic noodle measuring apparatus according to Embodiment 1 of the present invention. The automatic noodle measuring device has a hopper 1 into which the noodle N is charged. The hopper 1 accommodates the stored water W0 therein, and the noodle N is introduced into the stored water W0 from a non-illustrated noodle feeder. The upper end of the hopper 1 is opened and has a rectangular opening 1A. The hopper 1 has four inner side surfaces 2A to 2D connected to the opening 1A at the upper end, and a pair of inner side surfaces 2A and 2B facing each other are opposite to the vertical surface and have the same size as each other. A symmetrical inclined inner surface inclined at an angle is formed.
Further, a drain 1B is formed in the vicinity of the upper end of the hopper 1, and the water surface S of the stored water W0 in the hopper 1 is configured to maintain a constant height.

On the hopper 1, a plate-shaped charging chute 3 that extends obliquely upward from the edge of the opening 1 </ b> A of the hopper 1 located at the upper end of the inner side surface 2 </ b> A is disposed. The charging chute 3 is used for sliding the noodle N supplied from a noodle supplying machine (not shown) and introducing it into the stored water W0 in the hopper 1 from the opening 1A of the hopper 1 along the inner surface 2A. is there. Here, the crab noodle feeder preferably feeds a substantially constant amount so that the amount of crab noodle N present in the hopper 1 does not change significantly before and after the crab noodle N is charged.
The lower end of the hopper 1 is also open, and the funnel portion 4 is connected to the lower end of the hopper 1. The funnel portion 4 has a so-called truncated cone shape in which a cone is cut by a plane parallel to the bottom surface thereof, and the top portion is removed. The funnel portion 4 is connected to the lower end of the hopper 1 in such a direction that the diameter decreases downward. Yes. A noodle discharge port 5 is formed at the lower end of the funnel portion 4.

  A coating containing a fluororesin is applied to the inner surface of the funnel portion 4. This coating improves the lubricity of the inner surface of the funnel part 4 in order to prevent clogging of the noodles N in the funnel part 4, for example, by Nifgrip (registered trademark) of ULVAC TECHNO, Construction can be performed by performing surface treatment in which nickel and fluororesin are co-deposited on the funnel portion 4 formed of stainless steel or the like.

The funnel portion 4 has a plurality of through holes 4 </ b> A formed in the peripheral wall of the funnel portion 4. Each of these through-holes 4A faces the central axis of the truncated cone and has an elevation angle of 70 degrees with respect to the horizontal plane, and is formed above the funnel portion 4, that is, toward the lower end of the hopper 1.
Further, a ripening water supply container 6 is arranged outside the funnel part 4 so as to surround the peripheral wall of the funnel part 4, and an annular solution along the outer surface of the peripheral wall of the funnel part 4 is disposed inside the rupture water supply container 6. A salt water supply space 6A is formed. By supplying water into the melt water supply space 6 </ b> A, the water W <b> 3 is dissolved into the stored water W <b> 0 in the funnel portion 4 through the plurality of through holes 4 </ b> A formed in the peripheral wall of the funnel portion 4 toward the lower end of the hopper 1. It is configured to be supplied.

In addition, a support pipe 7 that is parallel to the inclined inner side surface 2A of the hopper 1 and extends substantially horizontally is disposed inside the hopper 1. The support pipe 7 is held by a pair of inner side surfaces 2 </ b> C and 2 </ b> D facing each other of the hopper 1 so as to be rotatable around a central axis C thereof.
A plurality of scoring bars are connected to the support pipe 7. The plurality of stirring rods include a plurality of pushing water supply pipes 8 arranged in parallel to each other at a predetermined interval in the length direction of the supporting pipe 7, and a supporting pipe so as to be orthogonal to the plurality of pushing water supply pipes 8. 7 has a plurality of rod members 9 arranged in parallel with each other at a predetermined interval in the length direction of the. Each pushing water supply pipe 8 and each rod member 9 extend in a direction perpendicular to the central axis C of the support pipe 7.

Further, the inside of each pushing water supply pipe 8 communicates with the inside of the support pipe 7, and the water is supplied to the supporting pipe 7, thereby pushing through the inside of the supporting pipe 7 and the inside of the pushing water supply pipe 8. The pushing water W <b> 2 is configured to be supplied from the tip of the water supply pipe 8 into the stored water W <b> 0 in the hopper 1.
Furthermore, a stir bar driving unit 10 is connected to the support pipe 7 outside the hopper 1. The scraping bar driving unit 10 rotates the support pipe 7 around the central axis C within a predetermined angle range, thereby causing the plurality of pushing water supply pipes 8 and the plurality of bar members 9 connected to the support pipe 7 to move. The water is swung in the stored water W0 in the hopper 1.

Further, a water supply pipe 11 extending parallel to and substantially horizontally with respect to the input chute 3 is disposed above the input chute 3, and a plurality of poured water supply pipes 12 are connected to the water supply pipe 11. Each poured water supply pipe 12 extends from the water supply pipe 11 through the upper end of the inclined inner surface 2A of the hopper 1 to the stored water W0 in the hopper 1, and is directed in the direction along the inner surface 2A. .
The inside of each of the pouring water supply pipes 12 communicates with the inside of the water supply pipe 11, and by supplying water to the water supply pipe 11, the pouring water supply passes through the inside of the water supply pipe 11 and the inside of the pouring water supply pipe 12. The pour water W1 is supplied from the tip of the pipe 12 into the stored water W0 in the hopper 1 along the inner surface 2A.

A water supply unit 13 is connected to the unsealed water supply container 6, the support pipe 7, and the water supply pipe 11. The water supply unit 13 can supply water to the disentanglement water supply container 6, the support pipe 7, and the water supply pipe 11 at different water pressures and flow rates. In addition, the stored water W0 discharged from the drain 1B of the hopper 1 is again configured to be used as the poured water W1, the pushed water W2 or the unraveled water W3 from the water supply unit 13.
A poured water supply unit that feeds the poured water W1 from the upper end of the hopper 1 into the stored water W0 in the hopper 1 along the inner side surface 2A of the hopper 1 by the feed water pipe 11, the plurality of poured water supply pipes 12, and the water supply unit 13. Is configured.
Further, the support pipe 7, the plurality of pushing water supply pipes 8, the plurality of rod members 9, the stirring bar driving unit 10, and the water supply unit 13 swing and store the plurality of stirring bars in the stored water W 0 in the hopper 1. An agitation part for supplying the pushing water W2 into the water W0 and agitating the noodles in the hopper 1 into the funnel part 4 is configured.
Furthermore, the funnel part 4 and the water supply container 6 and the water supply part 13 constitute a water supply part that dissolves the stored water W0 in the funnel part 4 and supplies the water W3.

Under the bowl noodle discharge port 5 formed at the lower end of the funnel part 4, a measuring bowl connecting body 14 is arranged. The measuring rod connection body 14 is formed by connecting a pair of measuring rods 15 and 16 having the same shape and size to each other by a connecting plate 17. Each of the measuring bowls 15 and 16 has a generally cylindrical shape with the upper end and the lower end opened, and has a shape that tapers toward the upper side in the vicinity of the upper end, and the upper end has a diameter equivalent to that of the bowl noodle discharge port 5. ing. The upper ends of the weighing rods 15 and 16 are connected by a connecting plate 17 so as to be spaced apart from each other by a predetermined distance. Here, the predetermined interval between the upper ends of the weighing bowls 15 and 16 means that the portion of the connecting plate 17 existing between the upper end of the weighing bowl 15 and the upper end of the weighing bowl 16 covers the bowl noodle discharge port 5. The spacing is as good as possible.
The measuring bowls 15 and 16 are formed from a punching plate such as a punching metal having a plurality of through-holes so that only water can be discharged to the outside through the plurality of through-holes while containing the noodles inside. It is configured.

A weighing rod drive unit 18 is connected to the weighing rod connector 14. The measuring bowl drive unit 18 has a measuring bowl 15 at the lower side of the bowl noodle discharge port 5, with a small gap from the bowl noodle discharge port 5 formed at the lower end of the funnel unit 4. The measuring bowl connecting body 14 is reciprocated in the horizontal direction between the position arranged immediately below and the position where the other measuring bowl 16 is arranged directly below the bowl noodle discharge port 5.
When the connecting plate 17 of the portion existing between the upper end of the measuring rod 15 and the upper end of the measuring rod 16 is positioned immediately below the noodle discharge port 5 as the measuring rod connecting body 14 reciprocates, the connecting plate 17 As a result, the noodle discharge port 5 is closed, and the noodle discharge port 5 is gradually opened with the movement of the measuring knot linking body 14, and the upper end of one of the measuring rods 15 and 16 is directly below the noodle discharge port 5. When positioned, the noodle discharge port 5 is fully opened.
The measuring rod driving unit 18 can be formed of an air cylinder, an electromagnetic cylinder, or the like.

Further, a collection chute 19 is disposed below the weighing bowl connecting body 14, and a closing plate 20 is fixed to the upper end of the collection chute 19 just below the bowl noodle discharge port 5. The closing plate 20 is disposed at a height that is slightly spaced from the lower ends of the measuring rods 15 and 16 of the measuring rod connecting body 14, and the lower end of the measuring rod 15 or 16 positioned immediately below the noodle discharging port 5 is disposed on the closing plate 20. It is large enough to cover.
In addition, openings 19A and 19B larger than the lower end of the measuring rod 15 or 16 are formed on both sides of the closing plate 20 in the moving direction of the measuring rod connecting body 14, respectively.

For this reason, when the weighing rods 15 and 16 are located immediately above the closing plate 20, the lower ends of the weighing rods 15 and 16 are closed by the closing plate 20, and when the weighing rods 15 and 16 are located above the openings 19A and 19B. The lower ends of the weighing scales 15 and 16 are configured to be opened.
Further, a bowl noodle take-out port 21 is formed at the lower end of the collection chute 19 for taking out the bowl noodle N measured by the weighing bowls 15 and 16 and collected by the collection chute 19.

  Further, a control unit 22 is connected to the stir bar driving unit 10, the water supply unit 13 and the measuring rod driving unit 18. The control unit 22 drives the support pipe 7 to rotate within a predetermined angle range by the stir bar driving unit 10, supplies water to the water supply container 6, the support pipe 7, and the water supply pipe 11 by the water supply unit 13, and measures The reciprocating movement of the measuring rod connecting body 14 by the rod driving unit 18 is controlled.

Next, the operation of the automatic measuring device for crab noodles according to the first embodiment will be described.
First, the stored water W0 is accommodated in the hopper 1, and the plurality of pushing water supply pipes 8 and the plurality of rod members 9 are swung in the stored water W0 by the stirring rod driving unit 10 under the control of the control unit 22. At the same time, the water supply unit 13 supplies water into the water supply pipe 11 of the pouring water supply unit, the support pipe 7 of the biting unit, and the dissolving water supply space 6A of the dissolving water supply unit. Pour water W1 is supplied into the stored water W0 in the hopper 1 along the inner side surface 2A of the hopper 1, and the push water W2 is supplied into the stored water W0 in the hopper 1 from the plurality of push water supply pipes 8. Dissolved water W3 is supplied to the stored water W0 in the funnel portion 4 through the plurality of through holes 4A of the funnel portion 4.
Further, under the control of the control unit 22, the measuring rod driving unit 18 causes the measuring rod connecting body 14 to reciprocate in the horizontal direction.

In this state, the noodles N in which the noodles of multiple meals are boiled up together are not greatly changed before and after the addition of the noodles N from the noodle feeder (not shown). When the noodles N are supplied onto the charging chute 3 by a substantially constant amount, the noodles N slide down the charging chute 3 and move into the hopper 1 along the inner surface 2A inclined from the opening 1A of the hopper 1. Into the stored water W0.
At this time, since the pouring water W1 is supplied along the inner surface 2A from the tips of the plural pouring water supply pipes 12, the noodles N poured into the stored water W0 is placed on the inner surface 2A of the hopper 1 It is sent to the stirrer inside the hopper 1 without delay. In the agitation portion, the plurality of pushing water supply pipes 8 and the plurality of rod members 9 are swung and the pushing water W2 is supplied from the tips of the plurality of pushing water supply pipes 8. It is pushed toward the bottom.

The crab noodles N that reach the bottom of the hopper 1 through the stored water W0 are dissolved by the dewatering water W3 supplied toward the lower end of the hopper 1 from the plurality of through holes 4A formed in the peripheral wall of the funnel portion 4. While being done, it is discharged from the noodle discharge port 5 through the funnel portion 4.
Here, as shown in FIG. 3 (A), when one measuring bowl 15 is positioned directly under the bowl noodle outlet 5 as the measuring bowl coupling body 14 reciprocates, the bowl noodle outlet 5 is fully opened. Then, the noodles N are supplied together with the stored water W0 from the funnel part 4 through the noodles discharge port 5 into the measuring bowl 15. At this time, since the measuring bowl 15 is located immediately above the closing plate 20, the lower end of the measuring bowl 15 is closed by the closing plate 20, and the noodle N supplied to the inside of the measuring bowl 15 is discharged from the measuring bowl 15. Never happen. The stored water W0 supplied to the inside of the measuring bowl 15 together with the bowl noodles N is discharged to the outside of the measuring bowl 15 through the wall portion of the measuring bowl 15 formed from a punching plate.

After the noodles N are filled in the measuring bowl 15 in this way, the measuring bowl connecting body 14 is moved, and as shown in FIG. 3B, the upper end of the measuring bowl 15 and the upper end of the measuring bowl 16 are When the connecting plate 17 of the portion existing between is located directly under the noodle discharge port 5, the noodle discharge port 5 is closed by the connection plate 17, and the discharge of the noodle N from the funnel portion 4 is stopped. .
At this time, the position of the measuring rod 15 is shifted from the position directly above the closing plate 20 to the opening 19A side of the collection chute 19, and the lower end of the measuring rod 15 closed by the closing plate 20 gradually opens.

As shown in FIG. 3 (C), when the measuring bowl 15 is positioned above the opening 19A of the recovery chute 19, the lower end of the measuring bowl 15 is fully opened, and the noodles filled inside the measuring bowl 15 N falls into the collection chute 19 from the lower end of the measuring bowl 15 and is taken out from the bowl noodle outlet 21.
At this time, the other measuring bowl 16 is positioned immediately below the bowl noodle outlet 5, the bowl noodle outlet 5 is fully opened again, and passes through the bowl noodle outlet 5 from the funnel portion 4 to the inside of the bowl 12茹 Noodles N are supplied. At this time, since the measuring rod 16 is located immediately above the closing plate 20, the lower end of the measuring rod 16 is closed by the closing plate 20.

  In this way, the pair of measuring bowls 15 and 16 of the measuring bowl connecting body 14 are alternately filled with the bowl noodles N so that the volume of the bowl noodles N is sequentially measured, and the bowl noodle take-out port at the lower end of the collection chute 19 is obtained. 21 is taken out.

  According to the automatic measuring apparatus for crab noodles according to the first embodiment, the crab noodles N are substantially constant in such an amount that the amount of crab noodles N present in the hopper 1 does not change greatly before and after the addition of crab noodles N. The water W1 is poured into the stored water W0 in the hopper 1 through the charging chute 3 in an amount, and poured into the stored water W0 in the hopper 1 along the inner surface 2A of the hopper 1 from the plurality of poured water supply pipes 12. Pushing water W2 is supplied into the stored water W0 in the hopper 1 from the tips of the plurality of pushing water supply pipes 8 while the plurality of pushing water supply pipes 8 and the plurality of rod members 9 are swung, and the funnel portion 4, the dissolved water W3 is supplied to the stored water W0 in the funnel portion 4 toward the lower end of the hopper 1 through the plurality of through holes 4A, so that the noodles N charged in the hopper 1 are entangled and clogged. Without producing etc. While properly understood, it is discharged from 茹麺 outlet 5 through the lower end and a funnel portion 4 of the hopper 1. For this reason, the density of the noodles N in the stored water W0 in the hopper 1, especially the density of the noodles N in the stored water W0 in the lower end of the hopper 1 adjacent to the noodle discharge port 5 and the funnel part 4 is stable. In addition, the noodles N can be subdivided by volumetric measurement with high accuracy.

This is because the supply of the pouring water W1 along the inner surface 2A of the hopper 1 from the plural pouring water supply pipes 12, the supply of the pouring water W2 from the plural pushing water supply pipes 8, and the plural penetrations of the funnel portion 4 By supplying the scouring water W3 through the holes 4A, a stable water flow is generated in the stored water W0 in the hopper 1, and the sushi noodle N in the hopper 1 is not biased, and the dispersion of the sushi noodle N is promoted. This is considered to be a major factor.
In the first embodiment, each of the plurality of through holes 4A of the funnel portion 4 has an elevation angle of 70 degrees with respect to the horizontal plane. However, the present invention is not limited to this. Even if it has an elevation angle of 80 degrees and is formed toward the upper side of the funnel portion 4, the same effect can be obtained.

Embodiment 2
In the hopper 1 used in the first embodiment, the inner side surface 2A to which the charging chute 3 is connected and the inner side surface 2B opposite to the inner side surface 2A are opposite to the vertical surface and have the same size. Although it was inclined symmetrically with an angle, it is not limited to this.
As shown in FIG. 4, in the hopper 31 used in the automatic measuring device for crab noodles according to the second embodiment, the inner side surface 32B facing the inner side surface 32A to which the charging chute 3 is connected is more than the inner side surface 32A. Has a small inclination angle with respect to the vertical surface, and the inner side surface 32A and the inner side surface 32B are formed asymmetrically.
The automatic noodle measuring apparatus according to the second embodiment has the same configuration as the automatic noodle measuring apparatus according to the first embodiment except that a hopper 31 is used instead of the hopper 1.

By using such a hopper 31, the supply of the pouring water W1 along the inner surface 2A of the hopper 1 from the plural pouring water supply pipes 12, the supply of the pouring water W2 from the plural pushing water supply pipes 8, and In addition to the supply of the unraveling water W3 through the plurality of through holes 4A of the funnel part 4, the stability of the water flow in the hopper 31 is improved, and the dispersion of the noodles N in the stored water W0 is promoted. Furthermore, it becomes possible to accurately measure the volume of the noodles N.
In addition, the inclination angle with respect to the vertical surface of the inner side surface 32B facing the inner side surface 32A to which the charging chute 3 is connected can be set to 0, and the inner side surface 32B can be configured to extend in the vertical direction.

Embodiment 3
The automatic weighing device according to the first embodiment shown in FIGS. 1 and 2 is a series of weighing devices in which one funnel portion 4, one weighing rod connector 14 and one recovery chute 19 are arranged below the hopper 1. However, a plurality of weighing devices in which a plurality of funnel portions 4 are juxtaposed below a common hopper and a plurality of measuring rod connection bodies 14 and a plurality of recovery chutes 19 are arranged corresponding to the plurality of funnel portions 4 are provided. It can also be configured.
FIG. 5 shows an automatic measuring device for crab noodles according to the third embodiment. In this automatic weighing device, four funnel portions 4 are juxtaposed at the lower end of a common hopper 41, and a measuring rod connecting body 14 and a recovery chute 19 are arranged below each funnel portion 4, thereby providing four measuring devices. It is what.

The hopper 41 has an inner side surface 42A that is inclined with respect to the vertical surface, and a plate-shaped charging chute 43 extends obliquely upward from the upper end of the inner side surface 42A. Four pouring water supply pipes 12 corresponding to the four funnel portions 4 are connected to the water supply pipe 11 disposed above the charging chute 43 and extending substantially horizontally. By supplying water to the water supply pipe 11 from the water supply section 13, the water stored in the hopper 41 passes through the inside of the water supply pipe 11 and the inside of the water supply pipe 12 from the tip of the water supply pipe 12 along the inner side surface 42A. Pour water W1 is supplied during W0.
Further, in the support pipe 7 extending substantially horizontally inside the hopper 41, eleven indented water supply pipes 8 with respect to the four funnel portions, and ten illustrated so as to be orthogonal to these indented water supply pipes 8. The rod member 9 not to be connected is connected. By rotating the support pipe 7 around the central axis C within a predetermined angle range by the scraping bar driving unit 10, 11 push water supply pipes 8 and 10 bar members 9 connected to the support pipe 7 are used. Oscillates in the stored water W0 in the hopper 1 and supplies water to the support pipe 7 from the water supply unit 13, thereby passing the inside of the support pipe 7 and the inside of the push-in water supply pipe 8. The pushing water W2 is supplied into the stored water W0 in the hopper 1 from the tip of the hopper 1.

Further, a water supply container 6 is arranged so as to surround the peripheral walls of the four funnel parts 4 juxtaposed with each other, and the water supply container 6 is opened from the water supply part 13 to supply water into the water supply space 6A. By doing so, the water W3 is dissolved toward the lower end of the hopper 41 through the plurality of through holes 4A formed in the peripheral wall of each funnel portion 4 into the stored water W0 in each funnel portion 4.
As shown in FIG. 1, each of the four measuring rod connecting bodies 14 disposed below the bowl noodle discharge port 5 formed at the lower ends of the four funnel portions 4 includes a pair of measuring rods 15 and 16. The four measuring rod connecting bodies 14 are synchronized by the measuring rod driving section 18 and can be reciprocated in the horizontal direction.

Next, the operation of the automatic measuring device for crab noodles according to the third embodiment will be described.
First, the stored water W0 is accommodated in the hopper 41, and under the control of the control unit 22, the 11 pushing water supply pipes 8 and the 10 rod members 9 are swung in the stored water W0 by the stirring rod driving unit 10. At the same time, the water supply section 13 supplies water into the water supply pipe 11 of the pouring water supply section, the support pipe 7 of the pouring section, and the unraveling water supply space 6A of the unraveling water supply section. The poured water W1 is supplied from the supply pipe 12 into the stored water W0 in the hopper 41, and the pushed water W2 is supplied from the eleven pushed water supply pipes 8 into the stored water W0 in the hopper 41. Water W3 is supplied to the stored water W0 in the funnel portion 4 through the plurality of through holes 4A.
Further, under the control of the control unit 22, the four measuring rod connecting bodies 14 are reciprocated in the horizontal direction by the measuring rod driving unit 18.

In this state, the noodles N in which the noodles of noodles are boiled together and boiled so that the amount of the noodles N present in the hopper 41 does not change greatly before and after the addition of the noodles n In a small amount, it is poured into the stored water W0 in the hopper 41 by a substantially constant amount.
At this time, since the pouring water W1 is supplied along the inner side surface 42A from the tips of the four pouring water supply pipes 12, the noodles N poured into the stored water W0 is placed on the inner side surface 42A of the hopper 41. It is sent into the hopper 41 without stagnation. Inside the hopper 41, the eleven pushing water supply pipes 8 and the ten rod members 9 are swung and the pushing water W2 is supplied from the tips of the eleven pushing water supply pipes 8. Is pushed toward the bottom of the hopper 41.

The noodles N that have reached the bottom of the hopper 41 through the stored water W0 are dissolved water W3 supplied toward the lower end of the hopper 41 from a plurality of through holes 4A formed in the peripheral wall of each funnel portion 4. Is discharged from the bowl noodle discharge port 5 through the funnel portion 4.
Here, the four measuring rod connecting bodies 14 arranged below the four funnel portions 4 reciprocate in the horizontal direction in synchronization with the measuring rod driving section 18, and a pair of measuring rods of the respective measuring rod connecting bodies 14. By filling the noodles N alternately into 15 and 16, the noodles N are sequentially weighed. In this manner, the volume-measured noodles N are taken out from the noodle take-out ports 21 at the lower ends of the four collection chutes 19 arranged corresponding to the four funnel portions 4.

In Embodiment 3 described above, four automatic weighing devices are configured by juxtaposing four funnel portions 4. Similarly, multiple automatic weighing devices of two, three, or five or more are arranged. It can also be configured.
Further, as the hopper 41, like the hopper 1 in the first embodiment, a pair of inner side surfaces 2A and 2B facing each other are symmetrically inclined in the opposite direction with respect to the vertical surface and at the same angle. A hopper can be used, or an asymmetric hopper in which the inner side surface 32A and the inner side surface 32B are formed asymmetrically can be used like the hopper 31 in the second embodiment.

Embodiment 4
The funnel portion 4 used in the first to third embodiments has a truncated cone shape, and the plurality of through holes 4A formed in the peripheral wall respectively face the central axis of the truncated cone and are in a horizontal plane. Although the elevation angle is 70 degrees, the present invention is not limited to this, and a funnel portion 44 as shown in FIG. 6 can also be used.
The funnel portion 44 has a composite shape including a truncated cone portion 45 whose diameter decreases downward and a cylindrical portion 46 connected to the lower end of the truncated cone portion 45. A crab noodle outlet 47 is arranged. The truncated cone part 45 and the cylindrical part 46 have a common central axis C1.

  A plurality of first through holes 48 are formed in the peripheral wall of the truncated cone portion 45, respectively, toward the central axis C <b> 1 and at an elevation angle of 70 degrees with respect to the horizontal plane and toward the upper portion of the funnel portion 44. These first through-holes 48 are arranged in three rows along the central axis C1, and each row is divided into nine pieces separated from each other by a central angle of 40 degrees in the circumferential direction of the truncated cone portion 45. The first through holes 48 in rows adjacent to each other are arranged at positions shifted from each other by 20 degrees in the circumferential direction of the truncated cone portion 45.

On the other hand, a plurality of second through holes 49 are formed in the peripheral wall of the cylindrical portion 46, each having a depression angle of 30 degrees with respect to the horizontal plane and directed downward of the funnel portion 44. These second through holes 49 are arranged in two rows along the central axis C1, and each row has nine rows spaced apart from each other by a central angle of 40 degrees in the circumferential direction of the cylindrical portion 46. The second through holes 49 in the rows that are constituted by the second through holes 49 and are adjacent to each other are arranged at positions shifted from each other by 20 degrees in the circumferential direction of the cylindrical portion 46.
Further, as shown in FIG. 7, the plurality of second through holes 49 are formed so as to be inclined by 30 degrees in the same circumferential direction with respect to the direction toward the central axis C <b> 1. When the water W3 is supplied to the cylindrical portion 46 of the funnel portion 44 through the through hole 49, a downward swirling flow is formed inside the cylindrical portion 46.

By using such a funnel part 44, the unraveling of the noodles N in the funnel part 44 is promoted, and the volumetric measurement of the noodles N can be performed with higher accuracy.
The composite-shaped funnel portion 44 can be applied to a single automatic weighing device as shown in the first embodiment and a multiple automatic weighing device as shown in the third embodiment. Can do.

First, in an apparatus similar to the automatic weighing apparatus shown in FIGS. 1 and 2, two pieces of water are poured into both the inner surface 2A and the inner surface 2B of the hopper 1 having a capacity of 50 liters (5 × 10 ⁻² m ³ ). The pipe 12 is arranged, and the five pushing water supply pipes 8 are connected to the support pipe 7, and the funnel part 4 not coated with fluororesin is used, and the flow rate of the pushing water W2 is 66 kg / min. While fixing the flow rate of the melted water W3 at 47 kg / min, the water pressure and the flow rate of the poured water W1 are variously changed, and the volumetric measurement of the noodles N corresponding to 200 g of raw noodles having a thickness of 1.7 mm is performed twice. went. The measurement results are shown in Table 1.

  The standard deviation of the water W1 when the water pressure is 0.08 Mpa and the flow rate is 33 kg / min is 3.1 g, and the standard deviation when the water pressure is 0.02 Mpa and the flow rate is 13 kg / min can be measured more accurately than the standard deviation of 4.1 g. I understood it. In addition, when the water pressure of the pouring water W1 is set to 0.2 Mpa and 0.3 Mpa, the flow rate is too high and water that cannot be flowed to the lower part of the hopper 1 flows backward to the upper part of the hopper 1, and the noodles N are weighed. 15 and 16 could not be fed.

Example 1
Therefore, for the 50 liter hopper 1, the flow rate of the poured water W1 is fixed at 33 kg / min, the flow rate of the pushed water W2 is fixed at 66 kg / min, and the flow rate of the water W3 is fixed at 47 kg / min. An automatic metering device in which the supply pipe 8 is connected to the support pipe 7 is used, and two pouring water supply pipes 12 made of tubes are arranged on the inner surface 2A side of the hopper 1 where the noodles N are introduced, as shown in FIGS. Using the funnel portion 44 having a composite shape and not coated with a fluororesin, weighed noodles N corresponding to 200 g of raw noodles having a thickness of 1.7 mm twice. The scraping bar was swung at a swing angle of 90 degrees and at a speed of 1 reciprocation of 1 second. In addition, the noodles N were charged into the hopper 1 at a rate of 330 kg / hour, with the amount of each time charged being 200 g.

Example 2
Weighing is performed in the same manner as in Example 1 except that two piped water supply pipes 12 made of pipes are arranged on the inner surface 2A side of the hopper 1 and a funnel portion 44 coated with a fluororesin is used. It was.

Example 3
Weighing is carried out in the same manner as in Example 1 except that three piped water supply pipes 12 made of pipes are arranged on the inner surface 2A side of the hopper 1 and a funnel portion 44 coated with a fluororesin is used. It was.

Example 4
As shown in FIG. 4, three pouring water supply pipes 12 made of pipes are arranged on the inner surface 32A side of the hopper 31 having a capacity of 45 liters and the inner surface 32B facing the inner surface 32A extends in the vertical direction. Weighing was performed in the same manner as in Example 1 except that the funnel portion 44 provided with a coating containing resin was used.

Comparative Example 1
Weighing was performed in the same manner as in Example 1 except that two poured water supply pipes 12 made of tubes were arranged on the inner side 2B side opposite to the inner side 2A into which the noodles N of the hopper 1 were put.

Comparative Example 2
Except for the use of the funnel portion 44 in which three piped water supply pipes 12 made of pipes are arranged on both the inner side surface 2A side and the inner side surface 2B side of the hopper 1 and a coating containing a fluororesin is used. Measurement was performed in the same manner as in 1.

  Table 2 shows the measurement results of Examples 1-4 and Comparative Examples 1-2. In addition, “symmetric shape” in “hopper shape” in Table 2 refers to the inner surface 2A on the side where the noodles N are introduced and the inner surface facing the inner surface 2A, like the hopper 1 shown in FIG. 2B shows a hopper shape that is symmetrically inclined in the opposite direction with respect to the vertical plane and at an angle of the same size as each other, and the “asymmetrical shape” means that the noodles N are like the hopper 31 shown in FIG. The inner side surface 32A on the loading side and the inner side surface 32B facing the inner side surface 32A show a hopper shape formed asymmetrically with respect to the vertical surface.

It was found that the noodles N can be accurately measured by disposing the pouring water supply pipe 12 only on the inner surface 2A side of the hopper 1 or the inner surface 32A side of the hopper 31. Particularly, in Example 4 using the hopper 31 in which the inner side surface 32A and the inner side surface 32B are asymmetrically inclined as in the second embodiment shown in FIG. 4, the standard deviation is improved to 1.7 g. It was found that high-precision weighing is possible.
Further, in Examples 1 to 4, when the flow rate of the pouring water W1 was variously changed, and the volumetric measurement of the noodles N corresponding to 200 g of raw noodles having a thickness of 1.7 mm was performed, Examples 1 to 4 were performed. For the hopper 1 having a capacity of 50 liters used in 3 and the hopper 31 having a capacity of 45 liters used in Example 4, the flow rate of the poured water W1 is 15 kg / min or more and 45 kg / min or less. It was found that noodles N can be measured with high accuracy.
In Examples 2 to 4 using the funnel portion 44 to which a coating containing a fluororesin was applied, adhesion of the crab noodles N to the inner surface of the funnel portion 44 was not confirmed after the measurement, but the coating was applied. In Example 1 using the funnel part 44 that was not, adhesion of the noodles N was confirmed on a part of the inner surface of the funnel part 44 after the measurement was completed. It can be seen that the lubricity of the inner surface of the funnel 44 is improved by the coating containing the fluororesin.

Next, in order to examine the influence of the number of the pouring water supply pipes 12 that supply the pouring water W1 on the measurement accuracy, the following Examples 5 to 7 were performed.
Example 5
1 and 2, a single device similar to the automatic metering device shown in FIGS. 1 and 2 has a single feed water supply pipe 12 for a 50 liter hopper 1 and a flow rate of the feed water W1 of 2 m / sec. The flow rate of W2 is fixed at 8 m / sec, the flow rate of dissolved water W3 is fixed at 3 m / sec, and a funnel portion 44 having a composite shape shown in FIGS. N was weighed. The scraping bar was swung at a swing angle of 90 degrees and at a speed of 1 reciprocation of 1 second. In addition, the noodles N were charged into the hopper 1 at a rate of 330 kg / hour, with the amount of each time charged being 200 g.

Example 6
Weighing was carried out in the same manner as in Example 5 except that two pouring water supply pipes 12 were arranged on the inner surface 2A side of the hopper 1.
Example 7
Weighing was performed in the same manner as in Example 5 except that three pouring water supply pipes 12 were arranged on the inner surface 2A side of the hopper 1 and the flow rate of the pouring water W1 was 4 m / sec.
The measurement results of Examples 5 to 7 are shown in Table 3.

It was found that even when the number of the poured water supply pipes 12 was changed between 1 and 3, the measurement accuracy hardly changed.
In addition, although the standard deviation obtained in Examples 5-7 is 0.6-0.7g and is improving significantly compared with Examples 1-4, this uses half-size dry noodles. This seems to be the cause.

Next, in order to investigate the influence of various conditions when a four-line automatic weighing device was used, the following Examples 8 to 13 were carried out.
Example 8
In the four-unit apparatus similar to the automatic metering apparatus shown in FIG. 5, four pouring water supply pipes 12 are arranged for a hopper 41 having a capacity of 150 liters, and the flow rate of the pouring water W1 is 4 m / sec. The flow rate of W2 is fixed at 8 m / sec, the flow rate of dissolved water W3 is fixed at 3 m / sec, and the funnel portion 44 having a composite shape shown in FIGS. Weighed. The scraping bar was swung at a swing angle of 90 degrees and at a speed of 1 reciprocation of 1 second. In addition, the noodle N was charged in the hopper 41 at a rate of 330 kg / hour, with the amount of one charged being 200 g.

Example 9
Weighing was performed in the same manner as in Example 8 except that the flow rate of the pushing water W2 was 4 m / sec.
Example 10
Weighing was carried out in the same manner as in Example 9 except that the frustoconical funnel portion 4 was used and the flow rate of the water W3 was changed to 4 m / sec.
Example 11
Weighing was performed in the same manner as in Example 10 except that the flow rate of the poured water W1 was 6 m / sec.
Example 12
Weighing was performed in the same manner as in Example 10 except that five pouring water supply pipes 12 were arranged and the flow rate of the pouring water W1 was set to 8 m / sec.

  Table 4 shows the measurement results of Examples 8 to 12. The “standard deviation of each series” in Table 4 is an enumeration of four values for the noodles N taken out from the noodle take-out port 21 of the four collection chutes 19, and the “total standard deviation” is The standard deviation with respect to the whole of the bowl noodle N taken out from the bowl noodle take-out port 21 of the four collection chutes 19 is shown.

From the measurement results of Examples 10 to 12, when the flow rate of the pouring water W1 is increased to 8 m / sec as in Example 12, the value of the standard deviation is greatly increased, and the variation in measurement becomes large. It was confirmed that the measurement accuracy was improved by setting the flow rate of the poured water W1 to 6 m / second or less as in 10 and 11.
From the measurement results of Examples 8 and 9, the flow rate of the pushing water W2 as in Example 8 is 8 m / sec than the case where the flow rate of the pushing water W2 is 4 m / sec as in Example 9. It was confirmed that the weighing accuracy was improved. However, it was found that sufficient measurement accuracy could be obtained even when the flow rate of the pushing water W2 was reduced to 4 m / sec as in Example 9.
Further, from the measurement results of Examples 9 and 10, it was solved as in Example 9 and the flow rate of water W3 was 3 m / sec, and the flow rate of water W3 was 4 m / sec as in Example 10. It was confirmed that the weighing accuracy was improved compared to the case where However, it was found that sufficient measurement accuracy could be obtained even when the flow rate of the water W3 was increased to 4 m / sec as in Example 10.

  Furthermore, while the overall standard deviation in Example 10 using the truncated cone shaped funnel portion 4 shown in FIG. 1 is 2.5 g, the composite shaped funnel portion 44 shown in FIGS. 6 and 7 is used. The overall standard deviation in Example 9 was 2.2 g, and it was confirmed that the measurement accuracy was improved by using the funnel portion 44 having a composite shape.

  When various measurement experiments including the above Examples 1 to 12 were performed, the optimum flow rate conditions of the pouring water W1, the pushing water W2 and the dissolving water W3 in the single automatic metering device and the four automatic metering devices are: Each was found to be as shown in Table 5 below.

In Table 1 above, three pouring water supply pipes are used for a single automatic metering device. However, as confirmed in Examples 5 to 7, one pouring water supply pipe is used. But you can. If one pouring water supply pipe is arranged per station, accurate measurement can be performed.
Further, the automatic measuring device for crab noodles according to the present invention can be applied to the measurement of long pasta such as spaghetti, udon including cold wheat and raw noodles, soba and the like, as well as short pasta, yarn konjac, kudzu etc. However, it is possible to perform measurement with high accuracy and high processing capacity.

  1,31,41 Hopper, 1A, 19A, 19B Opening, 1B drain, 2A-2D, 32A, 32B, 42A Inner surface, 3,43 Loading chute, 4,44 Funnel part, 4A Through-hole, 5,47 Discharge port, 6 Dissolving water supply container, 6A Dissolving water supply space, 7 Support pipe, 8 Push water supply pipe, 9 Bar member, 10 Stirring bar drive part, 11 Water supply pipe, 12 Pour water supply pipe, 13 Water supply part , 14 Measuring bowl connected body, 15, 16 Measuring bowl, 17 Connecting plate, 18 Measuring bowl driving unit, 19 Recovery chute, 20 Closing plate, 21 Boiled noodle outlet, 22 Control unit, 45 Frustum portion, 46 Cylindrical portion, 48 1st through-hole, 49 2nd through-hole, N bowl noodles, C, C1 central axis, W0 stored water, W1 pouring water, W2 pushing water, W3 unraveling water, S water surface.

Claims (14)

A hopper having at least one inclined inner surface inclined at an upper end and a lower end and inclined with respect to a vertical plane, and containing stored water;
The upper surface of the inclined inner surface of the at least one inclined inner surface extends upward from the upper end of the inclined inner surface and is disposed on the hopper. The upper end of the hopper extends from the upper end of the hopper along the inclined inner surface of the hopper. An input chute for charging the noodles in the stored water;
A funnel portion connected to the lower end of the hopper and having a plurality of through-holes formed in the peripheral wall and a noodle discharge port formed at the lower end;
A discharge port opening and closing part for opening and closing the crab noodle discharge port;
The cocoon noodle discharged from the cocoon noodle discharge port disposed below the cocoon noodle discharge port and opened by the discharge port opening / closing part is accommodated, and only the stored water is discharged. A measuring bowl for volumetric measurement of noodles,
A pouring water supply unit for supplying pouring water from the upper end of the hopper along the one inclined inner side surface of the hopper into the stored water in the hopper;
A stirrer having a plurality of stirrers that swing in the stored water in the hopper and supplying the pushed water into the stored water to stir the noodles in the stored water into the funnel;
An automatic measuring apparatus for crab noodles, comprising: a deionized water supply unit configured to unravel the stored water in the funnel unit through the plurality of through holes.   2. The automatic noodle measuring device according to claim 1, wherein the hopper has a drain disposed in the vicinity of an upper end of the hopper and for maintaining a water level of the stored water in the hopper at a constant height.   The automatic measuring device for crab noodles according to claim 1 or 2, wherein a coating containing a fluororesin is applied to an inner surface of the funnel portion.   The hopper has a plurality of inner surfaces including the inclined inner surface, and an inner surface facing the inclined inner surface has a smaller inclination angle with respect to a vertical plane than the inclined inner surface. The automatic measuring device of crab noodles as described in any one of 1-3.   The said pouring water supply part each supplies the said pouring water through the some pouring water supply pipe | tube arrange | positioned at the upper end of the said inclined inner surface of the said hopper toward the lower end of the said hopper. An automatic measuring device for crab noodles according to one item. The biting portion is
A support pipe that extends substantially horizontally in the hopper and is rotatably arranged about a central axis thereof and to which the plurality of scoring bars are connected;
The scissors according to claim 1, further comprising: a stir bar driving unit that swings the plurality of stir bars by rotating the support pipe around the central axis within a predetermined angle range. Noodle automatic weighing device. The plurality of stirring bars are
A plurality of push-in water supply pipes that are connected to the support pipe in a state of being arranged perpendicular to the central axis of the support pipe and parallel to each other and whose inside communicates with the inside of the support pipe;
Corresponding to the plurality of push water supply pipes and connected to the support pipes in a state of being arranged in parallel to each other so as to be perpendicular to the central axis of the support pipe and perpendicular to the corresponding push water supply pipes The automatic measuring device for crab noodles according to claim 6, further comprising: a plurality of bar members, wherein the stirring portion supplies the pushing water into the stored water through the support pipe and the plurality of pushing water supply pipes. The unraveling water supply part has an unraveling water supply container disposed outside the funnel part so that an annular unraveling water supply space is formed along the outer surface of the peripheral wall of the funnel part.
The melt water is supplied to the stored water in the funnel part through the plurality of through holes by supplying the melt water into the melt water supply space. Automatic measuring device for crab noodles. The upper ends of the pair of measuring rods are connected to each other by a connecting plate at a predetermined interval, and the measuring rod connecting body in which the upper end and the lower end of each measuring rod are opened,
The discharge port opening / closing unit has a measuring rod driving unit that reciprocates the measuring rod connecting body in a substantially horizontal direction under the bowl noodle discharging port, and the connection plate according to the reciprocating movement of the measuring rod connecting body. Is located under the bowl noodle outlet, closes the bowl noodle outlet and opens the bowl noodle outlet when the upper end of any one of the measuring bowls is located under the bowl noodle outlet. Item 9. An automatic measuring device for crab noodles according to any one of items 1 to 8. A closing plate disposed below the bowl noodle outlet so as to close the lower end of the bowl located under the bowl noodle outlet along with the reciprocating movement of the weighing bowl connector;
The automatic measurement of potato noodles according to claim 9, further comprising: a collection chute for collecting potato noodles falling from the lower ends of the measurement jars located on both sides of the closing plate with the reciprocating movement of the measurement candy coupling body. apparatus.   The automatic measuring device for crab noodles according to any one of claims 1 to 10, wherein the measuring trough is formed from a punching plate. The funnel portion has a truncated cone part whose diameter decreases downward and a cylindrical part connected to the lower end of the truncated cone part,
The bowl noodle outlet is disposed at the lower end of the cylindrical portion,
The plurality of through-holes are respectively formed in the peripheral wall of the truncated cone portion, and are directed to the central axis of the truncated cone portion and have a predetermined elevation angle with respect to a horizontal plane and are directed to the upper portion of the funnel portion. Each of the through-holes and the peripheral wall of the cylindrical portion, and is inclined in the circumferential direction with respect to the direction toward the central axis of the cylindrical portion and has a predetermined depression angle with respect to a horizontal plane, below the funnel portion. The automatic measuring device for crab noodles according to any one of claims 1 to 11, comprising a plurality of second through-holes that face each other. A plurality of funnels are juxtaposed at the lower end of the hopper,
A plurality of measuring rods corresponding to the plurality of funnels,
13. The automatic measuring device for crab noodles according to any one of claims 1 to 12, wherein the dissolving water supply unit supplies the dissolving water to the stored water in the plurality of funnels. The manufacturing method of the subdivision noodles which manufacture the subdivision noodles measured using the automatic measuring device of the noodles as described in any one of Claims 1-13.