KR101095278B1 - pontoon panel and buoyant body combination method - Google Patents

Abstract

The present invention provides a marine marina structure having a sea area and a variety of facilities associated with the marine space that can anchor small vessels such as yachts, boats, etc. The present invention is made of a box-shaped float body and installed on the water and Variable panel assembly 100 and section 200, buoyancy body 300, cover made of deformable marine reinforced aluminum material, which is deformed from a conventional float comprising a connecting bracket installed at four corners of the float body. Combination panel 500, the center coupling assembly 600, three types of rotary knobs (700, 930, 420), rubber plate 920, etc. are largely composed of the inter-panel assembly for the binding of each of the variable panel assembly 100 Due to the combination of the 400 is possible endless coupling lego-type, and also easy to add and remove the section 200 is possible to adjust the buoyancy by adjusting the amount of coupling of the buoyancy body 300 to be coupled thereto Introductory, the guide rail 630 through the screw hole-type block 800 that can be moved slidingly coupled to the guard frame (110, 120) and the support frame (150, 160) coupled to it is possible to design the shape of the appearance It is characterized by.

MARINA, MULTI FLOAT, polyethylene resin (HDPE), pile, pontoon

Description

Pontoon panel and buoyant body combination method

In the marine marina structure, which has a sea area for anchoring small marine vessels such as yachts and boats and related facilities, marina provides basic facilities for anchoring and managing leisure boats and all related services. Means a comprehensive leisure facility, including accommodation and business facilities. These marina facilities use aluminum pontoons, concrete pontoons, floating pontoons, modular pontoons, cable-connected pontoons, and pile-mounted pontoons, depending on the waves of the region to be developed, the tidal currents, the types of vessels to be moored, and the purpose. We are developing and utilizing a multi-floating system made of high density polyethylene resin (HDPE) as a way to improve the economics and difficulties of construction, instead of the existing method of construction and repair using concrete structures. Increasing activities and interests are driving the demands and utilization of users. In line with the needs of this era, the present invention combines the advantages of aluminum pontoons, modular pontoons, and multi-floating systems to secure boats and yachts at sea in small marina facilities or private marina facilities, such as mooring stations, slipways, boat lifts, etc. In addition, it is about the method of combining the pontoon panel and buoyancy body 300 that can be modified and deformed buoyancy adjustment to the maximum possible aesthetic effect.

MULTI FLOAT is a highly durable modular cube made of high density polyethylene resin (HDPE) that can be combined and separated in various shapes and sizes. A system that can safely support any structure above the float. References and prior art are registered in Korean Patent Office, Utility 20-0434010 (Float assembly) 2006. 12. 8,

In the marine marina structure, which has a sea area space for anchoring small vessels such as yachts and boats, and related facilities, the existing pontoons were limited to deformation installation after installation, and MULTI FLOAT The high density polyethylene resin (HDPE) is a modular durable cube with high durability and widely used as a system that can be combined and separated in various shapes and sizes, but there are some problems as follows. First, it was not economical because buoyancy adjustment was impossible, so the same amount of buoyant body should be installed in unnecessary parts such as moving space, and it was not easy to concentrate the buoyancy according to the load when installing the floating facility on the top of the float. This means that it is not economical in terms of space utilization compared to buoyancy of buoyancy body. Second, the existing float is a simple rectangular structure, and the design of the circle or curve is restricted when designing it, so unnecessary coupling takes place, and it has been fixed by ropes or piles to fix the combined float, but the effects of waves and tides Due to the large number of damages, some of the damages or deformations occurred, the design that minimized the topography and natural influences was required to solve the installation limitations caused by the natural environment and to install in more diverse areas. In addition, after installation, when a variety of atmosphere and aesthetic changes according to the purpose of use, terrain, and class of use is required, a lot of time and economic effort was required to replace the finishing materials. In order to solve these various problems, there was a need for a structure for maritime marina.

The present invention has been made in view of the above points,

The buoyancy adjustment is implemented by configuring the buoyancy body 300 to be separated and additionally coupled to the variable panel assembly 100, which increases the utilization of the space compared to the installation quantity of the buoyancy body 300. It is possible to express the outline of the combined panel close to the curve is a screw hole block provided to adjust at least one specific portion of the four corners of the variable panel assembly 100 toward the edge of the square center and vertex of the variable panel assembly 100. It is possible by, and can minimize the impact of the flow of the tidal buoyancy body 300 is installed on the sea surface where the flow of tidal flow is severe is possible by adjusting the installation interval between the buoyancy body 300 wide, at this time, the buoyancy decrease Is partially compensated for by increasing the amount of coupling of the buoyancy body 300 to the cylindrical section joined by the bell. In addition, the crushing effect is possible by attaching the buoyancy body 300 is rotated 45 degrees when attached to the variable panel assembly 100. Coupling of the buoyancy body 300 is coupled to the cylindrical section 200 to the section coupling hole 680 of the section coupling socket 620 is coupled to the lower side of the variable panel assembly 100 and then buoyancy body ( 300) can be combined. At this time, the section 200 is configured to be capable of longitudinally extending coupling and is installed in addition to the buoyancy body 300 is installed in addition to it is possible to adjust the buoyancy of another form, and also, having a variety of colors and materials The cover 500 can be easily replaced by the rotary knob 1 700 by replacing the cover 500 when a variety of atmospheres and aesthetic changes are required according to the purpose of use and the terrain and the use layer after the installation and installation. It is possible.

By effectively adding or subtracting the combined quantity of the buoyancy body 300 where the load is concentrated, the buoyancy adjustment can be performed, thereby providing economical installation and operation;

In addition, it is possible to increase the aesthetic effect of the installation by enabling the effective installation of the non-linear river shore and coastline as a coupling structure that allows the expression close to the curve;

In addition, since the separation between the buoyancy body 300 and the variable panel assembly 100 and the size control of the variable panel assembly 100 is possible, there is an advantage that it is possible to separate storage by type during storage and easy to load during transportation;

In addition, by installing the buoyancy body 300 by rotating the 45 degrees each place where the algae is severe to reduce the flow of the structure by the algae due to the wide gap between the buoyancy body 300 and the place to block the algae, such as a playground It is characterized by the fact that it can have a partial breaking effect by combining 45 degree lines;

In addition, the cover can be easily and quickly replaced with a variety of colors and materials produced according to the needs of the user has the effect of increasing the literary aesthetic effect;

In addition, the installation of the present invention does not destroy the coastal or tidal-flat environment to minimize the environmental impact, there is an advantage that it is easy to move, remove or expand as a combined floating body;

In addition, because it consists of a simple coupling structure, endless coupling possible Lego-type, there is a feature that can be configured to maximize the creativity of the designer when combining.

First, some terms and symbols used in the pontoon panel and buoyancy coupling method and the description of the invention that can be adjusted and deformed buoyancy of the name of the present invention were used to quote the appropriate foreign language to effectively explain the advantages and functions of the invention. Some of the names in the invention that are difficult to describe are the names selected and given in the category deemed to be the most appropriate by the present inventors, and the descriptions thereof are omitted.

In more detail, the variable panel assembly 100 includes a guard frame (female) 110, an insertion hole 111, a guide bush insertion hole 112, a guard frame (male) 120, and a guide bush insertion hole 121. , Baton 130, guide bush 140, support frame (female) 150, inlet hole 151, support frame (male) 160, low head bolt 180, flanged single-ended female thread (190) It is configured to include).

In addition, the panel assembly 400 is o-ring 410, rotary knob 3 (420), handle 3 internal thread 421, round bracket 430, coupling 440, center bolt (450), coupling The fastener 460 and a screw thread 470 are configured.

In addition, the cover assembly 500 is configured to include a trek 510, a rotary knob 1 fastener 520, a rotary knob 3 fastening groove 530, the cover frame 540.

In addition, the center coupling assembly 600 is the center socket 610, the guide rail 630, block alignment pin hole 631, rubber cover 640, cover impingement 650, guide rail support frame 660, groove 670, the section coupling socket coupling thread 681, the circular protrusion 690 is first defined.

As described above, the variable panel assembly 100 installed on the upper side of the buoyancy body 300 has four angles each attached at an internal angle of 90 ° based on the center of the center socket 610 included in the variable panel assembly 100. As the screw hole type block 800 is slid through the rail grooves 670 formed on both sides of the guide rail 630, the inner corners of the four corners of the variable panel assembly 100 are adjusted to the lock holes 810. The threaded block 800 is firmly coupled to the guide rail 630 by drawing in the pin.

Guide bush insertion holes 840 of the annular shape attached to the combined screw hole block 800 and the guide bush insertion holes 112 and 121 formed in one direction of the guard frame (female) 110 or the guard frame (male) 120, respectively. Inserting the guide bushing 140 to enable physical coupling to the inserted guide bushing 140 is connected to each block to the frame, as well as performing the function as a rotation axis when moving for the deformation of the variable panel assembly 100 It is a hinge-like structure, the screw hole block 800 is moved along the guide rail 630 when the screw hole block 800 is moved, the guardrail (female) 110 or the guard frame (male) 120 are each symmetrically The guard frame (male) and the guard frame (female) located and sliding in / out movement are simultaneously performed.

The guard frame (female) 110 and the guard frame (male) 120 with the guide bush 140 as the axis, respectively, the guard frame (male) 120 in the inlet hole 111 formed in the symmetrical guard frame. This sliding movement forms the deformation of the variable panel assembly 100 and performs the function of the support frame (arm) 150, the support frame (male) 160 in the same manner, and each of the inlet hole 151 Sliding) is possible to deform the overall area of the variable panel assembly 100 overall.

On the other hand, the variable panel assembly 100 is high in hardness and strength, preferably made of light stainless steel or aluminum alloy material, and its size can be produced in a variety of sizes suitable for the application limited to the form proposed by the present invention It is not.

More specifically, the guide bush 140 is a guide bush insert formed at the end of the screw hole block 800 for coupling the screw hole block 800, the guard frame (female) 110, the guard frame (male) 120. Inserted into and fixed to each of the guide bushing insertion holes 112 and 121 formed on one side of the block 800 of the inlet 840 and the frames, the combination of the frame and the block during the sliding movement of the block 800 simultaneously performs the function of the rotation axis. Do it.

In addition, the baton 130 for preventing separation and binding of the support frames 150 and 160 in the variable panel assembly 100 is installed around the support frame (arm) 150.

On the other hand, the screw hole block 800 is a structure that is sliding to move from the four vertices of the rectangular variable panel assembly 100 to the center point of the center socket 610 is coupled to the rail groove 670 of the guide rail 630 and mediated Is installed.

Low head bolt fasteners 940 and screw hole blocks formed on one side of the support frame (female) 150 and the support frame (male) 160 for coupling the screw hole block 800 and the support frame, respectively. The lower head bolts 180 are sequentially inserted into and fastened to the screw holes 820 formed in the 800.

At this time, the plurality of low head bolts 180 and the flanged one-sided female screw 190 for fixing the same are coupled to the frame and the block at the same time when the sliding movement of the screw hole block 800 performs the function of the rotation axis.

In addition, the center coupling assembly 600 is located at the center of the variable panel assembly 100 and provides a guide rail 630 coupled to the variable panel assembly 100 by a screw hole block 800,

  Cylindrical center socket 610, the buoyancy body 300, the rubber cover 640 to prevent twisting and fixing function to facilitate the coupling of the section 200 and the buoyancy body 300, which is coupled to the screw hole block 800 The guide rail 630, the guide rail support frame 660 for the solid binding of the guide rail, cover cover impingement 650 for supporting the load of the cover assembly 500 and the circular protrusion 690.

On the other hand, the upper side of the center socket 610, the Z side is the rotation handle 1 (700), the lower side of the screw X to the section coupling socket 620 is fixed to each other by the right turning action.

The central socket 610 is formed in the inner diameter.

More specifically, the four guide rails 630 have an internal angle of 90 ° with respect to the center of the vertical side of the center socket 610 and are attached to the center of the outer diameter of the center socket 610 on the horizontal side and each guide rail 630 amount. A rail groove 670 is formed at the side to function as a sliding hole 800 through the screw hole type block 800 in the rail groove 670 when the variable panel assembly 100 is deformed.

In addition, the cover assembly 500 is located on the Z side of the upper end of the center socket 610 is fixed due to the right turn of the rotary handle 1 (700) and is supported by the cover field clamp 650, the lower end In the track 510, the rotation knob 1 fastener 520 in the center, the rotary knob 3 fastening groove 530 for the mouth of the three rotary knobs in the four corners of the square, the bottom of the water structure is installed on the top of the cover The cover frame 540 for supporting the load and preventing the torsion, which smoothly moves the cover track guide 830 formed at the top of the center of the block 800 during sliding movement of the screw hole block 800 and prevents the cover from being detached. Tracks 510 are formed and installed, respectively.

On the other hand, the cover assembly 500 is made of hard wood, hard plastic material

It is desirable to design in various colors and designs so as to make the best use of the characteristics of the present invention, which are easy to replace and disassemble, and to add aesthetic beauty with anti-slip.

In addition, the section coupling socket 620 is coupled to the X side, which is the lower side of the central socket 610, and the upper side of the E side relative to the circular projection 690 formed in the center of the cylinder is formed on the outer diameter of the cylinder and a right turn thread is formed on the F side The lower end of the cylinder is formed with a thread of the right turn in the inner diameter to serve as a coupling function between the center socket 610 and the section 200.

More specifically, the section coupling socket 620 is coupled to the top in the direction symmetrical with the form coupled to the bottom when the underwater installation of the variable panel assembly 100, the section 200 is coupled to the top of the variable panel assembly 100, At the same time, it is also possible to install a water structure having a similar coupling system.

In addition, the section 200 is capable of extending coupling with the plurality of sections 200 is installed in the center of the literature buoyancy body 300 to function as a support and is coupled to the lower end of the section coupling socket 620.

At this time, the upper side of the section 200, the outer side of the cylinder on the C side, the lower end of the rotation knob 2 (930) is fastened to the inner diameter of the cylinder so that the extension section 210 or the rotary knob 2 (930) is fastened to the D side, the screw thread is turned right Is formed.

In addition, the section 200 serves as a support for supporting the buoyancy body 300, it is preferable to manufacture a high-strength, light and reinforced marine aluminum material with high hardness and strength.

In addition, the buoyancy body 300 is installed by coupling around the combined section 200, the buoyancy body 300 is four rubber cover 640 attached to the lower end of the guide rail 630 again buoyancy body 300 It is more firmly fixed by engaging with the rubber cover inlet groove 330 formed symmetrically on the top.

In addition, the protruding portion 350 formed at the lower end of the buoyancy body 300 is introduced into the groove 910 of the rubber plate 920 to be fixed due to the right turning action of the rotation knob 2 (930) to the variable panel assembly 100 in the water phase. Function to provide buoyancy.

As described above, the section 200 and the buoyancy body 300 has a structure capable of longitudinally extending coupling to adjust the number of installation of the buoyancy body 300 and due to the coupling function of the section variable panel assembly 100 It is possible to adjust the buoyancy according to the installation load of the water structure installed on the upper side.

On the other hand, the buoyancy body 300 is filled with styrofoam therein is preferably made of polyethylene or hard plastic material that prevents water from entering the water or moisture, bad weather, but if necessary reduce the requirements of the tubular, section (200) It can be manufactured and utilized in various forms, such as an integrated buoyancy body, a buoyancy adjustment small buoyancy body for fine adjustment of buoyancy, and a underwater installation cube.

In addition, the coupling between the plurality of variable panel assembly 100 is the guide bush insertion holes 112 and 121 formed at the point where the guard frame (female) 110 and the guard frame (male) 120 are in contact with the screw hole block 800, respectively. Coupling the guide bush 140 in the form of a hinge to the shaft and the fastening hole 170 is formed in the guide bush 140 inside the fastening of each of the four adjacent variable panel assembly 100 when coupling between the variable panel assembly 100 Up to four variable panel assemblies 100 are firmly bound by engaging the fastener 440 into the hole 170 from the bottom to the top.

At this time, the center bolt (450) is provided at the center of the coupling bolt 440, the screw thread formed on the center of the center bolt (450) and the screw thread formed inside the center of the rotary knob 3 (420) is bound by the right turn turning action to bind In addition, it is possible in this way infinite coupling of the variable panel assembly 100.

On the other hand, in order to further combine the section 200 and the buoyancy body 300 to the lower end of the inter-panel coupling member 400, the coupling 440 and the center bolt (450) formed of five couplings formed in the circular bracket 430 After the insertion into the metal fastener 460, the rotary knob 3 (420) is installed in the same manner as described above, and then the panel 200 is coupled to the panel bracket 400 by combining the section 200 at the bottom of the G side of the circular bracket 430 in a right-turn direction. It also functions to couple the buoyancy body 300 to the bottom.

At this time, the o-ring 410 is attached to the lower end of the handle 420 to prevent the separation of the coupling 440 when fixing the rotary handle 3 (420).

More specifically, as described above, the buoyancy body 300 may be installed in the space below the panel coupling body 400 where the section 200 and the buoyancy body 300 have two or more variable panel coupling bodies 100 coupled thereto. By being able to additionally install the buoyancy body 300 is to have a structure that can also be installed in the longitudinal longitudinal coupling can adjust the installation quantity of the buoyancy body 300 and due to this function above the variable panel assembly 100 It is possible to adjust the buoyancy according to the installation load of the water structure to be installed.

In addition, the buoyancy body between the section 200 and the buoyancy body 300 extending from the center of the variable panel assembly 100 and the section 200 and the buoyancy body 300 installed on the lower panel between the panel assembly 400 By adding a buoyancy body 300 without a separate fixing device in the empty space (300) is not installed will have a structure capable of adjusting buoyancy.

In addition, the rubber plate 920 prevents warpage between the buoyancy body 300 and the buoyancy body 300 when the buoyancy body 300 is combined to perform a breakage prevention function of the literary buoyancy body 300, the center of the rotation handle two fasteners ( 900).

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the buoyancy panel and buoyancy body coupling method that can be adjusted and deformed according to the present invention.

In the panel for pontoons that can adjust buoyancy and deformation,

In FIG. 1, the variable panel assembly 100 installed above the buoyancy body 300 is based on B ′ and B ″ of the center socket 610 included in the variable panel assembly 100 of FIG. 14, respectively. As shown in FIG. 5A of FIG. 16, the threaded block 800 of FIG. 13 is slid through the rail groove 670 formed at both sides of the four guide rails 630 attached to the cabinet at 90 °. As shown in Figs. 5a, 5b, 5c, and 5d, after adjusting the inner corners of the four corners 1a, 2a, 3a, and 4a of the variable panel assembly 100, the variable panel assembly is deformed. The screw hole block 800 is firmly coupled to the guide rail 630 by inserting a pin into the lock hole 810 as shown in FIGS. 13 and 3B and the block alignment pin hole 631 of FIGS. 3 (b) and 4 (a) are detailed views showing cross-sections of A 'and A "in FIGS. 13 and 14, respectively.

In more detail, the lock hole 810 and the block alignment pin hole 631 are formed on both side surfaces of the guide rail 630 for deformation and fixing of the screw hole block 800 due to the internal angle adjustment of the variable panel assembly 100. Formation may be provided in accordance with the need, as a matter of course, basically two or more lock holes 810 are formed is configured to be fixed after adjusting the deformation angle of the variable panel assembly 100.

On the other hand, the guide rail 630 is a core support of the variable panel assembly 100, it is reasonable to use after manufacturing a heavy load rail with a high rated allowable moment according to the installation of the upper structure of the variable panel assembly 100.

 In addition, each guide formed in one direction of the guide bush insertion hole 840 of the annular shape and the guard frame (female) 110 or the guard frame (male) 120 attached to the screw hole block 800 coupled in FIG. Inserting the guide bushing 140 to allow the physical coupling to the bush insertion (112, 121) and the inserted guide bushing 140 is connected to each block 800, the door, the shifting of the variable panel assembly (100) Simultaneously perform the function as the axis of rotation.

On the other hand, the configuration is connected to the guide bush 140 as an axis is a structure similar to the hinge when the screw hole block 800 is moved along the guide rail 630, the guardrail (arm) 110 or the guard frame (male) 120 is a structure in which the sliding frame, the guard frame (male) and the guard frame (female) and the sliding in and out movements occur at the same time, respectively, and eventually deforms the variable panel assembly 100. Is organized in such a way that

In addition, the support frame (female) 150 and the support frame (male) 160 coupled as shown in FIG. 3A in FIG. 12 are also slidably moved in the respective inlet holes 151, respectively. FIGS. 5B, 5C, and 5D of FIG. It is configured to allow deformation of the overall variable panel assembly 100 upper area, such as).

At this time, the part of the guard frame and the supporting frame that is physically contacted during the sliding movement of male and female is the structure of drawing in and out without additional devices such as balls, roller balls, and wheels. Reveal it.

On the other hand, the variable panel assembly 100 can be manufactured in various sizes suitable for the purpose and is not limited to the size and shape shown in the drawings.

 More specifically, the guide bush 140 in FIGS. 13 and 14 is a screw hole block of FIG. 13 for coupling the screw hole block 800 with the guard frame (female) 110 and the guard frame (male) 120. The guide bush insertion hole 840 formed at the end of the 800 and each of the guide bush insertion holes 112 and 121 formed at one side of the block 800 side of the frames are inserted and fixed, so that the frame and the block are coupled during the sliding movement of the block 800. Simultaneously performs the function of the rotating shaft.

More specifically, the lower head bolts formed on one side of the support frame (female) 150 and the support frame (male) 160 for coupling the screw hole block 800 and the support frame in FIGS. 13 and 14, respectively. The low head bolt 180 is sequentially inserted into and fastened to the screw hole 820 formed in the fastener 940 and the screw hole block 800.

At this time, the plurality of low head bolts 180 and the flanged one-sided female thread 190 for fixing the same also perform the function of the frame and block coupling and rotation axis when sliding the screw hole block 800.

In more detail, each arrow (1, 2, 3, 4) in FIG. 9A of FIG. 20 indicates that the vertex A ″ of the variable panel assembly 100 is the screw hole block 800 and the guide rail 630. When the sliding movement to the center of the rectangular variable panel assembly 100 by the movement direction of the frame, respectively, arrows (5, 6) is the movement direction of the screw hole-type block 800 when moving in the direction 5, 1, 4 times Arrows indicate the direction of the guard frame (male) 120 and arrows 2 and 3 indicate the direction of movement of the guard frame (female) 110.

In more detail, as the variable panel assembly 100 is deformed as described above, a circular configuration is possible when the plurality of variable panel assembly 100 is coupled as shown in FIG. 26, which proves that the irregular shoreline also has a soft curved configuration. have.

Deformation characteristics of the variable panel assembly 100 due to the function and coupling structure of the above components is not limited to 90 degrees of the rectangular interior of the variable panel assembly 100, the plurality of variable panel assembly 100 is modified by combining It is noted that the overall outline coupled by the variable panel assembly 100 can be transformed into a circular and curved coupling structure that is not limited to 90 degrees.

Meanwhile, in FIG. 14, the center coupling assembly 600 is located at the center of the variable panel assembly 100 and provides a guide rail 630 configured to couple the screw hole block 800 to the variable panel assembly 100. Cylindrical center socket 610 to facilitate section 200 and buoyancy body 300, rubber cover 640 to prevent and fix the buoyancy body 300, coupled with the screw hole block 800 of the The guide rail 630, the guide rail support frame 660 for the solid binding of the guide rail, cover cover impingement 650 for supporting the load of the cover assembly 500 and the circular protrusion 690.

In more detail, the upper side of the center socket 610 in FIG.

The same threaded handle 1 (700), the lower end of the X side section coupling socket 620 as shown in Figure 6 is formed in the inner diameter of the central socket 610 of FIG. FIG. 2D shows the rotation handle 1 perspective view, FIG. 2E shows the top view, FIG. 2F shows the side view, FIG. 6 shows the section coupling socket detail view, and FIG. 2I shows the section coupling socket perspective view, FIG. 2j) shows a plan view, and FIG. 2k shows a side view. However, these drawings are for illustrative purposes only and the present invention is not limited thereto.

In more detail, the threads formed on the inner diameters of the Z side, which is the upper end of the center socket 610, and the X side, which is the lower end, are formed symmetrically with each other.

On the other hand, the cylindrical center socket 610, the upper side of the socket 610, the Z side is removed after the removal of the rotation handle 1 (700) when installing the water structure and the marina facility, the section coupling socket 620 is added to the media, various support devices Right turn threads are formed for installation.

At this time, the four guide rails 630 in FIG. 14 have an internal angle of 90 ° with respect to the vertical centers of the central sockets 610 and B 'and B ", and are attached to the center of the outer diameter of the central socket 610 to the horizontal side. Rail grooves 670 are formed on both side surfaces of the guide rail 630 as shown in FIG. 4A, and when the variable panel assembly 100 is deformed, the screw hole blocks 800 of FIG. 13 are slid through the rail grooves 670. It will function.

In addition, the cover assembly 500 of FIG. 11 is located at the upper side of the center socket 610 of FIG. 14 at the Z side and is fixed due to the right-turning action of the rotation knob 1 (700) of FIG. Supported by the impeller 650, the track 510 at the lower end, the rotary knob 1 fastener 520 in the center, the rotary knob 3 fastening groove 530 for the mouth of the rotary knob 3 in the four corners of the square The cover frame 540 for preventing the load support and torsion of the water structure installed on the top of the cover, the lower end of the cover track guide 830 formed at the center of the block 800 during sliding movement of the screw hole block 800 The track 510, which functions to smoothly move and prevent the cover from being separated, is formed and installed as shown in FIG. 11, respectively. FIG. 11 is a detailed view of the cover, and FIG. 2v shows a rear view of the cover assembly 500, FIG. ) Shows a top view, and FIG. 2 (x) shows a side view.

6 is a detailed view of the section coupling socket, the section coupling socket 620 is coupled to the X side which is the lower side of the central socket 610 of FIG. 14 and the upper side of the circular protrusion 690 formed at the center of the cylinder. In the outer diameter of the cylinder is formed a right turn thread and the lower end of the cylinder on the F side is formed a right turn thread in the inner diameter to function as a coupling between the center socket 610 and the section 200, Figure 2i is a perspective view of the section coupling socket (2j) shows a plan view, and (2k) shows a side view, respectively.

More specifically, the section coupling socket 620 is coupled to the top of the variable panel assembly 100 in the symmetrical direction and the shape coupled to the upper end of the variable panel assembly 100 when the underwater installation of the variable panel assembly 100, the upper portion of the variable panel assembly 100 Edo section 200 is coupled, and at the same time is also provided to enable the installation of a water structure having a similar coupling system.

In addition, FIG. 5 is a detailed view of the section 200, the section 200 is capable of extending coupling with the plurality of sections 200 is installed in the center of the literature buoyancy body 300 to function as a support and the lower portion of the section coupling socket 620 In combination, Fig. 2g shows a section side view and Fig. 2h shows a perspective view, respectively.

At this time, FIG. 5 is an extension section 210 as shown in FIG. 27 or a rotation knob 2 as shown in FIG. 930 is a right turn screw thread is formed in the inner diameter of the cylinder.

In addition, the buoyancy body 300 as shown in FIG. 10 is supported by being coupled around the combined section 200, and the fixing of the buoyancy body 300 is four rubber covers attached to the lower end of the guide rail 630 of FIG. 640 is formed symmetrically on top of the buoyancy body 300 and eight rubber cover inlet grooves 340 and protrusions 330 having an internal angle of 45 degrees are engaged with each other, and FIG. 10 is a detailed view of the buoyancy body 300. As shown in FIG. 2Q, the buoyancy body 300 is a perspective view, FIG. 2R is a plan view, and FIG. 2S is a side view of the buoyancy body 300.

In more detail, in FIG. 10, the protrusion 350 formed at the lower end of the buoyancy body 300 is introduced into the groove 910 of the rubber plate 920, and is fixed due to the right turning operation of the rotation knob 2 930 as shown in FIG. 3. FIG. 2q is a perspective view of the buoyancy body 300, FIG. 2r is a plan view, and FIG. 2s is a side view.

At this time, the section 200 and the buoyancy body 300 has a structure capable of longitudinally extending coupling as shown in Figure 27 to adjust the number of installation of the buoyancy body 300 as shown in Figure 23 and the extension coupling function of such a section As a result, the buoyancy can be adjusted according to the installation load of the water structure installed above the variable panel assembly 100.

On the other hand, in Figure 23 (12a) is a buoyancy adjustment in the state coupled with one buoyancy body 300, 1 (1, 2, 3, 4) in the center of the four variable panel assembly 100, respectively; The buoyancy body 300 (B) is coupled to the bottom of the panel-to-panel assembly as shown in FIG. 7, and the buoyancy body 300 (1, 2, B), (3, 4, B) is respectively coupled without a separate coupling device. Two buoyancy bodies 300 (A, C) that combine in a fitting manner are combined.

Also, in FIG. 23, FIG. 12B is a diagram for adjusting buoyancy in a state in which one buoyancy body 300, 5 (5, 6, 7 and 8) is coupled to the center of the four variable panel assembly 100, respectively. The buoyancy body 300 (E) is coupled to the bottom of the panel-to-panel assembly as shown in FIG. 7, and the buoyancy body 300 (5, 6, 7, 8, E) is coupled to each other without a separate coupling device between the coupling. Four buoyancy bodies 300 (D, F, G, H) are combined.

More specifically, in Fig. 23, a 'and a "are dividing lines for dividing Figs. 12a and 12b, and Fig. 12a is a lower load and Fig. 12b is a buoyant body for supporting a heavy load. It can be seen as an example of coupling 300. At this time, when the buoyancy body 300 is coupled to the first buoyancy body 300, the number 1, 3 or more, as shown in Fig. 27 to endure a very high load It has a high load coupling structure.

In addition, the buoyancy body 300 is configured such that the center line C ″, C 'inner angle can be rotated 45 degrees as shown in FIG. 20, which is a rubber cover inlet groove 340 formed on the buoyancy body 300 is a guide rail ( 630, the protrusion 330 formed at the lower end of the buoyancy body 300 is coupled to the groove 910 formed on the rubber plate 920, respectively, to the rubber cover 640 attached to the lower end thereof, as shown in FIG. 20B. (Left, Right) After rotation, fixed installation is possible.

In more detail, the rotation coupling function of the buoyancy body 300 allows the buoyancy body 300 to be installed by rotating the buoyancy body 300 by 45 degrees at the time of installation of the present invention, where the tide is severe as shown in FIG. 24. Due to the gap formed between them, the flow of the structure by the algae (A, arrow) is reduced, and the place where the algae should be blocked, such as a playground, is rotated by 45 degrees as shown in Fig. 25 (A, arrow). It is configured to have a breaking effect. On the other hand, (9a) of FIG. 20 shows the state before rotation which did not rotate the buoyancy body 300. FIG.

In addition, as shown in Figures 18, 19, 21, 22, the coupling between the plurality of variable panel assembly 100 is shown in Figure 13

As shown in the guide frame insertion hole 112, 121 formed at the point where the guard frame (female) 110 and the guard frame (male) 120 is in contact with the screw hole block 800, respectively, the hinge hinge around the guide bush 140 (7a) is a detailed view of the circular bracket and the fitting, Figure 10a is a perspective view of the four variable panel assembly 100 is modified to combine.

In addition, a fastening hole 170 is formed in the guide bush 140, and thus, four fastening holes 170 are formed in each of the four adjacent fastening panel 170 when the variable panel assembly 100 is coupled to each other as shown in FIG. 18. Up to four variable panel assemblies 100 are engaged as shown in FIG. 19 by fastening the coupling bar 440 as shown in FIG. 7 in which two protruding cylinders are joined from the lower side to the upper side.

More specifically, the center of the coupling bolt 440 as shown in Figure 7 is provided with a center male bolt 450, the screw thread formed on the center of the center male bolt 450 and the screw thread formed inside the center of the rotary knob 3 (420) (421) ) Is coupled to the coupling 440 by the right turn

A maximum of four variable panel assemblies 100 are continuously connected to one set of the panel assembly 400 so that infinite coupling is possible. FIG. 7 is a detailed view of the assembly between the variable panel assemblies 100 and FIG. The perspective view of the assembly between the variable panel assembly 100, Figure 2m is a side view, Figure 2n is a plan view, respectively.

Meanwhile, in order to further combine the section 200 and the buoyancy body 300 at the lower end of the inter-panel assembly 400 as shown in FIG. 19, the circular bracket 430 as shown in FIG. 7 may be additionally installed.

The additional installation of the circular bracket 430 is rotated after pulling the coupling 440 and the center bolt (450) into the five coupling fasteners 460 formed in the circular bracket 430 from the lower side to the upper side as shown in FIG. It is fastened by installing the handle 3 (420) and Fig. 8A shows a detailed view of the interlocking panels. However, these drawings are for illustrative purposes only and the present invention is not limited thereto.

More specifically, the buoyancy body 300 is also coupled to the bottom of the inter-panel assembly 400 by combining the section 200 to the bottom of the round bracket 430 G side of the inter-panel assembly 400 fastened as described above. It is configured to be installed as shown in FIG.

In addition, the o-ring 410 is configured at the bottom of the handle 420 as shown in Figure 8 to prevent the separation of the coupling 440 when fixing the rotary knob 3 (420).

In addition, the rubber plate 920 as shown in FIG. 9 prevents warpage between the buoyancy body 300 and the buoyancy body 300 when the buoyancy body 300 is coupled to prevent breakage of the buoyancy body 300 and the section and rotation knob 2 fastening. Is configured to include a groove 910, the rotary knob 2 fastener (900).

The present invention can be combined with a simple structure and principle, allowing small-scale marina facilities such as fish tanks, river banks, dams, etc., and being manufactured in various sizes, which can be utilized as portable and largely pontoon bridges. It is possible to develop underwater structures with various accessories and water structures connected to it, cubes for underwater installation, and variable panel combinations that can be combined with them.

1 is a perspective view of all the configurations of the present invention assembled

Figure 2 is an assembly view showing an embodiment according to the present invention

Figure 3 is a rotary knob 2

4 is a rotation knob 1 detail view

5 is a section detail view.

6 is a detailed view of the section coupling socket

7 is a detailed view of the panel-to-panel assembly

8 is an assembly view between the panel assembly showing an embodiment according to the present invention

9 is a perspective view of the rubber plate

10 is a buoyancy body detail view

11 is a cover detail view

Figure 12 is a variable panel assembly assembly showing one embodiment according to the present invention

Figure 13 is a block assembly diagram showing an embodiment according to the present invention

Figure 14 is a perspective view of the center coupling assembly showing one embodiment according to the present invention

15 is a cross-sectional view in which all the configurations of the present invention are assembled.

Figure 16 is a plan view of four variable panel assembly showing an embodiment according to the present invention

17 is a cover assembly showing an embodiment according to the present invention

18 is a buoyancy body assembly showing an embodiment according to the present invention

19 is a perspective view of the combined buoyancy body showing an embodiment according to the present invention

20 is a bottom view of two buoyancy bodies showing one embodiment according to the present invention;

21 is a plan view of the modified four panels of the present invention combined

Figure 22 is a perspective view of a plurality of buoyancy body combined showing an embodiment according to the present invention

Figure 23 is a bottom view showing the buoyancy additional coupling in the configuration example according to the present invention

Figure 24 is a bottom view showing the flow of algae in the configuration example according to the present invention

25 is a bottom view showing the breaking effect in the configuration example according to the present invention

Figure 26 is a plan view showing a circular coupling state in the configuration example according to the present invention

Figure 27 is a perspective view of the buoyancy additional coupling state in the configuration example according to the present invention

<Code Description of Main Parts of Drawing>

A ', A "in Fig. 3: rotation knob 2 centerline,

             A: coupling direction coupled to the lower end of the section 200

4, B ', B ": rotation knob 1 centerline,

             B: coupling direction coupled to the upper side of the center socket 610

In Figure 5 C: the direction coupled to the section coupling socket 620,

          D: coupling direction in which the extension section 210 is coupled

E in Figure 6: the coupling direction is coupled to the lower side of the central socket 610

          F: engagement direction in which the section 200 is coupled

E ′, E ″ in FIG. 7: centerline of the panel assembly 400

              G: engagement direction in which the section 200 is coupled

10 in the phase: direction coupled to the variable panel assembly 100 side

          Lower: direction in which the auxiliary buoyancy body 310 is coupled

14, B ', B ": centerline of the center coupling assembly 600

         A ', A ": Cutting line of the guide rail 630

            Z: direction of engagement with the rotary knob 1 (700)

            X: direction in which the section coupling socket 620 is coupled

16, A ', A ", B', and B": left and right center lines of the variable panel assembly 100, respectively.

         1a, 2a, 3a, 4a, 1b, 2b, 3b, 4b, 1c, 2c, 3c, 4c, 1d, 2d, 3d, 4d: vertices of variable panel assembly 100

20, c, c ", e ', e": the center line of the variable panel assembly 100

                 c ': baseline rotated 45 degrees from the middle wire

           Arrows 1, 2, 3, 4: Direction of frame movement when panel deformation

           Arrow 5, 6: Direction of movement of the screw hole block 800 during panel deformation

1, 2, 3, 4, 5, 6, 7, 8: buoyancy body installed in the center of the panel in FIG.

          B, E: buoyancy body coupled to the lower panel coupling member 400

         A, C, D, F, G, H: buoyancy bodies joined together in a fixed buoyancy body

(A) in Figs. 24 and 25: direction of birds

U ', U "in FIG. 27: centerline

               1: buoyancy body 300

            2, 3: added auxiliary buoyancy body 310

100: variable panel assembly, 110: guard frame (female), 111: inlet hole, 112: guide bush insertion hole, 120: guard frame (male), 121: guide bush insertion hole, 130: baton, 140: guide bush, 150: Support frame (female), 151: inlet hole, 160: support frame (male), 180: low head bolt, 190: flanged one-sided female thread, 400: inter-panel assembly, 410: o-ring, 420: rotary knob 3, 421: handle 3 internal thread, 430: round bracket, 440: fastener, 450: center bolt, 460: fastener, 470: thread (470), 500: cover fastener, 510: trek, 520: rotary knob 1 fastener, 530: rotary knob 3 fastening groove, 540: cover frame, 600: center coupling assembly, 610: center socket, 630: guide rail, 631: block fitting pin hole, 640: rubber cover, 650: cover clamp, 660: guide rail support frame, 670: groove, 681: thread for joining the section coupling socket, 690: circular projection, 200: section, 210: extension section, 300: buoyancy body, 310: auxiliary buoyancy body, 320: section inlet, 330: Protrusion, 340: Rubber cover recess, 700: Rotating handle 1, 710: O-ring, 720: Rotating handle coupling thread, 800: Screw hole block, 810: Locking hole, 820: Screw mounting hole, 830: Covering track Guide, 840: guide bush insert, 900: rotary knob 2 fastener, 910: groove, 920: rubber plate, 930: rotary knob 2, 940: low head bolt fastener

Claims (8)

In the marine marina structure having a sea area and a variety of facilities associated with it can be anchored small marine vessels such as yachts, boats, It is installed on top of the buoyancy body 300 and has a square plane, but four screw hole blocks 800 attached to the four edge portions are coupled by the guide rail 630 so as to be slidably movable toward the center of the tetrahedron. Variable panel assembly 100 that can be; Guide bush inserting hole 840 of the ring shape attached to the screw hole block 800, The guide frame insertion slots 112 and 121 are formed in the direction of contact with the threaded block 800 of the guard frame (female) 110 or the guard frame (male) 120, and the interframe coupling is introductory, variable panel assembly ( 100) a guide bush 140 for simultaneously performing a function as a rotation axis when the screw hole block 800 for deformation; When the screw hole block 800 is moved, the screw hole block 800 is along the guide rail 630, and the guardrail (female) 110 or the guard frame (male) 120 are respectively symmetrical guard frames (male) and The sliding in and out movement is simultaneously performed through the inlet hole 111 formed in the guard frame (arm), Support frame (female) 150, support frame (male) 160 with a flanged single-ended female screw 190 coupled to a plurality of screw mounting holes 820 formed in the screw hole block 800 as an axis It is also coupled through each of the inlet holes 151, It is installed in the center of the variable panel assembly 100, and the upper portion of the coupling section 620 and the rotary knob 1 (700), the lower side of the coupling section 620 to install the thread (681, A center socket 610 formed symmetrically with each other; Four guide rails having an internal angle of 90 ° with respect to the center of the center socket 610 and attached to the horizontal side; The side where the section 200 is coupled to couple the section 200 to the center socket 610 is the inner diameter of the cylinder, the side to which the center socket 610 is coupled to the outer diameter of the cylinder thread (680, 620) for coupling, respectively A section coupling socket 620 formed to be coupled to the upper and lower portions of the variable panel assembly 100; The side coupling socket 620 is coupled to the outer diameter of the cylinder side, the extension section 210 is coupled to the inner diameter of the cylinder threaded pontoon section 200, respectively; A buoyancy body 300 that provides buoyancy to the variable panel assembly 100; Rotating handle 1 (700) for fixing the cover assembly 500; A cover assembly 500 installed at the center of the variable panel assembly 100 and configured to be easily attached and detached by the rotation knob 1 700; In order to protect the buoyancy body 300, there are eight grooves 910 installed below the buoyancy body 300 and between the buoyancy body 300 and the buoyancy body 300 and formed at intervals of 45 degrees in the circumferential direction, respectively. A rubber plate formed on the upper side; A circular bracket 430 installed to further couple the section 200 and the buoyancy body 300 to the lower end to which the plurality of variable panel assemblies 100 are coupled; Further installation of the circular bracket 430, the coupling knob 440 and the center number bolt 450 is introduced into the five coupling fasteners 460 formed in the circular bracket 430 from the lower side to the upper side and then rotate the handle 3 ( By installing 420, Panel for buoyancy adjustment and deformable, characterized in that it comprises a rotary knob 2 for the simultaneous fixing of the section 200 and the rubber plate 920. delete According to claim 1, The buoyancy body 300 is a cylindrical section inlet 320 is formed in the center of the hexahedron to be coupled to the section 200, the circumferential direction on the upper side to which the variable panel assembly 100 is coupled Along the buoyancy adjustment and deformable pontoon panel, characterized in that the eight rubber cover inlet grooves 340 formed at intervals of 45 degrees each, the lower side has eight projections 330 formed at intervals of 45 degrees, respectively. According to claim 1, wherein the inter-panel assembly 400 is the four cylindrical coupling fasteners 440 and the center male bolt 450 in the fastening holes 170 of each of two or more adjacent variable panel assembly (100) A screw thread 421 formed in the center of the rotary knob 3 420 by entering from the lower side to the upper side is fastened by a screw thread formed at the upper end of the center male bolt 450 and a right turn operation to one set of the panel assembly 400. Buoyancy adjustment and deformable pontoon panel, characterized in that up to four variable panel assembly 100 is bound, A section 200 coupled with the section coupling socket 620 coupled to the lower end of the center socket 610; Buoyancy body 300 is coupled to the fitting form in the coupled section 200 as described above;  A section 200 coupled to the lower end of the circular bracket 430 to which the plurality of variable panel assemblies 100 are coupled; Buoyancy body 300 is coupled to the fitting form in the coupled section 200 as described above;  In the coupling method coupled to the lower end portion of the buoyancy body 300, coupled as described above in the order of the rubber plate 920, the rotary knob 2 (930), due to the right turn rotation, The symmetrical coupling with the section coupling socket 620 and the section 200 coupled to the lower end of the center socket 610 is characterized in that it is configured to couple the buoyancy body 300 to the top of the variable panel assembly 100 Buoyancy coupling method, The buoyancy coupling method according to claim 5, characterized in that the buoyancy body (300) is configured to be further coupled and removed by extending the extension section in the section (200). The buoyancy body coupling method according to claim 5, wherein the buoyancy body (300) is coupled by rotating by 45 degrees. According to claim 5, Buoyancy method, characterized in that the section 200 can be coupled to the top of the variable panel assembly 100,

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