KR102671294B1 - Deck load system using joint bar connection structure - Google Patents

Abstract

The present invention improves the fastening force generated between decks and prevents rotting of wooden decks by maintaining a ventilation gap between decks and joists along with the buffering function of the deck fixed on the joists. This relates to a deck load system using a joint bar connection structure that allows for delay.
In the present invention, a plurality of decks with steps formed on both sides in the width direction are arranged on a joist while maintaining mutual spacing, and a joint bar connection structure is installed on both sides of the steps between the decks to close the gap between the decks. In the deck rod system, the joint bar connection structure is: a spacer that is coupled to the side wall, step, and lower surface of the deck at both ends in the width direction of each deck, and is formed in a length corresponding to the width of the joist on which the deck rests. ; Between the deck and the deck, both sides are arranged to press the spacer toward the joist, and the fastening member penetrates and fastens to the joist, so that both sides bring the spacer into close contact with the joist, and at the same time, the decks on both sides maintain a gap with the joist and are fixed. A joint bar that makes it possible; It is configured to include; a non-slip member that is coupled to the upper part of the joint bar and performs an anti-slip function between the deck and the deck.

Description

Deck load system using joint bar connection structure}

The present invention relates to a deck load system using a joint bar connection structure.

In detail, the present invention improves the fastening force generated between the deck and the joist, and maintains a ventilation gap between the deck and the joist along with the buffering function of the deck fixed on the joist, thereby preventing rotting of the wooden deck. ) is about a deck load system using a joint bar connection structure that can delay the load.

In addition, the present invention provides a configuration to prevent the non-slip member made of rubber or soft synthetic resin disposed between the deck from slipping and at the same time prevents shrinkage and displacement, depending on the characteristics of the rubber or soft synthetic resin material. This relates to a deck rod system using a joint bar connection structure with an ultraviolet ray blocking function to delay the easy hardening period as much as possible.

In general, deck refers to a floor finishing material, and is especially applied to various fields of the landscaping industry, such as the floor of verandas and terraces, walking trails in parks, and hiking trails. Such decks are mainly made of wood (natural wood, synthetic wood, and preservative wood) among various materials, and as they are given eco-friendly characteristics, they have recently been widely constructed in various buildings and parks.

Early deck construction was mainly done by arranging multiple decks on joists made of wood or steel and fixing the decks to the joists using nails or pieces. This type of deck construction does not have a beautiful appearance after construction, and when performing maintenance, such as replacing a damaged deck, the deck must be replaced after removing nails or pieces, which causes inconvenience and waste of materials. A problem occurred.

In order to solve these problems of conventional deck construction, the present applicant applied for a patent and registered it in Korea Patent No. 10-1200830 (2012.11.07. Joint bar deck, hereinafter referred to as prior invention), which allows for easy connection of decks to decks. A joint bar deck is being proposed that can be easily replaced by removing only the parts needed for repairs.

The joint bar deck of the prior invention is "a frame provided laterally at regular intervals and having a plurality of tap holes formed at regular intervals on the upper part, a deck installed at regular intervals on the upper part of the frame and having steps formed on both sides, and A spacer installed at regular intervals between the deck and the step of the deck, a connection bracket mounted on the upper part of the spacer, a bolt coupled to a tap hole of the frame through a long hole in the spacer through a fixing hole in the connection bracket, and It consists of a “connection deck connected to the upper part of the connection bracket.”

While the joint bar deck of the prior invention allows easy deck-to-deck connection and maintenance, the disadvantage is that the fastening force with the joint bar structure is lowered when the wooden deck shrinks due to changes in external temperature. do.

In addition, since the lower surface of the deck remains in close contact with the upper surface of the joist, the wooden deck easily rots (a phenomenon in which wood rots). For example, if moisture seeps into the deck after rain, the lower surface of the deck In other words, the area in contact with the joist is not properly ventilated, causing it to rot more easily.

Meanwhile, the connecting deck of the prior invention is mainly made of rubber material and functions as a non-slip member between decks. The connecting deck mainly contracts in the longitudinal direction (contraction in the width direction is caused by external temperature conditions, etc.). (occurs slightly due to combination with the connection bracket), the end of the deck and the end of the connection deck do not match, exposing poor aesthetics. In particular, the connection deck made of rubber or soft synthetic resin hardens due to environmental factors such as sunlight/heat when used for a long period of time, causing problems such as weakening of the non-slip function or being easily damaged.

The present invention was invented to solve the above problems.

Accordingly, the present invention improves the fastening force generated between the deck and the joist, and maintains a ventilation gap between the deck and the joist along with the buffering function of the deck fixed on the joist, thereby preventing rotting of the wooden deck. The purpose is to provide a deck load system using a joint bar connection structure that can delay.

In addition, the present invention provides a configuration to prevent the non-slip member made of rubber or soft synthetic resin disposed between the deck from slipping and at the same time prevents the non-slip member made of rubber or soft synthetic resin from being shrunk and out of position, and the characteristics of the rubber or soft synthetic resin material. Another purpose is to provide a deck rod system using a joint bar connection structure with an ultraviolet ray blocking function in order to delay the easy hardening period as much as possible.

In order to achieve the above object, the present invention has the following configuration.

In the present invention, a plurality of decks with steps formed on both sides in the width direction are arranged on a joist while maintaining mutual spacing, and a joint bar connection structure is installed on both sides of the steps between the decks to close the gap between the decks. In the deck rod system, the joint bar connection structure is: a spacer that is coupled to the side wall, step, and lower surface of the deck at both ends in the width direction of each deck, and is formed in a length corresponding to the width of the joist on which the deck rests. ; Between the deck and the deck, both sides are arranged to press the spacer toward the joist, and the fastening member penetrates and fastens to the joist, so that both sides bring the spacer into close contact with the joist, and at the same time, the decks on both sides maintain a gap with the joist and are fixed. A joint bar that makes it possible; It is configured to include; a non-slip member that is coupled to the upper part of the joint bar and performs an anti-slip function between the deck and the deck.

Here, the upper part of the step of each deck is formed to have an inclined surface upward toward the end of the deck, and the point of the spacer coupled to the deck, which is coupled to the step of the deck, is formed with an inclined surface corresponding to the inclined surface of the step, so that the spacer is connected to the deck by a joint bar. When coupled, the ends of both decks are configured to generate coupling force on opposite sides.

In addition, the spacer is made of rubber or synthetic resin, the point connected to the side wall and the step of the deck is formed of a hard part made of a hard material, and the point connected to the lower surface of the deck is made of a relatively soft material. It is formed from soft parts.

Meanwhile, the joint bar is formed on both sides as a pressing part for pressing the upper part of the spacer, and a locking end is formed at the end of the pressing part for a non-slip member to be inserted and coupled, and the stiffening end is fitted and coupled to both sides of the non-slip member. A locking groove is formed to become.

In order to achieve the above other objects, the present invention has the following configuration.

When both longitudinal sides of a plurality of arranged decks are finished with a finishing material, the non-slip member is coupled to both sides of the non-slip member in the longitudinal direction, and is sandwiched between the joint bar and the finishing material to prevent shrinkage of the non-slip member in the longitudinal direction. It is composed of elements.

Additionally, the non-slip member is made of rubber or synthetic resin and is formed by mixing a UV blocker.

As described above, the present invention prevents frequent breakage by cushioning the impact generated on the deck rod by spacers formed on both sides of the deck in the width direction, and at the same time, a ventilation space is formed between the lower surface of the deck and the joist to ensure long-term use. It has the effect of delaying the decay of wooden decks and extending their useful life.

In addition, the present invention has the effect of maintaining the maximum bonding force even when the wooden deck shrinks due to external temperature changes by maintaining the bonding force on opposing sides when joining the joint bars due to the inclined surface formed on the step of the deck.

On the other hand, the present invention suppresses the shrinkage of the non-slip member due to external temperature changes by means of an anti-shrinkage member coupled to the non-slip member, thereby preventing displacement such as the end of the non-slip member not matching the end of the deck or the end being lifted. This has the effect of maintaining a more beautiful appearance.

In particular, the present invention provides an ultraviolet ray blocking function to the non-slip member to delay the curing time of the non-slip member as much as possible, thereby maintaining the member's unique function for a longer period of time and extending its service life.

Figure 1 is a perspective view of the deck load system according to the present invention.
Figure 2 is a cross-sectional view of the deck load system according to the present invention.
Figures 3a to 3c are illustrations of the construction process of the deck rod system according to the present invention.
Figure 4 is an illustration of a further embodiment of the present invention.

Embodiments of the present invention as described above will be described in detail with reference to the attached drawings.

Figure 1 is a perspective view of the deck load system according to the present invention, and Figure 2 is a cross-sectional view of the deck load system according to the present invention.

Referring to the drawing, in the deck rod system according to the present invention, a plurality of decks (2) are arranged on a joist (1) while maintaining mutual spacing, and a joint is formed between the decks (2) and the gap between the decks (2). The bar connection structure 10 is installed and configured. Here, steps 3 are formed on both sides of the deck 2 in the width direction to match the height of the upper surface of the deck 2 and the upper surface of the joint bar connection structure 10.

The joint bar connection structure 10 includes a spacer 20 coupled to the deck 2, a joint bar 30 coupled between the spacers 20, and a non-slip member 40 coupled to the joint bar 30. ).

The spacer 20 is a cover-shaped structure that is combined at both ends of each deck 2 in the width direction to surround the side wall, step 3, and lower surface of the deck 2. In particular, the spacer 20 is formed to have a length approximately equal to the width of the joist 1 on which the deck 2 is placed, so as not to waste members.

At this time, the upper part of the step 3 of each deck 2 is formed to have an inclined surface T that extends upward toward the end of the deck 2. In addition, among the spacers 20 coupled to the deck 2, the point coupled to the step 3 of the deck 2 forms an inclined surface T corresponding to the inclined surface T of the step 3.

When the inclined surface (T) formed on the step (3) of the deck (2) and the inclined surface (T) formed on the spacer (20) are joined by the joint bar (30), which will be described later, the ends of both decks (2) It is a configuration in which the bonding force is generated on the opposing sides, that is, on the inside of the gap maintained by the decks (2) on both sides, so that a more solid bonding force can be maintained even if the wooden deck (2) shrinks due to changes in season or temperature. .

In particular, the point of the spacer 20 in close contact with the lower surface of the deck 2 is configured to maintain a constant gap between the deck 2 and the joist 1. This is because a ventilation space is formed by the gap, so that the wood It is configured to delay as much as possible the point at which the deck (2) deteriorates.

Here, the spacer 20 is made of rubber or synthetic resin, and the point where it is connected to the side wall of the deck 2 and the step 3 is formed as a hard part 21, and is attached to the lower surface of the deck 2. The joining point is formed as a relatively soft part 22.

The hard part 21 is used to ensure that the spacer 20 has a high bonding force supported by the joint bar 30 after coupling it to the deck 2 (hard characteristic, in the case of soft, weak support due to soft elasticity). occurrence), and the soft part 22 is configured (soft characteristics) to enable the deck 2 to respond with considerable elasticity to impacts applied from the top when supporting the deck 2 on the joist 1. am. Accordingly, the spacer 20 can be manufactured using a profile extrusion method in order to form a double soft hard property in a single member.

The joint bar 30 is disposed between the deck 2 so that both sides press the spacer 20 toward the joist 1, that is, downward.

For this purpose, the joint bar 30 is mainly manufactured by bending a frame made of metal, and both sides are formed with pressing parts 31 for pressing the upper part of the spacer 20. The pressing parts 31 are It is a configuration that is bent while maintaining an inclined shape corresponding to the inclined surface (T) of the above-described step (3) and spacer (20).

The joint bar 30 formed in this way allows fastening members 35, such as bolts and pieces, to pass through the upper part of the cross-section at approximately the center point and fasten to the joist 1 to press the spacers 20 on both sides to secure the deck 2. It is fixed in place.

Meanwhile, a locking end 32 is formed at the end of the pressing portion 31 formed on both sides of the joint bar 30 for the non-slip member 40 to be inserted and coupled thereto.

The non-slip member 40 is coupled to the upper part of the joint bar 30 and is configured to perform an anti-slip function between the deck 2 and the deck 2. This non-slip member 40 is made of rubber or soft synthetic resin to maximize the non-slip function.

In addition, the non-slip member 40 is formed with a locking groove 41 on both sides for the locking end 32 of the joint bar 30 to be inserted into and coupled to, and penetrates the joint bar 30 when observed from above. In order to hide the installed fastening member 35 and the joint bar 30, it is preferable that the width of the upper part is at least equal to or larger than the width of the joint bar 30.

Figures 3a to 3c are illustrations of the deck rod system construction process according to the present invention.

Figure 3a illustrates a state in which spacers 20 are fitted and coupled to both sides of the deck 2, and at this time, the deck 2 and the joist 1 are maintained at a distance by the hard portion at the bottom of the spacer 20. It is a state.

Figure 3b illustrates a state in which the joint bar 30 is coupled between the deck 2 where the spacer 20 is inserted, and the joint bar 30 is fastened to the joist 1 by the fastening member 35, The spacer 20 is pressed by the pressing portions 31 on both sides of the joint bar 30, and the decks 2 on both sides are fixed in place.

Here, the fixing force of the deck 2 due to the inclined surface T of the step 3 and the spacer 20 acts in opposite directions, that is, to the inside of the mutual gap, so that the deck 2 is more firmly fixed.

Figure 3c shows a state in which the deck rod system is completed by combining the non-slip member 40 on the upper part of the joint bar 30 to close the gap between the decks 2 on both sides.

<Additional Example>

Figure 4 is an illustrative diagram of an additional embodiment of the present invention.

Referring to the drawings, the configuration of the additional embodiment is a configuration applied when both longitudinal sides of a plurality of arranged decks 2 are finished with a finishing material 4.

Specifically, the deck rod system of the additional embodiment is one in which anti-shrinkage members 42 are combined on both sides of the non-slip member 40 in the longitudinal direction, and the anti-shrinkage members 42 are connected to the joint bar 30 and the finishing material 4. ) is sandwiched between the non-slip members 40 to suppress longitudinal shrinkage.

Meanwhile, the non-slip member 40 is made of rubber or a soft synthetic resin material as in the original embodiment, and is formed by mixing a UV blocker. Therefore, the non-slip member 40 can maintain the non-slip function for a long period of time and extend its useful life by delaying hardening as much as possible due to environmental factors such as sunlight/heat.

In particular, in order to couple the non-slip member 40 and the anti-shrinkage member 42, a coupling hole 43 for coupling the anti-shrinkage member 42 is formed at the end of the non-slip member 40, and the anti-shrinkage member 42 is formed at the end of the non-slip member 40. (42) is approximately orthogonal to the hanging piece (44) sandwiched between the joint bar (30) and the finishing material (4), and is inserted into the coupling hole (43) to form a coupling piece portion (45) for providing fixing force. .

At this time, the coupling piece portion 45 is inserted into two or more coupling holes 43 formed in the non-slip member 40 to provide fastening force, and the ends and sides of the coupling piece portion 45 are provided with coupling holes of the non-slip member 40 ( 43) A locking protrusion 46 is formed to provide higher fixing force by pressing the inner wall in a wedge shape.

10: Joint bar connection structure 20: Spacer
21: hard part 22: soft part
30: joint bar 31: pressurizing part
32: Locking end 40: Non-slip member
41: Locking groove 42: Anti-shrinkage member

Claims (6)

A plurality of decks (2) with steps (3) formed on both sides in the width direction are arranged on the joist (1) while maintaining mutual spacing, and are jointed at the steps (3) on both sides between the deck (2) and the deck (2). In the deck rod system configured to have a bar connection structure (10) installed to close the gap between the decks (2),
The joint bar connection structure 10 is:
It is formed of a rubber or synthetic resin material, and is joined at both ends in the width direction of each deck (2) in a form that surrounds the side wall, step (3), and lower surface of the deck (2), thereby forming the side wall and step (3) of the deck (2). The point coupled to the step is formed of a hard part 21 made of a hard material, and the point coupled to the step 3 forming a slope T slanted upward toward the end of the deck 2 is the step 3. ) is formed with a corresponding inclined surface (T) so that a bonding force is generated on the opposite side of the ends of both decks (2), and the point where it is coupled to the lower surface of the deck (2) is relatively soft. A spacer (20) formed of a soft portion (22) made of a material and having a length corresponding to the width of the joist (1) on which the deck (2) rests;
A pressing portion 31 is formed between the deck 2 and the deck 2 to have an inclined surface corresponding to the inclined surface T of the spacer 20 to press the spacers 20 on both sides toward the joist 1. The fastening member 35 penetrates and is fastened to the joist 1, thereby bringing the spacers 20 on both sides into close contact with the joist 1, thereby maintaining the gap between the decks 2 on both sides and the joist 1. A joint bar 30 to be fixed;
At the ends of the pressing portions 31 formed on both sides of the joint bar 30, a locking groove 41 is formed for the locking end 32 to be inserted into and coupled to, and a shrinkage prevention member 42 is provided to suppress longitudinal shrinkage. A non-slip member 40 made of rubber or synthetic resin mixed with an ultraviolet ray blocker to form a non-slip member 40 coupled to the upper part of the joint bar 30 and performing an anti-slip function between the deck 2 and the deck 2; A deck load system using a joint bar connection structure comprising a. delete delete delete delete delete