KR102701025B1 - An equipment for connecting profiles - Google Patents

Abstract

One aspect of the present invention provides a profile connecting device, comprising: a first connecting member including a first receiving portion formed of a pair of mutually opposing plates, a first connecting portion formed of a plate connecting one end of the first receiving portion, and a first fastening portion protruding from one side of the first connecting portion on the opposite side of the first receiving portion; a second connecting member including a second receiving portion formed of a pair of mutually opposing plates, a second connecting portion formed of a plate connecting one end of the second receiving portion, and a second fastening portion protruding from one side of the second connecting portion on the opposite side of the second receiving portion; and a first connecting member including a coil spring connected to the first and second fastening portions to interconnect the first and second connecting members; wherein outer peripheral surfaces of the first and second fastening portions are connected to inner peripheral surfaces of one end and the other end of the coil spring, respectively.

Description

{AN EQUIPMENT FOR CONNECTING PROFILES}

The present invention relates to a profile connecting device, and more specifically, to a profile connecting device that can effectively buffer external force applied to a floating solar power generation facility for a long period of time, can be easily connected, and can reduce the cost required for manufacturing.

A solar power plant is a collection of structures in which multiple solar modules are connected in series or parallel. These solar power plants are generally installed on land, which requires enormous land purchase and construction costs, and since they are mostly built by cutting down hillsides, the environment is destroyed. In addition, if installed on land, the solar modules are heated by geothermal heat in the summer, and they cannot be cooled effectively, which is a factor that reduces the power generation efficiency of the solar modules.

To solve this problem, floating solar power generation systems are being developed that install solar modules on water surfaces such as lakes, rivers, ponds, dams, and oceans. These floating solar power generation systems are power generation systems that utilize multiple floating structures with multiple solar modules installed on the water surface along with buoys.

The above floating structures should be firmly connected and fastened to each other. The above floating structure may include a main buoyancy body for fixing a solar module that floats on the water surface while fixing the solar module, and, if necessary, may further include an auxiliary buoyancy body installed on the water surface to supplement the buoyancy of the main buoyancy body and allow a worker to move around the solar module. In this case, adjacent individual buoyancy bodies and/or unit units including two or more buoyancy bodies may be directly connected to each other, or may be connected and fastened to each other by a connecting member for interconnecting support members such as profiles fixed on the buoyancy bodies.

When such floating solar power generation systems are applied to the sea, the load applied to the buoyancy body supporting the solar modules may increase relatively significantly depending on climate change, wave strength, height, etc., compared to when applied to fresh water such as lakes and reservoirs. Accordingly, there is a risk that the buoyancy body, which is usually made of plastic or synthetic resin, may be broken or damaged by external impacts such as waves. In addition, when the buoyancy body is significantly broken, the buoyancy and supporting force provided to the solar module may be lost, causing the solar module to become submerged.

A method of connecting unit units including two or more buoyant bodies using a simple connecting member in the form of a conventional single rod has been proposed. However, this type of connecting member has the problem of being easily broken because it cannot accommodate relative vertical displacement, horizontal displacement, and rotational displacement between unit units that inevitably occur due to external forces such as waves and wind.

Korean Patent Registration Nos. 10-1929428 and 10-2255890 disclose a unit unit connecting bracket that can actively accommodate relative vertical displacement, horizontal displacement, and rotational displacement between unit units, and can mitigate, absorb, and block shock transmitted between unit units to reduce accumulated fatigue load.

However, the coil spring here is essentially a compression spring, and while such a compression spring can appropriately respond to pressure among external forces applied to adjacent units, it is difficult to respond to tension, and since the compression spring allows a certain pitch or lead, the guide pin, etc. provided inside the compression spring is exposed to the outside through this, and the guide pin, etc. can easily be corroded or damaged by moisture, salt, etc.

In addition, since the connection between two adjacent brackets depends only on separate components such as bolts and coil springs interposed therebetween, and in particular, since both ends of the coil spring are simply inserted into a low-friction component made of polypropylene material and connected to the bracket, if unnecessary clearance occurs between the coil spring and the low-friction component or the low-friction component is damaged, the two unit units to which each bracket is connected are completely separated, and if the irregular floating or mooring state of the separated unit units continues, the separated unit units must be relocated and rearranged to their original positions before repairing or replacing the bolts, coil springs, etc., so there is a problem of reduced maintainability.

The present invention is to solve the problems of the prior art described above, and an object of the present invention is to provide a profile connecting member and a connecting structure including the same, which can effectively buffer external force applied to a floating solar power generation facility for a long period of time, can be easily connected, can reduce the cost required for manufacturing, and can improve maintainability.

One aspect of the present invention provides a profile connecting device, including: a first connecting member including a first receiving portion formed of a pair of mutually opposing plates, a first connecting portion formed of a plate connecting one end of the first receiving portion, and a first fastening portion protruding from one side of the first connecting portion on the opposite side of the first receiving portion; a second connecting member including a second receiving portion formed of a pair of mutually opposing plates, a second connecting portion formed of a plate connecting one end of the second receiving portion, and a second fastening portion protruding from one side of the second connecting portion on the opposite side of the second receiving portion; and a first connecting member including a coil spring connected to the first and second fastening portions to interconnect the first and second connecting members; wherein outer peripheral surfaces of the first and second fastening portions are connected to inner peripheral surfaces of one end and the other end of the coil spring, respectively.

In one embodiment, the coil spring may be a tensile spring.

In one embodiment, the inner diameter of the tension spring may be reduced by the tensile behavior of the tension spring, thereby strengthening the connection between the first and second fastening portions and the tension spring.

In one embodiment, the first and second connecting members include first and second connecting holes, respectively, and the first and second fastening members are cylinders formed with both ends open coaxially with the first and second connecting holes, respectively, and further include a second connecting member connecting the first and second coupling members along the inner side of the coil spring, and one end and the other end of the second connecting member can be installed to penetrate the interior of the cylinder and the first and second connecting holes, respectively.

In one embodiment, the second connecting member may include one selected from the group consisting of a chain, a pin, a rod, a bar, a pipe, and a combination of two or more thereof.

In one embodiment, the second connecting member further includes first and second catches formed at one end and the other end, and at least one of the first and second catches is formed to have a preset clearance with at least one of the inner surfaces of the first and second connecting members while the tension spring maintains a circular shape, and the clearance can limit a tensile behavior of the tension spring and a movement of the first and second coupling members along the second connecting member to a preset range.

In one embodiment, the second connecting member may be made of one selected from the group consisting of metal, plastic, elastomer, rubber, and combinations of two or more thereof.

In one embodiment, the coil spring may include a compression spring and a tension spring extending from both ends of the compression spring.

In one embodiment, at least a portion of the inner surface of the tension spring can be joined to the outer surface of the first and second fastening members.

In one embodiment, the inner diameter of the tension spring may be reduced by the tensile behavior of the tension spring, thereby strengthening the connection between the first and second fastening portions and the tension spring.

According to one aspect of the present invention, a profile connecting device comprises: a first connecting member including a first receiving portion made of a pair of mutually opposing plates, a first connecting portion made of a plate connecting one end of the first receiving portion, and a first fastening portion protruding from one side of the first connecting portion opposite the first receiving portion; a second connecting member including a second receiving portion made of a pair of mutually opposing plates, a second connecting portion made of a plate connecting one end of the second receiving portion, and a second fastening portion protruding from one side of the second connecting portion opposite the second receiving portion; And a first connecting member formed of a coil spring that is connected to the first and second connecting members and interconnects the first and second connecting members; wherein the outer peripheral surfaces of the first and second connecting members are connected to the inner peripheral surfaces of one end and the other end of the coil spring, respectively, so that the floating solar power generation facility can effectively buffer external force applied to the facility for a long period of time, can be easily connected, can reduce the cost required for manufacturing, and can improve maintainability.

It should be understood that the effects of the present invention are not limited to the effects described above, but include all effects that can be inferred from the composition of the invention described in the detailed description or claims of the present invention.

FIG. 1 is a perspective view of a profile connecting device according to one embodiment of the present invention.
FIG. 2 is a perspective view (FIG. 2(a)) and a plan view (a plan view viewed from the AA' direction of FIG. 2(a)) of a first joining member (or a second joining member) according to one embodiment of the present invention.
FIG. 3 is a cross-sectional view showing the tensile behavior of a tensile spring according to one embodiment of the present invention.
FIG. 4 is a front view of a profile connecting device according to one embodiment of the present invention.

Hereinafter, the present invention will be described with reference to the attached drawings. However, the present invention can be implemented in various different forms, and therefore, it is not limited to the embodiments described herein. In addition, in order to clearly describe the present invention in the drawings, parts that are not related to the description are omitted, and similar parts are assigned similar drawing reference numerals throughout the specification.

Throughout the specification, when a part is said to be "connected" to another part, this includes not only the case where it is "directly connected" but also the case where it is "indirectly connected" with another part in between. Also, when a part is said to "include" a certain component, this does not mean that it excludes other components, but rather that it can have other components, unless otherwise specifically stated.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings.

FIG. 1 is a perspective view of a profile connecting device according to one embodiment of the present invention, and FIG. 2 is a perspective view and a plan view of a first connecting member (100) (or a second connecting member, 200) according to one embodiment of the present invention. Referring to FIG. 1 and FIG. 2, a profile connecting device according to one aspect of the present invention includes a first connecting member (100) including a first receiving portion (110) formed of a pair of plates facing each other, a first connecting portion (120) formed of a plate connecting one end of the first receiving portion (110), and a first fastening portion (130) protruding from one side of the first connecting portion (120) opposite to the first receiving portion (110); It may include a second connecting member (200) including a second receiving portion formed of a pair of mutually opposing plates, a second connecting portion formed of a plate connecting one end of the second receiving portion, and a second fastening portion protruding from one side of the second connecting portion opposite to the second receiving portion; and a first connecting member (300) formed of a coil spring that is connected to the first and second fastening portions to mutually connect the first and second connecting members (100, 200).

The term "profile" as used herein means a bar-shaped and/or tubular member having a predetermined aspect ratio (ratio of diameter to length (D/L) or ratio of cross-sectional area to length (A/L)), and may be interpreted to include frames, pipes, rods, shaped steel, steel pipes, etc. The profile may be classified, for example, into C-shaped steel, H-shaped steel, I-shaped steel, L-shaped steel, square pipes, etc. depending on the shape of its cross-section, and may be classified into solid and hollow types depending on whether or not empty space is allowed inside.

The first connecting member (100) may include a first receiving portion (110) formed of a pair of plates facing each other, a first connecting portion (120) formed of a plate connecting one end of the first receiving portion (110), and a first fastening portion (130) protruding from one side of the first connecting portion (120) on the opposite side of the first receiving portion (110).

The first receiving portion (110) may be formed of plates spaced apart from each other at a predetermined interval. When the first receiving portion (110) receives an end of a profile, the interval may be determined according to the thickness and/or width of the profile.

The first connecting portion (120) may be formed of a plate connecting one end of the first receiving portion (110). The first connecting portion (120) may extend from an end of the first receiving portion (110) to close an end of the first receiving portion (110). The first connecting portion (120) may be formed by bending the plate forming the first receiving portion (110) along a predetermined bend line at a preset angle, for example, 80 to 120°, preferably 90 to 100°, more preferably 90°.

Among the first connecting member (100), the first receiving portion (110) and the first connecting portion (120) may be formed by bending a single plate, preferably a metal plate, and may be formed as a single body. The thickness of the plate may be 1 to 5 mm, preferably 2 to 4 mm, but is not limited thereto.

The first fastening portion (130) may be formed by protruding from one side of the first connecting portion (120) opposite the first receiving portion (110). The first fastening portion (130) may be formed by protruding from one side of the first connecting portion (120) opposite the first receiving portion (110) in a vertical direction to a preset height (or length), such as a cylinder, a cylindrical column, a pipe, or the like, and the outer surface thereof may be a smooth surface or, if necessary, a rough surface including screw threads of a preset standard.

The first connecting portion (120) and the first fastening portion (130) may be integrally joined to each other by welding or the like, or may be integrally cast using a predetermined mold (form or mold). In addition, the first receiving portion (110), the first connecting portion (120), and the first fastening portion (130) may be integrally cast using a predetermined mold (form or mold).

The second connecting member (200) may include a second receiving portion made of a pair of mutually opposing plates, a second connecting portion made of plates connecting one end of the second receiving portion, and a second fastening portion protruding from one side of the second connecting portion opposite to the second receiving portion.

In the above profile connecting device, the specifications of the first and second connecting members (100, 200) may be the same as each other, and the positional relationship, shape, structure, etc., are symmetrical with respect to the first connecting member (300), so the structural and mechanical characteristics of the second connecting member (200) and its lower components, the second receiving portion, the second connecting portion, and the second fastening portion, are the same as those described above with respect to the first connecting member (100) and its lower components, the first receiving portion (110), the first connecting portion (120), and the first fastening portion (130).

The above first connecting member (300) may be formed of a coil spring that is connected to the first and second fastening members to interconnect the first and second connecting members (100, 200).

Fig. 3 is a cross-sectional view showing the tensile behavior of a tensile spring according to one embodiment of the present invention. Referring to Figs. 2 and 3, the outer peripheral surfaces of the first and second fastening portions can be joined to the inner peripheral surfaces of one end and the other end of the coil spring.

The inner diameters of one end and the other end of the coil spring may have specifications greater than the outer diameters of the first and second fastening portions, respectively, and the one end and the other end of the coil spring may receive and fix the first and second fastening portions, respectively. Such receiving and fixing may be accomplished by fitting or inserting the first and second fastening portions into one end and the other end of the coil spring, respectively, and then pressurizing one end and the other end of the coil spring in the direction of the central axis.

The above coil spring may be a tension spring. The above tension spring is a coil spring designed to resist an extension or tensile load, and is elongated and deformed by an extension or tensile load applied to both ends below a critical point, and can be compressed and restored when the load is weakened or eliminated.

The above-mentioned tensile spring can be manufactured by winding metal and/or plastic wire, etc. along a helically direction. The specifications of the above-mentioned tensile spring, the material diameter, the distance between adjacent materials (wire, etc.) along the central axis direction, the elastic modulus, etc. can be adjusted and designed so that the extensional deformation and compression recovery of the above-mentioned tensile spring are relatively superior to the compression deformation and extensional recovery.

For example, the tensile spring may be wound so that the materials (such as wires, wires, etc.) are tightly wound so that the distance between adjacent materials along the central axis is about 10 cm or less, preferably about 5 cm or less, more preferably about 3 cm or less, and advantageously, about 1 cm or less, and, if necessary, may be wound so that this distance substantially disappears to about 0.5 cm or less, preferably about 0.1 cm or less.

If the above coil spring is composed only of a compression spring, it can appropriately respond to a compression load among the external forces applied to adjacent units, but it is difficult to respond to an extension or tensile load, and since the compression spring allows a certain pitch or lead, a part located inside the compression spring among the profile connecting devices is exposed to the outside as it is, and thus can easily be corroded or damaged by moisture, salt, etc.

In this regard, since the tensile spring can be elongated and bent within an allowable range, it can appropriately respond to an elongation or tensile load among external forces applied to adjacent unit units, and can convert at least some of the compressive load into a bending load in the axial direction to buffer it. In addition, when the material of the tensile spring is wound in close contact with each other, the outer surface of the first and second fastening portions among the first and second connecting members (100, 200), the space between the first and second connecting members (100, 200), and other members located therein are prevented from being exposed to the outside, thereby protecting them from moisture, salt, etc.

Referring to FIG. 3, the inner diameter of the tensile spring may be reduced by the tensile behavior of the tensile spring, thereby strengthening the connection between the first and second fasteners and the tensile spring. The term "tensile behavior" as used herein means a behavior in which the tensile spring is extended and/or deformed in one direction and/or in both directions along the central axis by a predetermined tension, i.e., a tensile load, and in some cases, may mean a behavior in which the tensile spring is contracted and/or deformed in one direction and/or in both directions along the central axis when the tensile load is released.

FIGS. 3(a) and 3(b) are cross-sectional views of the tensile spring in a state where the tensile spring maintains its original shape and in a state where the tensile spring is extended and deformed by a tensile load, respectively. In a state where the tensile spring maintains its original shape, the tensile spring may have a predetermined inner diameter (D1) and pitch (P1). The pitch of the tensile spring means the length in the direction of the central axis of the tensile spring between the central axis of the material wound in the cross-section including the central axis of the tensile spring and the central axis of the immediately adjacent material, and is also used in a similar meaning to lead and pitch lead.

When the above-described tensile spring is extended and deformed by a predetermined tensile load, the pitch of the tensile spring may increase to P2 and the inner diameter may decrease to D2. When a tensile load is applied to the tensile spring while one end and the other end of the tensile spring are respectively connected to the first and second fastening portions, the inner diameters of the one end and the other end of the tensile spring may decrease, thereby strengthening the connection with the first and second fastening portions. The connection between the first and second fastening portions and the tensile spring may be further strengthened as the tensile behavior of the tensile spring is repeated.

FIG. 4 is a front view of a profile connecting device according to one embodiment of the present invention. Referring to FIGS. 2 and 4, the first and second connecting portions (120) may include first and second connecting holes (121), respectively, and the first and second fastening portions may be cylinders formed with both ends open coaxially with the first and second connecting holes (121), respectively, and may further include a second connecting member (400) that connects the first and second coupling members (100, 200) along the inner side of the coil spring, and one end and the other end of the second connecting member (400) may be installed by penetrating the interior of the cylinder and the first and second connecting holes (121), respectively.

The first and second connecting holes (121) may be formed by punching a portion of the plate material constituting the first and second connecting portions (120), preferably, the central portion, to a predetermined standard. With reference to the first connecting member (100), the first fastening portion (130) may be a cylinder formed with both ends open coaxially with the first connecting hole (121). Preferably, the cylinder may be formed by extending from the outer surface or periphery of the first connecting hole (121) along the central axis of the first connecting hole (121) to a predetermined length or height. The outer surface or periphery of the first connecting hole (121) and the cylinder may be integrally joined to each other by welding or the like, or may be integrally cast by a predetermined mold (formwork or mold). Additionally, the first receiving portion (110), the first connecting portion (120), the first connecting hole (121), and the first fastening portion (130) may be cast as a whole using a predetermined mold (formwork or die).

The second connecting member (400) can connect the first and second connecting members (100, 200) along the inner side of the coil spring. The first and second connecting holes (121) formed in the first and second connecting members (100, 200), respectively, and the internal space of the cylinder constituting the first and second fastening portions (130) can provide a space or path through which the second connecting member (400) can pass, and thus, one end and the other end of the second connecting member (400) can be connected to the first and second connecting members (100, 200), respectively.

The second connecting member (400) may include one selected from the group consisting of a chain, a pin, a rod, a bar, a pipe, and a combination of two or more thereof, and may preferably be formed of a member in the form of a pin and/or a rod, but is not limited thereto. When the second connecting member (400) is formed of a pin and/or rod-shaped member, the first and second fastening members (100, 200) connected by the second connecting member (400) may move, for example, slide, along the central axis direction of the second connecting member (400) within a preset range when the coil spring (300) is subjected to extension and/or contraction deformation. The diameter of the second connecting member (400) may be smaller than the diameter of the first and second connecting holes (121). Preferably, the diameter of the second connecting member (400) may be designed to be smaller than the diameters of the first and second connecting holes (121) so that a predetermined clearance may be provided between the second connecting member (400) and the first and second connecting holes (121).

In addition, in order to prevent damage or breakage of the second connecting member (400) and the first and second connecting holes (121) due to repeated friction between them, at least one of the outer surface of the second connecting member (400) and the inner surface of the first and second connecting holes (121) may include a lubricating, corrosion-resistant, and chemical-resistant functional layer formed by coating, painting, lamination, or the like.

The second connecting member (400) may further include first and second catch portions (112, 112') formed at one end and the other end. At least one of the two ends of the second connecting member (400) may include a predetermined screw thread, and at least one of the first and second catch portions (112, 112') may be a nut fastened to the screw thread. Only one of the two ends of the second connecting member (400) may include a predetermined screw thread, and one of the first and second catch portions (112, 112') may be a nut fastened to the screw thread, and the other may be a bolt head formed integrally with the second connecting member (400).

The above second connecting member (400) may be made of one selected from the group consisting of metal, plastic, elastomer, rubber, and a combination of two or more thereof, preferably metal, but is not limited thereto.

At least one of the first and second catch portions (112, 112') is formed by leaving a preset clearance (G) between at least one of the inner surfaces of the first and second connecting portions (120) and the tension spring (300) while maintaining its original shape, and the clearance (G) can limit the tensile behavior of the tension spring (300) and the range of movement of the first and second connecting members (100, 200) along the second connecting member (400) to a preset length, specifically, the length of the clearance (G) among the entire length in the direction of the central axis of the second connecting member (400).

The above-mentioned clearance (G) limits the tensile behavior of the tensile spring (300) to the above-mentioned range, thereby buffering external force applied to adjacent units, specifically, extension (or tensile), compression, rotation, and bending loads, and at the same time, prevents the tensile spring (300) from being damaged or broken even when an excessive tensile load is applied to the tensile spring (300). In addition, the diameters of the first and second engaging portions (112, 112') can be designed to be larger than the diameters of the first and second connecting holes (121), thereby preventing the first and second connecting members (100, 200) from being separated from the second connecting member (400).

The first and second connecting members (100, 200) can be mutually connected by the first connecting member (300) connected to the first and second fastening portions, and the second connecting member (400) connected to the first and second connecting portions. That is, in the profile connecting device, the first and second connecting members (300, 400) are independently connected to the first and second connecting members (100, 200), so that when both are connected, a complementary and synergistic buffering effect can be implemented, and even if one of them is deformed or damaged, a minimum buffering effect can be maintained within a predetermined range.

The plates forming the first and second receiving portions may each include at least one pair, preferably at least two pairs, of first and second catch holes (111) provided at opposing positions while being spaced apart from each other by a predetermined interval. A member such as a bolt or rivet that mutually fixes or hinge-connects an end of a profile received in the first receiving portion (110) and the first connecting member (100) may be inserted through the first catch hole (111).

Meanwhile, if the coil spring is composed only of a tensile spring, at least some of the compressive load can be converted into a bending load in the axial direction and buffered, but if a strong compressive load that is difficult to convert into a bending load is applied, or if a bending load is continuously applied, the durability of the tensile spring may be reduced.

Referring to Fig. 4, the coil spring may include a compression spring (Sc) and a tensile spring (St) extending from both ends of the compression spring (Sc). The compression spring (Sc) is a coil spring designed to operate in the opposite direction to the tensile spring (St), that is, to resist a compressive load, and is compressed and deformed by a compressive load below a critical point applied to both ends, and can be restored by extension when the load is weakened or eliminated.

The tension spring (St) provided at both ends of the coil spring and the compression spring (Sc) provided therebetween may be integrally formed by winding and processing a single wire, etc. At least a portion of the inner surface of the tension spring (St) provided at one end of the coil spring may be coupled to the first fastening portion (130) in the same manner as described above, and at least a portion of the inner surface of the tension spring (St) provided at the other end of the coil spring may be coupled to the second fastening portion in the same manner as described above.

The central portion of the above coil spring may include the compression spring (Sc), and preferably, may include the remaining portion of the compression spring (Sc) and the tension spring (St) provided at both ends thereof but not involved in the connection with the first and second fastening portions (130).

In the case where the tensile spring (St) of the above coil springs is entirely involved in the connection with the first and second fastening portions, the buffering effect is implemented only by the compression spring (Sc) of the above coil springs, so while it can appropriately respond to a compressive load among the external forces applied to adjacent unit units, it is difficult to respond to an extensional or tensile load, and since the part located inside the compression spring (Sc) of the above profile connecting device is exposed to the outside as it is, it can easily be corroded or damaged by moisture, salt, etc.

By the tensile behavior of the tensile spring (St) provided at both ends of the coil spring, the inner diameter of the tensile spring (St) may be reduced, so that the coupling between the first and second fastening portions and the tensile spring may be strengthened. Referring to Fig. 3, when the tensile spring (St) is extended and deformed by a predetermined tensile load, the pitch of the tensile spring (St) may increase to P2, while the inner diameter may be reduced to D2. When a tensile load is applied to the tensile spring (St) in a state where one end and the other end of the tensile spring (St) are respectively coupled to the first and second fastening portions, the inner diameters of the one end and the other end of the tensile spring (St) may be reduced, so that the coupling with the first and second fastening portions may be strengthened. The connection between the first and second fasteners and the tension spring (St) can be further strengthened as the tensile behavior of the tension spring (St) is repeated.

The above description of the present invention is for illustrative purposes, and those skilled in the art will understand that the present invention can be easily modified into other specific forms without changing the technical idea or essential features of the present invention. Therefore, it should be understood that the embodiments described above are exemplary in all respects and not restrictive. For example, each component described as a single component may be implemented in a distributed manner, and likewise, components described as distributed may be implemented in a combined manner.

The scope of the present invention is indicated by the claims set forth below, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention.

100: First connecting member 110: First receiving part
111: 1st catch 112, 112': 1st catch, 2nd catch
120: First connecting part 121: First connecting hole
130: First fastening part 131: Outer surface of first fastening part
200: Second connecting member 300: First connecting member
Sc: Compression spring St: Tension spring
400: Second connecting member (pin) G: Free play
P1, P2: Pitch of tension spring D1, D2: Inner diameter of tension spring

Claims (10)

A first connecting member including a first receiving portion made of a pair of mutually opposing plates, a first connecting portion made of plates connecting one end of the first receiving portion, and a first fastening portion protruding from one side of the first connecting portion opposite to the first receiving portion;
A second connecting member including a second receiving portion made of a pair of plates facing each other, a second connecting portion made of plates connecting one end of the second receiving portion, and a second fastening portion protruding from one side of the second receiving portion on the opposite side of the second connecting portion; and
A first connecting member comprising a coil spring that is joined to the first and second fastening members and interconnects the first and second connecting members;
The outer surface of the first and second fastening parts are respectively connected to the inner surface of one end and the other end of the coil spring,
The outer surface of the first and second fastening parts is a smooth surface,
The above coil spring is a tensile spring,
A profile connecting device in which the inner diameter of the tension spring is reduced by the tensile behavior of the tension spring, thereby strengthening the connection between the first and second fastening portions and the tension spring. delete delete In the first paragraph,
The first and second connecting portions include first and second connecting holes, respectively,
The first and second connecting parts are cylinders formed with both ends open coaxially with the first and second connecting holes, respectively.
Further comprising a second connecting member connecting the first and second connecting members along the inner side of the coil spring,
A profile connecting device, wherein one end and the other end of the second connecting member are installed through the interior of the cylinder and the first and second connecting holes, respectively. In paragraph 4,
A profile connecting device, wherein the second connecting member comprises one selected from the group consisting of a chain, a pin, a rod, a bar, a pipe, and a combination of two or more of these. In paragraph 5,
The second connecting member further includes first and second catches formed at one end and the other end,
At least one of the first and second engaging portions is formed by leaving a preset gap with at least one of the inner surfaces of the first and second connecting portions while the tension spring maintains its original shape,
A profile connecting device, wherein the above-mentioned clearance limits the tensile behavior of the tensile spring and the movement of the first and second connecting members along the second connecting member to a preset range. In paragraph 5,
A profile connecting device, wherein the second connecting member is made of one selected from the group consisting of metal, plastic, elastomer, rubber, and combinations of two or more thereof. A first connecting member including a first receiving portion made of a pair of mutually opposing plates, a first connecting portion made of plates connecting one end of the first receiving portion, and a first fastening portion protruding from one side of the first connecting portion opposite to the first receiving portion;
A second connecting member including a second receiving portion made of a pair of plates facing each other, a second connecting portion made of plates connecting one end of the second receiving portion, and a second fastening portion protruding from one side of the second receiving portion on the opposite side of the second connecting portion; and
A first connecting member comprising a coil spring that is joined to the first and second fastening members and interconnects the first and second connecting members;
The outer surface of the first and second fastening parts are respectively connected to the inner surface of one end and the other end of the coil spring,
The outer surface of the first and second fastening parts is a smooth surface,
The above coil spring includes a compression spring and a tension spring extending from both ends of the compression spring,
At least a portion of the inner surface of the above tensile spring is joined to the outer surface of the first and second fastening parts,
A profile connecting device in which the inner diameter of the tension spring is reduced by the tensile behavior of the tension spring, thereby strengthening the connection between the first and second fastening portions and the tension spring. delete delete