KR101837602B1 - Solar power plant constructed on the water - Google Patents

Abstract

The present invention relates to a water solar energy generating device with a fusing unit reinforced type multi-room float which is made in a multi-room structure having a plurality of sealing spaces of which the insides are separated by partition walls to obtain a stable structure. In the water solar energy generating device, concentrative strength reinforcement is made for portions weak against external impact due to floating matters to minimize damage due to floating matters such as floating ice, plants and the like. The water solar energy generating device has the fusing unit reinforced type multi-room float suitable for realizing a large product. The water solar energy generating device has a bracket for frame intersection connection which can simply connect two frames, crossing each other in a cross type, while stably supporting the two frames, can minimize the number of coupling components of a bolt or the like, and can stably cope with rotation moment between frames.

Description

TECHNICAL FIELD [0001] The present invention relates to a solar photovoltaic power generation system having a frame cross connection bracket having a reinforced multi-

The present invention relates to an aquarium photovoltaic power generation apparatus, and more particularly, to a solar photovoltaic power generation apparatus having a multi-room structure having a plurality of closed spaces divided by a partition wall and structurally stable, It is possible to easily connect two multi-room floats reinforced with fused parts suitable for realizing a large-sized product by minimizing damage caused by suspension such as drift ice and vegetation and stably supporting two frames crossing in a cross shape, And more particularly to an aquarius photovoltaic power generation apparatus having a frame cross connection bracket capable of minimizing the number of fastening parts such as a frame crossing connection member and more reliably coping with an interframe rotation moment.

Recently, regulations are being implemented to curb carbon dioxide emissions worldwide, and development of new generation devices that do not emit carbon dioxide is required.

As such, there is no emission of carbon dioxide, and a power generation device using solar energy is a typical power generation device using clean energy. Recently, the development and installation costs of technology have been reduced, and the spread has been spreading.

However, there is a difference in generating capacity depending on the area and the amount of sunshine. However, due to the use of enormous land for installation on a large area, there are many restrictions on the purchase of the land. There was a real difficulty in drawing up the cooperation of the surrounding people in order to install the large-scale power generating facilities.

In addition, as in the prior art, the photovoltaic power generation apparatus installed on the land generates enormous amount of heat in the process of generating electricity by receiving sunlight and enormous amount of wastes are transferred from the land where the solar power generation apparatus is installed, Which causes degradation of performance and causes malfunctions.

Accordingly, a water photovoltaic power generation system in which a solar panel is installed on a water surface of a river, a lake, a reservoir, a dam, and the like is actively proposed in order to secure a wide open space and a large amount of sunshine while reducing problems, The situation is continuing.

Such a solar photovoltaic power generation device includes a float that floats the solar panel and the frame assembly on the surface of the water. In the case of a float, the float is made of a PE material, and the interior is empty in a large space or EPS (foamed styrofoam) In the form of filling.

In the case of the float according to the prior art having one internal space, the compressive strength is weak and it is easy to break and it is difficult to realize a large-sized product. In order to overcome such problems, the thickness of the wall must be made thick, but in this case, another problem of lowering the economical efficiency has been caused.

Korean Patent Registration No. 1503504 (Feb.

The present invention has been made in order to solve the problems of the related art as described above, and it is an object of the present invention to provide a multi-room structure having a plurality of closed spaces divided by a partition wall and structurally stable, It has intensive strength reinforcement for areas vulnerable to external impact, minimizes damage caused by drift ice and vegetation, and is suitable for realizing a large product. It has two multi-room floats, And an object of the present invention is to provide an aquarius photovoltaic power generation apparatus having a frame cross connection bracket that can be easily connected while stably supporting and minimizes the number of fastening parts such as bolts and can more stably cope with interframe rotational moment.

According to an aspect of the present invention, there is provided an aquarium photovoltaic generation apparatus comprising a float, a first frame and a second frame crossing in a cross shape floating on the water by the float, And a plurality of solar panels supported on an upper portion of the frame assembly. The float is formed by injection molding to have a bottom plate and an outer wall by injection molding. One of two semi-bodies formed individually in a container shape is placed in an upper part of the other in an inverted state and then joined in a state of facing each other at an upper part and a lower part to form a body formed as an empty space with its inside sealed, The fused portion formed along the upper wall portion of the outer wall has a plurality of rows formed in the outer direction from the inner side of the outer wall end portion Wherein the frame cross connection bracket includes a rectangular plate-shaped main body portion having a first side and a second side which are opposite to each other and in which the first frame and the second frame are in contact with each other, And a first bolt hole for fastening a bolt to the first body frame, the first bolt hole being formed in a U-shape with the main body part being folded in one direction from two side ends of the four side ends of the body part, A pair of first contact wing portions and a pair of first contact wing portions and a pair of second contact wing portions which are bent in the other direction from the remaining two side end portions of the four side end portions of the main body portion where the first contact wing portion is not formed, And a pair of second contact wings having a second bolt hole for fastening the bolt and surrounding the surface of the second frame, And a first stress dispersing portion formed to be a curved surface having a semicircular cross section and capable of dispersing stress, wherein a portion of the second contact wing portion, which is connected to the main body portion, And the stress can be dispersed in the curved surface.

In the float, a plurality of transverse bulkheads and longitudinal bulkheads for reinforcing the strength of the multi-room are formed in the hollow spaces formed by the semi-main body junctions, And a sloped portion formed to be inclined in a direction to widen toward the upper side from the vertical portion so that the outer wall of the semi-main body is gradually protruded toward the fused portion where the outer walls meet with each other .

In the float, a reinforcing protrusion protruding outward along the periphery of the vertical portion of the outer wall is formed at a thickness of 8 times or more the thickness of the bottom plate, and the reinforcing protrusion is formed in the same vertical line And a skeleton structure formed by intersecting the vertical plate and the horizontal plate.

The bottom plate of the float is formed in a checkerboard shape in which a plurality of ribs are orthogonal to each other to reinforce the strength. Ribs connected to the ribs formed on the bottom plate for reinforcing strength are formed on the transverse bulkheads and the vertical bulkheads. And a claw that is connected to the rib formed on the bottom plate is formed on the inner side surface.

In addition, a plurality of pipe openings passing through the body vertically are formed at each intersection of the transverse bulkhead and the longitudinal bulkhead of the float, and the two pipe openings of the pipe openings are provided with insulating supports each having the same height A first electrode rod fixed to one of the insulating supports and having a lower end portion extended in a lengthwise direction to a vicinity of a lower end portion of the pipe runner and a lower end portion having a shorter length than the first electrode rod, A comparator for receiving and comparing a capacitance value due to water introduced into the first electrode rod and the second electrode rod and water flowing into the pipe inner hole; And a signal transmitting unit for transmitting a signal indicating to which electrode of the first electrode rod and the second electrode rod which water electrode has been touched to the outside, The output section further comprising, can be characterized in that to determine the risk of flooding of the solar panel is installed on the upper float.

In addition, a plurality of cut portions may be formed in the first stress dispersing portion and the second stress dispersing portion of the frame cross-connecting bracket, respectively.

Further, the body portion of the frame cross-connecting bracket may be differentiated from the first contact wing portion and the second contact wing portion so as to reduce friction caused by surface contact with the first frame and the second frame with respect to one surface and the other surface A plurality of fine dimples having a diameter within a range of 50 to 250 mu m and spaced apart from each other are formed on the plating layer and the dimples of the plating layer are made cloudy A plurality of fine oil pockets for accommodating a liquid lubricant and reducing a friction area are formed on a surface of the solid lubricant particle and a friction between the first and second frames Characterized in that it is made of a material which generates fine particles so as to lubricate away from the surface due to contact .

The water photovoltaic power generating apparatus according to the present invention is characterized in that the fused-portion-reinforcing multi-room float provided therein has a multi-room structure having a plurality of closed spaces, the inside of which is partitioned by barrier ribs, structurally stable, It is possible to suppress damages due to floating matters such as drift ice and vegetation by making the strength reinforcement in the form that the fusion bonding portions are thermally fused by multiple heat fusion lines.

The float provided in the present invention is characterized in that the float of the present invention has an arch structure of an inclined portion in which an outer wall protrudes around a multi- The strength of the site was intensively reinforced to minimize damage by the float.

In addition, the float provided in the present invention has a heat-welded portion in which multiple joining is performed, and a reinforcing protruding portion which is intensively reinforced by the arch structure by the outer wall inclined portion and which is about ten times thicker than the bottom plate, It is reinforced up to the strength of the plate. It is strengthened by connecting the outer wall, the bottom plate and the bulkhead by the bracket and the ribs. It is tightly reinforced to the inner strength so that it has a thinner wall by injection molding. There is no problem in implementing.

In addition, the frame cross connection bracket provided in the present invention can easily connect two frames intersecting with each other in a state of stably supporting the frame, and the number of fastening parts such as bolts can be minimized.

In addition, the frame cross-connection bracket provided in the present invention is characterized in that stress is not concentrated by the first stress dispersing portion and the second stress dispersing portion formed of curved semicircular surfaces while exhibiting high rigidity with respect to the inter- The maximum stress value is lowered under the same load condition and the stress distribution is stabilized.

In addition, the frame crossing bracket provided in the present invention may have a structure in which a low friction structure different from the first contact wing portion and the second contact wing portion is formed on the surface of the main body portion, Can be easily slid in the longitudinal direction thereof and the damage between them can be minimized.

Fig. 1 is a view showing a state of use of an aquarium photovoltaic apparatus according to an embodiment of the present invention
2 is a perspective view of a float in an aquarium photovoltaic apparatus according to an embodiment of the present invention.
Fig. 3 is a perspective view showing a state in which the float is separated from the semi-main body of the float solar photovoltaic apparatus according to the embodiment of the present invention,
4 is a plan view of the float half body in the aquarium photovoltaic apparatus according to the embodiment of the present invention.
5 is a longitudinal sectional view taken along line AA of FIG.
6 is a partial cross-sectional view for explaining a multi-stage electrode for measuring the level of a float in an aquarium photovoltaic power generation apparatus according to an embodiment of the present invention
7 is a circuit diagram for explaining a signal portion for level measurement of a float in an aquarium photovoltaic apparatus according to an embodiment of the present invention
FIGS. 8 to 11 are photographs showing an actual sample of a float in an aquarium photovoltaic power generating apparatus according to an embodiment of the present invention
FIG. 12 is a perspective view showing a state where two frames crossing each other in a cross shape are connected by a frame cross connection bracket in an aquarium photovoltaic power generation apparatus according to an embodiment of the present invention.
13 is a perspective view for explaining a structure of a frame cross connection bracket in an aquarius solar power generation apparatus according to an embodiment of the present invention;
14 is a view for explaining a low friction construction applied to a main body portion of a frame crossing connection bracket in an aquarius solar power generation apparatus according to an embodiment of the present invention;
Fig. 15 is a cross-sectional view of the frame cross-linking bracket shown in Fig. 14, which is a reference image for explaining a spray drying method among various methods for forming solid lubricant particles, which is one of the elements forming a low-
16A and 16B are graphs showing stress distribution at the same load condition for comparing the case where the stress dispersing portion of the frame crossing connection bracket is formed and the case where the stress dispersing portion of the frame crossing connecting bracket is not formed in the water solar power generation apparatus according to the embodiment of the present invention
17A to 17F are a series of reference drawings for explaining a method of manufacturing a frame cross connection bracket in an aquarius solar power generation apparatus according to an embodiment of the present invention
18 is a perspective view for explaining the structure of a modified frame cross connection bracket in the water power generation system of the present invention

A water photovoltaic generation apparatus according to embodiments of the present invention will be described in detail with reference to the accompanying drawings. The present invention is capable of various modifications and various forms, and specific embodiments are illustrated in the drawings and described in detail in the text. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. Like reference numerals are used for like elements in describing each drawing. In the accompanying drawings, the dimensions of the structures are enlarged to illustrate the present invention, and are actually shown in a smaller scale than the actual dimensions in order to understand the schematic structure.

Also, the terms first and second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. On the other hand, unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

1 is a use state diagram of an aquarium photovoltaic apparatus according to an embodiment of the present invention.

As shown in the figure, an aquarium photovoltaic apparatus according to an embodiment of the present invention comprises a float 10, a frame assembly 20, and a solar panel 30, The structure is structurally stable, and the damage caused by the impact even if it collides with floating matters such as drift ice and vegetation on the fused portion and the outer wall which may be vulnerable to an external impact due to floats The float 10 is structurally very stable even though the outer wall is thin and uniformly formed with a high quality by injection molding, so that the large-sized product having a standard of 1000 mm or more And the collision of float is not easily damaged even in harsh environments. Has the advantage of providing an optimal float for a solar photovoltaic system.

In addition, according to the present invention, a frame crossing connection bracket provided for connecting a first frame and a second frame intersecting in a cross shape in a frame assembly 20 exhibits high rigidity with respect to interframe rotation moment, So that the maximum stress value is lowered under the same load condition and the stress distribution is stabilized.

Hereinafter, an aquarium photovoltaic apparatus according to an embodiment of the present invention will be described in detail with reference to the float and the frame cross-linking bracket.

First, the float 10 will be described.

FIG. 2 is a perspective view of a float in an aquarium photovoltaic power generation apparatus according to an embodiment of the present invention, and FIG. 3 is a cross-sectional view of a floating solar power generation apparatus according to an embodiment of the present invention, FIG. 4 is a half-body plan view of a float in an aquarium photovoltaic power generation apparatus according to an embodiment of the present invention, and FIG. 5 is a longitudinal sectional view taken along line AA of FIG.

As shown in the drawings, the float in the aquarium photovoltaic power generation apparatus according to the embodiment of the present invention is formed by individually molding two semi-main bodies 100 in a container shape so as to have a bottom plate 110 and an outer wall 120 by injection molding One of them is turned upside down and is placed on the upper side in a symmetrical form, and then the two semi-bodies 100 are joined together by thermal fusion to form a body formed as a hollow space sealed inside.

As shown in FIG. 5, the fused portion 123 formed along the upper end of the outer wall 120 of the semi-main body 100 has a plurality of heat fusion lines (hereinafter referred to as " 123a. ≪ / RTI > If the fused portion 123 is provided as a plurality of heat fusion lines 123a, the multiple fused portions are formed not by one but by a plurality of fused portions by heat fusion, The problem that the fused portion 123 is dropped or damaged due to a load or an impact due to the collision of the float can be completely solved. Thus, although the advanced method of thermally fusing two semi-main bodies 100 formed as individual pieces to form a complete individual float has the advantage that the entire walls are formed in a thin and uniform high quality, the fused portion 123 It is possible to intensively strengthen the strength of the fused portion 123 in a situation where a problem of being easily fallen or damaged while being subjected to a concentrated load can be intensively intensified so that the fused portion 123 can be transformed to the most rigid portion in terms of strength It is. Particularly, it is preferable that the strength reinforcement is performed in consideration of the fact that the portion where the fused portion 123 is formed is an intermediate portion of the outer wall most frequently colliding with the float based on the whole body.

In addition, a horizontal partition wall 130a and a vertical partition wall 130b for forming a multi-room intersect with each other to form a skeletal structure and to reinforce the strength in the closed space formed by joining the semi-main bodies 100 .

The semi-main body 100 is composed of a rectangular bottom plate 110 having rounded corners and an outer wall 120 formed from the periphery of the bottom plate 110 to have a container shape. In the case of the outer wall 120 A vertical part 121 formed vertically along the periphery of the bottom plate 110 and an inclined part 123 extending from the upper end of the vertical part 121 and formed in an inclined shape widening outward toward the upper side . According to the configuration of the outer wall 120 having the inclined portion 123, as shown in FIG. 2, the outer wall 120 between the semi-main bodies 100 has a gradually protruding shape toward the fused portion 123, do. Such a structure is achieved by making the fused portion 123, which has been structurally changed to the most rigid portion by the plurality of thermal welding lines 123a, to be the most protruding portion outward from the outer wall 120, . Thereby protecting other portions of the outer wall 120 relative to the collision. The shape of the outer wall 120 having the inclined portion 123 is a shape that protrudes outward toward the middle height where the fused portion 123 is positioned when the two half bodies 100 are joined to form the complete outer wall 120 So that it is not a perfect arcuate but has a shape similar to an arched shape. This makes the outer wall 120 more structurally robust than when it is made of a simple flat surface.

A plurality of ribs 131 are formed on the bottom plate 110 and the horizontal barrier ribs 130a and the vertical barrier ribs 130b for strength reinforcement. The ribs 131 formed on the bottom plate 110 are formed in a crosswise grid shape and the ribs 131 connected to the ribs 131 formed on the bottom plate 110 are formed on the horizontal barriers 130a and the vertical barriers. Is formed. The inner wall of the outer wall 120 is formed with a claw 124 connected to a rib 131 formed on the bottom plate 110. If the ribs 131 and the brackets 124 are formed to reinforce the strength, sufficient strength required for designing can be secured even if the outer wall 120 and the horizontal barrier ribs 130a and the vertical barrier ribs 130b are formed to be thinner It becomes possible.

A reinforcing protrusion 140 protruding outward along the vertical portion 121 is formed at a lower end of the vertical portion 121 of the outer wall 120. [ The reinforcing protrusion 140 is formed to have a thickness of 8 to 10 times the thickness of the bottom plate 110 to reinforce the strength of the bottom plate 110 to a sufficient level. Here, the reinforcing protrusion 140 has a skeleton structure formed by crossing the vertical plate 141a and the horizontal plate 141b, so that the reinforcing protrusion 140 is lightweight as compared with the case of the through plate. In addition, the reinforcing protrusions 140 are balanced by making the fused portions 123 protruding outward at the middle height to be equal to the protruding degree.

As described above, the float 10 intensively strengthens the strength by thermally fusing the fused portion 123, which is structurally most vulnerable, to the plurality of heat fusion lines 123a, while the slope portion 123 The reinforcing protrusions 140 are formed to have an upper end and a lower end that are about 10 times thicker than the bottom of the main body. The strength of the bottom plate 110 is increased by the arch structure, Respectively. The outer wall 120 reinforced by these constructions and the plurality of bridges 124 and ribs 131 connecting the horizontal partition 130a and the vertical partition 130b from the bottom plate 110 are spaced apart from each other The strength of the entire interior including the horizontal barrier ribs 130a and the vertical barrier ribs 130b can be reinforced.

A sample photograph actually implementing such a float 10 is attached to FIG. 8 to FIG. 11. It can be seen that the reinforcing structure as described above is so strong and balanced as to be reminiscent of muscularity even in its outline.

Subsequently, the additional configurations of the float 10 will be described.

FIG. 6 is a partial cross-sectional view for explaining a multi-stage electrode for level measurement of a float in an aquarium photovoltaic power generation apparatus according to an embodiment of the present invention, and FIG. 7 is a cross- And is a circuit diagram for explaining a signal portion for level measurement provided in the float.

As shown in the figure, in the float 10 of the aquarium photovoltaic power generation apparatus according to the embodiment of the present invention, two of the pipe tubes 132 formed at the intersection of the vertical barrier ribs 130b and the horizontal barrier ribs 130a, The insulating support 151 is provided at the same height in the inner hole 132a of the clearance pipe 132 and is fixed to one of the insulator supports 151 so that the lower end thereof is elongated to the vicinity of the lower end of the pipe A second electrode rod 152 fixed to the other one of the insulating supports 151 and having a shorter length than the first electrode rod 152 and having a lower end portion extending only to the upper portion of the pipe tube 132; 153 are provided.

A comparator 161 for receiving and comparing capacitances due to water flowing into the first electrode rod 152 and the second electrode rod 153 and the internal hole 132a of the pipe tube 132, And a signal output unit 162 for receiving a signal indicating to which electrode of the first electrode rod 152 and the second electrode rod 153 that the electrode has reached the water, 160).

The first electrode rod 152 is contacted with the water before the second electrode rod 153 touches the water so that the charging charge of the water is discharged through the ground, thereby preventing the sensing malfunction. Strong static electricity externally applied is also discharged through the first electrode rod 152, thereby ensuring stable sensing. The surface tension of the first electrode rod 152 and the second electrode rod 153 is minimized by gradually reducing the lower end of the first electrode rod 152 and the second electrode rod 153 when the water contacts the first electrode rod 152 and the second electrode rod 153 To prevent malfunctions that may occur due to water.

The comparator 161 receives and adjusts the capacitance value due to the water introduced into the first electrode rod 152 and the second electrode rod 153 and the inner hole 132a of the pipe tube 132, respectively. The capacitance value added or subtracted by the comparator 161 is divided into a case where only the first electrode rod 152 is in contact with water and a case where water is in contact with both the first electrode rod 152 and the second electrode rod 153, The output unit 162 transmits different signals to the facility management room according to the capacitance values (for example, 5.0 V and 2.5 V) that are compared in the comparator 161.

According to such a construction, the first electrode rod 152 senses a case where the flooded water level is high, and the second electrode rod 153 senses a case where the flooded water level is a low water level. If the first electrode rod 152 senses that the flooded water level is high, it means that there is a risk of flooding the solar panel due to the excessive load of the facilities installed on the float, so measures must be taken promptly.

Next, the frame crossing connection bracket will be described in detail.

12 is a perspective view showing a state where two frames crossing each other in a cross shape are connected by a bracket for crossing a frame in an aquarius PV system according to an embodiment of the present invention.

The frame crossing connection bracket 200 in the aquarium photovoltaic apparatus according to the embodiment of the present invention is mounted on the frame assembly 20 The first frame P1 and the second frame P2 intersecting in a cross shape can be connected simply and stably.

To this end, the frame cross connection bracket 200 in the aquarium power generation apparatus according to the embodiment of the present invention is configured to simultaneously enclose the first frame P1 and the second frame P2 as shown in FIG. 12 U-shaped structures are combined to form a unique structure. Furthermore, it is more stable under the same load condition by the structure including the stress dispersion structure which can effectively disperse the stress.

FIG. 13 is a perspective view for explaining a structure of a frame crossing connection bracket in an aquarium photovoltaic power generating apparatus according to an embodiment of the present invention, and FIG. 14 is a cross- Fig. 7 is a view for explaining a low friction construction applied to the body of the bracket; Fig. And FIG. 15 is a reference photograph for explaining a spray drying method among various methods for forming solid lubricant particles, which is one of the elements having a low friction structure on the surface of the main body portion in FIG. 16A and 16B are stress distribution diagrams under the same load condition for comparing the case where the stress dispersing portion of the frame crossing connecting bracket is formed and the case where the stress dispersing portion of the frame crossing connecting bracket is not formed in the aquarium power generating apparatus according to the embodiment of the present invention.

As shown in the drawings, the frame cross connection bracket 200 of the aquarium photovoltaic power generation apparatus according to the embodiment of the present invention includes a main body 210, a pair of first contact wings 220 and a pair of second contact wings Shaped structure in which the first electrode 230 faces in the opposite direction.

 The body portion 210 of the frame crossing bracket is provided with a rectangular plate-like member whose upper and lower surfaces, which are opposite to each other, contact the first frame P1 and the second frame P2. The first frame P1 is in contact with the upper surface of the main body 210 in a close contact state and the second frame P2 is in contact with the lower surface of the opposite side in a close contact state.

In the case of such a body 210, sliding of the first frame P1 and the second frame P2 due to friction between the first frame P1 and the second frame P2, Since the operation is not smooth, the position adjustment operation is not smooth, and there is a high possibility of friction damage on the surface in the process of sliding while being in contact with each other. Accordingly, in order to minimize surface friction with respect to each other, a plurality of dimples 211a are formed on the surface of the main body 210 as shown in an enlarged part of FIG. 14, and in addition, The solid lubricant particles 212 are formed so as to be capable of rolling so as to have bearing characteristics.

Such a configuration is such that a shape that is linearly slid to adjust the position of the first frame P1 and the second frame P2 in a state of being in contact with the main body 210 is a linear reciprocating motion and a rotational movement (Refer to Korean Patent Registration No. 1507012 (Feb. 23, 2014)), the dimple 211a is applied to an automobile engine while paying attention to the relationship between the piston and the piston, .

According to such a configuration, when the surface contact with the main body 210 due to the movement of the first frame P1 and the second frame P2 causes a low friction effect by a plurality of dimples 211a, The low friction effect of the solid lubricant particles 212 acts in combination to exhibit an excellent low friction effect. A plating layer 211 of Ni-SiC is formed on the surface of the body 210 and a dimple 211a is formed on the plating layer 211 so that the low friction effect of the solid lubricant 212 In addition, we can expect a higher level of low friction effect.

According to the configuration in which the spherical solid lubricant particles 212 are accommodated in the dimple 211a, the movement of the first frame P1 and the second frame P2, as shown in Fig. 14, The abrasion and friction of the plating layer 211 can be minimized by the rolling action of the solid lubricant particles 212 and the minimization of the contact area in an environment in which the sliding contact is strongly brought into sliding friction contact. Further, depending on the material constituting the solid lubricant particles 212, the debris particles generated by the progressively worn solid lubricant particles 212 in the sliding friction contact environment may be mixed with the liquid lubricant to perform additional lubrication .

Here, the solid lubricant particles 212 may be manufactured in accordance with the operating environment of the present invention, or may be prepared by purchasing what is sold. For example, the IF-WS ₂ synthesized by the Weisman Institute in the early 1990s began commercial production in 2002, unlike the platelet-shaped MOS ₂ , which has a spherical shape with a diameter of about 3 to 350 nm. In the case of IF-WS ₂ , it may be possible to provide the IF-WS ₂ in micrometers suitable for accommodating inside the dimple 211a. In general, as it is known to perform rolling friction between the rough surfaces of the metal, It is expected that rolling friction can be carried out even in the state of being accommodated in the inside.

For reference, the spherical solid lubricant particles 212 can be prepared in various manners only by the present technology. In order to prepare spherical particles, a spray drying method is used. A molding method, a method of forming a sphere by using a surface tension while flowing a molten slurry or a slurry on a surface having nano protrusions, a method using a surface tension provided through a cooling step and a subsequent step of a drying step, a method using a Lotus effect, And molding methods using 3D printers.

In addition, a plurality of fine oil pockets 212a are formed on the surface of the solid lubricant particles 212 to accommodate a liquid lubricant, such as the surface of a golf ball. It is possible to form the fine oil pockets 212a on the surface of the solid lubricant particles 212 in various ways. Among them, in the case of the spray drying method and the powder molding method, fine powder particles smaller than the replacement lubricant particles 212 The microcapsules are agglomerated on the surface of the spherical particles prepared in advance and then heat-treated. As a result, fine oil pockets are naturally formed between the agglomerated fine particles as shown in Fig. In addition, laser processing to form fine oil pockets by irradiating laser while rotating spherical particles, micro-discharge machining to form fine oil pockets by pressing spherical particle surfaces using dimple-shaped tools, spherical particles and fine oil pockets And a 3D printing method capable of forming simultaneously can be used.

On the other hand, unlike the surface of the main body 210 having the low friction structure, the first contact wing 220 and the second contact wing 230 do not add a separate structure for low friction It can be noted. The first contact wing 220 and the second contact wing 230 are fastened with the bolts 240a and 240b in a state of wrapping both sides of the first frame P1 and the second frame P2. The first frame P1 and the second frame P2 must be firmly fixed with respect to each other, and as the frictional contact between the surfaces becomes stronger, more stable fixing becomes possible.

The first contact wing 220 is bent upward from two side ends of the four side edges of the main body 210 to be opposite to each other and is U-shaped together with the main body 210 And a first bolt hole 220a for fastening the bolt 240a to cover the surface of the first frame P1.

The second contact wing portion 230 is bent in the other direction from the remaining two side end portions of the four sides of the main body portion 210 where the first contact wing portion 220 is not formed, And a second bolt hole 230a for fastening the bolt 240a to cover the surface of the second frame P2 in a U shape together with the body 210. [

When the first contact wing 220 and the second contact wing 230 are formed in a U-shaped structure together with the body 210 in opposite directions to each other, the U- The first frame P1 and the second frame P2 can be maintained in a state of being crossed accurately in a state in which the second frame P2 is not fastened and supported on both sides from both sides of the first frame P1 and the second frame P2 from the beginning The entire process from the operation of adjusting the connecting position by crossing the frame P1 and the second frame P2 to the operation of fastening by using the bolts 240a and the nut 240b can be very easily performed.

Further, the first contact wing 220 and the second contact wing 230 are provided with a first stress dispersing part 225 and a second stress dispersing part 225, each of which is a curved surface having a semi- (235) is formed. In the case of the first stress distribution portion 225, the first contact wing portion is formed at a predetermined portion connected to the body portion 210, and in the case of the second stress distribution portion 235, the second contact wing portion 230 The main body part 210 is formed at a predetermined position.

When the first stress dispersing part 225 and the second stress dispersing part 235 are formed in the first contact wing part 220 and the second contact wing part 230 as described above, a comparison of the stress distribution diagrams of FIGS. 16A and 16B The maximum stress concentration concentrated under the same load condition is remarkably reduced. 16A and 16B, when a torque of 4 [kg · m], which is the same load, is applied, the first stress distribution portion 225 is applied to the first contact wing portion 220 and the second contact wing portion 230, And the second stress dispersing portion 235 are formed. When the first stress dispersing portion 225 and the second stress dispersing portion 235 are formed, the maximum stress concentrated Is 222 [MPa], but when the first stress dispersing unit 225 and the second stress dispersing unit 235 are not formed, the maximum concentrated stress reaches 435 MPa.

On the other hand, the frame cross-connection bracket is prepared by purchasing PosMAC (product name), which is a high corrosion-resistant alloy steel produced by POSCO. In the case of POSMAV, alloyed steel with zinc, aluminum and magnesium is suitable for use in a watery environment.

A method for manufacturing a frame cross-linking bracket included in an aquarium photovoltaic apparatus according to an embodiment of the present invention will be described in detail with reference to FIGS. 17A to 17F.

First, as shown in FIG. 17A, PosMAC, which is a high corrosion resistant alloy steel produced by POSCO, is prepared as a material and then press cut to form a cruciform developed view. At this time, the main body 210, the first contact wing 220 and the second contact wing 230 are formed, and the first bolt hole 220a and the second bolt hole 220b are also formed. At the corner where the first contact wing 220 and the second contact wing 230 meet, the chamfer 222 is formed to facilitate the subsequent bending operation. The boundary between the main body 210 and the first contact wing 220 and the boundary between the body 210 and the second contact wing 230 are sliced to a low depth to form a folded line.

Thereafter, an operation for bending the developed view progresses. The first contact wing portion 220 and the second contact wing portion 230 are pressed against a predetermined portion of the main body portion 210 to form a first stress dispersing portion 225 having a semi- Thereby forming a stress dispersion portion 235. [

17C, the first contact wing 220 is folded upward to form a U-shape upward with the body 210, and the second contact wing 230 is folded upward along the folding line, Is bent downward to form a U-shape downward with the main body 210. Thus, the overall shape of the bracket for crossing the frame in the water photovoltaic generation apparatus according to the embodiment of the present invention is prepared.

Thereafter, an operation of forming a plating layer 211 of Ni-SiC material on the surface of the main body 210 proceeds. 15D, before forming the Ni-SiC plated layer 211 by electroplating, the first contact wing 220 and the second contact wing 230, which are the remainder of the body 210, Is covered with a tape 240 having an insulating and waterproof function so that only the main body 210 is exposed. Then immerse in the electrolyte solution in the electrolytic bath.

At this time, the upper taped base material is placed on the cathode of the electrolytic bath for forming the Ni-SiC plating layer 211, and the anode is placed on the anode with the Ni balls in the Ti basket Place it at a proper distance. The electrolyte solution is prepared using Ni-Sulfamate having a purity of 180% or more.

17E, a Ni-SiC plating layer 211 is formed only on the surface of the main body 210. When the plating layer 211 is formed, the dimples 211a are formed on the plating layer 211 by laser irradiation . This is because a low friction effect of the plating layer 211 and a low friction effect due to a plurality of patterned dimples 211a can be obtained in combination. If the dimples 211a are temporarily formed on the surface of the main body 210 and then the plating layer 211 is formed by electroplating, the electrolyte solution is uniformly formed in the dimples 211a of the small size formed first It is difficult to uniformly coat the entire surface of the main body 210, and the friction effect is reduced by half.

When the formation of the plating layer 211 and the formation of the dimples 211a are completed as in the above process, the dimples 211a are formed on the surface of the main body 210 in the manner of spraying or pressing the solid lubricant particles 212 strongly by the aerosol method, .

Then, the tape 240 surrounding the first contact wing 220 and the second contact wing 230 is peeled off. In this way, a frame cross connection bracket is completed in an aquarium power generation apparatus according to an embodiment of the present invention.

Subsequently, a modified configuration of the frame crossing connection bracket will be described.

18 is a perspective view for explaining a modified configuration of a frame crossing connection bracket in an aquarius solar power generation apparatus according to an embodiment of the present invention.

As shown in the figure, the frame cross connection bracket having a modified structure in the aquarium photovoltaic apparatus according to the embodiment of the present invention has a plurality of first and second stress dispersing units 225 and 235, And cutouts 225 and 135 are formed. According to such a configuration, when the applied load is less than a predetermined level, the first stress dispersing unit 225 and the second stress dispersing unit 235 disperse the stress so that the stress is not concentrated. However, , It acts as a damper that is deformed earlier than other parts and protects other parts. This not only broadens the range of coverage for various loads applied, but also allows for a precise prediction of the deformed portion of the entire frame cross-connecting bracket, which makes it possible to greatly facilitate the corresponding design of the load.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is clear that the present invention can be suitably modified and applied in the same manner. Therefore, the above description does not limit the scope of the present invention, which is defined by the limitations of the following claims.

100: half body 110: bottom plate
120: outer wall 123: fused portion
123a: thermal fusion line 130a:
130b vertical barrier rib 140 reinforcing projection
210: main body 211: plated layer
211a: dimple 212: solid lubricated particle
220: first contact wing 225: first stress distributor
230: second contact wing portion 235: second stress distribution portion

Claims (7)

A frame assembly including a float, a first frame and a second frame floating in a water phase by the float and crossing in a cross shape, and a frame cross connection bracket for connecting the first frame and the second frame, An aquarium photovoltaic device comprising a plurality of solar panels supported on an upper portion of an assembly,
In the float,
One of two semi-bodies molded individually in a container shape to have a bottom plate and an outer wall by injection molding is placed in the upper part of the other in an inverted state and then joined in a state of facing each other at the upper part and the lower part, And a plurality of fusing lines formed along an upper end of the outer wall of the semicircular body, the plurality of fusing lines being formed in an outward direction from the inner side of the outer wall end,
The frame crossing connection bracket includes:
A rectangular plate-shaped main body portion having one side and the other side opposite to each other contacting the first frame and the second frame; and a pair of side edge portions that are bent in one direction from one another and face each other A pair of first contact wings having a first bolt hole for bolt tightening to cover the surface of the first frame in a U shape together with the main body part, And a pair of second bolt holes for engaging a surface of the second frame in a U-shape together with the main body portion while being bent in the other direction from the other two side ends where the wing portion is not formed, And a second contact wing portion, wherein a portion of the first contact wing portion connected to the main body portion is formed as a curved surface having a semicircular cross section so as to disperse the stress And a first portion of the second contact wing portion connected to the main body portion is formed as a curved surface having a semicircular cross section so that stress can be dispersed,
In the float, a plurality of transverse bulkheads and longitudinal bulkheads for reinforcing the strength of the multi-room are formed in the hollow spaces formed by the semi-main body junctions, and the outer wall of the semi-main body is formed along the bottom- Wherein the outer wall of the semi-main body is gradually protruded toward the fused portion where the outer wall of the semi-main body contacts with each other,
A reinforcing protrusion protruding outward along the vertical portion is formed to a thickness greater than the thickness of the bottom plate at a vertical lower portion of the outer wall of the float, the reinforcing protrusion protruding on the same vertical line as the fused portion, And a skeleton structure formed by intersecting the vertical plate and the horizontal plate. delete The method according to claim 1,
Wherein the reinforcing protrusion is formed to a thickness of at least 8 times the thickness of the bottom plate. The method according to claim 1,
The bottom plate of the float is formed in a cross plate shape in which a plurality of ribs are orthogonal to each other to reinforce the strength and ribs connected to ribs formed on the bottom plate for reinforcing strength are formed in the horizontal partition wall and the vertical partition wall, Wherein the cradle is connected to a rib formed on the bottom plate. The method according to claim 1,
A plurality of pipe openings passing through the body vertically are formed at each intersection of the transverse bulkhead and the longitudinal bulkhead of the float, and an insulation support provided at the same height in the two pipe inner openings of the pipe openings, A first electrode fixed to one of the insulating supports and installed at a lower end of the tube so as to be elongated to the vicinity of a lower end of the tube, and a second electrode fixed to the other one of the insulation supports, the lower end having a shorter length than the first electrode, And a second electrode rod extending only to the upper portion,
A comparator for receiving and comparing a capacitance value due to water flowing into the first electrode rod, the second electrode rod, and water flowing into the pipe tube inner hole, and a comparator for receiving, from the first electrode rod and the second electrode rod, Further comprising a signal output unit for transmitting a signal to the outside,
So that the risk of flooding of the solar panel installed in the upper portion of the float can be judged. The method according to claim 1,
Wherein a plurality of cut-out portions are respectively formed in the first stress dispersing portion and the second stress dispersing portion of the frame cross-connecting bracket. The method according to claim 6,
The body portion of the frame crossing connection bracket is differentiated from the first contact wing portion and the second contact wing portion so as to reduce friction caused by surface contact with the first frame and the second frame, A plating layer of a Ni-SiC material having a thickness of 1.0 mm or less is formed, and a plurality of fine dimples having a diameter within a range of 50 to 250 mu m are formed in the plating layer, and the dimple of the plating layer is made cloudy, Wherein a plurality of fine oil pockets for receiving a liquid lubricant and reducing a friction area are formed on the surface of the solid lubricant particle and friction contact with the first frame and the second frame Characterized in that it consists of a material which causes fine particles to lubricate away from the surface PV device.

Images