JP2020130046A - Pulp chip for culture medium and method for producing culture medium - Google Patents

Abstract

To provide a pulp chip for culture medium that can efficiently produce a high-quality culture medium.SOLUTION: A pulp chip for culture medium is used for production of a culture medium 1 for seed planting, and is composed of dry pulp made of wood crushed with a crusher and has a bulk density of 70 kg/mor more.SELECTED DRAWING: Figure 1

Description

The present invention relates to pulp chips for a medium and a method for producing a medium.

As a medium (nursery) for planting seeds and cultivating plants, there is one that uses a fiber aggregate composed of a large number of fibers extracted from dry pulp derived from wood (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2004-350655

When producing the above-mentioned medium, there is a problem that the work efficiency is poor because the operator manually breaks the block-shaped or sheet-shaped dry pulp into small pieces and puts them into the disintegrator.

An object of the present invention is to solve the above-mentioned problems and to provide a pulp chip for a medium and a method for producing a medium, which can efficiently produce a high-quality medium.

In order to solve the above-mentioned problems, the first invention is a pulp chip for a medium used for producing a medium for planting seeds, which comprises dry pulp derived from wood crushed by a crusher and has a bulk density of 70 kg. It is set to / m ³ or more.

In order to solve the above-mentioned problems, the second invention is a method for producing a medium for planting seeds. First, dry pulp derived from wood is crushed by a crusher to produce pulp having a bulk density of 70 kg / m ³ or more. Prepare a chip. Then, the pulp chips are dissociated to take out the fibers, and the plurality of fibers form a fiber aggregate.

The bulk density of the pulp chips in the present invention is such that the pulp chips are freely dropped from a position at a height of 13.5 cm with respect to the upper opening edge of the 100 cm ³ container whose upper surface is open, and the upper opening edge of the container is opened. The weight of the pulp chips in the container when the pulp chips were put up to the part was measured, and the bulk density per 1 m ³ was calculated.

In the present invention, since the dry pulp is crushed by a crusher, it is possible to improve the work efficiency when taking out the fibers from the pulp chips.
Further, by setting the bulk density of the pulp chips to 70 kg / m ³ or more, the average fiber length of a large number of fibers taken out from the pulp chips can be maintained at a length suitable for the medium.

The pulp chips for a medium are preferably of a size that has passed through a screen mesh whose hole diameter is set between 1 mm and 20 mm in the crusher. Further, in the pulp chip for a medium, the value obtained by dividing the tapping bulk density by the bulk density is preferably 1.0 or more and 1.9 or less.
For the tapping bulk density of pulp chips in the present invention, put 10 g of pulp chips into a 100 ml graduated cylinder, tap the bottom of the graduated cylinder until the volume of the pulp chips does not decrease, and then read the scale on the flattened surface. Measure the volume with. After that, the tapping bulk density can be obtained by calculating the weight per unit volume (1 m ³ ).
By setting the ratio of the tapping bulk density and the bulk density of the pulp chips in this way, it is possible to suppress the generation of dust when the dry pulp is crushed or when the pulp chips are handled. In addition, the average fiber length can be effectively maintained at a length suitable for the medium.

It is preferable that the average fiber length of the plurality of fibers taken out from the pulp chips is 400 μm or more.
By setting the fibers taken out from the pulp chips to 400 μm or more in this way, it is possible to suppress the seeds from sinking into the fiber aggregates, and the morphology of the fiber aggregates composed of a large number of fibers does not easily collapse. Become.

Further, when the dry pulp is derived from softwood, the fibers taken out from the pulp chips are longer than when the dry pulp is derived from hardwood, and water is discharged when the fibers are put in the container. The outflow of fibers from the pores is reduced.
Further, when the dry pulp is derived from hardwood, the blockage by the fiber mass to the discharge hole is weakened and the drainage property is improved as compared with the case where the dry pulp is derived from softwood.

Setting the Canadian Standard Freeness (CSF) of the fiber aggregates between 400 ml and 780 ml is preferred as it allows the medium to have drainage properties suitable for plant cultivation.

The method for producing a pulp chip for a medium and a medium of the present invention can efficiently produce a high-quality medium suitable for plant cultivation.

It is a perspective view which showed the culture medium using the pulp chip which concerns on embodiment of this invention. It is a table which showed the suitability evaluation of the culture medium using the pulp chip which concerns on embodiment of this invention.

Embodiments of the present invention will be described in detail with reference to the drawings as appropriate.
The pulp chips of the present embodiment are granular derived from wood and are used for producing the medium 1 shown in FIG.
Medium 1 is a fiber assembly 10 composed of a large number of fibers taken out from pulp chips. The fiber assembly 10 is housed in the container 20. Then, the seeds can be germinated by planting the seeds on the surface of the fiber aggregate 10 and allowing the fiber aggregate 10 to retain water.

The dry pulp used in the pulp chips of this embodiment is derived from at least one of hardwoods and softwoods and is hardened into blocks or sheets. This dry pulp is crushed by a crusher to produce pulp chips.
The pulp chips of the present embodiment are derived from at least one of a hardwood and a softwood, but when the softwood is derived, a large number of fibers extracted from the pulp chips are obtained as compared with the case where only the hardwood is derived. The average fiber length can be increased. When the hardwood is derived, the drainage property is improved as compared with the case where only the softwood is derived.

The crusher used when producing the pulp chips of the present embodiment may be any type of crusher that is pulverized by a shearing force, and for example, a cutter mill type crusher can be preferably used. The cutter mill type crusher is a known crusher that continuously shears and crushes dry pulp with a rotary blade and a fixed blade. In such a cutter mill type crusher, the dry pulp is gradually finely sheared, and when the pulp chips become smaller to a predetermined size, the pulp chips pass through the holes of the screen mesh and are collected. Further, in addition to the cutter mill type crusher, a crusher such as a biaxial type, a triaxial type or a shredder that crushes with two or three roll blades may be used.

In the crusher of the present embodiment, the hole diameter of the screen mesh is set between 1 mm and 20 mm. The hole diameter of the screen mesh is more preferably 3 mm to 15 mm. The larger the hole diameter of the screen mesh, the larger the size of the collected pulp chips. That is, the pulp chips that have passed through the screen mesh having a large hole diameter have a coarse particle size. If the screen mesh is 1 mm or less, the fibers become too short due to crushing, which is unsuitable. Further, if the screen mesh is 20 mm or more, the pulp chips become too coarse and the workability at the time of disintegration is inferior.

The bulk density of the pulp chips of this embodiment is 70 kg / m ³ or more. The bulk density of the pulp chips is more preferably 80 kg / m ³ or more.
The value obtained by dividing the tapping bulk density of the pulp chips of the present embodiment by the bulk density is 1.0 or more and 1.9 or less. The value obtained by dividing the tapping bulk density by the bulk density is more preferably 1.05 or more and 1.85 or less, and further preferably 1.1 or more and 1.8 or less. By setting the ratio to 1.0 or more, it is possible to obtain a pulverized product having sufficient fineness to improve the work efficiency when extracting the fibers from the pulp. Further, by setting the ratio to 1.9 or less, the amount of dust can be suppressed when crushing dry pulp or handling pulp chips. To set the ratio in a preferable range, for example, a method of adjusting the diameter of the screen mesh can be mentioned.

The bulk density of the pulp chips in the present embodiment is such that the pulp chips are freely dropped from a position at a height of 13.5 cm with respect to the upper opening edge of the 100 cm ³ container whose upper surface is open, and the upper opening of the container is opened. The weight of the pulp chips in the container when the pulp chips were put up to the edge was measured, and the bulk density per 1 m ³ was calculated.

The fiber assembly 10 is obtained by dissociating pulp chips with a dissociator to take out fibers and collecting a large number of fibers.
In the present embodiment, the average fiber length of a large number of fibers taken out from the pulp chips is 400 μm or more. More preferably, the average fiber length of many fibers is 450 μm or more. Further, the average fiber length of many fibers is more preferably 2500 μm or less. Wood pulps of longer lengths are not available on the market for general purposes, and the use of such pulps increases costs.

The Canadian Standard Freeness (CSF) of the fiber assembly 10 of this embodiment is between 400 ml and 780 ml. The Canadian standard freeness of the fiber assembly 10 is more preferably between 450 ml and 750 ml.

Next, the method for producing the medium 1 of the present embodiment will be described.
First, pulp chips obtained by crushing block-shaped or sheet-shaped dry pulp with a crusher are prepared.

Subsequently, the pulp chips and water are put into a dissociator, and the pulp chips are dissociated by the dissociator to take out a large number of fibers.
The disintegrator of the present embodiment has a function of loosening the pulp chips into single fibers by mixing the pulp chips and water and rotating them at high speed. The structure of the disintegrator is not limited, and various known disintegrators can be used.

In the disintegrator, a slurry containing a large number of fibers is formed. By putting this slurry in the container 20, a fiber aggregate 10 composed of a large number of fibers is formed. As a result, the medium 1 contained in the container 20 is formed.

In the pulp chips of the present embodiment as described above, since the dry pulp is crushed by a crusher, the work efficiency at the time of producing the pulp chips can be improved.

Further, by setting the bulk density of the pulp chips to 70 kg / m ³ or more, the average fiber length of a large number of fibers taken out from the pulp chips can be maintained at a length suitable for the medium.

The pulp chip of the present embodiment is a size that has passed through a screen mesh having a hole diameter set between 1 mm and 20 mm. Further, in the pulp chip of the present embodiment, the value obtained by dividing the tapping bulk density by the bulk density is 1.0 or more and 1.9 or less.
By setting the ratio of the tapping bulk density and the bulk density of the pulp chips in this way, it is possible to suppress the generation of dust when the dry pulp is crushed or when the pulp chips are handled.

In the present embodiment, since the average fiber length of a large number of fibers taken out from the pulp chip is 400 μm or more, it is possible to prevent the seeds planted on the surface of the fiber aggregate 10 from sinking into the fiber aggregate 10. Seeds can germinate well.

The fiber assembly 10 of this embodiment has a Canadian standard freeness between 400 ml and 780 ml. The fiber aggregate 10 having such freeness (water drainage degree) has drainage property suitable for plant cultivation.
When the Canadian standard freeness of the fiber assembly 10 is less than 400 ml, the dehydration time of the fiber assembly 10 is delayed and the workability is deteriorated. Also, wood pulp with a Canadian standard freeness of fiber assembly 10 greater than 780 ml is not available on the market for general purposes, and the use of such pulp increases costs.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments and can be appropriately modified without departing from the spirit of the present invention.
The dry pulp of this embodiment is derived from at least one of hardwoods and softwoods. That is, the dry pulp may be derived from only hardwood or only softwood, or may be derived from a mixture of hardwood and softwood.

In addition, the types of hardwoods and softwoods are not limited.
For example, as hardwoods, Acacia mangium, A.I. auricaliformis, A.I. catechu (Acacia catechu), A.I. decurrens (Acacia Decalence), A.I. holocericea (Acacia holocericia), A.I. leptocarpa, A.I. Maidenii, A.A. Mearnsii, A.I. Melanoxylon (Acacia melanoxylone), A.I. Nerifolia (Acacia Nerifolia), A.I. sylvestris, or A. squirrel. Peregrinalis and the like, acacia wood which is a hybrid of these, Eucalyptus camaldulensis, E. coli and E. coli. Degrupta (Eucalyptus degrupta), E.I. globulus, E.I. grandis (Eucalyptus grandis), E.I. maculata, E.I. punkata, E.I. saligna, E.I. tereticornis (Eucalyptus terenicornis), E.I. urophylla (Eucalyptus urophylla), A. aulacocarpa (Acacia auracocarpa), or A. Examples thereof include classicalpa (acacia classicalpa) and hybrids thereof (hybrid).
"A." is an abbreviation for acacia and "E." is an abbreviation for eucalyptus.
As coniferous trees, spruce or lodgepole pine such as White Spruce, Black Spruce, or Hemlock is a kind of tree, White Fir, Douglas Fir, or Bals. Fir trees such as Fire, poplar trees such as Aspen, Spruce Pine, Radiata Pine, Lodgepole Pine, or Elliot Pine (Lodgepole Pine), or Elliot Pine. Such as pine trees, or cedar trees such as Red Ceder (Red Cedar) are preferably used.

Next, an example in which the effect of the present invention has been confirmed will be described.
The evaluation of the suitability of the pulp chips of this embodiment (Example) and the pulp chips of Comparative Example for a medium was compared. The table of FIG. 2 shows the bulk density of the pulp chips of Examples and Comparative Examples, the value obtained by dividing the tapping bulk density by the bulk density, the fiber length, the freeness of the fiber aggregate, and the suitability evaluation of the medium.

The pulp chips of Examples and Comparative Examples are dry pulp (moisture content of about 7%) derived from softwood or hardwood crushed into granules by a cutter mill type crusher.
The size of the pulp chips is adjusted by changing the hole diameter of the screen mesh of the crusher. The pulp chips of Examples 5 and 6 have passed through a screen mesh having a hole diameter of 15 mm, and have the largest grains among the Examples and Comparative Examples. The pulp chips of Comparative Example 1 have passed through a screen mesh having a hole diameter of 0.15 mm, and have the smallest grains in Examples and Comparative Examples.

The bulk density of the pulp chips in Examples and Comparative Examples is such that the pulp chips are freely dropped from a position at a height of 13.5 cm with respect to the upper opening edge of the 100 cm ³ container having an open upper surface, and the upper side of the container is opened. The weight of the pulp chips in the container when the pulp chips were put up to the opening edge of the container was measured, and the bulk density per 1 m ³ was calculated.
Further, the tapping bulk density of the pulp chips in Examples and Comparative Examples was flattened after 10 g of pulp chips were put into a 100 ml graduated cylinder and the bottom of the graduated cylinder was tapped until the volume of the pulp chips did not decrease. Read the scale on the surface and measure the volume. After that, the tapping bulk density was obtained by calculating the weight per unit volume (1 m ³ ).

In the present embodiment, when the pulp chips are dissociated and the fibers are taken out, the pulp chips dispersed in 3% with water are put into a dissociator and dissociated by the dissociator for 15 minutes to form a slurry containing fibers. did. Then, the average fiber length of a large number of fibers taken out from the pulp chips was measured.

In this embodiment, a fiber aggregate consisting of a large number of fibers taken out from a pulp chip was formed, and the Canadian standard freeness (CSF: JIS P 811-2) of the fiber aggregate was measured.

The pulp chips of Example 1 use hardwood as a raw material and have a size that passes through a screen mesh having a hole diameter of 3 mm. The bulk density of the pulp chips of Example 1 is 90 kg / m ³ , the ratio of the tapping bulk density to the bulk density is 1.69, and the average fiber length is 483 μm. The Canadian standard freeness of the fiber assembly of Example 1 is 500 ml.

The pulp chips of Example 2 use hardwood as a raw material, and have a size that passes through a screen mesh having a hole diameter of 6 mm. The bulk density of the pulp chips of Example 2 is 127 kg / m ³ , the ratio of the tapping bulk density to the bulk density is 1.54, and the average fiber length is 532 μm. The Canadian standard freeness of the fiber assembly of Example 2 is 517 ml.

The pulp chip of Example 3 uses hardwood as a raw material, and has a size that passes through a screen mesh having a hole diameter of 8 mm. The bulk density of the pulp chips of Example 3 is 138 kg / m ³ , the ratio of the tapping bulk density to the bulk density is 1.42, and the average fiber length is 584 μm. The Canadian standard freeness of the fiber assembly of Example 3 is 459 ml.

The pulp chip of Example 4 uses hardwood as a raw material and has a size that passes through a screen mesh having a hole diameter of 10 mm. The bulk density of the pulp chips of Example 4 is 160 kg / m ³ , the ratio of the tapping bulk density to the bulk density is 1.31, and the average fiber length is 577 μm. The Canadian standard freeness of the fiber assembly of Example 4 is 469 ml.

The pulp chips of Example 5 are made of hardwood as a raw material and have a size of passing through a screen mesh having a hole diameter of 15 mm. The bulk density of the pulp chips of Example 5 is 151 kg / m ³ , the ratio of the tapping bulk density to the bulk density is 1.20, and the average fiber length is 593 μm. The Canadian standard freeness of the fiber assembly of Example 5 is 490 ml.

The pulp chips of Example 6 use softwood as a raw material, and have a size that passes through a screen mesh having a hole diameter of 15 mm. The bulk density of the pulp chips of Example 6 is 223 kg / m ³ , the ratio of the tapping bulk density to the bulk density is 1.26, and the average fiber length is 2370 μm. The Canadian standard freeness of the fiber assembly of Example 6 is 747 ml.

The pulp chip of Comparative Example 1 uses hardwood as a raw material and has a size that passes through a screen mesh having a hole diameter of 0.15 mm. The bulk density of the pulp chips of Comparative Example 1 is 63 kg / m ³ , the ratio of the tapping bulk density to the bulk density is 2.09, and the average fiber length is 244 μm. In Comparative Example 1, the Canadian standard freeness cannot be measured due to the short fiber length.

The pulp chip of Comparative Example 2 uses hardwood as a raw material and has a size that passes through a screen mesh having a hole diameter of 0.5 mm. The bulk density of the pulp chips of Comparative Example 2 is 39 kg / m ³ , the ratio of the tapping bulk density to the bulk density is 1.95, and the average fiber length is 385 μm. In Comparative Example 2, the Canadian standard freeness cannot be measured due to the short fiber length.

In the medium using the pulp chips of Examples 1 to 6, the morphology of the fiber aggregates did not easily collapse, and drainage properties suitable for plant cultivation could be obtained. In addition, the seeds planted on the surface of the fiber aggregate did not sink into the fiber aggregate, and the seeds could germinate well.

In the pulp chips of Examples 1 to 6, the work efficiency is high because the amount of dust generated when the dry pulp is crushed or when the pulp chips are handled is very small.

On the other hand, in the pulp chip of Comparative Example 1, it is difficult to maintain the fiber aggregate, so that the medium cannot be formed. In the pulp chips of Comparative Example 2, the seeds planted in the fiber aggregates sink into the fiber aggregates, so that it is difficult for the seeds to germinate.
In the pulp chips of Comparative Example 1 and Comparative Example 2, a large amount of dust was generated during crushing of dry pulp and handling of pulp chips.

From the above examples, it was found that the pulp chips and the method for producing pulp chips of the present invention can efficiently produce a high-quality medium suitable for plant cultivation.

1 medium 10 fiber aggregate 20 container

Claims (7)

A pulp chip for a medium used for producing a medium for planting seeds.
Consists of wood-derived dry pulp crushed by a crusher
A pulp chip for a medium having a bulk density of 70 kg / m ³ or more. The pulp chip for a medium according to claim 1.
A pulp chip for a culture medium, which has a hole diameter of 1 mm to 20 mm and has passed through a screen mesh set in the crusher. The pulp chip for a medium according to claim 1 or 2, wherein the value obtained by dividing the tapping bulk density by the bulk density is 1.0 or more and 1.9 or less. The pulp chip for a medium according to any one of claims 1 to 3.
The dry pulp is a pulp chip for a medium, which is derived from softwood or hardwood. A method for producing a medium for planting seeds.
At the stage of crushing dry pulp derived from wood with a crusher to prepare pulp chips with a bulk density of 70 kg / m ³ or more,
The stage of disassembling the pulp chips and taking out the fibers,
A method for producing a medium, which comprises a step of forming a fiber aggregate by a plurality of the fibers. The method for producing a culture medium according to claim 5.
A method for producing a medium, wherein the average fiber length of the plurality of fibers taken out from the pulp chips is 400 μm or more. The method for producing a culture medium according to claim 5 or 6.
A method for producing a medium, characterized in that the Canadian standard freeness of the fiber aggregate is between 400 ml and 780 ml.

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