JP2016055646A - Treated wood provided with agent pocket, and production method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a production method of a treated wood capable of improving antiseptic property, termite repellency or flameproofness of wood by simple means.SOLUTION: In a production method of a treated wood, a pocket 2 for filling an agent therein is formed by hollowing a hole from the surface of a wood 1 toward the inside, and the agent is filled in the pocket, which is selected from a liquid, pasty or solid antiseptic agent, termite-proofing agent, flameproofing agent or mixture containing two or more thereof, and containing at least boron or a boron-containing compound.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a treated wood in which a cavity (medicine pocket) for filling a medicine is provided inside the wood, and a method for manufacturing the treated wood.

  Wood is widely used as a building material, but since it is susceptible to rot caused by decaying fungi and insect damage due to termites, bark beetles, etc., it is necessary to take antiseptic / anticidal measures to withstand long-term use. is necessary. Moreover, since it is a flammable material, it is preferable to take measures to enhance its flameproof property (sometimes called flame retardancy or nonflammability). As a method for taking these treatments on wood, preservatives, termites (sometimes called insecticides), flame retardants (sometimes called flame retardants or fire retardants), etc. are added to wood. Application or spraying method (coating / spraying method), immersing wood in these chemicals to infiltrate these agents into the wood (immersion method), or using pressure to apply these agents into the wood There are methods for press-fitting (pressure reduction / pressure injection method). Among these, the coating / spraying method and the dipping method have the advantage that they do not require special equipment and can be carried out easily, but the drug stays on the surface of the wood or the surface layer, and the amount of the drug fixed on the wood is small. Because there are few, it is difficult to obtain long-term effects. On the other hand, the pressure reduction / pressure injection method differs depending on the type of material and the presence or absence of insizing processing, but because the chemical is forcibly permeated from the surface of the wood to a depth of about 5 to 20 mm, the application / spraying method or immersion Compared with the law, there is generally an advantage that a long-term effect can be obtained.

  In Patent Document 1, a copper-based chemical is pressure-injected into wood, then a boric acid-based chemical is injected under reduced pressure, and a water-repellent treatment agent is applied to the surface of the wood. A method is described.

  As described in Patent Document 1, the method of infiltrating a drug into wood using pressure (depressurization / pressure injection method) has a long-term effect compared to the coating / spraying method and the dipping method. However, in order to perform this process, it is necessary to use a special vacuum pressurizing kettle for decompression and pressure injection into wood. However, many of these decompression and pressure kettles for wood exist in areas close to large cities where major companies have entered, such as Kanto, Sendai, Aichi, Osaka, Hiroshima, and Fukuoka. There are almost no areas far from the city. Considering environmental factors and regional economic revitalization, it is preferable to use felled timber in areas close to the felling area (effective use of local timber, local production for local consumption). It is difficult to use timber that has been cut in the region as a long-term durable building material in the region. Once again, it is transported horizontally to the area where the timber is used. The cost of transporting heavy and bulky items such as timber is high and has a significant impact on commodity prices, thus hindering the effective use of locally produced timber.

  Therefore, providing a method that can perform the same level of processing as the pressure reduction and pressure injection method with simple means without the need for special equipment such as a pressure reduction pressurization furnace, It can be said that it is preferable in revitalizing the effective use (local production for local consumption) and revitalizing the local economy such as promotion of local employment.

JP 2010-111101 A

  The present invention provides a method for treating wood by simple means.

In the present invention, by forming a hole for filling the wood with a chemical by hollowing out holes from the surface of the wood to the inside, preservatives, ant-proofing agents, and / or flameproofing agents (hereinafter referred to as `` wood ''). Impregnation with “antiseptic / anticidal / flameproofing agent” or simply “medicine” and a pocket for filling the drug (hereinafter referred to as “medicine pocket” or simply “pocket”) Manufacturing of treated wood comprising filling an antiseptic / anticidal / flameproofing agent containing boron or a boron-containing compound (hereinafter sometimes collectively referred to as a “boron-based compound”) Provide a method. In general, it is difficult to infiltrate the drug into the core of the wood due to the nature of the tissue, but in the present invention, by drilling a hole in the wood and filling the drug inside the hole (in the drug pocket), The drug can be spotted in the center of the wood. Moreover, after the wood has been installed for a long time, the durability of the wood can be easily maintained by filling the medicine pocket again with the medicine when the effect of the initial medicine decreases (maintenance) ). Further, the present inventor has the effect that the boron compound is drawn (infiltrated) into the inside of the drug applied by impregnation from the outside by including the boron compound in the drug filled in the drug pocket. I found. The present invention includes, but is not limited to:
(1) Step 1 for forming a pocket for filling a medicine in a wood by hollowing out a hole from the surface of the wood toward the inside;
Step 2 of impregnating wood with an antiseptic, an antiseptic, a flameproofing agent, or a mixture containing two or more of these, and an antiseptic, an antiseptic, and a flameproofing agent in a pocket for filling the chemical Or filling with a drug comprising at least boron or a boron-containing compound selected from a mixture comprising two or more of these
A method for producing treated wood, comprising:
(2) The method according to (1), wherein the pocket for filling the drug is a hole having a diameter of 6 mm or more.
(3) The method according to (1) or (2), wherein the preservative, the antproof agent, the flameproofing agent, or the mixture containing two or more thereof impregnated into the wood in Step 2 contains at least a metal compound.
(4) The method according to any one of (1) to (3), wherein the boron or the boron-containing compound includes a borate and a glycol.
(5) The pocket for filling the drug is a hole having a diameter of 6 to 20 mm, and in the step 3, the liquid, paste, or solid drug is filled in the pocket. (1) to (4 The method according to any one of (1).
(6) The method according to any one of (1) to (4), wherein in the step 3, the small pieces of wood impregnated with the drug are filled into the pockets.
(7) The treated wood is a laminated wood, and after applying steps 1 and 3 to a part or all of the laminated lamina, the lamina is joined to each other to obtain a laminated wood, and the obtained laminated wood is subjected to the above steps. 2. The method according to any one of (1) to (6), comprising applying 2 to a treated wood.
(8) A method of maintaining the antiseptic, ant-proofing, or flameproofing properties of a structure formed using the treated wood produced by the method according to any one of (1) to (7) There,
Filling the pocket for filling the agent in the treated wood forming the structure again with boron or a boron-containing compound between 3 and 10 years after the structure is formed.

  In the present invention, a hole is formed in the wood to form a drug pocket, and the drug pocket is filled with an antiseptic / anticide / flameproofing agent containing a boron-based compound. The drug can be present in the inner part of the wood that is difficult to cause. In addition, the boron-based compound in the drug pocket has an action of drawing (infiltrating) the drug applied by impregnation from the outside into the inside, and assists the penetration of the drug from the outside into the wood. Furthermore, when the effect of the initial drug is weakened after a long period of time, the durability of the wood can be easily maintained by filling the drug pocket again with the drug (maintenance).

  According to the present invention, the medicine filled in the medicine pocket inside the wood and the medicine applied by impregnation from the outside can be used without requiring special equipment such as a decompression and pressure pot for wood. And the drug effect over the entire surface layer can be obtained. The fact that no pressure and pressure kettle is required for wood treatment leads to the promotion of local use of local timber to reduce the cost of transporting timber to the area where the pressure and pressure kettle is located (local production for local consumption). The local timber is processed locally, leading to local employment promotion.

  Wood is usually decayed and damaged by the surface layer in contact with the outside. However, in the present invention, when the antiseptic / anticidal agent is applied by impregnation from the outside, first, it is decayed by the chemical applied by the impregnation from the outside. , Insect damage is prevented. The boron-based compound filled in the drug pocket slowly moves through the tissue of the tree, and after a while after construction (for example, from about 1 to 3 years depending on the installation environment), gradually into the wood sapwood part It will come to support the antiseptic and ant-repellent effect of the drug applied by impregnation from the outside. Boron compounds, in particular, have the property of moving (diffusing) to the higher moisture content, and move to humid areas where rotting fungi and termites are active, contributing to their control. .

  Further, the boron-based compound also has a flameproofing effect, and when the flameproofing agent is applied from the outside by impregnation in the present invention, the flameproofing agent applied by the external impregnation and the sapwood from the inside of the wood The flameproof (flame retardant) improving effect by both the boron compound penetrating into the part is obtained.

  Furthermore, in the treated wood of the present invention, after about 2 to 5 years have passed since the construction, the boron pocket can be filled again into the drug pocket as maintenance. Due to these effects, the wood of the present invention can achieve long-term durability (for example, about 10 years) even when used outdoors or in a relatively humid indoor environment. The wood of the present invention is installed outside such as, but not limited to, guardrails, benches, fences, signboards, fences, park playground equipment, piles for environmental maintenance, household deck materials, solar panel mounts, etc. Materials for structures, materials used indoors such as indoor pools, hot springs, or relatively humid factories, public facilities such as educational facilities where non-combustible treatment is defined in the building conditions, nursing homes, It is particularly suitable as a material used in urban houses.

It is an example of the process wood of this invention. It is an example of the process wood of this invention. It is an example of the process wood of this invention. It is an example of the process wood of this invention.

  The method for producing treated wood according to the present invention comprises a step 1 for forming a pocket for filling a medicine (medicine pocket) in the wood by hollowing out a hole from the surface of the wood toward the inside; A step 2 of impregnating the flameproofing agent, and a step 3 of filling the chemical pocket with an antiseptic / anticidal / flameproofing agent containing a boron-based compound.

  Step 1 and step 2 may be performed in this order, or the order may be reversed. It is preferable to perform step 2 after performing step 1, since a drug penetration effect can be expected from the surface of the hole opened as a drug pocket. Step 3 is usually performed after steps 1 and 2. However, for example, when performing the step 1 of providing the drug pocket in the laminated lamina, after performing the step 1 of providing the drug pocket and the step 3 of filling the drug in the drug pocket, the lamina is joined, The step 2 of impregnating the drug from the outside may be performed.

  As wood, wood that can be used for ordinary building materials may be used. The state of the wood is not limited, but raw wood before drying is preferable. Further, prior to the formation of the drug pocket (step 1) or the impregnation of the drug (step 2), the lumber may be processed and processed according to the use design. The shape of the wood is not particularly limited, and may be any of round material, square material, plate material, and the like. Moreover, a laminated material may be sufficient and the lamina for forming a laminated material may be sufficient.

<Formation of drug pocket-step 1>
The drug pocket is a hole cut out from the surface of the wood toward the inside, and is filled with an antiseptic / antalistic / flameproofing agent containing a boron-based compound (step 3). The drug pocket needs to have a pore size that can be filled with antiseptic, antproof, and flameproofing agents. In addition, as will be described later, when it is intended to refill with chemicals (maintenance) after a certain period of time after forming wood into a structure, It is preferable to have a pore size that allows the drug to be filled manually or by using a simple injection device (without decomposing the product). Therefore, the hole diameter is preferably 6 mm or more, more preferably 10 mm or more. If the pore size is too small, it may be difficult to fill the drug, and the pocket volume will be small, so that a sufficient amount of drug cannot be held in the pocket. The upper limit of the hole diameter is not particularly limited, but if the hole diameter is too large, the strength of the wood may be lowered, and therefore it is preferably 20 mm or less. Therefore, the hole diameter is preferably 6 to 20 mm, and more preferably 10 to 20 mm.

  The drug pocket is a hole that is hollowed out from the surface of the wood toward the inside, for example, a hole that is hollowed in parallel to the long axis direction of the wood from the vicinity of the center of the wood mouth to the inside of the wood. There may be (for example, FIG. 1). Alternatively, it may be a hole that is cut out from the side surface of the wood to the inner central portion of the wood perpendicularly to the long axis direction of the wood (for example, FIGS. 3 and 4) or obliquely (for example, FIG. 2). 1-3, 1 is wood, 2 is a medicine pocket formed inside the wood, 3 is a lid for closing the entrance of the medicine pocket after filling the medicine pocket, 4 is A piece of wood impregnated with a drug is shown. 1 and 2 are examples of round materials, and FIGS. 3 and 4 are examples of square materials. However, the shape of the wood is not limited to these, and there is a plate shape, a material that has been molded according to the design used, and decoration. It may be given. When refilling the drug for maintenance, the hole for the drug pocket should be opened so that the hole entrance (external opening) appears on the outer surface of the structure after the wood is assembled into the structure. It is preferable to cut out.

  The depth of the drug pocket can be determined according to the diameter and length of the wood. If it is too deep, there may be disadvantages such as a drop in the strength of the wood, and if it is too shallow, the amount of drug that can be injected into the pocket will be reduced and the effect of sufficient drug will not be obtained, so from the mouth end to the long axis direction In the case of punching holes in parallel, it is preferable to cut the holes to a length (depth) of about 50 to 80% of the long axis length, for example, exceeding about half the long axis length of the wood. In addition, when drilling a hole perpendicularly or obliquely to the long axis direction of the wood, the bottom of the hole (the tip of the hole) is a point where the diameter of the wood is 50 to 80% when the hole is observed from the face of the wood. It is preferable to cut out so as to reach the point. In addition, after forming a hole that penetrates wood once, the drug pocket is closed to one end of the through hole with a plug having a predetermined length, a hardware, or a sealing agent to form a hole having a predetermined depth. It may be formed.

  The tool for forming the drug pocket is not particularly limited, and a commonly used tool such as a drilling machine or an electric drill may be used. The shape of the hole cross section of the drug pocket is not particularly limited as long as the drug can be filled, and may be any shape such as a circular shape, an elliptical shape, and a square shape. For example, if a drilling machine or an electric drill is used, it will be circular.

  The formation position of the medicine pocket is determined according to the shape of the wood, the purpose of use, and the installation location. For example, when used as a material for a structure installed outdoors, the wood is most susceptible to decay and termite damage near the ground. It is preferable to provide a drug pocket directed toward the back. In addition, since the vicinity of the cut end such as the long axis end of wood is likely to deteriorate, a hole is cut out from the long axis end in parallel to the long axis direction of the wood, or at a position about 5 to 10 cm away from the long axis end. It is preferable to cut out holes from the side of the wood into the wood.

  The number of drug pockets provided in one piece of wood may be determined according to the size, shape, purpose of use, etc. of the wood. If the number of drug pockets is excessive, it may take time to form pockets, the amount of drug to be filled will increase the cost, and the strength of the wood may decrease. One piece may be provided for one piece of wood, or a plurality of drug pockets may be provided on one piece of wood with a distance between the center points of the pockets of 30 cm to 90 cm, for example, about 60 cm to 90 cm. For example, in the case of a plate material, the pockets may be arranged in a staggered manner at intervals of 30 to 60 cm, starting from about 5 to 10 cm from the cut end.

  By the above method, in this invention, the chemical | medical agent pocket for filling a chemical | medical agent is provided in the mouth end or side surface of wood. In addition, in the pressure injection treatment of wood, in general, in order to promote penetration into the inside of the drug, an insizing process in which a fine cut is made over the entire length of the wood may be performed before the injection treatment. The notch in the insizing process has a small diameter and is shallow, so it cannot be said that the hole can be filled and held with the medicine, and does not correspond to the “pocket for filling medicine” in the present invention.

<Impregnation of drug-step 2>
In the step 2 of impregnating the wood with an antiseptic, antproofing agent, flameproofing agent, or a mixture of two or more thereof (also simply referred to as “preserving / anticidal / flameproofing agent”), the chemical is applied to the wood in the usual manner. May be impregnated. Examples of the impregnation method include a coating / spraying method, a dipping method, and a reduced pressure / pressure injection method. Among these, the dipping method (under normal pressure) can be said to be the most preferable aspect in view of the balance between cost and effect. In the present invention, by filling the medicine pocket provided inside the wood with the medicine, the medicine can be present inside the wood, which is usually difficult to permeate the medicine. Even if it is simple methods, such as immersion under a normal pressure, without requiring this, the high chemical | medical agent effect can be acquired. As a chemical immersion method, a commonly used method may be used. In general, depending on the type of drug, wood is immersed in a solution in which a drug of a predetermined concentration is dissolved in water or oil for about 5 minutes to 72 hours. The fact that a high durability improvement effect can be obtained with a simple facility (for example, a bath for immersion) without using a special vacuum pressurizer is that wood produced in an area that does not have a vacuum pressurizer is used. It leads to the promotion of local use (local production for local consumption) without transporting it to a certain area, which has great advantages in terms of the environment and the revitalization of the local economy.

  As described above, in the present invention, by providing a chemical pocket in the wood, a high effect can be obtained without using a vacuum pressurizing kettle in the impregnation (step 2). The use of pressure-injected wood is not excluded. Even when the wood into which the medicine is decompressed and pressurized is used in the present invention, the effect of the present invention can be obtained by diffusion of the medicine from the medicine pocket. In addition, when the medicine pocket is formed so that the entrance of the pocket appears on the outer surface, there is an advantage that maintenance for refilling the medicine pocket into the medicine pocket after a certain period of time is possible. A commonly used method may be used as the method of pressure reduction and pressure injection. In this specification, the term "pressure reduction / pressure injection" refers to the general method of injecting chemicals into wood using pressure in a pressure / pressure chamber, and pressure reduction injection, pressure injection, and pressure / pressure injection. including.

  As antiseptic / anticidal / flameproofing agents impregnated into wood, generally, chemicals known for these actions may be used. For example, a preservative, an antproofing agent, or a flameproofing agent approved by the Japan Wood Preservation Association, the Japan Shiromari Countermeasures Association, the Japanese Flame Protection Association, the Japanese Flame Retardant Association, or AWPA (American Wood Protection Association) of the United States . Examples of antiseptic / anticidal agents include metal compounds containing metals such as copper, zinc, and silver (for example, copper / alkyl ammonium compounds (ACQ), copper naphthenates (NCU), zinc naphthenates (NZN)), Zinc Versatate / Pyrethroid Compound (VZN), Chromium / Copper / Arsenic Compound (CCA), etc.), Quaternary Ammonium Salt Compound (Alkylammonium Compound (AAC), Boron / Alkylammonium Compound (BAAC) etc.), Azole Compound ( AZP), neonicotinoid compounds, boron or boron-containing compounds (borate, borax, boron, glycol / borate, etc.), creosote oil, etc., flame retardants (flame retardants, flame retardants) Also called boron or boron-containing compounds (borate, borax, boron, glycol) Borate, etc.), metal compounds (such as aluminum hydroxide, magnesium hydroxide), phosphoric acid compounds (such as ammonium polyphosphate), sodium salt compounds (such as sodium aluminate), ammonium bromide, and the like. Can be used alone or in combination. In addition, one chemical | medical agent may have several effects among antiseptic | preservation, antproof, and flameproofing.

  As will be described later with respect to Step 3, boron or a boron-containing compound (also referred to as boron-based compound) filled in the drug pocket has an action of drawing a metal compound into the wood (that is, an action of promoting penetration into the wood). It was found that there was. Therefore, it is preferable to use a metal compound as a chemical | medical agent which impregnates wood at the process 2, and the copper containing compound which is a chemical | medical agent containing copper is especially preferable. In the impregnation (step 2), by using a drug containing a metal compound, the metal compound applied from the outside by the impregnation interacts with the boron compound filled in the drug pocket, and a higher effect is obtained. It is done. Specifically, the boron compound promotes the penetration of the metal compound into the wood. Normally, metal compounds are fixed and difficult to penetrate into the wood, but boron compounds filled in drug pockets inside the wood promote the penetration of metal compounds into the wood. As a result, a larger amount of the metal compound can be fixed to the wood. In addition, the initial effect is exhibited by the metal compound that is relatively fixed and is likely to stay on the surface layer portion. After several years (for example, about 3 years) after the initial effect fades, the drug pocket has been filled. Since the boron compound gradually permeates into the surface layer portion (sapwood portion) of the wood, the boron compound supplements the effect of the metal compound. Thus, it is possible to obtain a long-term durability improvement effect.

  In the present invention, in Step 2, it is preferable to impregnate a boron compound in addition to the metal compound. When impregnating a boron compound in addition to a metal compound, the boron compound and the metal compound may be impregnated separately (sequentially), or a mixed solution in which the metal compound and the boron compound are mixed is impregnated. You may use for. Boron compounds easily penetrate into wood with a lot of moisture, while fixed-type chemicals such as metal compounds are difficult to penetrate due to pressure when moisture remains on the wood. It is preferable to impregnate a raw tree containing a boron compound with a boron compound, take it out, dry it once, and then impregnate it with a metal compound. In this way, it is considered that some of the boron-based compounds impregnated on the surface are slightly outflowed when the next metal compound is impregnated, but this does not cause all boron-based compounds to flow out. However, most of the boron-based compound that has penetrated into the interior remains without flowing out. The boron-based compound remaining inside exhibits an effect of drawing the metal compound to be impregnated next into the wood.

  In addition, it is preferable to dry a timber after a chemical | medical agent impregnation (process 2).

<Filling the drug into the drug pocket-Step 3>
An antiseptic / anticidal / flameproofing agent containing a boro-oxygen-based compound is filled in the chemical pocket of the wood in which the pocket is formed (step 1). As the boron-based compound, borate, borax, boron, glycol / borate and the like can be used as described above with respect to step 2. Examples of borates include sodium borate, zinc borate, calcium borate, sodium calcium borate, calcium magnesium borate, organic borates (trimethyl borate, boronic acid, etc.), and boric acid Examples of sodium include sodium metaborate (NaBO ₂ ), sodium tetraborate (Na ₂ B ₄ O ₇ ), sodium pentaborate (Na ₂ B ₅ O ₈ ), and sodium hexaborate (Na ₂ B ₆ O ₁₀ ). sodium eight borate _{(Na 2 B 8 O 13)} , disodium borate _{(Na 4 B 2 O 5)} , and include these hydrates. Among them, disodium octaborate tetrahydrate (DOT) is preferable because of its high solubility in an aqueous solvent.

  Furthermore, as the boron-based compound filled in the drug pocket, it is preferable to use a glycol / borate containing borate and glycol. Examples of the glycol include propylene glycol and ethylene glycol, and short chain polyalkylene glycols in which several of these are connected, such as diethylene glycol, triethylene glycol, and polyethylene glycol containing four or more ethylene glycol units. It is done. Glycol has the function of assisting diffusion of borate in the wood by dissolving the borate therein, and also has the function of keeping the borate in the wood (making it difficult to leach out). . Furthermore, the present inventor has found that wood to which glycol has been applied becomes stiff and difficult to break. It is speculated that the part containing glycol is cured in a high temperature environment such as direct sunlight. Moreover, it is thought that hardening of glycol contributes also to suppression of leaching of borate from wood.

  The boron-based compound may be used as a liquid or paste by dissolving or suspending in a solvent, or solidified into a drug pocket. For example, it can be used as a liquid or slurry boron compound by dissolving or suspending borate in water. A commercially available boron compound may also be used. For example, a solution containing about 40% by mass of disodium octaborate tetrahydrate (DOT), polyethylene glycol, and water is commercially available from the US company Nisus Corporation under the trade name “BORA-CARE”. The stock solution or a solution diluted with water may be used. Furthermore, it is also preferable to use a paste-like medicine in which the borate concentration is higher than that of the stock solution of “BORA-CARE” by kneading the borate with “BORA-CARE”. Such borate-rich paste-like drugs are easier to fill with a spatula or the like in the drug pocket than liquid drugs in which boric acid is dilute, and compared to liquid drugs. Since it penetrates from the drug pocket into the wood over time, it has an advantage that the effect is easily sustained.

  The chemical | medical agent with which it fills in a chemical | medical agent pocket may contain arbitrarily other antiseptic | preservative / anticide / flameproofing agents as described in the column of Step 2 in addition to the boron compound. Preferably, the boron concentration in the antiseptic / anticidal / flameproofing agent filled in the drug pocket is 20 to 70% by mass, more preferably 50 to 70% by mass.

  The amount of drug filled into the drug pocket is determined according to the volume of the drug pocket. It is preferable to fill the drug in an amount of 70% or more of the volume of the drug pocket. More preferably, it is preferable to fill the drug in an amount that fills the entire volume of the drug pocket.

The method of filling the drug pocket with the drug is not particularly limited, and when the drug is liquid or pasty, it may be filled with a device such as a sprayer, a dropper, a caulking gun, or a spatula. In such a case, it may be inserted into the medicine pocket.
After filling the drug pocket with the drug, it is preferable to close the open end of the drug pocket with a stopper. As will be described later, when it is intended to refill the chemical after a certain period of time after forming the wood into a structure, the stopper is removable or a tool such as a drill is used. What can be easily removed or can be perforated is preferable. Examples of the types of plugs include, but are not limited to, wooden plugs and cork plugs.
In addition, as a method of filling a medicine pocket containing a boron compound into a medicine pocket, after impregnating a medicine containing a boron compound into a wood piece or the like that is approximately the same size as the medicine pocket, the wood piece is placed in the medicine pocket. It may be done by embedding. The method of filling a pocket with a small piece of wood impregnated with a chemical is less difficult to reduce the strength of wood compared to the method of filling a pocket with a liquid, paste, or solid solid chemical. It can be said that it is particularly suitable when wood is used as the structural material.
The method for impregnating the wood piece with the chemical containing the boron compound is not particularly limited, and examples thereof include a coating / spraying method, a dipping method, a reduced pressure / pressure injection method, and the like. In view of impregnating a large amount of chemical with a piece of wood, the reduced pressure / pressure injection method is preferable. In the case of the pressure reduction / pressure injection method, a piece of wood may be immersed in a liquid containing 20% by mass or more of a boron-based compound, and the drug may be forcibly permeated into the piece of wood using a reduced pressure pressurizer. . For example, the step 1 of providing a drug pocket in a logging or consumption area of wood and the step 2 of impregnating the drug are performed, and the step of impregnating the chemical into a small piece of wood by pressure reduction and pressure injection in an area where the pressure reduction and pressure pot is provided, Step 3 (i.e., impregnating the drug) transporting the small piece of wood impregnated with the chemical from the area where the pressure and pressure kettle is located to the logging or consumption area of the wood and filling the pocket with the chemical in the logging or consumption area of the wood A step of embedding a small piece of wood in the pocket) may be performed. In this case, a small piece of wood will be transported from an area where there is a decompression and pressure kettle to the logging or consumption area of the wood, but since the small piece of wood is not larger than the wood itself, the wood itself is equipped with a decompression and pressure kettle. Compared to horizontal transportation in the area, the transportation cost is not high, and it is unlikely to be a factor that hinders local production for local consumption of wood.
The size and shape of the wood piece is preferably the same size and shape as the drug pocket, but is not limited to this, and any piece that does not easily fall out of the pocket may be used. For example, depending on the shape of the hole in the pocket, it may be round bar shape, square shape, wedge shape, etc., and the length may be substantially the same as or longer than the depth of the drug pocket. After filling a small piece of wood longer than the depth of the drug pocket into the drug pocket, the portion of the small piece of wood protruding from the wood surface may be cut out to the same height (flatness) as the wood surface, if necessary.

  In general, a boron compound has a property of gradually moving (diffusing) to a higher moisture content by repeating dissolution and precipitation. Boron compounds filled in the center of the wood (drug pocket) gradually diffuse inside the wood depending on the installation environment of the wood, especially in places where the wood has a lot of moisture (for example, due to rain or high humidity) It moves toward a place with a lot of moisture (surface layer part) or near the wet ground. Since such a place with a lot of moisture is a place that is particularly susceptible to damage by decaying fungi and termites, it can be said that the movement of the boron-based compound to a place with a lot of moisture is efficient for antiseptic and ant protection.

When the boron-based compound reaches the surface of the wood, it may be leached due to moisture from the outside such as rain. However, most of the boron-based compound is not lost at once. Even if the boron compound concentration temporarily decreases slightly due to leaching, the boron compound in the wood gradually moves to a place with high moisture, so the concentration of boron compound in a place with high moisture is Rise again. In addition, the toxicity threshold value with respect to the decaying fungi of borate is generally said to be 1.0 to 1.5 kg / m ³ BAE in terms of boric acid.

  In the present invention, as described later, the drug containing the boron compound may be refilled in the drug pocket in accordance with the leaching of the boron compound and the decrease in the effect of other drugs. In normal wood that does not have such pockets, after the boron compound has been leached or after a certain period of time has passed and the effect of the drug has decreased, the boron compound or the like is applied again to the external surface, etc. In the present invention, when a drug containing a boron-based compound is directly applied to the inside of the wood (drug pocket), the drug can be present inside the wood for a longer period of time. .

<Processed wood>
The treated wood obtained through the above steps 1 to 3 can be used as a material for forming various structures. The treated wood of the present invention is not limited to, for example, but is limited to guard ants, benches, fences, signboards, board fences, park playground equipment, piles for environmental maintenance, households, due to its high ant / antiseptic / flameproof properties. Deck materials for construction, materials for outdoor installations such as solar panel mounts, materials used indoors such as indoor pools, hot springs, or relatively humid factories, and non-combustible treatment is defined in the building conditions It can be preferably used as a material used in public facilities such as educational facilities, nursing homes, and urban housing.
Further, the laminated wood or the lamina for forming the laminated wood may be subjected to the above treatment to obtain treated wood. When the above-mentioned treatment is performed on the laminated material itself, a step 1 for providing a drug pocket in the laminated material, a step 2 for impregnating the drug, and a step 3 for filling the pocket with the drug may be performed. In addition, when lamina is bonded to a laminated material after processing the lamina, a process 1 for providing a drug pocket in the lamina, a process 2 for impregnating the drug, and a process 3 for filling the pocket with the drug were performed. Later, the lamina may be joined together to form a laminated material, or after laminating a drug pocket in the lamina and step 3 of filling the medicine into the pocket, the lamina are joined together to form a laminated material. You may perform the process 2 which makes a material impregnate a chemical | medical agent. In the case of performing the step 2 of impregnating the chemical after forming the laminated material, the immersion time of the laminated material in the chemical is preferably about 5 to 30 minutes, and more preferably about 5 to 10 minutes. If the laminated material is immersed in the drug solution for a long time, the lamina may peel off or expand.
In the case where drug pockets are provided on the lamina, the drug pockets may be arranged at intervals of 30 to 60 cm starting from about 5 to 10 cm from the cut end of the lamina. At this time, the pockets may be formed so that the drug pockets are arranged in a staggered pattern when the lamina is joined to form a laminated material. After filling the pocket with the drug, the lamina may be joined to form a laminated material. At this time, the entrance of the medicine pocket may or may not appear on the surface of the laminated material. When the entrance of the drug pocket appears on the surface of the laminated material, maintenance (refilling of the drug into the drug pocket) described later becomes easy. On the other hand, when the entrance of the medicine pocket does not appear on the surface of the laminated material, maintenance described later cannot be performed, but there is an advantage that a material having an excellent appearance can be obtained.
When the drug pocket is provided in the lamina, the drug pocket may be provided in all the lamina used for the laminated lumber, but depending on the thickness of the lamina, etc., about 1 to 2 or 3 lamina in the laminated lumber Drug pockets may be provided at a rate.
As described above, as a method of filling the glue in the laminar or the pocket provided in the lamina for forming the glue, the pocket may be filled with a liquid, paste, or solid medicine. The wood piece may be embedded in the pocket after impregnating the chemical with a piece of wood that has substantially the same size as the pocket. From the viewpoint of the strength of the laminated material, it is preferable to embed a small piece of wood impregnated with a drug.

<Refilling drug pockets (maintenance)>
Generally, wood structures installed outdoors or in humid environments are subject to maintenance such as reapplying chemicals at a rate of about once every 1 to 5 years, depending on the application, installation environment, degree of degradation, etc. Is done. In order to perform reapplication of the medicine without destroying the form of the structure, it is usually performed by applying or spraying the medicine. However, since the drug is applied only to the vicinity of the surface of the structure only by applying or spraying the drug, the durability of the effect is limited. In the present invention, when the drug pocket is formed so that the entrance of the drug pocket appears on the outer surface of the structure, the drug can be easily filled into the drug pocket inside the wood during maintenance. Thereby, a chemical | medical agent can be directly reapplied to the inside of wood, and the long-term sustainability of an effect is acquired.

  As the drug to be refilled in the drug pocket, an antiseptic, antproof, and flameproofing agent containing a boron compound can be used in the same manner as in the process of filling the drug pocket in Step 3. From the viewpoint of cost, only a boron compound may be used as a refilling agent. As a method for refilling the medicine, for example, in the same manner as in Step 3, a method of refilling (replenishing) a liquid, paste, or solid medicine into the pocket, or a small piece of wood previously embedded in the medicine pocket. After removing, it can be performed by a method of embedding a new piece of wood impregnated with a drug in a pocket.

  The maintenance may be performed at a normal frequency according to the use of the structure, the installation environment, the possibility of deterioration, and the like. Generally, it is performed once every 1 to 5 years. The first maintenance after installing the wood is preferably performed in the second to third years when the cracks in the wood have settled. Since the medicine in the medicine pocket penetrates into the wood over time, the second and subsequent maintenance may be from the first maintenance to the fifth year or later, depending on the installation environment.

  At the time of maintenance, in addition to refilling the medicine pocket with the medicine, the medicine may be applied or sprayed as usual. The application or spraying is preferably performed on the entire outer surface of the structure, and in particular, the cracked portion is preferably performed carefully. The chemical | medical agent to apply | coat or spray is not restrict | limited in particular, What is necessary is just to use the above-mentioned general antiseptic | preservative / ant-proof / flameproofing agent.

  Although the specific example which concerns on implementation of this invention is shown below, this invention is not limited to these.

(Production Example 1)
As wood, a round pile of cedar and cypress having a diameter of about 7 cm and a length of about 90 cm was prepared by peeling the bark and sharpening one end in a tapered shape. Using a drilling machine, a hole with a hole diameter of 10 mm and a depth of 40 cm was cut out in the center of the mouth end on the side opposite to the pointed end of the round pile (formation of a drug pocket). The round pile formed with the drug pocket was immersed in an aqueous solution containing 15% by mass of DOT for 1 hour. The obtained round pile was dried and then immersed in a 1% by mass copper naphthenate solution (trade name QNAP, manufactured by Nisus Corp., USA) for 10 hours. After drying the obtained round stake, the drug pocket is filled with glycol / borate aqueous solution (trade name Bora-Care of Nisus US, diluted twice with water), and a wooden plug is struck. , Covered. The obtained timber (round stake) can be used by being driven into the ground outdoors (for example, as a mark or a fence for setting a boundary in a park or a sidewalk).

  Every three years after the round pile is installed outdoors, the wooden plug is removed, and the above glycol / borate aqueous solution is filled again and covered with a wooden plug. Also, spray or brush the glycol / borate aqueous solution on the entire outer surface of the round pile. Thereby, the durability of the round pile is maintained, and durability of 10 years or longer is obtained.

(Production Example 2)
As wood, a round pile of cedar and cypress having a diameter of about 12 cm to 18 cm and a length of about 4 to 7 m was prepared by peeling the bark and sharpening one end in a tapered shape. A hole with a hole diameter of 10 mm and a depth of 40 cm was cut out at the center of the mouth end on the opposite side of the pointed end of the round pile, and holes with a hole diameter of 10 mm and a depth of 8 cm were cut out at 90 cm intervals on the side of the wood. (Formation of drug pocket). The round pile formed with the drug pocket was immersed in an aqueous solution containing 15% by mass of DOT for 1 hour. The obtained round pile was dried and then immersed in a 1% by mass copper naphthenate solution (trade name QNAP, manufactured by Nisus Co., USA) for 12 hours. After drying the obtained round stake, the drug pocket is filled with glycol / borate aqueous solution (trade name Bora-Care of Nisus US, diluted twice with water), and a wooden plug is struck. , Covered. The obtained timber (round pile) can be used as a fence for outdoor playground equipment or guardrails.

(Production Example 3)
The following treatment was performed on laminated wood, cedar and cypress wood having a cross section of 15 cm × 25 cm, which was wood formulated for beams and pillars. A hole with a hole diameter of 10 mm and a depth of 10 cm was cut every 60 cm (formation of a drug pocket) on the long-axis side surface (back surface) that was not visible from the room side when the wood was installed. The wood in which the drug pocket was formed was immersed in an aqueous solution containing 15% by mass of DOT for 1 hour. The obtained wood was dried, and then, an aqueous solution of glycol / borate (stock solution of Bora-Care of Nisus, USA) was filled in the drug pocket, and a wooden plug was struck and capped. The obtained wood can be suitably used for, for example, hot springs, indoor pools, and humid indoor structural materials such as factories in humid environments. The chemical | medical agent with which it filled in the chemical | medical agent pocket moves toward the direction where the moisture content of a timber is high, and acts so that the decay | rotation of the part with a high moisture content may be suppressed.

(Production Example 4)
The following treatments were performed on cedar wood and cypress wood having a cross section of 15 cm × 25 cm, which was wood that was formulated for interior decoration or for beams and pillars. On the side of the long axis that is not visible from the indoor side when the wood is installed (back side), at a position 10 cm from the cut end of the wood (end of the long axis), and at intervals of 45 cm, the hole diameter is 10 mm, and the depth is about 10 cm ( A hole (corresponding to a depth of about 80% of wood) was cut out (formation of a drug pocket). The wood in which the chemical pockets were formed was immersed in a mixed solution of 15% by mass of DOT (antiseptic / anticidal / flameproofing agent) and a commercially available liquid for flame retardant treatment for 36 to 48 hours. The obtained wood was dried, and then the drug pocket was filled with the same drug as that used for the dipping treatment, and a wooden plug was struck and capped. The obtained timber can be used for a structural material such as a nursing home, a public facility such as an educational facility, a nursing home, or a residential house in an urban area, where non-combustible treatment is defined in the building conditions. The flameproofing agent containing the boron compound filled in the drug pocket diffuses into the wood over time. Usually, when the flameproofing agent penetrates into the wood from the outside, an immersion time of about 72 hours is required. However, in the wood of the present invention provided with the drug pocket, the flameproofing agent is also introduced from the surface of the hole of the drug pocket. Further, since the chemical | medical agent which osmose | permeated and was further filled in the chemical | medical agent pocket also spread | diffused to wood, the immersion time of a flame retardant to wood can be shortened and the flame retardance performance can be given to the inside of wood more.
(Production Example 5)
The following treatment was performed on laminated wood, cedar and cypress wood having a cross section of 15 cm × 25 cm, which was wood formulated for beams and pillars. A hole having a hole diameter of 8 mm and a depth of 10 cm was cut every 60 cm (formation of a drug pocket) on the long-axis side surface (back surface) that was not visible from the room side when the wood was installed. The wood in which the drug pocket was formed was immersed in an aqueous solution containing 15% by mass of DOT for 1 hour, and then immersed in a 1% by mass of copper naphthenate solution for 10 hours. The obtained wood was dried.
A small piece of wood with a diameter of 8 mm and a length of 10 cm is diluted with a glycol / borate aqueous solution (diluted stock of Bora-Care, trade name of US Nisus Co., Ltd. twice) using a vacuum pressurizer. Injected under pressure. The obtained piece of wood containing the drug was hammered into the aforementioned drug pocket. The obtained wood can be suitably used for, for example, hot springs, indoor pools, and humid indoor structural materials such as factories in humid environments. The medicine filled in the wood piece in the medicine pocket moves from the wood piece to the inside of the wood around the piece in the direction of high moisture content, and acts to suppress the rot of the high moisture content portion. .
(Production Example 6)
A drug pocket with a hole diameter of 12 mm and a depth of 3 cm is provided 5 cm from the side of the side of the laminated laminar (grinding board) with a cross section of 18 cm x 5 cm, which is a wood formulated for beams and pillars. Thereafter, drug pockets of the same size were provided at intervals of 60 cm. A small piece of wood having a diameter of 12 mm and a length of 3 cm into which a glycol / borate aqueous solution (diluted stock of Bora-CARE under the trade name of Nisus, USA) was injected under reduced pressure was injected into the drug pocket. In the same manner, a lamina is prepared with a drug pocket 10 cm from the end of the mouth, and then a drug pocket of the same size is prepared at intervals of 60 cm. Glycol / borate aqueous solution is decompressed and pressurized in the lamina drug pocket. The injected wood piece or the wood piece soaked with glycol / borate aqueous solution for 4 hours or more was struck. These laminaes were joined alternately in the long axis direction so that the drug pockets were arranged in a zigzag pattern to form a plate shape. A plurality of similar plates were prepared. These plates were overlapped and joined so that the wood grain crossed alternately, and a cross assembled plate (CLT) was created. The obtained CLT was immersed in an aqueous solution containing 15 to 23% by mass of DOT for 5 minutes, and then dried to a water content of about 10% by mass to obtain a 1% by mass copper naphthenate solution (available from Nisus Corporation, USA). (Product name QNAP) was immersed for 5 minutes and dried.
The obtained laminated board has high strength and can be suitably used as a structural material for construction. The medicine filled in the small piece of wood in the medicine pocket moves from the small piece of wood to the inside of the wood around the small piece in the direction of high moisture content so as to suppress rot and insect damage in the high moisture content part. Works.
(Production Example 7)
A timber formulated for beams and pillars for large wooden buildings, with a hole diameter of 12 mm and a depth of 3 cm 5 cm from the side of the side of the laminated laminar (grinding board) with a cross section of 60 cm x 60 cm Then, drug pockets of the same size were provided at intervals of 60 cm. A small piece of wood having a diameter of 12 mm and a length of 3 cm, in which a glycol / borate aqueous solution (a product obtained by diluting a stock solution of Bora-CARE under the name of Nisus in the United States) twice for at least 4 hours, was struck in the drug pocket. In the same manner, a lamina is prepared with a drug pocket 10 cm from the end of the mouth, and then a drug pocket of the same size at 60 cm intervals. Glycol / borate aqueous solution is added to the lamina drug pocket for 4 hours or more. Dipped wood pieces were struck. These laminaes were joined alternately in the long axis direction so that the drug pockets were arranged in a zigzag pattern to form a plate shape. A plurality of similar plates were prepared. These plates were overlapped and joined so that the wood grain crossed alternately, and a cross assembled plate (CLT) was created. A glycol / borate aqueous solution having a concentration of 20% by mass or more was applied twice or more to the obtained CLT, and then dried. Further, it was immersed in a 1% by mass naphthenic acid copper solution (trade name QNAP of Nisus, USA) for 5 minutes, or a 1% by mass of naphthenic acid copper solution (trade name QNAP, USA by Nisus) was applied twice and dried.
The obtained laminated board is highly durable against water leakage and insect damage. It can also be suitably used as a structural material for construction that cannot be maintained by fireproof coating with gypsum board or the like. The medicine impregnated in the wood piece in the medicine pocket moves from the wood piece to the inside of the wood around the piece in the direction of high moisture content so as to suppress rot and insect damage in the high moisture content part. Works.

1: wood, 2: medicine pocket, 3: lid, 4: wood piece impregnated with medicine

Claims (8)

Step 1 for forming a pocket for filling a medicine in a wood by hollowing out a hole from the surface of the wood toward the inside;
Step 2 of impregnating wood with an antiseptic, an antiseptic, a flameproofing agent, or a mixture containing two or more of these, and an antiseptic, an antiseptic, and a flameproofing agent in a pocket for filling the chemical Or filling with a drug comprising at least boron or a boron-containing compound selected from a mixture comprising two or more of these
A method for producing treated wood, comprising:   The method according to claim 1, wherein the pocket for filling the drug is a hole having a diameter of 6 mm or more.   The method according to claim 1 or 2, wherein the preservative, the antproofing agent, the flameproofing agent, or the mixture containing two or more thereof impregnated into the wood in Step 2 contains at least a metal compound.   The method according to any one of claims 1 to 3, wherein the boron or boron-containing compound comprises a borate and a glycol.   The pocket for filling a medicine is a hole having a diameter of 6 to 20 mm, and in Step 3, the liquid, paste, or solid medicine is filled into the pocket. The method according to item.   The method according to any one of claims 1 to 4, wherein, in Step 3, the small pieces of wood impregnated with the drug are filled in the pockets.   The treated wood is laminated wood, and after applying steps 1 and 3 to a part or all of the laminated lamina, the lamina is joined together to form laminated wood, and the obtained laminated wood is subjected to step 2 above. The method of any one of Claims 1-6 including making a treated wood. A method of maintaining the antiseptic, ant-proofing, or flameproofing properties of a structure formed using the treated wood produced by the method according to any one of claims 1 to 7,
Filling the pocket for filling the agent in the treated wood forming the structure again with boron or a boron-containing compound between 3 and 10 years after the structure is formed.