KR20190135825A - box - Google Patents

Abstract

The present invention relates to an insulating and fireproof corrugated packing box made of a silica aerogel powder layer, and more specifically, to an insulating and fireproof corrugated packing box made of a silica aerogel powder layer, which can maximally maintain insulation property of silica aerogel powder which is nano-porous and can improve a fireproof function by incombustibility of silica by providing insulation of the silica aerogel powder to an adhesive by using the silica aerogel powder having excellent insulation.

Description

Insulating and fire resistant cardboard packaging box made of silica airgel powder layer {box}

The present invention relates to a heat-insulating and fire-resistant corrugated cardboard packaging box consisting of a layer of silica airgel powder, and more particularly, to insulate the nano-porous silica airgel powder by giving the heat insulating property of the silica airgel powder to the adhesive using the silica airgel powder having excellent heat insulating properties. It relates to a heat insulating and fire-resistant cardboard packaging box made of a layer of silica airgel powder that can maintain the maximum properties and increase the fire resistance function due to the non-combustibility of silica.

Corrugated cardboard is produced in various cross-sections depending on the desired characteristics, but is usually made in the form of hexagonal cells or wavy bones (hereinafter referred to as "honeycomb core"). Such honeycomb cores are widely used in equipment and apparatus for high strength and light weight, in which weight to volume is reduced but rigidity is increased.

When manufacturing and fixing a honeycomb core having a hexagonal cell shape, the honeycomb core having a hexagonal cell shape cuts a liner paper corresponding to a thickness, applies an adhesive to the face of the liner paper at predetermined intervals, and then shifts the adhesive surface from each other. The honeycomb core is manufactured by joining and laminating, and the honeycomb core is stretched to the left and right, and the cardboard is attached to the stretched upper and lower surfaces.

In general, honeycomb cores are used in consideration of the strength of plywood, cardboard, bending and impact absorption, cushioning properties, as well as the interior of various panels such as office furniture, partition panels, doors or fire doors. It is a well known fact.

In the construction of honeycomb core, conventionally, laminated sheets of standard cardboard are cut into strips to form a grid, and the grids are overlapped on top and bottom to bond each other in a zigzag state at regular intervals to form a hexagonal development structure. .

In honey-chem core made of ordinary cardboard, the upper and lower grids stacked alternately are composed of single-layered cardboard with thin lamination, so that the strength of honeycomb itself is lowered and the lamination of single-layer structure is external during tensile work or storage. Deformation or tearing occurs due to the crushing of the upper and lower edge parts easily due to impact, and as a result, the hexagonal structure (honeycomb structure) of the honeycomb core is incomplete, resulting in a decrease in the strength of the honeycomb core, and a defect thereof. It is very difficult and complicated to make honeycomb core molding work by worker's handwork, and it is accompanied by a lot of labor, and its strength is weak, so it is not desirable in function or shape. It indicates a fault.

The honeycomb core grid is made of corrugated cardboard, but the honeycomb core grid is made of corrugated cardboard, but its strength and cushioning are somewhat compensated, but it is simply formed by superimposing the cardboard grid on top and bottom. The corrugated grid has a triple structure and therefore has a considerable thickness, which requires a lot of labor and labor for tensioning, which leads to poor workability. Tension force is required, and there is a closed end where the weak adhesive part of the paper glued to the bone part of the cardboard grid itself and the both ends of the bone is easily dropped or torn, resulting in a high rate of defects and a low production process. To increase production costs It shows economic factors.

Any method known generally for silica airgel powder may be used in the method for producing a heat-insulating and fire-resistant corrugated cardboard comprising a layer of silica airgel powder according to the present invention. Such airgel powders are generally prepared in a sol-gelation process. Sol-gelation processes are well known in the art for sol-gel techniques [RKColloid Chemistry of Silica and Silicates 1954, chapter 6; CJ Brinker, GW Scherer, Sol-Gel Science, 1990, Chaps 2 and 3]. That is, the airgel powder is obtained by preparing the wet gel by the sol-gelation process of the airgel powder precursor and drying the wet gel. Specifically, the wet gel is obtained by undergoing hydrolysis, condensation reaction and aging by the reaction of the aerogel powder precursor and water during the sol-gelation process. For example, hydrolysis proceeds by adding a catalyst to the aerogel powder precursor and water in an alcohol solvent, and the condensation reaction of the hydrolyzate proceeds to form a “sol” compound. In this case, the condensation reaction may be carried out in the presence of a base or an acid catalyst, but when using a metal alkoxide, it is more preferable to use a base catalyst. The solution in sol state is gelled and matured for a sufficient time to produce a wet gel.

Insulating and refractory corrugated cardboard manufacturing method of the silica airgel powder layer provided according to the present invention is significantly superior in thermal insulation performance effect compared to the prior art to prepare a thermal insulation adhesive or to add a functional mineral. In particular, while increasing the heat insulating properties of the silica airgel powder as much as possible due to the chemical properties of the non-combustible silica can increase the fire resistance. The silica airgel powder insulating corrugated cardboard according to the present invention is provided with various adhesive properties, coating properties and the like by adjusting the content of the silica airgel powder.

According to the present invention, the silica airgel powder having excellent thermal insulation property can be used to provide the thermal insulation property of the silica airgel powder to the adhesive to maintain the thermal insulation properties of the nanoporous silica airgel powder and to increase the fire resistance function due to the incombustibility of the silica. It is an object to provide a heat insulating and fire-resistant cardboard consisting of an airgel powder layer.

The present invention is a corrugated cardboard packaging box consisting of a corrugated core layer between both surface ground layers, the core core layer is made of a honeycomb core layer, the silica airgel is characterized in that the heat insulating silica airgel layer is applied inside the hexagonal honeycomb structure of the honeycomb core. It relates to a heat-insulating and fire-resistant cardboard packaging box consisting of a powder layer.

In the present invention, by adding a silica airgel powder having excellent thermal insulation, it is possible to simply configure an adhesive paste having improved thermal insulation and fire resistance, and to manufacture thermal insulation and fire resistant corrugated cardboard containing silica airgel maximizing thermal insulation characteristics.

1 is an exploded perspective view showing a cardboard packaging box of the present invention.
Figure 2 is an exploded perspective view showing a cardboard packaging box of the present invention.
Figure 3 is an exploded perspective view showing a cardboard packaging box of the present invention.
Figure 4 is an exploded cross-sectional view showing a cardboard packaging box of the present invention.
Figure 5 is an exploded cross-sectional view showing a cardboard packaging box of the present invention.
Figure 6 is an exploded cross-sectional view showing a cardboard packaging box of the present invention.
Figure 7 is an exploded cross-sectional view showing a cardboard packaging box of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in more detail the heat insulating and fire-resistant corrugated cardboard manufacturing method consisting of a silica airgel powder layer according to the present invention. In the following description of the present invention, when it is determined that detailed descriptions of related well-known technologies or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to a client's or operator's intention or custom. Therefore, the definition should be made based on the contents throughout the specification.

The present invention is a corrugated cardboard packaging box consisting of a corrugated core layer between both surface ground layers, the core core layer is made of a honeycomb core layer, the silica airgel is characterized in that the heat insulating silica airgel layer is applied inside the hexagonal honeycomb structure of the honeycomb core. It relates to a heat-insulating and fire-resistant cardboard packaging box consisting of a powder layer.

In the present invention, the heat insulating material silica airgel layer is used by mixing the heat insulating material silica airgel powder with an adhesive.

In the present invention, the adhesive is an acrylic adhesive or a starch adhesive.

In the present invention, the heat insulating material silica airgel layer is characterized by being used by mixing 20 to 90 parts by weight of silica airgel powder per 100 parts by weight of the adhesive base.

In the present invention, the heat insulating material silica airgel layer is characterized in that the heat insulating material silica airgel impregnated in the non-polar organic solvent impregnated silica airgel with a weight ratio to the organic solvent to be impregnated silica airgel 10 to 90 weight ratio.

In the present invention, the nonpolar organic solvent impregnated with the silica airgel is characterized by using a nonpolar organic solvent having no -OH group, including n-hexane, cyclohexane, DMF.

In the present invention, the insulating silica airgel layer is prepared by mixing a silica aerogel impregnated with an organic solvent with a molten polymer resin to prepare nanofibers from a polymer resin mixed with a silica aerogel to have nanometer-level pores, and the silica airgel is laminated. It is contained in the nanometer-level pores are laminated with nanofibers so as not to be separated from the pores, characterized in that the insulating material silica aerogel sheet manufactured by manufacturing a nanofiber spinneret sheet or mat.

In the present invention as shown in Figures 1 to 3, the corrugated core layer of the corrugated cardboard box consisting of a corrugated core layer between both surface layer is composed of a honeycomb core layer, the heat insulating silica airgel layer is applied to the inside of the hexagonal honeycomb structure of the honeycomb core. It is possible to maintain the thermal insulation properties of the nano-porous silica airgel powder to the maximum and to provide a heat insulating and fire-resistant corrugated cardboard consisting of a layer of silica airgel powder that can increase the fire resistance function due to the incombustibility of the silica.

In the present invention, as shown in Figures 1 to 3, the insulating silica airgel layer may maintain the thermal insulation properties of the nanoporous silica airgel powder by mixing the insulating silica airgel powder with the adhesive and increase the fire resistance function due to the incombustibility of the silica. It is possible to provide a heat insulating and fire-resistant cardboard consisting of a layer of silica airgel powder.

In the present invention as shown in Figures 1 to 3, the adhesive can maintain the thermal insulation properties of the nano-porous silica airgel powder using an acrylic adhesive or a starch adhesive, and can increase the fire resistance function due to the incombustibility of the silica. It is possible to provide a heat-insulating and fire-resistant cardboard consisting of an airgel powder layer.

In the present invention as shown in Figures 1 to 3, the heat insulating material silica airgel layer is used to mix the silica airgel powder in the adhesive base 20 to 90 parts by weight per 100 parts by weight of the adhesive of the nano-porous silica airgel powder It is possible to provide a heat-insulating and fire-resistant corrugated cardboard consisting of a layer of silica airgel powder that can be maintained as much as possible and can increase the fire resistance function due to the incombustibility of the silica.

In the present invention as shown in Figure 1 to 3, the heat insulating material silica airgel layer is a heat insulating material silica airgel impregnated with a non-polar organic solvent impregnated silica airgel expressing heat insulating properties in a 10 to 90 weight ratio by weight of the organic solvent to be impregnated with silica airgel. It can be used to maintain the thermal insulation properties of the nano-porous silica airgel powder and to provide a heat-resistant and fire-resistant cardboard consisting of a layer of silica airgel powder that can increase the fire resistance function due to the incombustibility of the silica.

1 to 3, in the present invention, the nonpolar organic solvent impregnated with silica airgel is preferably a nonpolar organic solvent having no -OH group, including n-hexane, cyclohexane, and DMF.

In the present invention, as shown in Figures 1 to 3, the heat insulating material silica airgel layer is mixed with a silica aerogel impregnated with an organic solvent with a molten polymer resin to prepare nanofibers from a polymer resin mixed with silica airgel to form pores at the nanometer level. The nano-porous material is laminated using a silica aerogel sheet manufactured by manufacturing a nanofiber spinneret sheet or mat by laminating with nanofibers so that the silica airgel is contained in the nanometer-level pores and is not separated from the pores. The thermal insulation properties of the silica airgel powder can be maintained to the maximum, and due to the non-combustibility of the silica can provide a thermal insulation and fire-resistant cardboard consisting of a layer of silica airgel powder that can increase the fire resistance function.

1 to 3, the present invention relates to a corrugated cardboard made of a heat insulating and fire resistant silica airgel powder layer made of a silica airgel powder layer.

When the silica airgel powder (density 005 ~ 03g / ml, thermal conductivity 5 ~ 30mW / mK) is mixed in the starch adhesive paste base in the present invention as shown in Figures 1 to 3, the particle size of the silica airgel powder is preferably 20㎛ to 50㎛ If the particle size is less than 20㎛, it is too light to disperse evenly in the glue pool base, and if the particle size of silica airgel powder exceeds 50㎛, the particle size is too large and the thickness of the adhesive layer is uneven at the time of adhesion, so that smooth adhesion is possible. It becomes impossible.

1 to 3, the amount of the silica airgel powder added in the present invention is preferably 20 to 90 parts by weight per 100 parts by weight of the adhesive. If the amount is less than 20 parts by weight, the thermal insulation performance does not come out properly and the silica airgel powder of When the added amount exceeds 90 parts by weight, the adhesive force of the adhesive may be too small to be impossible to install.

In addition, the starch adhesive in the present invention is a water-soluble paste prepared by mixing starch and water, so when the hydrophobic silica airgel powder is simply mixed, the silica airgel powder is not mixed, and even if floating or mixed on the top of the aqueous solution, there is a disadvantage in that it is not evenly dispersed.

Therefore, in the present invention, the hydrophobic silica airgel powder is mixed with ethanol to make a slurry, and then mixed with an adhesive to be effectively dispersed. According to the construction method, water can be conveniently added to the adhesive containing the silica airgel powder constituted by the present invention. In order to maintain the adiabatic properties of the silica airgel powder, it is necessary to use the silica airgel powder whose surface is hydrophobically modified so that the nanoporosity can be maintained as moisture does not penetrate inside the silica airgel powder when the adhesive is mixed.

The adhesive containing silica airgel provided according to the present invention can be configured in a simpler process compared to the prior art of preparing a heat insulating adhesive or adding a functional mineral, and maintaining the heat insulating properties of the silica airgel powder as it is. Maximization as well as fire resistance can be improved.

Example 1

A slurry is prepared by mixing 100 ml of ethanol with 120 g of hydrophobic silica airgel powder. After mixing 350 g of water with 200 g of starch powder, the mixture is heated to 100 ° C. for 40 minutes to make a gel state, and stirred for 20 minutes by adding silica airgel powder in a slurry state. After the stirring was cooled, 100 g of water was added as a viscosity regulator and stirred for 20 minutes until it was evenly dispersed. In order to measure the thermal conductivity of the mixed agitated mixture, a predetermined amount of agitated substance was applied to a commercially available product (30 cm × 30 cm × 1 cm), adhered, and dried to measure a thermal conductivity (hotplate). In this case, the thermal conductivity was 0049 kcal / mh, and the silica airgel adhesive layer had a thickness of 052 mm.

The present invention is composed of a heat insulating material silica airgel layer impregnated with a non-polar organic solvent silica silica gel expressing a heat insulating property in a 20 to 90 weight ratio by weight relative to the organic solvent to be impregnated with the silica air gel.

In the present invention, the nonpolar organic solvent impregnated with the silica airgel is preferably a nonpolar organic solvent having no -OH group, including n-hexane, cyclohexane, and DMF.

In the present invention, the silica aerogel impregnated with an organic solvent is mixed with the molten polymer resin to prepare nanofibers from the polymer resin mixed with silica aerogel to have a nanometer pore, and the silica airgel is the nanometer pore It is preferable to use a silica aerogel sheet prepared by laminating together with the nanofibers so as not to be separated from the pores and manufacturing the nanofiber spinnerette sheet or mat.

 <Example 2>

20 g of silica airgel is impregnated with 10 ml of DMF. Then, 1 ml of silane is added to modify the surface of the silica airgel. In addition, 34 g of PAN was completely dissolved in 15 ml of DMF, and the surface modified and silica air gel impregnated with DMF was added to the PAN solution, and stirred well to prepare an electrospinning raw material mixture. The viscosity of the raw material mixture before charging to the discharge section of the electrospinning system is maintained so that droplets can be made without exiting the discharge section. While maintaining the voltage at 30,000V, the nanospinning proceeds and the nanofibers are spun off. The thickness of the laminated fabric can be arbitrarily adjusted according to the use purpose. When the thickness of the laminated fabric is 02 ~ 05mm, the nano-spun laminated fabric is taken and dried at about 160 ° C. to obtain a silica airgel insulating sheet formed of PAN resin in which the silica airgel does not escape from the interior of the laminated fabric.

10, 10 ', 10-1: surface layer 12, 12': corrugated layer
20: honeycomb core layer 30, 40, 40 ': heat insulating material silica airgel layer

Claims (7)

In the corrugated packaging box consisting of a corrugated core layer between both surface layer, wherein the corrugated cardboard box is made of a core layer of the honeycomb core, characterized in that the heat insulating silica airgel layer is applied inside the hexagonal honeycomb structure of the honeycomb core. Insulating and fire resistant cardboard packaging box consisting of a layer of silica airgel powder. The heat insulating and fire-resistant cardboard packaging box of claim 1, wherein the insulating silica airgel layer is used by mixing the insulating silica airgel powder with the adhesive. The heat-insulating and fire-resistant cardboard packaging box of claim 2, wherein the adhesive is an acrylic adhesive or a starch adhesive. The heat-insulating and fire-resistant cardboard packaging box of claim 1, wherein the insulating silica airgel layer is used by mixing silica airgel powder in an adhesive base with 20 to 90 parts by weight per 100 parts by weight of the adhesive. The method of claim 1, wherein the insulating silica airgel layer is characterized in that the insulating silica aerogel layer impregnated in the non-polar organic solvent impregnated silica airgel with heat insulating properties in a weight ratio of 10 to 90 weight ratio of the organic solvent to be impregnated with the silica airgel. Insulating and fire resistant cardboard packaging box consisting of a layer of silica airgel powder. The method of claim 5, wherein the non-polar organic solvent impregnated with the silica airgel is n-hexane, cyclohexane, DMF, including a non-polar organic solvent having no -OH group, characterized in that the heat insulating and made of silica airgel powder layer Fireproof cardboard packaging box. The method of claim 1, wherein the insulating silica airgel layer is prepared by mixing a silica aerogel impregnated with an organic solvent with a molten polymer resin to prepare nanofibers from a polymer resin mixed with silica aerogel to have a nanometer pore and laminated Silica airgel is made of a layer of silica airgel powder, characterized in that the silica aerogel sheet is manufactured by manufacturing a nanofiber spinneret sheet or mat laminated with nanofibers contained in the nanometer-level pores so as not to be separated from the pores Insulated and fireproof cardboard packaging box.

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