JP7218967B1 - Adjustment joints and movable adjustment joint components used therefor - Google Patents

Abstract

[Problem] To provide an adjustment mechanism capable of reliably improving the quality of edible plate seaweed by incorporating it into the outflow amount output system for laver dough liquid proposed in Patent Document 1, and a movable adjustment mechanism used therefor. A component is provided. An adjustment joint (14) includes a first adjustment joint constituent member (15) as a movable adjustment joint constituent member, which extends in the left-right direction of the diversion tank (3) with its lower end floating from the bottom of the diversion tank (3), and a first adjustment joint (14). It is positioned in front of the flow dividing member 15 and extends in the left-right direction of the flow dividing tank 3 with its lower end attached to the bottom of the flow dividing tank 3 and overlapped with the lower end of the first adjusting flow connecting forming member 15 in the front-rear direction. and a second adjustment joint component 16 . The first adjustment member 15 is slidably adjustable in the lateral direction by a slide adjustment mechanism comprising a fixed piece 15a, long holes (bolt insertion holes) 15b and 15c, bolts 15d and nuts. [Selection drawing] Fig. 3

Description

The present invention relates to adjustment joints and movable adjustment joint components used therein. More specifically, the present invention provides an adjustment mechanism for adjusting the flow rate of a mixture of water and finely minced raw laver, which is the raw material dough, and a movable adjustment mechanism used for this, when producing edible dried laver. Concerning components.

Dried seaweed to be eaten is prepared by continuously supplying a mixed liquid of finely minced raw seaweed and water (hereinafter simply referred to as "seaweed dough liquid") into a paper box to make a slatted seaweed miss. After papering into a rectangular flat sheet, it is generally commercialized through the process of drying and peeling off the seaweed sheet (production of edible plate seaweed).

By the way, if the weight of the raw seaweed flowing onto the seaweed misuse is unstable, uneven drying may occur, which may reduce the quality of the edible plate seaweed.
As a technology to solve this problem, for example, a flow rate sensor is placed at the position where the laver dough liquid flows out on the laver mistake, and it is considered to control the amount of laver dough liquid outflow required for each edible plate laver. be done.

However, in the production of edible sheets of nori, it is necessary to uniformly flow out the nori dough liquid onto the nori sheet for molding. It will be broken and it will be difficult to measure directly. For this reason, the manager cannot grasp the unit amount of the laver dough liquid for one sheet of edible laver, which is one of the causes of deterioration in the quality of the edible laver.
Therefore, the present applicant has made it possible for the administrator to grasp the amount of the laver dough liquid that flows out on the laver mistake, and the outflow of the laver dough liquid that can improve the quality of the edible plate laver. We have proposed a quantity output system (see Patent Document 1).

The laver dough liquid outflow output system proposed in Patent Document 1 comprises at least a laver-making machine M' shown in FIG. 6, a flow meter 101, and a communication terminal (not shown).
As shown in FIG. 6, the laver-making machine M′ has a machine box 102 and a nori dough liquid supply mechanism 103 . The nori dough liquid supply mechanism 103 includes a branch tank 104 provided above the paper box 102 that stores the laver dough liquid L', and a branch tank 104 that supplies the laver dough liquid L' into the paper box 102. and a vessel 105 . The laver making machine M' transports laver waste 106, which is horizontally conveyed by a laver waste conveying mechanism (not shown) provided below the paper box 102, to a water disposal table 107 provided below. It is configured to be sandwiched between a water retention mechanism 109 having a water retention bag 108 and a transparent mass 110 .

The flow divider 105 of the laver dough liquid supply mechanism 103 is a curved hollow tube having an upper end communicating with the bottom of the flow dividing tank 104 and a lower end having a funnel-shaped tapered supply port 105a. It is inserted from the shoulder of the box 102 so that the seaweed dough liquid L' can be supplied into the box 102 from the supply port 105a. The paper box 102 is also formed with an overflow port 102a that extends downward from the shoulder into which the flow divider 105 is inserted and discharges the seaweed dough liquid L' overflowing from the paper box 102.

A plurality of laver dough liquid outflow holes 102c are formed in the bottom plate 102b of the paper box 102, and these laver dough liquid outflow holes 102c are provided with a plurality of paper making valves 102d. (Push-down valve) 102e enables it to be opened and closed. The opening and closing operation of the papermaking valve 102e follows the vertical movement of the papermaking valve hanger plate 102f.

The flow meter 101 is a sensor that measures the outflow flow rate of the seaweed dough liquid L′ supplied to the paper box 102, and is arranged at the bottom of the flow dividing tank 104 between the flow dividing tank 104 and the flow dividing device 105. .
The communication terminal has a calculator and an output unit. The calculation unit calculates the outflow of the laver dough liquid L' from the time T from when the laver dough liquid L' flows into the paper box 102 until it overflows from the machine box 102, and the outflow rate Q of the laver dough liquid L'. Calculate the quantity (Q×T). The output unit outputs the outflow amount calculated by the calculation unit.

According to the nori dough liquid outflow output system having the above configuration, it is possible for the administrator to grasp the outflow amount of the laver dough liquid L′ flowing out onto the laver mistake 106, thereby improving the quality of the edible plate laver. can be achieved.

Specification and drawings of Japanese Patent Application No. 2021-010553

The outflow amount output system of laver dough liquid proposed in Patent Document 1 enables the administrator to grasp the outflow amount of laver dough liquid flowing out on the laver mistake, as described above, and the edible plate laver. However, it has been desired to ensure the quality improvement of the edible plate laver.

Therefore, the present inventors have made further intensive studies, and found that turbulence occurs when the laver dough liquid is supplied from the separate tank into the paper making box, and the raw laver dough liquid in the laver dough liquid supplied into the making box After finding out that there is a possibility of unevenness in the concentration of seaweed, we devised the internal structure of the diversion tank of the laver dough liquid supply mechanism, so that the disturbance when the laver dough liquid is supplied from the diversion tank to the paper box. It was found that by suppressing the occurrence of flow, it is possible to reduce the possibility of occurrence of unevenness in the concentration of fresh laver in the laver dough liquid supplied to the paper box.
In addition, the present inventors have found that the nori dough liquid flowing from the upstream side to the downstream side of the diversion tank has an uneven flow rate in the left and right direction (longitudinal direction) of the diversion tank, and multiple After identifying the possibility that the amount of nori dough liquid supplied to each machine box may vary, the internal structure of the diversion tank of the nori dough liquid supply mechanism was further devised to create a diversion tank. It was found that it is possible to suppress the occurrence of unevenness in the flow rate in the left and right direction (longitudinal direction) of the machine, and to reduce the possibility of occurrence of variation in the amount of laver dough liquid supplied into each paper box.
Based on these findings, the inventors have completed the present invention.

The present invention has been made in view of the above circumstances, and by incorporating it into the nori dough liquid outflow output system proposed in Patent Document 1, it is possible to ensure the quality improvement of edible plate laver. It is an object of the present invention to provide an adjustable joint and a movable adjustable joint component used therein.

In order to achieve the above object, the configuration of the adjustment mechanism according to the present invention is as follows:
(1) An adjustment for adjusting the flow rate of the laver dough liquid, which is a mixture of finely minced raw laver and water, provided inside a horizontally elongated storage tank that extends in the left-right direction and stores the laver dough liquid. in Seki,
a first adjustment joint component extending in the left-right direction of the storage tank with its lower end floating from the bottom of the storage tank;
When the downstream side of the flow of the seaweed dough liquid is the front and the upstream side is the rear, it is positioned in front of the first adjustment member, and has a lower end attached to the bottom of the storage tank and the first adjustment member. a second adjustment joint component extending in the left-right direction of the storage tank while overlapping the lower end of the first adjustment joint component in the front-rear direction;
The first adjustment joint component is provided so as to be slidably adjustable in the lateral direction by a slide adjustment mechanism.

The configuration (1) of the adjustment mechanism of the present invention has the following effects.
That is, according to the above configuration (1), the seaweed dough liquid pumped into the storage tank is allowed to pass between the bottom of the storage tank and the lower end of the first adjustment joint constituent member, and the second adjustment joint By climbing over the constituent parts, it becomes possible to discharge the seaweed dough liquid into the supply pipe at a constant speed and by a constant amount. As a result, it is possible to suppress the occurrence of turbulence when the laver dough liquid is supplied from the storage tank into the paper box.
Therefore, according to the configuration (1) above, it is possible to reduce the possibility of occurrence of unevenness in the concentration of raw laver in the laver dough liquid supplied into the paper box. As a result, by incorporating the above configuration (1) into the outflow output system for the seaweed dough liquid proposed in Patent Document 1, it is possible to reliably improve the quality of the edible plate seaweed.
Further, according to the above configuration (1), the gap between the bottom of the storage tank and the lower end of the first adjustment joint component (movable adjustment joint component) is set to the first adjustment joint component (movable adjustment joint component) ) in the lateral direction to adjust the flow from the upstream side to the downstream side (the second adjustment mechanism component side), and the flow rate in the left and right direction (longitudinal direction) of the storage tank is uneven. The water depth of a certain laver dough liquid is adjusted so as to be suppressed by the first adjusting member (movable adjusting member), and the nori dough liquid flowing downstream (second adjusting member) is stored in the storage tank. It is possible to suppress the occurrence of unevenness in the flow rate in the left-right direction (longitudinal direction) (the flow rate of the laver dough liquid in the left-right direction (longitudinal direction) of the storage tank can be stabilized).
Therefore, according to the configuration (1) above, it is possible to reduce the possibility of occurrence of variation in the amount of laver dough liquid supplied into each of the plurality of paper boxes arranged horizontally and at equal intervals. As a result, by incorporating the configuration (1) above into the outflow output system for the seaweed dough liquid proposed in Patent Document 1, it is possible to flow out the same weight of raw seaweed onto each seaweed mistake. Therefore, unevenness in drying does not occur, and the quality improvement of each sheet of edible plate laver having the same weight can be ensured.

In the above configuration (1) of the adjustment mechanism of the present invention, it is preferable to adopt the following configuration (2).

(2) When the downstream side of the flow of the seaweed dough liquid is defined as the front and the upstream side as the rear, it is positioned behind the first adjustment member and has a lower end attached to the bottom of the storage tank. a third adjustment joint component extending in the left-right direction of the storage tank in a state where the
A bar that extends in the left-right direction of the storage tank while being spaced apart from the upper end of the third adjustment member and that can move up and down.

According to the preferred configuration of (2) above, the gap between the upper end of the third adjustment member and the bar is appropriately adjusted by moving the bar up and down, thereby pumping the seaweed dough into the storage tank. Fluid can be directed toward the first control element in increments. As a result, it is possible to reliably discharge the laver dough liquid by a constant amount to the supply pipe, so that the generation of turbulent flow when the laver dough liquid is supplied from the storage tank to the machine box can be surely suppressed. can be done.

Further, the configuration of the movable adjustment joint component according to the present invention is
(3) A movable adjustment joint component as the detachable first adjustment joint component used for the adjustment joint of the configuration (1) or (2) above ,
Assuming that the downstream side of the flow of the seaweed batter liquid is the front side and the upstream side is the rear side when the movable adjustment member is attached to the storage tank, the left and right ends of the movable adjustment member are provided respectively. , and fixed pieces are provided parallel to both the left and right inner wall surfaces of the storage tank, and each of the fixed pieces is provided with a long hole as a bolt insertion hole parallel to the lateral direction of the movable adjustment member. It is characterized by

According to the above configuration (3) of the movable adjustment joint component of the present invention, the left and right ends of the movable adjustment joint component are attached to both the left and right inner wall surfaces of the storage tank by the bolts and nuts inserted through the long holes. can be detachably fixed to the Then, by loosening the bolt and sliding the movable adjustment joint component in its lateral direction, the gap between the bottom of the storage tank and the lower end of the movable adjustment joint component (first adjustment joint component) is adjusted. be able to.

According to the present invention, the generation of turbulent flow when the laver dough liquid is supplied from the storage tank into the machine box is suppressed, and the concentration of raw laver in the laver dough liquid supplied into the machine box is uniform. The possibility of occurrence can be reduced. As a result, by incorporating the configuration of the present invention into the outflow amount output system for seaweed dough liquid proposed in Patent Document 1, it is possible to ensure the quality improvement of edible plate seaweed. In addition, according to the present invention, the occurrence of unevenness in the flow rate of the laver dough liquid flowing downstream (the side of the second adjustment joint component) in the left-right direction (longitudinal direction) of the storage tank is suppressed, and the It is possible to reduce the possibility of occurrence of variations in the amount of nori dough liquid supplied into each of the machine boxes arranged at intervals. As a result, by incorporating the configuration of the present invention into the nori dough liquid outflow output system proposed in Patent Document 1, it is possible to cause the same weight of raw laver to flow out onto each laver mistake, so drying There is no occurrence of unevenness, and the quality improvement of each sheet of edible plate laver having the same weight can be ensured.

FIG. 1 is a rear view showing the configuration of a laver-making machine including a movable adjusting joint component according to embodiment 1 of the present invention (a laver blade, a water retention mechanism, and a transparent mass are omitted). FIG. 2 is a partially cutaway side view showing the configuration of the laver-making machine including the movable adjustment joint component according to embodiment 1 of the present invention. FIG. 3 is an enlarged side view, partly cut away, showing the configuration around the branch tank of the laver dough liquid supply mechanism including the movable adjustment component according to Embodiment 1 of the present invention. FIG. 4 is an enlarged side cross-sectional view showing the configuration of the adjustment joint including the movable adjustment joint constituent member in Embodiment 1 of the present invention. FIG. 5 is a partially cutaway side view showing the configuration of a laver-making device including a movable adjustment component according to embodiment 2 of the present invention. FIG. 6 is a partially broken side view showing the configuration of a conventional laver sheeting device.

Hereinafter, the present invention will be described in more detail using preferred embodiments. However, the following embodiments are merely examples embodying the present invention, and the present invention is not limited thereto.

[Embodiment 1]
(Structure of laver machine)
First, the configuration of a laver-making device including a movable adjustment component according to Embodiment 1 of the present invention will be described with reference to FIGS. 1 and 2. FIG.

FIG. 1 is a rear view showing the configuration of a laver-making machine including movable adjustment joint constituent members according to embodiment 1 of the present invention (the seaweed slip, water retention mechanism, and transparent mass are omitted), and FIG. 2 is the configuration of the movable adjustment joint. FIG. 2 is a partially cutaway side view showing the configuration of a laver sheeting device including members.

As shown in FIGS. 1 and 2, the laver making machine M has a making box 1 and a nori dough liquid supply mechanism 2 . The nori dough liquid supply mechanism 2 includes a flow division tank 3 as a storage tank for storing the laver dough liquid L, which is provided at the rear (rear side) of the paper making box 1, and a nori feeder from the diversion tank 3 into the paper making box 1. and a flow divider 4 as a supply pipe for supplying the dough liquid L. Then, the laver making machine M disposes the laver waste 5 horizontally conveyed by a laver waste conveying mechanism (not shown) provided below the paper making box 1 to a drainage table 6 and a water retention table provided below. It is configured to be sandwiched between a water retention mechanism 8 having a bag 7 and a transparent mass 9. - 特許庁

The diversion tank 3 has a laterally long shape extending in the left-right direction, and a plurality of sets of a papermaking box 1, a diversion device 4, a water retention mechanism 8 and a transparent mass 9 are arranged horizontally at regular intervals. FIG. 1 exemplifies a case where five sets of paper box 1, flow divider 4, water retaining mechanism 8, and transparent mass 9 are arranged horizontally at equal intervals.

The flow divider 4 of the laver dough liquid supply mechanism 2 has a rear end bent upward and a front end (supply port 4a) bent downward, and portions other than the rear end and the front end are straight. It consists of a hollow tube. The rear end of the flow divider 4 communicates with the front bottom of the flow dividing tank 3, and the front end thereof is inserted from the shoulder of the paper box 1 to supply the seaweed dough liquid L into the paper box 1 from the supply port 4a. It is made possible. Further, the paper box 1 is formed with an overflow port 1a that extends downward from the shoulder into which the flow divider 4 is inserted and discharges the seaweed dough liquid L overflowing from the paper box 1. - 特許庁
More specifically, the flow splitter 4 is in a state where the entirety is gradually inclined downward from the upstream side toward the downstream side. The tilt angle is, for example, about 0° to about 20°. FIG. 2 illustrates a case where the flow divider 4 is maintained substantially horizontally with a slight forward downward inclination. Such a configuration can be realized by bringing the height position of the branch tank 3 closer to the height position of the paper box 1 .

Such a configuration of the laver dough liquid supply mechanism 2 has the following effects.
That is, according to such a configuration, the entire flow divider 4 that supplies the seaweed dough liquid L stored in the flow dividing tank 3 to the paper box 1 gently tilts downward from the upstream side to the downstream side. Therefore, it is possible to reduce the drop when the seaweed dough liquid L is supplied from the diverter tank 3 into the paper box 1, thereby suppressing the occurrence of turbulence.
Therefore, according to such a configuration, it is possible to reduce the possibility of occurrence of unevenness in the concentration of raw seaweed in the seaweed dough liquid L supplied into the paper box 1 . As a result, by incorporating such a configuration into the nori dough outflow output system proposed in Patent Document 1, it is possible to ensure the quality improvement of the edible plate laver.

The papermaking box 1 is formed in the shape of a hollow housing, and is provided therein with a papermaking valve 1d supported by a plurality of valve stems 1c suspended from a papermaking valve hanger plate 1b provided at the upper end. The supply port 4a of the flow divider 4 inserted from the shoulder of the papermaking box 1 is arranged facing the papermaking valve 1d.

A plurality of seaweed dough outflow holes 1f are formed in the bottom plate 1e of the paper box 1, and these seaweed dough outflow holes 1f are a plurality of seaweed dough valves vertically installed (leaded) in the paper making valve 1d. (Push-down valve) 1g can be opened and closed. The opening and closing operation of the papermaking valve 1g follows the up-and-down movement of the papermaking valve hanger plate 1b.

By vertically driving a papermaking arm 10 disposed above the papermaking box 1, the papermaking valve hanger plate 1b is moved between the papermaking valve hanger plate 1b and the valve frame 1h at the top of the papermaking box 1 via a spring 11. When the main valve stem 12 connected and held is pressed, it is elastically moved up and down.

That is, by vertically driving the paper making arm 10 to move the paper making valve 1d up and down, the seaweed dough outflow hole 1f can be opened and closed. Further, in the lower part of the box 1, there is arranged a cylindrical transparent mass 9 which is open at the top and bottom and has a collar portion 9a formed on the peripheral edge of the upper end. The transparent mass 9 can move up and down so that it can come into contact with and separate from the seaweed shavings 5 .

The water retention mechanism 8 includes a flexible water retention bag 7 attached to the lower part of a lower mass 7a formed in the shape of a rectangular plate so as to be able to be compressed and expanded. It is configured by arranging. The lower mass 7a is provided with a plurality of vertically penetrating water passage holes (not shown). The water surface position of the water retained in the water can be moved up and down.

A pumping pipe 13 for pumping the seaweed dough liquid L into the branch tank 3 is arranged on the rear side inside the branch tank 3 . Here, the pressure-feeding pipe 13 is branched into two left and right first and second pressure-feeding pipes 13a and 13b. The tip portion of the first pressure-feeding pipe 13a is positioned rearward (rear side) in the vicinity of the bottom of the flow dividing tank 3 to which the second flow dividing device 4 from the left is communicated. In addition, the tip of the second pressure feed pipe 13b is located behind (on the rear side) near the bottom of the flow dividing tank 3 to which the second flow dividing device 4 from the right is communicated.
An adjustment joint 14 for adjusting the flow rate of the seaweed dough liquid L is provided inside the flow dividing tank 3, positioned in front of (rear to) the communicating portion with the flow dividing device 4. - 特許庁

Such a configuration of the laver dough liquid supply mechanism 2 has the following effects.
That is, according to such a configuration, the adjustment joint 14 for adjusting the flow rate of the seaweed dough liquid L is provided inside the flow dividing tank 3, in front of the portion communicating with the flow dividing device 4. It is possible to suppress the generation of turbulence when the laver dough liquid L stored in the paper making box 1 is supplied to the paper making box 1 by discharging the laver dough liquid L stored in the inside 3 into the flow divider 4 at a constant speed and in a constant amount. can.
Therefore, according to such a configuration, it is possible to reduce the possibility of occurrence of unevenness in the concentration of raw seaweed in the seaweed dough liquid L supplied into the paper box 1 . As a result, by incorporating such a configuration into the nori dough outflow output system proposed in Patent Document 1, it is possible to ensure the quality improvement of the edible plate laver.

(Structure of coordinator)
Next, the configuration of the adjustment joint including the movable adjustment joint constituent members according to Embodiment 1 of the present invention will be described in further detail with reference to FIGS. 3 and 4 as well.

FIG. 3 is a partially broken enlarged side view showing the configuration around the branch tank of the laver dough liquid supply mechanism including the movable adjustment component in embodiment 1 of the present invention, and FIG. 4 includes the movable adjustment component. FIG. 4 is an enlarged side cross-sectional view showing the configuration of an adjustment joint;

As shown in FIGS. 2 to 4, the adjustment joint 14 is a first adjustment joint component as a movable adjustment joint component that extends in the horizontal direction of the diversion tank 3 with its lower end floating from the bottom of the diversion tank 3. 15 is located in front of the first adjustment joint component 15, and has its lower end attached to the bottom of the flow dividing tank 3 and overlaps the lower end of the first adjustment joint component 15 in the front-rear direction. 3, a second adjustment joint component 16 extending in the left-right direction. Here, the first adjustment joint component member 15 is made of a flat plate material with its upper and lower ends bent forward by 90°, and the entirety is inclined rearward (the inclination angle α from the directly above direction is, for example, about 10° to 20°). Further, the second adjustment joint component 16 is also made of a flat plate material, and is inclined rearward as a whole (the inclination angle β from the directly above direction is, for example, about 20° to about 30°).

According to such a configuration, the seaweed dough liquid L pressure-fed into the split tank 3 is allowed to pass between the bottom of the split tank 3 and the lower end of the first adjustment joint component 15, and the second adjustment joint component 16, it is possible to discharge the seaweed dough liquid L to the flow divider 4 at a constant speed and in a constant amount. As a result, it is possible to suppress the occurrence of turbulent flow when the seaweed dough liquid L is supplied from the diversion tank 3 into the paper box 1 .

The left and right ends of the second adjustment joint component 16 are fixed to the left and right inner wall surfaces of the flow dividing tank 3, respectively. That is, the second adjustment joint component 16 is in a fixed state.
On the other hand, the first adjusting joint component 15 is provided with fixed pieces 15a parallel to the left and right inner wall surfaces of the flow dividing tank 3 at both left and right ends thereof. A pair of upper and lower elongated holes (bolt insertion holes) 15b and 15c are formed parallel to the lateral direction of the member 15, respectively. The left and right end portions of the first adjustment member 15 are detachable from the left and right inner wall surfaces of the flow dividing tank 3 by means of bolts 15d and nuts (not shown) inserted through the long holes 15b and 15c. can be fixed.

As described above, each fixed piece 15a of the first adjustment member 15 is provided with a pair of upper and lower elongated holes 15b and 15c parallel to the lateral direction of the first adjustment member 15 as bolt insertion holes. It is Therefore, by loosening the bolt 15d and sliding the first adjustment member 15 in its lateral direction (see double-headed arrows A and B in FIGS. 3 and 4), the bottom of the diversion tank 3 and the first The gap G1 with the lower end of the 1-adjustment joint component 15 can be adjusted. That is, the first adjustment joint component 15 is slidably adjustable in the lateral direction by a slide adjustment mechanism comprising a fixed piece 15a, long holes (bolt insertion holes) 15b and 15c, a bolt 15d and a nut. After the gap G1 has been adjusted, the bolts 15d are tightened to fix the first adjustment component 15. As shown in FIG.

By the way, if the first adjustment joint component (movable adjustment joint component) 15 as in this embodiment is not provided, the upstream side (the third adjustment joint component 17 described later) of the flow dividing tank 3 and the downstream side ( There is a possibility that the flow rate of the seaweed dough liquid L flowing into the second adjusting joint component 16 side) may be uneven in the left-right direction (longitudinal direction) of the diversion tank 3 . For this reason, the water passes over the second adjusting joint component member 16 and is guided to each of the plurality of flow dividers (supply pipes) 4 arranged horizontally and at equal intervals, and is supplied into the corresponding paper box 1 . There is a possibility that the amount of laver dough liquid L will vary. As a result, the weight of the raw seaweed flowing out from the seaweed dough liquid outflow hole 1f formed in the bottom plate 1e of each paper box 1 onto each seaweed mist 5 becomes unstable, and uneven drying occurs, resulting in an edible plate seaweed. There is a risk of degrading the quality of each sheet.

However, if the first adjustment joint component (movable adjustment joint component) 15 as in the present embodiment is provided, the following effects can be obtained.
That is, the gap G1 between the bottom of the flow dividing tank 3 and the lower end of the first adjustment joint component (movable adjustment joint component) 15 is formed by moving the first adjustment joint component (movable adjustment joint component) 15 in the lateral direction. By appropriately adjusting by sliding, the left-right direction ( The water depth of the seaweed dough liquid L with uneven flow rate in the longitudinal direction) is adjusted so as to be suppressed by the first adjustment joint component (movable adjustment joint component) 15, and the downstream side (second adjustment joint component 16 side) ) in the left-right direction (longitudinal direction) of the diversion tank 3 (longitudinal direction) of the nori dough liquid L flowing in the diversion tank 3 can be suppressed. flow rate can be stabilized).
Therefore, the seaweed dough liquid is passed over the second adjusting joint component 16 and guided to each of the plurality of flow dividers (supply pipes) 4 arranged horizontally at equal intervals, and supplied into the corresponding respective paper boxes 1. It is possible to reduce the possibility that the amount of L will vary. As a result, by incorporating the configuration of the adjusting joint 14 of the present embodiment into the nori dough outflow output system proposed in Patent Document 1, nori dough outflow holes formed in the bottom plate 1e of each box 1 Since it is possible to flow the same weight of raw seaweed from 1f onto each seaweed mistake 5, uneven drying does not occur, and the quality improvement of each sheet of edible plate seaweed with the same weight is ensured. can do.

Further, the adjustment joint 14 is provided behind the first adjustment joint constituent member 15, and is a third adjustment joint constituent member extending in the horizontal direction of the diversion tank 3 with its lower end attached to the bottom of the diversion tank 3. 17, and a bar 18 (see double arrows C and D in FIGS. 3 and 4) which extends in the left-right direction of the flow dividing tank 3 in a state separated from the upper end of the third adjustment member 17 and which can move up and down. , is further provided. Here, the third adjustment joint component 17 is made of a flat plate material that is bent in the shape of a bow with an angular shape that protrudes forward, and is entirely inclined rearward (the inclination angle γ of the lower end portion from directly above is, for example, , about 10° to about 20°). The left and right end portions of the third adjustment joint component member 17 are fixed to the left and right inner wall surfaces of the flow dividing tank 3, respectively. That is, the third adjustment joint component 17 is in a fixed state.

According to such a configuration, the gap G2 between the upper end of the third adjustment member 17 and the bar 18 can be appropriately adjusted by moving the bar 18 up and down (see double arrows C and D in FIGS. 3 and 4). By adjusting, the seaweed dough liquid L pressure-fed into the splitting tank 3 can be flowed toward the first adjusting mechanism component 15 by a constant amount. As a result, since it is possible to discharge the seaweed dough liquid L into the diverter 4 at a constant rate, turbulent flow when the laver dough liquid L is supplied from the diverter tank 3 into the paper box 1 can be prevented. can be reliably suppressed.

(Operation of laver machine)
Next, the operation of the laver-making machine including the movable adjustment component according to the first embodiment of the present invention will be described with reference to FIGS. 1 to 4 as well.

Generally speaking, the seaweed dough liquid L stored in the diversion tank 3 is supplied into the paper box 1 from the supply port 4 a of the flow diversion device 4 .
As shown in FIGS. 1 and 2, first, when the laver-making machine M is started, the laver dough liquid L, which is constantly pumped through the pumping pipe 13 and stored in the branch tank 3 of the laver dough liquid supply mechanism 2, is stored. It is divided and supplied into each paper box 1 by a corresponding flow divider 4 . The seaweed dough liquid L supplied into each paper box 1 fills the inside of the paper box 1, and when it is full, it overflows and overflows from the overflow port 1a.

As shown in FIGS. 2 to 4, inside the flow dividing tank 3, first, the seaweed dough liquid L pumped from the tip of the pumping pipe 13 wraps around the back side of the third adjustment member 17 (Fig. 3), and then passes through the gap G2 between the upper end of the third adjustment member 17 and the bar 18 (see arrow f in FIG. 3). Here, the gap G2 between the upper end of the third adjustment member 17 and the bar 18 is appropriately adjusted by moving the bar 18 up and down (see double arrows C and D in FIGS. 3 and 4). , the seaweed dough liquid L pressure-fed into the diversion tank 3 can be flowed toward the first adjustment mechanism constituent member 15 by a constant amount. The seaweed dough liquid L that has passed through the gap G2 between the upper end of the third adjustment member 17 and the bar 18 passes through the gap G1 between the bottom of the branch tank 3 and the lower end of the first adjustment member 15, and After getting over the second adjustment joint component 16 (see arrow t in FIG. 3), it is discharged to each flow divider 4 at a constant speed and a constant amount at a time (see arrow h in FIG. 3), whereby the seaweed dough liquid is discharged. The generation of turbulent flow when L is supplied from the diverter tank 3 into the paper box 1 is suppressed. As a result, it is possible to reduce the possibility of occurrence of unevenness in the concentration of raw laver in the laver dough liquid L supplied into the paper box 1, and to ensure the quality improvement of the edible plate laver.

The seaweed dough liquid L discharged to each flow divider 4 is supplied into the corresponding paper box 1 from the supply port 4a of the flow divider 4 . Then, the laver dough liquid L filled in the paper box 1 becomes the amount of the laver dough liquid that flows out onto the laver mist 5 in one operation.

Here, the gap G1 between the bottom of the flow dividing tank 3 and the lower end of the first adjustment joint component (movable adjustment joint component) 15 is such that the first adjustment joint component (movable adjustment joint component) 15 (See double-headed arrows A and B in FIGS. 3 and 4) for proper adjustment. For this reason, the laver that flows from the upstream side (the third regulator component 17 side) to the downstream side (the second regulator component 16 side) has an uneven flow rate in the horizontal direction (longitudinal direction) of the diverter tank 3. The water depth of the dough liquid L is adjusted so as to be suppressed by the first adjusting joint component (movable adjusting joint forming member) 15, and the laver dough liquid L flowing downstream (second adjusting joint forming member 16 side) is diverted. It is possible to suppress the occurrence of unevenness in the flow rate in the left-right direction (longitudinal direction) of the tank 3 (the flow rate of the seaweed dough liquid L in the left-right direction (longitudinal direction) of the branch tank 3 can be stabilized).
Therefore, the seaweed dough liquid is passed over the second adjusting joint component 16 and guided to each of the plurality of flow dividers (supply pipes) 4 arranged horizontally at equal intervals, and supplied into the corresponding respective paper boxes 1. It is possible to reduce the possibility that the amount of L will vary. As a result, the raw laver of the same weight can be discharged from the laver dough liquid outflow hole 1f formed in the bottom plate 1e of each paper box 1 onto each laver mistake 5, so that uneven drying does not occur. , it is possible to ensure the quality improvement of each piece of edible plate laver with the same weight.

The dried seaweed 5 is intermittently transported by a predetermined distance along the transport path in a predetermined cycle. After that, the laver-making machine M lowers the transparent mass 9 and brings its lower open surface into contact with the upper surface of the lower mass 7a through the seaweed shavings 5. - 特許庁As a result, the seaweed miss 5 is sandwiched between the transparent mass 9 and the lower mass 7a.

Next, the laver-making machine M raises the waste table 6 to push up the center of the lower portion of the water-retaining bag 7, thereby compressing the water-retaining bag 7. - 特許庁As a result, the water stored inside the water retaining bag 7 permeates the seaweed shavings 5 from the water passage holes of the lower mass 7a and flows out into the transparent mass 9, and the upper surface of the seaweed shavings 5 is filled with water. state.

Next, in the laver making machine M, the main valve stem 12 is pushed down by the making arm 10 to press the making valve 1d, and the making valve 1g is lowered to open the nori dough outflow hole 1f in the bottom plate 1e of the making box 1. state. As a result, the seaweed batter liquid L is allowed to flow down onto the seaweed mistake 5 for papermaking.

After making the laver sheet, the laver sheet forming apparatus M raises the sheet sheet forming valve 1d to close the nori dough outflow hole 1f. Then, the operation returns to the step of diverting and supplying the seaweed dough liquid L into the paper box 1, and the above-described operations are repeated.

In the present embodiment, the case where the entire flow divider 4 gently slopes downward from the upstream side to the downstream side has been described as an example. However, the present invention is not necessarily limited to such a configuration. An adjustment joint 14 including a first adjustment joint component (movable adjustment joint component) 15 for adjusting the flow rate of the seaweed dough liquid L is provided inside the flow dividing tank 3 before the communicating portion with the flow divider 4. If so, the state in which the flow divider 4 is arranged is arbitrary.

Further, in the present embodiment, the adjustment joint 14 is provided behind the first adjustment joint component 15 and extends in the lateral direction of the diversion tank 3 with its lower end attached to the bottom of the diversion tank 3 . An example of a case further comprising a third adjustment joint component 17 and a vertically movable bar 18 that extends in the left-right direction of the flow dividing tank 3 while being separated from the upper end of the third adjustment joint component 17 . mentioned and explained. However, the present invention is not necessarily limited to such a configuration. The adjustment joint 14 is composed of a first adjustment joint constituent member (movable adjustment joint constituent member) 15 extending in the left-right direction of the diversion tank 3 with its lower end raised from the bottom of the diversion tank 3 , and the first adjustment joint constituent member 15 . A second adjustment joint structure which is provided at the front and which extends in the left-right direction of the diversion tank 3 while its lower end is attached to the bottom of the diversion tank 3 and overlaps the lower end of the first adjustment joint-constituting member 15 in the front-rear direction. , the provision of the third adjustment component 17 and the bar 18 is optional.

Further, in this embodiment, the first adjustment joint component (movable adjustment joint component) 15 is shortened by a slide adjustment mechanism comprising a fixed piece 15a, long holes (bolt insertion holes) 15b and 15c, bolts 15d and nuts. A case in which it is provided so as to be slidably adjustable in the hand direction has been described as an example. However, the present invention is not necessarily limited to such a configuration. Any other configuration can be adopted as the slide adjustment mechanism as long as the first adjustment joint constituent member (movable adjustment joint constituent member) 15 can be slidably adjusted in the lateral direction.

[Embodiment 2]
Next, the configuration of a laver-making machine including movable adjustment-related structural members according to Embodiment 2 of the present invention will be described with reference to FIG.

FIG. 5 is a partially cutaway side view showing the configuration of a laver-making device including a movable adjustment component according to embodiment 2 of the present invention.

The laver-making machine M2 of this embodiment differs from the laver-making machine M of the first embodiment only in the configuration of the laver dough liquid supply mechanism, particularly the configuration of the flow divider (supply pipe). It is the same as the first embodiment. For this reason, other configurations are given the same reference numerals, detailed descriptions thereof are omitted, and FIGS. 1 to 4 and the description of the first embodiment are used.

As shown in FIG. 5, the seaweed machine M2 has a machine box 1 and a seaweed dough supply mechanism 19. As shown in FIG. The nori dough liquid supply mechanism 19 includes a flow division tank 3 as a storage tank for storing the laver dough liquid L provided at the rear (rear side) of the paper making box 1 , and a nori dough from the diversion tank 3 into the paper making box 1 . and a flow divider 20 as a supply pipe for supplying the liquid L.

The flow splitter 20 of the laver dough liquid supply mechanism 19 extends downward with its upper end communicating with the front bottom of the split flow tank 3, and after being bent twice at an angle of 135°, the downstream part It is in a state of gently sloping downward toward the side. The front end portion (downstream portion) of the flow divider 20 is inserted from the shoulder portion of the paper box 1 so that the seaweed dough liquid L can be supplied into the paper box 1 from the supply port 20a.
The inclination angle of the downstream portion of the flow divider 20 is, for example, about 0° to about 20°. FIG. 5 illustrates a case where the downstream portion of the flow divider 20 is maintained substantially horizontally with a slight forward downward inclination.

Such a configuration of the laver dough liquid supply mechanism 19 has the following effects.
That is, according to such a configuration, the downstream portion of the flow divider 20 that supplies the seaweed dough liquid L stored in the flow division tank 3 to the paper box 1 gently slopes downward from the upstream side to the downstream side. Therefore, it is possible to reduce the drop when the seaweed dough liquid L is supplied from the diverter tank 3 into the paper box 1, thereby suppressing the occurrence of turbulence.
Therefore, according to such a configuration, it is possible to reduce the possibility of occurrence of unevenness in the concentration of raw seaweed in the seaweed dough liquid L supplied into the paper box 1 . As a result, by incorporating such a configuration into the nori dough outflow output system proposed in Patent Document 1, it is possible to ensure the quality improvement of the edible plate laver.

The internal structure of the flow dividing tank 3 is the same as that of the first embodiment, and includes a first adjustment member (movable adjustment member) 15 .
Since the effects of the first adjustment joint component (movable adjustment joint component) 15 are the same as in the case of the first embodiment, description thereof will be omitted, and FIGS. invoke.

In the present embodiment, the case where the downstream portion of the flow divider 20 gently slopes downward from the upstream side to the downstream side has been described as an example. However, the present invention is not necessarily limited to such a configuration. An adjustment joint 14 including a first adjustment joint component (movable adjustment joint component) 15 for adjusting the flow rate of the seaweed dough liquid L is provided inside the flow dividing tank 3 before the portion communicating with the flow divider 20. If so, the state in which the flow divider 20 is arranged is arbitrary.

1 paper making box 1a overflow port 1b paper making valve hanger plate 1c valve stem 1d paper making valve 1e bottom plate 1f seaweed dough outflow hole 1g paper making valve (push-down valve)
1h valve frame 2, 19 seaweed dough supply mechanism 3 branch tank (storage tank)
4,20 flow divider (supply pipe)
4a Supply port 5 Nori seaweed mistake 6 Drain basin 7 Water retention bag 7a Lower mass 8 Water retention mechanism 9 Transparent mass 9a Flange 10 Paper arm 11 Spring 12 Main valve stem 13 Pressure-feeding pipe 13a First pressure-feeding pipe 13b Second pressure-feeding pipe 14 Adjusting joint 15 First adjustment joint component (movable adjustment joint component)
15a Fixed pieces 15b, 15c Long hole (bolt insertion hole)
15d Bolt 16 Second adjustment component 17 Third adjustment component 18 Bar L Seaweed dough liquid M, M2 Nori sheeting device G1, G2 Gap

Claims (3)

It is provided inside a horizontally elongated storage tank that stores a laver dough liquid, which is a mixture of finely minced raw laver and water, and is an adjustment valve that adjusts the flow rate of the laver dough liquid. hand,
a first adjustment joint component extending in the left-right direction of the storage tank with its lower end floating from the bottom of the storage tank;
When the downstream side of the flow of the seaweed dough liquid is the front and the upstream side is the rear, it is positioned in front of the first adjustment member, and has a lower end attached to the bottom of the storage tank and the first adjustment member. a second adjustment joint component extending in the left-right direction of the storage tank while overlapping the lower end of the first adjustment joint component in the front-rear direction;
The adjustment joint, wherein the first adjustment joint constituent member is provided so as to be slidably adjustable in a lateral direction by a slide adjustment mechanism. When the downstream side of the flow of the seaweed dough liquid is defined as the front and the upstream side is defined as the rear, it is provided behind the first adjustment member, and the lower end is attached to the bottom of the storage tank. a third adjustment joint component extending in the left-right direction of the storage tank;
2. The adjustment joint according to claim 1, further comprising a bar that extends in the left-right direction of the storage tank while being spaced apart from the upper end of the third adjustment joint component and that is vertically movable. A movable adjustment joint component used for the adjustment joint according to claim 1 or 2 and serving as the detachable first adjustment joint component ,
Assuming that the downstream side of the flow of the seaweed batter liquid is the front side and the upstream side is the rear side when the movable adjustment member is attached to the storage tank, the left and right ends of the movable adjustment member are provided respectively. , and fixed pieces are provided parallel to both the left and right inner wall surfaces of the storage tank, and each of the fixed pieces is provided with a long hole as a bolt insertion hole parallel to the lateral direction of the movable adjustment member. A movable adjustment component, characterized in that:

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