JP2016192912A - Auxiliary sowing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an auxiliary sowing device which can achieve an excellent germination rate and product harvest of a uniform quality and can perform sowing work simply and efficiently in producing a plant.SOLUTION: An auxiliary sowing device includes: a seed receipt tray 1 and a seed pressure tray 2. In a reception base body 11B constituting the seed reception tray 1, a reception side penetration hole having a diameter allowing a seed to penetrate is formed. In a pressure base body 21B constituting the seed pressure tray 2, a unit pressure part 21A is arranged to protrude. The seed reception tray 1 is placed on a sowing surface so that the reception side penetration hole matches a sowing position on the sowing surface. A free end of the unit pressure part 21A having penetrated the reception side penetration hole can press the seed arranged at the sowing position. The free end side of the unit pressure part 21A protrudes from a sowing surface side peripheral edge of the reception side penetration hole toward the sowing surface by a predetermined length.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a sowing aid for planting seeds on a sowing mat at the time of hydroponics, and particularly to a sowing aid in consideration of workability.

As a method for cultivating plants, a method has been practiced since ancient times in which seeds are planted in soil and photosynthesis is performed by sunlight.
On the other hand, in recent years, hydroponics has been performed in which seeds are planted on a support without using soil as a medium, and plants are grown by bringing moisture and nutrients into contact with the seeds and roots.
Such hydroponics has advantages such as easier nutrient control and easier control in terms of microbiological hygiene compared to soil cultivation, and plant cultivation by obtaining these advantages. It has been put to practical use as an industrialization tool.

By the way, in such hydroponics, a large number of seeds are planted on a sowing mat serving as a support for supporting a plant to grow the plant.
However, when such a cultivation method is adopted, the sowing operation is an operation of sequentially planting seeds at a large number of sowing positions (usually, sowing holes and sowing notches are formed) formed on the sowing mat. It becomes.
However, since such a sowing operation is very time-consuming, a technique for simplifying a series of sowing operations has been proposed (see, for example, Patent Document 1).

Patent Document 1 discloses a seeding device.
In this technique, an apparatus for embedding seeds in a plurality of slits formed in a sponge medium is disclosed.
The seed array plate used has a plurality of through holes, and when the seed array plate is placed on the top surface of the medium, the through holes are configured to align with the slit positions formed in the medium. Has been.
Therefore, when the seed array plate is placed on the upper surface of the medium and the seed is dropped into the through hole, the seed is arranged above the slit. In this state, the seed is embedded in the culture medium by burying the seed in the slit by pressing the seed from above with the rod-shaped member.

JP 2014-236722 A

By the way, when a plant is cultivated by such hydroponics, it is not necessary to simply embed a seed in a medium, and it is necessary to embed in consideration of germination and growth of the plant.
In other words, depending on the seed embedding depth, there are differences in germination and growth, especially from the viewpoint of industrial production of plants, while pursuing higher germination and growth, and with uniform quality. There is a need to produce plants.
However, the technique described in Patent Document 1 does not embed a large number of seeds at an optimal depth at a uniform depth. From such a viewpoint, a technique for embedding a large number of seeds at an optimal depth and a uniform depth is required. It was.
Furthermore, it has been desired to improve the sowing work so that it can be performed more easily. That is, in particular, the demand for work / working for elderly people and persons with disabilities has increased in recent years, and there is a demand for the development of a technology that allows such workers to work easily and reliably.

An object of the present invention is to solve the above-mentioned problems, and to provide a sowing aid capable of realizing a good germination rate and a uniform product yield when producing a plant.
Another object of the present invention is to provide a sowing aid capable of performing sowing work simply and efficiently.

  According to the sowing aid according to claim 1, the above-mentioned problem is a sowing aid for assisting sowing work on a urethane sowing mat used as a planting base for hydroponics, The sowing aid comprises a seed receiving tray placed on the sowing surface of the sowing mat, and a seed pressing tray that presses the seed sowed on the sowing surface, and the seed receiving tray The tray is formed to have a plate-shaped receiving portion base serving as a base, and the receiving base has a receiving-side through hole having a diameter through which the seed penetrates. A plate-shaped pressing portion base is provided, and the pressing portion base is provided with a unit pressing portion, and the seed receiving tray has the receiving side through-hole at a seeding position on the seeding surface. Is placed on the sowing surface so that the The free end portion of the unit pressing portion that has penetrated the through hole in the seeding position direction is configured to be able to press seeds arranged in the seeding position in the penetration direction, and the unit pressing portion This free end portion side is solved by being configured to project a predetermined length from the seeding surface side peripheral end edge of the receiving side through-hole toward the seeding surface.

Thus, in the seeding aid according to the present invention, the unit pressing part protruding from the pressing part base (projecting toward the seeding surface side) seeds the seed set at the seeding position of the seed receiving tray. It can be pressed toward the inside of the mat. At this time, since the receiving through-hole is aligned with the sowing position, if the seed is dropped into the receiving through-hole, the seed is automatically placed at the sowing position (the seed receiving tray is Because it is placed on the sowing surface of the sowing mat).
Moreover, since the free end side of the unit pressing part is configured to protrude a predetermined length from the seeding surface side peripheral edge of the receiving side through hole toward the seeding surface, the free end side of this unit pressing part is Then, it will sink into the sowing mat for a predetermined length.
In this way, it is possible to embed seeds in the sowing mat at this predetermined length, and after seeding the seed for sowing, the operation of embedding the seed in the sowing mat can be easily performed. At the same time, since the length is set to a predetermined length (predetermined length), there is no variation in embedding work by the operator.

Specifically, as described in claim 2, at the sowing position, a notch or a hole for embedding seeds in the sowing mat is formed at the sowing position, and the predetermined length is determined by the sowing. The seed embedding depth at the position is preferred.
Furthermore, specifically, as described in claim 3, the predetermined length is a seed embedding depth that correlates with at least one of the germination rate of the seed and the growth amount of a plant grown from the seed. It is preferable.
Still more specifically, as described in claim 4, it is preferable that the predetermined length has the embedding depth of 2 mm to 8 mm.

In such a configuration, since the seeds are arranged at the sowing position, the end of the unit pressing portion takes the seeds into the sowing mat, and as a result, the seeds are placed at a depth of a predetermined length. Will be placed.
Therefore, seeds are embedded at a predetermined depth in the sowing mat.
Thus, since seeds can be planted at a predetermined depth, the uniformity of product quality (the quality of plants at the time of harvest) can be ensured.
Moreover, this predetermined length is good to set it as the value determined by the correlation with the germination rate of a seed and the production amount of the plant which grew, as described in a claim.
In other words, if the embedding depth is small, the plant is poorly fixed to the sowing mat, and problems such as bending of the root occur, resulting in a decrease in the amount of grown plants.
In addition, if the embedding depth is large, the germination rate is poor, and even if budding occurs, the foliage cannot protrude upward from the seeding surface, and growth is inhibited.
Therefore, if the predetermined length is determined with such Merck Mars, a suitable embedding depth can be ensured uniformly.
For this reason, it becomes possible to realize a good germination rate and uniform product yield.
A suitable embedding depth is 2 mm to 8 mm.
Moreover, since the notch or the hole for embedding seeds in the sowing mat is formed at the sowing position, workability is improved.

Furthermore, at this time, as described in claim 5, the unit pressing portion includes a columnar root portion protruding from a surface of the pressing portion base that faces the seeding surface, and the seeding surface side of the root portion. A cylindrical embedded portion protruding from the bottom surface toward the seeding surface, and the bottom surface diameter of the root portion is configured to be larger than the bottom surface diameter of the embedded portion. It is preferable.
If comprised in this way, since a root part is a large diameter, the intensity | strength of a unit press part will become high and damage to the unit press part at the time of pressing can be prevented effectively.

At this time, as described in claim 6, a plurality of the receiving side through holes and the unit pressing portions are formed, and each of the receiving side through holes and the pressing portion correspond one-to-one. Is preferable.
With such a configuration, a large number of seeds can be embedded at a number of sowing positions at a time, so that workability is greatly improved.

Furthermore, at this time, as defined in claim 7, in the seed receiving tray, a plurality of partition walls are adjacent to the seed receiving surface, which is a surface opposite to the surface facing the sowing surface. Preferably, the partition wall protrudes so as to be interposed between the side through holes, and the partition wall inhibits the movement of seeds between the adjacent receiving side through holes.
With such a configuration, it is possible to prevent seeds sowed in the seed receiving tray from rolling and bouncing and moving to the adjacent receiving side through-holes, thereby improving workability.

Moreover, at this time, as described in claim 8, in the seed receiving surface, from the periphery of the receiving side through hole, an inclination extending in a reverse taper direction in a direction opposite to the side on which the seeding surface is disposed. It is preferable that the surface is formed.
By being configured in this manner, the seed is guided by the inclined surface and falls into the receiving side through hole.
That is, since the operator may drop the seed aiming at the inclined surface portion having a larger diameter than the small-diameter receiving side through hole, workability is improved.

  Furthermore, at this time, as described in claim 9, the seed receiving tray and the seed pressing tray are formed in a substantially rectangular shape, and an operator can insert the seed receiving tray into the opposite end sides of the seed receiving tray. A receiving handle portion for supporting the load of the seed receiving tray is formed, and a pressing side handle portion for an operator to support the load of the seed pressing tray is formed at opposite ends of the seed pressing tray. If it is formed, workability is improved because the seed receiving tray and the press tray are easily transported.

According to the sowing aid according to the present invention, the seed can be embedded in the sowing mat at the free end of the unit pressing portion that penetrates the receiving side through hole.
Therefore, a troublesome embedding operation can be easily performed.
Further, since the free end portion of the unit pressing portion is configured to protrude a predetermined length from the seeding surface side peripheral edge of the receiving side through-hole toward the seeding surface, the end portion of the unit pressing portion has this seed. The seeds can be taken into the mat for sowing, and as a result, the seeds can be arranged at a depth of a predetermined length. Therefore, seeds are embedded at a predetermined depth in the sowing mat.
By determining this depth based on the seed germination rate and the amount of grown plant production, a suitable embedding depth can be ensured uniformly, realizing a good germination rate and uniform quality product yield. It becomes possible to do.
Furthermore, since the strength of the unit pressing portion is increased by forming the base portion of the unit pressing portion to have a large diameter, it can withstand repeated use.
In addition, a large number of receiving side through-holes and unit pressing parts are formed so that each receiving-side through hole and pressing part correspond to each other one-to-one. Therefore, workability is greatly improved.
In addition, workability is improved by forming a cut or a hole at the sowing position, standing a partition wall, forming an inclined surface, and forming a receiving handle and a pressing handle.
Thus, according to the sowing aid according to the present invention, it is possible to realize a good germination rate and a uniform product harvest when producing plants, and to perform sowing work simply and efficiently. Is possible.

It is a perspective explanatory view of the sowing aid according to an embodiment of the present invention. It is a two-view figure of the seed receiving tray which concerns on one Embodiment of this invention. It is a two-view figure of the seed press tray which concerns on one Embodiment of this invention. It is an expanded two-plane figure of the unit seed receiving part and unit pressing part which concern on one Embodiment of this invention. It is explanatory drawing which shows the conveyance state of the sowing aid which concerns on one Embodiment of this invention. It is explanatory drawing which shows the structure of the mat | matte for sowing concerning one Embodiment of this invention. It is explanatory drawing which shows operation | movement of the sowing aid which concerns on one Embodiment of this invention. It is a bar graph which shows a sowing operation time comparison test result. It is a bar graph which shows the result of a harvest period ground part fresh weight comparison test. It is explanatory drawing which shows the modification of this invention.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
Note that the configuration described below does not limit the present invention and can be variously modified within the scope of the gist of the present invention.
The present embodiment relates to a sowing aid that enables a good germination rate and uniform product harvest in producing plants, and at the same time, improves the workability of sowing work.

1 to 6 show an embodiment of the present invention. FIG. 1 is a perspective explanatory view of a sowing aid, FIG. 2 is a two-side view of a seed receiving tray, and FIG. 3 is two sides of a seed pressing tray. FIG. 4, FIG. 4 is an enlarged two-sided view of the unit seed receiving part and the unit pressing part, FIG. 5 is an explanatory view showing the carrying state of the sowing aid, FIG. 6 is an explanatory view showing the structure of the sowing mat, and FIG. It is explanatory drawing which shows operation | movement of an auxiliary device.
8 and 9 relate to the results of various tests on the sowing aid according to the present embodiment, FIG. 8 is a bar graph showing the results of the sowing time comparison test, and FIG. It is a bar graph which shows the result of a test.
In addition, FIG. 10 is explanatory drawing which shows the modification (thing regarding a seed press tray).

≪About composition of sowing aid≫
The structure of the sowing aid S according to this embodiment will be described with reference to FIGS.
As shown in FIG. 1, the sowing aid S according to this embodiment includes a seed receiving tray 1 and a seed pressing tray 2 as a set.
Hereinafter, the side of the seed receiving tray 1 on which the seed seeding surface is directed is referred to as the upper side, and the opposite side, that is, the side on which the seeding mat 3 is disposed with respect to the seed receiving tray 1 is referred to as the lower side.

<About the structure of the seed receiving tray>
As shown in FIG. 2, the seed receiving tray 1 according to the present embodiment includes a rectangular seed receiving portion 11, receiving side handle portions 12, 12 formed at both ends in the longitudinal direction, the seed receiving portion 11 and the receiving portion. It has the mounting parts 13 and 13 which connect the side handle parts 12 and 12 and is comprised.
The seed receiving part 11 is a rectangular plate-like body, and mounting parts 13 and 13 extend outward from both ends facing in the longitudinal direction.
The mounting portion 13 rises upward, bends from the upper end side of the rising wall 13a and extends outward (in a direction away from the seed receiving portion 11) (in parallel with the seed receiving portion 11). And an end mounting wall 13b (extending).
In addition, the height (distance in the vertical direction) of the rising wall 13a is configured to be equal to the height (distance between both bottom surfaces) of the root portion 21a described later.

Further, receiving side handle portions 12 and 12 are formed in the vicinity of the central portion of the outer side edges of the end portion mounting walls 13b and 13b, respectively.
The receiving handle portion 12 stands upward from the end placement wall 13b (hereinafter referred to as “receiving side standing wall 12a”), then bends outward (in a direction away from the seed receiving portion 11). (Hereinafter referred to as "receiving side force wall 12b"), and then hanging downward (hereinafter referred to as "receiving side hanging wall 12c"). (Shape) part. The space inside the substantially U-shape is a receiving arm insertion space K1, and the operator can insert the arm from below and lift the seed receiving tray 1 via the receiving handle portions 12 and 12. (See FIG. 5).
In this embodiment, for example, in consideration of convenience when used by an elderly worker or a worker with a disability, the receiving handle portions 12 and 12 are provided, but the present invention is not limited thereto. The structure which is not provided with this receiving side handle parts 12 and 12 may be sufficient. That is, the receiving side handle parts 12 and 12 formed at both ends in the longitudinal direction are not provided, and even a flat plate-like structure can be used suitably.

  The seed receiving part 11 is a member in which a plurality of unit seed receiving parts 11A divided into a rectangular shape are aligned with respect to a substantially rectangular receiving part base body 11B. In the present example, a plurality of unit seed receiving portions 11A formed in a substantially square shape are aligned along a column and a row, so that a substantially rectangular seed receiving portion 11 is configured.

With reference to FIG. 4A, the configuration of the unit seed receiving portion 11A will be described.
The unit seed receiving part 11A is a part that is partitioned into squares by partitioning the four sides with partition walls 11a. The partition wall 11a is a wall body that stands vertically upward from the receiving base 11B. The space partitioned by the partition walls 11a on these four sides is referred to as “unit sowing space K2.” The surface on which the partition wall 11a is erected is the “seed receiving surface” in the claims.
The unit seed receiving portion 11A is formed with a receiving side through hole 11b so as to penetrate the upper surface and the lower surface.
The opening diameter of the receiving side through hole 11b is configured to be larger than the seed to be sown, and is configured to have a diameter through which an embedded portion 21b described later can pass.
However, the opening diameter of the receiving side through hole 11b is set to be sufficiently small so as not to exceed twice the diameter of the seed, and one seed can be inserted into the receiving side through hole 11b. .

  Furthermore, an inclined surface 11c is formed from the upper end edge of the receiving side through hole 11b so as to extend in an inversely tapered shape toward the upper outside. In other words, the inclined surface 11c has an upper opening circle (in closest contact with the upper end edge of the receiving side through hole 11b and the four partition walls 11a (or closest to four points corresponding to the contact points when inscribed) And a peripheral surface of the receiving-side through hole 11b having a larger opening diameter than the receiving-side through hole 11b. Therefore, when viewed from above, the receiving-side through-hole 11b is visually perceived as being perforated at the center of the dish-shaped opening. Is done.

  Since it is configured in this manner, when seeds are sown in the unit sowing space K2, the seeds are guided by the inclined surface 11c and reach the receiving side through hole 11b. At this time, even if the wall is repeatedly collided and rebounded on each wall surface in the unit sowing space K2 due to the energy of the fall at the time of sowing, the partition wall 11a becomes a barrier, and this seed is adjacent to or close to the unit seed receiving part 11A And is inhibited from moving.

  Note that, mat receiving walls 11d and 11d that are erected downward are formed from both ends of the receiving portion base 11B where the rising wall 13a is erected. That is, the mat locking walls 11d and 11d hang perpendicularly to the receiving base 11B in a downward direction opposite to the direction in which the rising wall 13a stands. In this example, it hangs downward by about 5 mm, and it is configured so that the sowing surface portion (becomes the upper surface) of the sowing mat 3 can be locked between these mat locking walls 11d and 11d. .

<About the structure of the seed pressing tray>
As shown in FIG. 3, the seed pressing tray 2 according to this embodiment includes a rectangular pressing portion 21 and pressing-side handle portions 22, 22 formed at both ends in the longitudinal direction.
The pressing side handle 22 is formed on opposite ends of the pressing portion 21. In this example, it is formed on both sides forming both ends in the longitudinal direction of the substantially rectangular pressing portion base 21B.
The pressing-side handle portion 22 stands upward from the end side (hereinafter referred to as “pressing-side standing wall 22a”), then bends and extends outward (in the direction away from the pressing portion base 21B) (hereinafter, “ Side portion (hereinafter referred to as “outer hanging wall 22 c”), and a portion of a substantially U shape (substantially U shape having an opening below) that hangs downward (hereinafter referred to as “outer hanging wall 22 c”). ing. In addition, although mentioned later, the space inside this substantially U-shape becomes the pressing side arm insertion space K3 so that the operator can insert the arm from below and lift the seed pressing tray 2 via the pressing side handle portions 22 and 22. It is configured (see FIG. 5).

Further, the pressing side handle portion 22 is formed over the entire length of the original edge of the rising source, and the receiving side handle portions 12 and 12 are fitted into the pressing side arm insertion space K3 in a nested manner. It is configured as follows.
Therefore, the pressing side standing walls 22a and 22a are fitted between the receiving side standing walls 12a and 12a, and at the same time, the pressing side force wall 22b and 22b and the pressing side hanging walls 22c and 22c are received side force point walls 12b and 12b. And the receiving-side hanging walls 12c, 12c are fitted in a nested manner.
In addition, as above-mentioned, the receiving side handle part 12 is formed in the center part vicinity of the both opposing sides of the seed receiving part 11, and the both ends which form the longitudinal direction both ends of the substantially rectangular shaped press part base | substrate 21B Is formed over the entire length.
Therefore, when the pressing side handle part 22 is removed from the state where the pressing side handle part 12 is fitted in the receiving side handle part 12, a place where the receiving side handle part 12 and the pressing side handle part 22 are not stacked is provided. Can be used as a clue. Therefore, the removal work of both becomes easy.
In this embodiment, for example, in consideration of convenience when used by elderly workers or workers with disabilities, the pressing side handle portions 22 and 22 are provided, but the present invention is not limited thereto. The structure which is not provided with this press side handle parts 22 and 22 may be sufficient. That is, the pressing side handle portions 22 and 22 formed at both ends in the longitudinal direction are not provided, and even a flat plate-like configuration can be preferably used.
At this time, the length in the longitudinal direction of the pressing portion 21 is made different from the total length in the longitudinal direction of the seed receiving portion 11 and the placement portions 13 and 13 (for example, the former length is made longer than the latter length). By forming it large, it can be used as a clue when separating the two.

The pressing portion 21 is a member in which a plurality of unit pressing portions 21A are aligned with a substantially rectangular pressing portion base 21B. In this example, the unit pressing portion 21A formed in a circular shape when viewed from above is the lower surface of the substantially rectangular pressing portion base 21B (the surface facing the seed receiving portion 11 side and facing the seeding mat 3 side). A substantially rectangular pressing portion 21 is formed by aligning a plurality of lines along the columns and rows on the side surface.
The length in the longitudinal direction of the pressing portion base 21B is set to be twice as long as the length in the same direction of the end placement wall 13b than the length in the longitudinal direction of the receiving portion base 11B.
And the unit pressing part 21A is not formed in the range which each covers the length for the edge part mounting wall 13b in the longitudinal direction both ends of the pressing part base | substrate 21B.
That is, the range in which the unit pressing portion 21A is formed is a range in which the unit pressing portion 21B is kept inward from the both end portions of the pressing portion base 21B by a distance corresponding to the end portion mounting wall 13b.

The configuration of the unit pressing portion 21A will be described with reference to FIG.
The unit pressing portion 21A is a substantially cylindrical portion having two large and small diameters.
The unit pressing portion 21A includes a cylindrical root portion 21a protruding downward from the pressing portion base 21B, an embedded portion 21b having a smaller diameter than the root portion 21a, and a connecting portion 21c that connects these portions. It is configured.
The center of the bottom surface of the base portion 21a and the center of the bottom surface of the embedded portion 21b are arranged coaxially in a direction axis perpendicular to the pressing portion base 21B, and the bottom edge periphery of the root portion 21a and the top periphery of the embedded portion 21b Are connected by a connecting portion 21c having a tapered slope as an outer wall. That is, the connecting portion 21c has a truncated cone shape having both the bottom circle of the root portion 21a and the upper circle of the embedded portion 21b as both bottom surfaces.
In addition, by setting the diameter of the root portion 21a to be larger than the diameter of the embedded portion 21b, it is possible to prevent the unit pressing portion 21A from being damaged when the seed is pressed by the embedded portion 21b.
In addition, you may comprise the structure of 21 A of this unit press part with the base part 21a and the embedding part 21b. That is, the embedded portion 21b may be configured to extend directly from the bottom center of the root portion 21a.
With this configuration, when a plurality of seeds enter the unit sowing space K2, seeds that are not arranged in the receiving side through hole 11b are embedded in the unit pressing portion 21A (moving in the direction of the sowing cut 31a). ) Can be effectively prevented. That is, the space in which the frustoconical connecting portion 21c exists functions as a seed retreat space that is not disposed in the receiving side through hole 11b.

Further, the unit pressing portion 21A is configured to be able to enter the unit seed receiving portion 11A.
The outer shape of the connecting portion 21c is configured to follow the inner shape of the inclined surface 11c, and the connecting portion 21c can be aligned with the inclined surface 11c. At the same time, the embedded portion 21b is configured to penetrate the receiving side through hole 11b.

At this time, the lower end side of the embedded portion 21b is configured to protrude downward from the receiving side through hole 11b, and this protruding length t1 (the length in the vertical direction, that is, the direction perpendicular to the pressing portion base 21B). ) Is 2 mm to 8 mm, preferably 3 mm to 8 mm, more preferably 3 mm to 6 mm. In this example, the optimal protrusion length t1 is set to 5 mm in consideration of the germination rate and the yield.
For this reason, the length t of the embedded portion 21b may be obtained by adding the depth of the receiving side through hole 11b (that is, the thickness of the receiving portion base body 11B) to the protruding length t1.

As described above, since the seed receiving tray 1 and the seed pressing tray 2 are configured, when the seed pressing tray 2 is set on the seed receiving tray 1, the receiving handle portion 12 is fitted into the pressing handle portion 22. At the same time, both longitudinal ends of the pressing portion base 21B are placed on the end placement walls 13b and 13b.
In this state, each unit pressing portion 21A enters each unit seed receiving portion 11A, and at the same time, the embedded portion 21b is inserted into the receiving side through hole 11b. In this state, the lower end side of the embedded portion 21b is configured to protrude downward from the receiving side through-hole 11b by a predetermined length (5 mm in this example).

≪About composition of mat for sowing≫
The configuration of the sowing mat 3 according to the present embodiment will be described with reference to FIG.
The sowing mat 3 according to the present embodiment is a prismatic member formed of urethane foam.
The sowing mat 3 is a three-dimensional member configured to have a sowing surface 3A that is a surface (usually an upper surface) on which plant seeds are planted and a liquid-facing surface 3B that faces the sowing surface 3A. .
The sowing mat 3 according to the present embodiment is divided into a plurality of sowing units 31.
That is, it is a shape in which notches are formed in the shape of a ridge so that one sowing unit 31 has a cube shape.

And the surface on the sowing side which is one surface of the sowing unit 31 (usually the surface facing upward, hereinafter referred to as “unit sowing surface 31A”, and the surface facing the unit sowing surface 31A is referred to as “unit liquid facing surface 31B”. The seeding cut 31a cut into a cross shape is formed in the central portion of the above.
That is, if the seed is dropped near the center intersection of the sowing cut 31a and a downward force is applied to the seed, the seed can be embedded by the guide of the cross-shaped sowing cut 31a.

≪Seed embedment operation≫
Next, the seed embedding operation of the sowing assisting device S according to the present embodiment will be described with reference to FIG.
First, the sowing mat 3 is set below the seed receiving tray 1. Actually, the seed receiving tray 1 is placed and fixed on the sowing surface 3A of the sowing mat 3.
As described above, since the matting walls 11d and 11d are formed in the sowing mat 3, sowing the longitudinal direction of the sowing surface 3A between the mat locking walls 11d and 11d, sowing. The seed receiving tray 1 is placed and fixed on the mat 3 for use.
At this time, the correspondence is constructed so that one unit seed receiving portion 11A is stacked immediately above one unit sowing surface 3A.
More specifically, the center part of the receiving side through hole 11b is configured to be aligned with the crossing point of the sowing cut 31a.

In this state, seeds (in this example, coated seeds are used) are sown in the unit seed receiving part 11A. That is, seeds are dropped toward the unit sowing space K2.
This may be manual seeding or a commercially available seeder.
When seeds are dropped in the unit sowing space K2 in this way, the seeds roll into the receiving side through holes 11b. That is, it is guided down the inclined surface 11c to the receiving side through hole 11b.

At this time, since the seeding surface 3A is present below the receiving side through hole 11b (that is, the bottom of the receiving side through hole 11b is blocked by the seeding surface 3A), the receiving side through hole 11b. The seeds that fall on are placed on the sowing surface 3A as they are. At this time, since the central portion of the receiving side through-hole 11b is configured to be aligned with the crossing point of the sowing cut 31a, the seed is automatically placed on the crossing point of the sowing cut 31a. It will be.
As described above, since the partition wall 11a exists, even if the seeds are adjacent or close to each other in the unit sowing space K2 due to the energy caused by the dropping at the time of sowing, the seeds are adjacent or close to each other. It does not move to the part 11A, and sowing work is simplified.

Next, the seed pressing tray 2 is set.
As described above, this setting is performed by fitting the receiving side handle portions 12 and 12 into the pressing side arm insertion space K3 in a nested manner. In the set state, as described above, both end portions in the longitudinal direction of the pressing portion base 21B (portions where the unit pressing portion 21A is not formed) are placed above the end portion mounting wall 13b.
At this time, each unit pressing portion 21A is inserted into the corresponding unit seed receiving portion 11A. In this example, the unit pressing part 21A and the unit seed receiving part 11A correspond one-to-one.

FIG. 7A shows a state immediately before the seed pressing tray 2 is set.
In this state, the embedded portion 21b is disposed immediately above the receiving side through hole 11b. That is, it is arrange | positioned just above the seed arrange | positioned at this receiving side through-hole 11b.
Summing up the above, the vicinity of the crossing point of the sowing cut 31a, the seed, and the embedded portion 21b are aligned in a straight line in the vertical direction.

When the seed pressing tray 2 is completely set, the state shown in FIG. 7B is obtained.
As described above, the lower end side of the embedded portion 21b has a predetermined length and is configured to protrude downward from the receiving side through hole 11b (in this example, 5 mm).
For this reason, in the state where the seed pressing tray 2 is set, the lower end of the embedded portion 21b presses the seed into the seeding cut 31a for a predetermined length.
By this action, seeds are embedded in the sowing mat 3 at a depth of a predetermined length.
As described above, the seed receiving tray 1 and the seed pressing tray 2 are formed with a large number of unit seed receiving portions 11A and a large number of unit pressing portions 21A, which correspond one-on-one. It becomes possible to embed seeds in a large number of sowing cuts 31a in a single operation.

In addition, when the vicinity of both ends in the longitudinal direction of the pressing portion base 21B is pressed from above, the seed receiving tray 1 can be pressed in the direction of the sowing mat 3 via the end placement wall 13b.
Thereby, seeds can be embedded while lightly pressing the sowing mat 3.
With this configuration, for example, even when the sowing mat 3 is formed of a material having a high elongation rate, the seed embedded by the embedded portion 21b is effectively prevented from being pushed back, and the seed is reliably secured. The seeding cut 31a can be held.

≪Various verification tests≫
Next, various test results when the sowing aid S according to the present embodiment is used will be described.
1. Work Time Reduction Test (1-1) Purpose The sowing time when the sowing aid S according to this embodiment is used is compared with the conventional sowing work.
Also, the improvement of workability for workers with disabilities will be confirmed.

(1-2) Experimental system A worker who has a mild disability and a worker who has a severe disability perform sowing by conventional sowing work, and measure the required time.
In this conventional sowing work, the work of manually embedding seeds in the sowing cut 31a of the sowing mat 3 is executed for 31 minutes in all sowing units.
Using the sowing apparatus S according to the present embodiment, a worker having a severe obstacle performs the sowing work and measures the required time.

(1-3) Results The results are shown in FIG.
As shown in FIG. 8, the time required for the sowing work was dramatically shortened by using the sowing apparatus S according to the present embodiment.
This was also shortened compared to the conventional work hours of mildly handicapped persons performed as controls.

(1-4) Conclusion / consideration It was confirmed that the sowing apparatus S according to the present embodiment greatly contributes to shortening the time of sowing work. In particular, the effect is remarkable for workers with severe disabilities, and it is considered that the sowing work of elderly people with weak power and workers with disabilities can be dramatically improved.

2. Relationship between seed embedding depth, germination rate and harvest ground weight (2-1) Purpose How seed embedding depth in sowing mat 3 affects seed germination rate and harvest ground yield Check whether it affects.

(2-2) Experimental system A seeding mat 3 washed with tap water and tightly squeezed was placed, and 1.5 L of tap water was poured into the seeding mat 3 so as not to protrude. Thereafter, the seeds were embedded in the sowing cut 31a by changing the depth by 1 mm from 0 mm to 22 mm one by one. As samples, n = 10 were prepared for each depth.
After sowing, the lid was covered and left in a dark place for 3 days, and then 1.9 L of tap water was poured into it and irradiated with light. And the germination state was observed on the 9th day.
Then, in view of the germination state, as a sample for the growth test, a sample with an embedding depth of 0 mm to 8 mm and a sample with an embedding depth of 9 mm as a negative control are selected, and the sample is transplanted to a cultivation apparatus containing the solution, Planted on the 25th day. Thereafter, the fresh weight on the ground was measured after 42 days.

(2-3) Result As for the observation result of the 9th day about a germination rate, germination was confirmed in any depth.
However, the number of samples in which the foliage is open above the sowing mat 3 differs greatly between the embedding depths of 8 mm and 9 mm, and the rate at which the foliage of the samples having an embedding depth of 8 mm or less opens is equal to the guaranteed germination rate of seeds (80 %) Or more.
In the sample with an embedding depth of 9 mm or more, the rate at which the foliage opens above the sowing mat 3 is below the guaranteed germination rate (80%) of the seeds. Some things could not be sprouted.
In addition, in the samples with an embedding depth of 0 mm, many of the roots were bent in a square shape, and in the samples with an embedding depth of 1 mm to 2 mm, the roots were wobbled.
Samples with an embedding depth of 3 mm or more were securely fixed to the sowing mat 3.
Moreover, the result of the above-ground raw weight measurement is shown in FIG.

(2-4) Conclusion / Discussion Considering the result of germination rate and the result shown in FIG. 9, it is considered that the embedding depth is 2 mm to 8 mm, preferably 3 mm to 8 mm, more preferably 3 mm to 6 mm.

≪Modification example≫
Next, a modified example of the above embodiment will be described.
In this modified example, the shape of the unit pressing portion 21A is different.
Since other configurations are the same as the configurations according to the above-described embodiment, the description thereof is omitted.
The second unit pressing portion 121A in this example is a cylindrical member.
An annular groove R formed concentrically is cut into the bottom surface of the second unit pressing portion 121A.
Thus, by cutting the groove R, the seed can be reliably embedded in the sowing cut 31a without escaping the seed.

As described above, according to the sowing aid S according to the present embodiment, the sowing work can be easily performed.
Further, unlike the conventional case, it is not necessary to drop seeds into the small-diameter recesses provided in the center of the seeding surface 3A of the sowing unit 31, and the seeds may be dropped into the unit sowing space K2 opening having a larger diameter than the recesses. Therefore, the tension at the time of sowing is relieved.
Moreover, it is preferable because a large number of seeds can be embedded at once.
Furthermore, since all the seeds can be embedded at a predetermined depth where the germination rate and the above-ground raw weight are optimum, it greatly contributes to productivity and quality uniformity.
Moreover, since the receiving side handle part 12 and the pressing side handle part 22 are formed, the burden on the operator can be reduced and workability can be greatly improved.

S seeding aid 1 seed receiving tray 11 seed receiving part 11A unit seed receiving part 11a partition wall 11b receiving side through hole 11c inclined surface 11B receiving part base 11d mat locking wall K2 unit sowing space 12 receiving side handle part 12a receiving side standing up Wall 12b Receiving side force point wall 12c Receiving side hanging wall K1 Receiving side arm insertion space 13 Placement part 13a Standing wall 13b End placement wall 2 Seed pressing tray 21 Pressing part 21A Unit pressing part 21a Root part 21b Embedding part 21c Connecting part 21B Press part base body 22 Press side handle part 22a Press side standing wall 22b Press side force wall 22c Outer hanging wall K3 Press side arm insertion space 3 Seeding mat 3A Seeding surface 3B Liquid facing 31 Seeding unit 31A Unit seeding surface 31a Seeding notch 31B Unit liquid facing 121A Second unit pressing part R Groove part

Claims (9)

It is a sowing aid for assisting sowing work to a sowing mat made of urethane used as a planting base for hydroponics,
The sowing aid comprises a seed receiving tray placed on the sowing surface of the sowing mat, and a seed pressing tray that presses the seed sowed on the sowing surface,
The seed receiving tray is formed having a plate-shaped receiving portion base serving as a base, and the receiving portion base is formed with a receiving side through hole having a diameter through which the seed penetrates.
The seed pressing tray is configured to have a plate-shaped pressing portion base serving as a base, and a unit pressing portion protrudes from the pressing portion base.
The seed receiving tray is placed on the sowing surface such that the receiving side through hole is aligned with the sowing position on the sowing surface,
The free end portion of the unit pressing portion that penetrates the receiving side through-hole toward the sowing position direction is configured to be able to press seeds arranged at the sowing position in the penetrating direction,
The seeding aid is characterized in that a free end portion side of the unit pressing portion is configured to protrude a predetermined length from the seeding surface side peripheral end edge of the receiving side through-hole toward the seeding surface. . In the sowing position, a cut or hole for embedding seeds in the sowing mat is formed,
The seeding aid according to claim 1, wherein the predetermined length is a seed embedding depth at the sowing position. The predetermined length is
The seeding aid according to claim 2, wherein the seed embedding depth correlates with at least one of the germination rate of the seed and the growth amount of the plant grown from the seed.   The seeding assisting device according to claim 2 or 3, wherein the predetermined length is the embedding depth of 2 mm to 8 mm. The unit pressing portion includes a columnar root portion protruding from a surface of the pressing portion substrate facing the seeding surface, and a columnar embedding protruding from the bottom surface side bottom surface of the root portion toward the seeding surface. And is configured to have,
The seeding assisting device according to any one of claims 1 to 4, wherein a bottom surface diameter of the root portion is configured to be larger than a bottom surface diameter of the embedded portion.   6. The receiving side through hole and the unit pressing portion are formed in a plurality, and each receiving side through hole and the pressing portion correspond to each other one to one. The sowing aid according to any one of the above. In the seed receiving tray, a seed receiving surface, which is the surface opposite to the surface facing the sowing surface, has a plurality of partition walls protruding so as to be interposed between the adjacent receiving side through holes. And
The seeding aid according to claim 6, wherein the partition wall inhibits movement of seeds between adjacent receiving side through holes.   In the seed receiving surface, an inclined surface extending in a reverse taper shape is formed from the peripheral edge of the receiving side through hole in a direction opposite to the side where the seeding surface is disposed. Or the seeding auxiliary device of Claim 7. The seed receiving tray and the seed pressing tray are formed in a substantially rectangular shape,
On both opposite sides of the seed receiving tray, a receiving side handle for an operator to support the load of the seed receiving tray is formed,
The press side handle part for an operator to support the load of the said seed press tray is formed in the both ends which the said seed press tray opposes, The Claim 1 thru | or 8 characterized by the above-mentioned. Seeding aid.

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