KR20240094483A - Handrail Post Using Right Angle Bending Bracket for Wood Joining a Prefabricated Floor Deck - Google Patents

Abstract

The present invention improves construction quality as well as on-site constructability by assembling a binding bracket bent at a right angle to a wooden pillar made in two parts from a railing pillar of a prefabricated floor deck, which is a landscaping facility, and prevents the pillar from deforming itself immediately after construction. An exterior pillar body forming a symmetrical structure in which a pair of unit timbers are divided into two to form the exterior of the railing pillar, and forming an "ㄱ" shaped fitting groove extending in a right angle direction at both side ends to provide an exterior pillar body; A plurality of reinforcing supports are located between a pair of unit timbers in the exterior pillar body and are formed at upper and lower intervals so as to make surface contact in a face-to-face state, and are provided at both ends of the width of the reinforcement supports and are inserted into fitting grooves of the exterior pillar main body. A binding bracket including a binding piece provided for coupling, wherein the binding piece of the binding bracket is seated and coupled in a fitting groove of the exterior pillar body and extends in the same direction corresponding to the side surface of the exterior pillar body. A first connection piece is formed, a second connection piece is fastened to the fitting groove in the first connection piece and extends in a direction perpendicular to both ends of the first connection piece, and the first connection piece and the second connection piece are formed. Two-split wood joining using a right-angle bending binding bracket that is concavely formed in a "∨" cross-sectional shape along the inner border of the piece and includes a bending guide groove that guides the right-angled bending of the second binding piece with respect to the first binding piece. We provide prefabricated floor deck railing pillars.

Description

{Handrail Post Using Right Angle Bending Bracket for Wood Joining a Prefabricated Floor Deck}

The present invention relates to a bipartite wooden prefabricated floor deck railing pillar using a right-angle bending binding bracket. More specifically, the present invention relates to a bipartite wooden pillar manufactured by bending in a right angle direction in the railing pillar of a prefabricated floor deck, which is a landscaping facility. This relates to a bi-split wood combined prefabricated floor deck railing column using a right-angle bending binding bracket that improves construction quality as well as on-site constructability by assembling brackets and prevents deformation of the column itself immediately after construction.

In general, floor decks form sidewalks that allow pedestrians to move along trails located in hiking trails, parks, playgrounds, resorts, or tourist destinations, and have recently been widely constructed on terraces of country homes and pensions.

Here, the floor deck structure is made of wood with vertical floor decks laid continuously in steps, and handrails are assembled and installed on both sides of the floor deck to ensure safe walking for pedestrians.

These railings are installed at intervals in the longitudinal direction of the floor deck, but are constructed by combining a railing beam connecting the railing columns with a railing column that extends upward from the floor deck.

At this time, the railing pillar must be installed with railing beams to basically support the railing beams, must not break when a pedestrian leans on the railing beam, and must have a structure that prevents the railing beams from easily coming off.

Furthermore, wood is mainly used as a material for railing pillars to suit the floor deck.

However, due to the nature of wood, there was a problem in that it repeatedly contracted and expanded due to rainwater and moisture, causing it to burst in vulnerable areas, significantly reducing the strength of the railing pillars.

To compensate for this, high-strength metal profiles are commonly used inside wooden pillars, but the process of inserting and installing the profiles inside the wood is difficult, and there is a problem that workability and constructability are poor.

As a prior art disclosed to solve the above problems, Republic of Korea Patent Publication No. 1742245 (2017.05.25.) describes a railing pillar for a deck load, made of metal, and fixed to a yoke in the center. An outer tube insertion hole is formed into which the upper part of the pillar fixing device is fitted, and parallel protrusions are formed in parallel to each other on surfaces facing each other with respect to the outer tube insertion hole, protruding outward in both directions, and the parallel protrusions are formed to protrude outward in both directions. A first bent portion is formed at the tip by bending outward in a direction perpendicular to the parallel protrusion, and a second bent portion is formed at the tip of the first bent portion in a direction parallel to the parallel protrusion, and is formed between adjacent second bent portions. A first insertion groove is formed, and a third bend is formed by bending in the opposite direction to the first bend at a corner where the first bend and the parallel protrusion meet, and a second insertion groove is formed between the adjacent third bends. A column frame is formed in which the second insertion groove is formed on a surface corresponding to the longitudinal direction of the column frame and is formed perpendicular to the longitudinal direction of the joist; It is made of wood, and has bend fitting grooves formed on both sides, so that the bent fitting groove is inserted into the second bend, and one side is inserted into the first insertion groove, and is connected to the column frame. and; It is installed by being inserted into the second insertion groove in a vertical direction, and the distance between both ends is longer than the distance between the third bent parts to prevent horizontal separation when inserted into the second insertion groove. Vertical finishing wood on the other side is divided into a plurality of pieces and inserted vertically and spaced apart from each other; In a state where one side of the vertical finishing wood and the other side of the vertical finishing wood are combined with the column frame, the upper finishing cap is fitted and coupled to the lower inner side while receiving the top of the column frame, the one side of the vertical finishing wood, and the other side of the vertical finishing wood. Accordingly, railing pillars for deck rods that can easily construct railings of various designs and improve the durability of the railings are known.

In addition, Registered Patent Publication No. 2031078 (2019.10.04.) discloses an exterior material in which a first receiving groove is formed in the center of the interior by combining a pair of unit timbers, and a second receiving groove is formed on both sides of the interior, respectively; A first profile installed in the first receiving groove; And a second profile installed in the second receiving groove, wherein each of a pair of unit metal members is fixedly coupled to the unit wood, and the unit metal members are fixed to each other by sliding coupling with each other. The unit metal member of the second profile extends in a direction perpendicular to a first facet that is in close contact with the first receiving groove and has a fastening hole through which the fastening member is coupled to the first facet. It is formed of a second hexahedron in which an insertion portion protrudes, and a third hexahedron that is formed on one side of the first facet at a predetermined distance from the second hexahedron and has a receiving portion protruding, and a pair of the unit metal members. are arranged symmetrically to each other, and the insertion portion and the receiving portion of one unit metal member are slidably coupled in the vertical direction to correspond to the receiving portion and the insertion portion of the other unit metal member, respectively, to form a square profile shape, and the insertion portion is formed as a bar. It is formed in the shape of a bar, and the receiving part is configured to form a slot that can accommodate the bar in a slide manner, thereby reinforcing sufficient strength, making installation easy, and minimizing deformation due to moisture. Prefabricated railing posts for rods are known.

However, the above-described prior art, Patent Publication No. 1742245 and Registered Patent Publication No. 2031078, both require a lot of manufacturing and construction costs due to the excessive application of metal frames to the pillars, and require many parts at the construction site. Because it had to be assembled, not only did it take a lot of construction time, but there was a problem that constructability was poor.

In addition, in the case of Registered Patent Publication No. 1742245 among the above-described prior technologies, when processing a plurality of bends applied to a pillar frame of metal material that is bound and joined in response to the bend fitting groove in the vertical finishing wood of wood, it bends in the right angle direction. Because processing is difficult, the angle of the bend corresponding to the bend fitting groove of the wood is inclined to an obtuse or acute angle, making it difficult to assemble toward vertically finished wood, and causing self-distortion or bending of the product, which reduces durability and construction quality. There was a problem.

KR Registered Patent Publication No. 10-1742245 (2017.05.25.) KR Registered Patent Publication No. 10-2031078 (2019.10.04.)

The present invention is intended to solve the above problems, and is configured to form an integrated pillar assembly by binding a binding bracket bent in a right angle direction to a wooden pillar manufactured in two parts, thereby minimizing the manufacturing cost of the product through a simple structure. On the other hand, the purpose is to provide a bipartite wood combined prefabricated floor deck railing column using a right-angle bending binding bracket that can improve the durability and construction quality of the wood column while improving on-site construction with a simple assembly structure.

The bipartite wooden prefabricated floor deck railing pillar using a right-angle bending binding bracket proposed by the present invention has a symmetrical structure in which a pair of unit timbers are divided into two to form the exterior of the railing pillar, and extends in a right angle direction at both side ends. An exterior pillar body forming an L-shaped fitting groove; A plurality of reinforcing supports are located between a pair of unit timbers in the exterior pillar body and are formed at upper and lower intervals so as to make surface contact in a face-to-face state, and are provided at both ends of the width of the reinforcement supports and are inserted into fitting grooves of the exterior pillar main body. A binding bracket including a binding piece provided for coupling, wherein the binding piece of the binding bracket is seated and coupled in a fitting groove of the exterior pillar body and extends in the same direction corresponding to the side surface of the exterior pillar body. A first connection piece is formed, a second connection piece is fastened to the fitting groove in the first connection piece and extends in a direction perpendicular to both ends of the first connection piece, and the first connection piece and the second connection piece are formed. It includes a bending guide groove that is concavely formed in a "∨" cross-sectional shape along the inner boundary of the piece and guides right-angled bending of the second binding piece with respect to the first binding piece.

The upper and lower spacing between the plurality of reinforcement supports of the binding bracket is formed by flow holes formed through the lateral direction.

The bending guide groove of the binding bracket is formed to a depth of 1/3 to 1/4 based on the total thickness of the binding piece.

On the first binding piece, a phosphorescent pigment is applied to enable re-emission of light after accumulating sunlight and illumination light on the outer surface.

In addition, a fitting guide groove formed concavely inward on one surface corresponding to the reinforcing support portion of the binding bracket in the exterior pillar body is fitted into the fitting guide groove to elastically bind the exterior pillar body and the binding bracket. It is composed of elastic binding means for contact support.

According to the bipartite wood combined prefabricated floor deck railing column using the right angle bending binding bracket according to the present invention, the exterior column body composed of a pair of unit wood pieces is manufactured in two parts and assembled together with the binding bracket, but the binding bracket is directed toward the exterior column body. Since it is configured to be assembled in a right-angled direction, the assembly work of the handrail pillar is simple, promoting excellent on-site constructability, shortening the construction period, minimizing product manufacturing costs, promoting excellent price competitiveness of the product, and reducing construction costs. In addition, the bending processability of the product is excellent, preventing distortion or bending of the handrail pillar, and improving the durability of the product and construction quality.

1 is a perspective view showing one embodiment according to the present invention.
Figure 2 is a plan cross-sectional view showing one embodiment according to the present invention.
Figure 3 is a perspective view showing the exterior pillar body in one embodiment according to the present invention.
Figure 4 is a perspective view showing a binding bracket in one embodiment according to the present invention.
Figure 5 is a partial enlarged cross-sectional view showing one embodiment according to the present invention.
Figure 6 is a plan view showing before and after processing the binding piece of the binding bracket in one embodiment according to the present invention.
Figure 7 is a perspective view showing an elastic binding means in one embodiment according to the present invention.

The present invention includes an exterior pillar body having a symmetrical structure in which a pair of unit timbers are divided into two to form the exterior of a railing pillar, and forming an "ㄱ" shaped fitting groove extending in a right angle direction at both side ends; A plurality of reinforcing supports are located between a pair of unit timbers in the exterior pillar body and are formed at upper and lower intervals so as to make surface contact in a face-to-face state, and are provided at both ends of the width of the reinforcement supports and are inserted into fitting grooves of the exterior pillar main body. A binding bracket including a binding piece provided for coupling, wherein the binding piece of the binding bracket is seated and coupled in a fitting groove of the exterior pillar body and extends in the same direction corresponding to the side surface of the exterior pillar body. A first connection piece is formed, a second connection piece is fastened to the fitting groove in the first connection piece and extends in a direction perpendicular to both ends of the first connection piece, and the first connection piece and the second connection piece are formed. Two-split wood joining using a right-angle bending binding bracket that is concavely formed in a "∨" cross-sectional shape along the inner border of the piece and includes a bending guide groove that guides the right-angled bending of the second binding piece with respect to the first binding piece. Prefabricated floor deck railing pillars are a feature of the technical composition.

Next, a preferred embodiment of a bipartite wood-jointed prefabricated floor deck railing pillar using a right-angle bending bracket according to the present invention will be described in detail with reference to the drawings.

First, an embodiment of a bipartite wood combined prefabricated floor deck railing pillar using a right angle bending binding bracket according to the present invention includes an exterior pillar body 10 and a binding bracket 20, as shown in Figures 1 and 2. This is done.

The exterior pillar body 10 forms the overall exterior of the pillar and is composed of two unit timbers divided into two halves to form a symmetrical structure. In other words, the exterior pillar body 10 is a railing pillar composed of a pair of two unit timbers, and the pair of unit timbers is arranged and applied in a symmetrical structure.

The exterior pillar body 10 is constructed using wood. More specifically, it is possible to process and use general natural wood, and it is also possible to use synthetic wood obtained by compression molding by mixing natural wood flour (sawdust) with eco-friendly polymer resin such as polypropylene (PP) or polyethylene (PE). do.

In the above, the unit wood of the exterior pillar body 10 contains 45 to 50% by weight of dimethylcarbonate; 20 to 25% by weight of hydrodesulfurized heavy naphtha; 15 to 20% by weight of boiled linseed oil; 1 to 10% by weight of a wood impregnating agent mixed in equal weight ratios with methyl methacrylate emulsion, ammonium lauryl sufate surfactant, and polydimethylsiloxane silicone oil; 1 to 5% by weight of Cypress essential oil; 1 to 5% by weight of soybean oil fatty acid; 1-5% by weight of 1-Methoxy-2-propanol acetate; 1 to 5% by weight of inorganic bacteriocide mixed with cupric chloride powder (CuCl ₂ ) and copper sulfide powder (CuS) in a 1:1 weight ratio; 1 to 2% by weight of dioctyl phthalate desiccant; A wood oil stain composition containing 0.5 to 1% by weight of zinc pyrithione (organic bacteriocide) is used, which is impregnated, applied and dried.

Optionally, the wood oil stain composition may further include 1 to 5% by weight of TiO ₂ photocatalyst powder (titanium dioxide) with a particle size of 3 to 5 μm.

In addition, the wood oil stain composition includes at least one selected from trialkyl phosphate, alkyldiaryl phosphate, trialyl phosphate, and resorcinol bisphenyl phosphate. The composition may further include 1 to 5% by weight of a phosphorus-based flame retardant and/or an inorganic flame retardant selected from aluminum hydroxide, antimony oxide, and magnesium hydroxide.

In addition, the wood oil stain composition contains 1 to 3% by weight of ferric oxide (red) (Ferric oxide; Cas No. 1309-37-1) and ferric oxide (yellow) (Ferric oxide; Cas No. 51274-00) as inorganic pigments. -1) It may be formulated to contain an additional 1 to 3% by weight.

The exterior pillar body 10 is configured to form a flat plane or curved surface on the outer side wall surface. That is, the exterior pillar body 10 can be configured as a polyhedron with a flat side wall and a cross-sectional shape such as a square, hexagon, or octagon, and the exterior pillar body 10 has a curved side wall. It is also possible to configure the overall appearance to form a cylinder.

As shown in FIGS. 2 and 3, the exterior pillar body 10 is positioned to face each other on both sides with respect to the binding bracket 20, and the exterior pillar body 10 corresponds to the binding bracket 20. This forms a coupling groove (11).

The fitting groove 11 forms a groove extending in an “ㄱ” shape, and extends in a right angle direction to both side ends of the exterior pillar body 10, which is in contact with the surface contacting surface corresponding to the binding bracket 20. form

The fitting groove 11 is a binding seating area where the binding bracket 20 can be assembled on the outer surface of the exterior pillar body 10, and the binding bracket 20 is fitted into the inside of the external pillar main body 10. It is formed to secure a binding area where assembly is possible.

The exterior pillar body 10 has a clearance guide portion at a corner between one surface facing the binding bracket 20 and the fitting groove 11, which has an outwardly convex curved surface to enable smooth binding of the binding bracket 20. It forms (13).

The binding bracket 20 functions as a frame for a railing pillar by integrally binding and fixing the exterior pillar body 10, which is made of a pair of unit timbers.

As shown in FIGS. 2 and 4, the binding bracket 20 is located between unit timbers of the exterior pillar body 10 and is configured to make surface contact with the exterior pillar body 10 on both sides, respectively. .

As shown in [FIG. 4], the binding bracket 20 extends in the vertical and longitudinal direction corresponding to the exterior pillar body 10.

Materials that can be used for the binding bracket 20 include metal materials such as aluminum or stainless steel, or synthetic resin materials such as plastic.

As shown in FIGS. 2 and 4, the binding bracket 20 is basically formed in a straight cross-sectional shape and is provided with a plurality of reinforcing supports 21 spaced apart from each other at the top and bottom, and at both ends of the reinforcing supports 21. It constitutes a binding piece (25) that does.

The reinforcing support portion 21 is located between a pair of unit timbers in the exterior column body 10 and is provided on both sides to support the exterior column body 10 in surface contact in a face-to-face state.

The reinforcing supports 21 are formed at vertical intervals and are joined to the inner surfaces of both sides of the binding piece 25 by forming welds W, and flow holes 22 are formed laterally through the upper and lower spacing of the plurality of reinforcing supports. ) is formed.

That is, the flow hole 22 secures a space through which various components, such as bolts, wires, and horizontal railings, toward the binding bracket 20 through the exterior column body 10 can flow in the lateral direction. do.

When the flow hole 22 is configured in the binding bracket 20 as described above, it is possible to ensure smooth passage and inflow of binding means such as bolts, wires, handrails, etc., while minimizing the weight of the binding bracket 20 itself and reducing material costs. It is possible to improve the price competitiveness of the product by lowering the price.

The binding pieces 25 are provided at both ends of the reinforcing support portion 21 extending in the width direction from the binding bracket 20, and are fitted into the fitting grooves 11 of the exterior pillar body 10 to bind the binding pieces 25. A pair of exterior pillar bodies (10) arranged symmetrically with respect to the reinforcing support portion (21) of the bracket (20) are integrated and fixed together.

As shown in FIGS. 4 and 5, the binding piece 25 includes a first binding piece 25a that is seated and coupled within the fitting groove 11 of the exterior column body 10, and the exterior column body 10. A second coupling piece (25b) coupled to the fitting groove (11), and a bending guide groove (25c) formed along the inner border of the first coupling piece (25a) and the second coupling piece (25b). Compose.

The first binding piece 25a has a structure with one surface exposed on the side of the exterior pillar body 10, and is seated and coupled to the fitting groove 11 of the external pillar main body 10 to form the external pillar body 10. ) is formed to extend in the same direction corresponding to the side surface, that is, in a direction perpendicular to the reinforcement support portion 21.

A phosphorescent pigment is applied to the outer surface of the first binding piece 25a. That is, after accumulating sunlight and illumination light (for example, artificial light sources such as fluorescent lamps, incandescent lamps, mercury lamps, etc.) irradiated on the surface of the first binding piece 25a exposed to the outside, the light can be re-radiated. do.

As described above, when sunlight or illumination light is accumulated on the surface of the exposed first binding piece 25a of the binding bracket 20 and then a phosphorescent pigment is applied to enable the light to be re-radiated, the light is accumulated and then the light It is possible to improve the identification efficiency of the pillar by re-emitting light in this absent dark place.

The second connection piece 25b is formed to be fastened to the fitting groove 11 in the first connection piece 25a.

The second binding piece 25b extends in a direction perpendicular to both ends of the first binding piece 25a. That is, the first binding piece (25a) of the binding pieces (25) is directed toward the fitting groove (11) of the exterior pillar body (10), which is symmetrically disposed with respect to the reinforcing support portion (21) of the binding bracket (20). The second binding pieces 25b extending in a perpendicular direction from both ends of the unit bind and secure the pair of exterior pillar bodies 10 as one body.

The bending guide groove 25c connects the second binding piece 25b of the binding bracket 20 when bending the second binding piece 25b based on the first binding piece 25a. The piece 25b is guided to be bent at a right angle to the first binding piece 25a.

The bending guide groove 25c is formed concavely in a “∨” cross-sectional shape along the inner boundary of the first fastening piece 25a and the second fastening piece 25b.

The bending guide groove 25c of the binding bracket 20 is formed to a depth T2 of 1/3 to 1/4 based on the total thickness T1 of the binding piece 25.

In the above, when the depth (T2) of the bending guide groove (25c) is formed to a depth (T2) of less than 1/4 of the total thickness (T1) of the binding bracket (20), the second binding piece (25b) During bending processing, an obtuse angle is formed based on the first binding piece 25a, and the depth T2 of the bending guide groove 25c is 1 based on the total thickness T1 of the binding bracket 20. If formed at a depth (T2) exceeding /3, an acute angle is formed with respect to the first binding piece (25a) during bending processing of the second binding piece (25b). In this way, when the second connection piece 25b forms an obtuse angle or an acute angle with respect to the first connection piece 25a, distortion or bending of the railing pillar occurs.

In addition, in the present invention, a fitting guide groove (15) is formed on the exterior pillar body (10), and an elastic fastening means (30) is configured to elastically fit into the fitting guide groove (15).

The fitting guide groove 15 is formed concave inward on one surface of the exterior pillar body 10 corresponding to the reinforcing support portion 21 of the binding bracket 20.

The elastic fastening means 30 is fitted into the fitting guide groove 15 to maintain contact with the external pillar body 10 and the binding bracket 20, and is connected to the external pillar body 10. The brackets (20) are configured to elastically bind and support each other.

As shown in FIG. 7, the elastic binding means 30 has a cross-sectional shape of approximately "∨" and is constructed using a metal material with a certain rigidity to exhibit excellent shape restoration ability according to elasticity.

That is, according to the bipartite wood combined prefabricated floor deck railing pillar using the right angle bending binding bracket according to the present invention configured as described above, the exterior pillar body made of a pair of unit timbers manufactured in two parts is assembled together with the binding bracket, but the exterior is Since the binding brackets are configured to be assembled in a right-angled direction toward the pillar body, the assembly work of the handrail pillar is simple, promoting excellent on-site constructability, shortening the construction period, minimizing product manufacturing costs, and ensuring excellent price competitiveness of the product. It not only reduces construction costs, but also improves the durability of the product and the quality of construction while preventing distortion or bending of the handrail pillar while providing excellent bending processability.

In the above, a preferred embodiment of a bipartite wood combined prefabricated floor deck railing pillar using a right angle bending binding bracket according to the present invention has been described, but the present invention is not limited thereto and includes the claims, the specification of the invention, and the accompanying drawings. It is possible to implement various modifications within the scope, and this also falls within the scope of the present invention.

10: Exterior pillar body 11: Fitting groove
13: Gap guide part 15: Fitting guide groove
20: Binding bracket 21: Reinforcement support
22: floating hole 25: binding piece
25a: 1st connection 25b: 2nd connection
25c: Bending guide groove
T1: Thickness of binding bracket T2: Depth of bending guide groove
W: welding area

Claims (5)

An exterior pillar body forming a symmetrical structure in which a pair of unit timbers are divided into two to form the exterior of a railing column, and forming an “ㄱ” shaped fitting groove extending in a right angle direction at both side ends;
A plurality of reinforcing supports are located between a pair of unit timbers in the exterior pillar body and are formed at upper and lower intervals so as to make surface contact in a face-to-face state, and are provided at both ends of the width of the reinforcement supports and are inserted into fitting grooves of the exterior pillar main body. It includes a binding bracket comprising a binding piece provided to be coupled to it,
The binding piece of the binding bracket includes a first binding piece that is seated and coupled in the fitting groove of the exterior pillar body and extends in the same direction corresponding to the side surface of the exterior pillar body, and is connected to the fitting groove in the first binding piece. A second binding piece is bonded and connected to both ends of the first binding piece and extends in a direction perpendicular to the second binding piece, and is formed concavely in a cross-sectional shape of a "∨" shape along the inner boundaries of the first binding piece and the second binding piece. A bipartite wood combined prefabricated floor deck railing pillar using a right angle bending binding bracket including a bending guide groove that guides the right angle bending of the second binding piece based on the first binding piece.
In claim 1,
A bipartite wood combined prefabricated floor deck railing pillar using a right-angle bending binding bracket in which the upper and lower spacing of the plurality of reinforcing supports of the binding bracket is made of flow holes formed through penetrating in the lateral direction.
In claim 1,
The bending guide groove of the binding bracket is a bipartite wood combined prefabricated floor deck railing pillar using a right angle bending binding bracket formed at a depth of 1/3 to 1/4 based on the total thickness of the binding piece.
In claim 1,
A bipartite wood combined prefabricated floor deck railing pillar using a right-angle bending binding bracket that accumulates sunlight and illumination light on the external surface and then applies a phosphorescent pigment to enable re-emission of light on the first binding piece.
The method according to any one of claims 1 to 4,
A fitting guide groove formed concavely inward on one surface corresponding to the reinforcing support portion of the binding bracket in the exterior pillar body is fitted into the fitting guide groove to elastically connect and support the exterior pillar body and the binding bracket. A bipartite wood combined prefabricated floor deck railing pillar using a right angle bending binding bracket including an elastic binding means.

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