KR101947148B1 - Damper and solar module apparatus having the same - Google Patents

Abstract

The present invention relates to a damper for generating a damping force only when an external force equal to or greater than a predetermined magnitude is applied to an entire section in a vertical direction inside a damper. A damper according to the present invention includes: a body having an inner space; A main rod having one end extended to the outside of the body and provided to be movable in the longitudinal direction of the body in the internal space; A buffer that is coupled to the other end of the main rod and is provided to be movable along the longitudinal direction of the body in the internal space, The buffer may include an upper valve capable of moving up and down with respect to a longitudinal direction of the body; A piston provided on the lower side of the upper valve with at least one through hole penetrating in the vertical direction; An elastic member provided between the upper valve and the piston, one end of which is coupled to a lower portion of the upper valve and the other end is coupled to an upper portion of the piston; A lower valve provided on the lower side of the piston with at least one through-hole penetrating in the vertical direction; And a lower portion of the auxiliary rod is engaged with a lower surface of the lower valve so that the auxiliary rod is moved upwardly to the lower portion of the lower valve, The lower valve is also elevatably provided together with the fluid filled in the inner space moving through the through hole and the through hole to buffer movement of the piston and the lower valve.

Description

[0001] DAMPER AND SOLAR MODULE APPARATUS HAVING THE SAME [0002]

The present invention relates to a damper and a solar module apparatus including the damper.

Recently, in order to replace fossil fuels, the construction of eco-friendly power generation facilities using solar energy, wind power, and tidal energy, which are clean energy sources that do not cause environmental pollution, is gradually increasing. Among these power generation facilities, a photovoltaic power generating device that generates power by arranging a photovoltaic module that converts sunlight into electric energy is attracting attention. The photovoltaic device does not require any additional energy or driving source, and has an advantage that it is not limited to the installation of photovoltaic devices of various sizes ranging from a small scale to a large scale. A plurality of solar cells are arranged in a solar cell module, and the solar cells are irradiated with sunlight to collect the collected energy.

1 is a view showing a conventional solar power generation apparatus.

The conventional photovoltaic device 1 is basically provided with a column 2 fixed to a ground or a poured concrete structure. A connecting member 3 may be provided on the upper portion of the column 2 and a connecting member 3 may be connected to the sunlight frame 4.

The solar module 5 may be disposed on the upper surface of the solar cell frame 4. [ The sunlight frame 4 is a structure having a rectangular shape with a large size and is used in a state in which an expensive solar module 5 is mounted.

There is a problem that the sunlight frame 4 is shaken due to strong wind, earthquake or vibration, the column is warped by the vibration generated thereby, or the sunlight frame 4 is separated from the column.

Further, conventionally, there is a problem that the vibration generated when the sunlight frame 4 is shaken can not be attenuated, and the structural stability of the solar cell generator 1 is remarkably lowered.

Further, even if a shock absorber such as a damper is provided to attenuate such vibration, the shock absorber requires many various parts and complicated designs in order to set the resistance value of the fluid. Therefore, there has been a difficulty in terms of suitable capacity, function, and unit cost to be applied to the photovoltaic device.

Further, in the conventional conventional damper, the orifice holes are formed with a constant cross sectional area, and there is a limit in which a damping force acts only in a certain section.

The present invention provides a damper capable of generating a buffering effect by reacting only with an external force equal to or greater than a predetermined magnitude in a whole section of a damper in a vertical direction.

The present invention relates to wind. And to provide a damper and a solar module device including the same that can maintain structural stability even with external influences such as vibration.

The present invention is to provide a damper capable of effectively damping vibration while simplifying the structure of a damper and a solar module apparatus including the damper.

The objects of the present invention are not limited thereto, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

The present invention provides a damper.

According to an embodiment of the present invention, there is provided a body having an internal space; A main rod having one end extended to the outside of the body and provided to be movable in the longitudinal direction of the body in the internal space; A buffer that is coupled to the other end of the main rod and is provided to be movable along the longitudinal direction of the body in the internal space, The buffer may include an upper valve capable of moving up and down with respect to a longitudinal direction of the body; A piston provided on the lower side of the upper valve with at least one through hole penetrating in the vertical direction; An elastic member provided between the upper valve and the piston, one end of which is coupled to a lower portion of the upper valve and the other end is coupled to an upper portion of the piston; A lower valve provided on the lower side of the piston with at least one through-hole penetrating in the vertical direction; And a lower portion of the auxiliary rod is engaged with a lower surface of the lower valve so that the auxiliary rod is moved upwardly to the lower portion of the lower valve, The lower valve is also elevatably provided together with the fluid filled in the inner space moving through the through hole and the through hole to buffer movement of the piston and the lower valve.

According to one embodiment, when the main rod descends along the longitudinal direction of the body by an external force, the piston descends along the main rod, the separation distance between the piston and the lower valve decreases, The piston and the lower valve rise along the main rod when the main rod rises along the longitudinal direction of the body by an external force, The fluid sequentially passes through the vent hole and the through hole, the spacing distance between the upper valve and the piston is reduced, and the elastic member is compressed, whereby a buffering effect is generated by the fluid and the elastic member.

According to an embodiment of the present invention, an upper portion of the elastic member is coupled to the upper portion of the piston, an end of the elastic member is coupled to the upper portion of the upper portion of the piston, When the valve is in close contact with the piston, a predetermined region of the upper portion of the through hole is blocked by the upper valve.

According to an embodiment of the present invention, the upper valve is provided with a vent hole passing through in the vertical direction, and the vent hole is provided so as to have a cross sectional area smaller than that of the through hole, and the vent hole is in contact with the piston Is formed at a position where the vent hole and the through hole can communicate with each other.

According to one embodiment, the lower surface of the piston is formed to be inclined at a predetermined angle with respect to the longitudinal direction of the body, the upper surface of the lower valve is formed to be inclined at a predetermined angle with respect to the longitudinal direction of the body, The inclination angle and shape of the surface correspond to the inclination angle and shape of the lower surface of the piston, and the upper surface of the lower valve and the lower surface of the piston are provided so as to be in close contact with each other.

According to one embodiment, the cross-sectional area of the through-hole is larger than the cross-sectional area of the through-hole such that the flow rate through the through-hole is smaller than the flow rate through the through-hole.

According to one embodiment, the cross-sectional area of the latching portion is formed to be larger than the cross-sectional area of the hollow portion of the lower valve, so that the lower end of the auxiliary rod is engaged with the lower surface of the lower valve adjacent to the hollow.

The present invention provides a solar module device.

According to an embodiment of the present invention, there is provided a main frame, which is installed side by side with the ground, A rotation support portion for allowing the main frame to rotate axially; And a support frame installed on the lower side of the main frame and supporting the main frame from the ground, wherein the damper is interlocked with the main frame and is installed by being inclined at a predetermined angle with respect to the support frame, When the main frame rotates, the rotation of the main frame is buffered.

According to an embodiment of the present invention, there is further provided a structural frame installed on the main frame and on which a solar panel is mounted, and the structural frame and the main frame are interlocked with each other and rotated.

According to an embodiment of the present invention, a buffering effect can be generated only when an external force equal to or greater than a predetermined magnitude is applied to the entire section of the damper in the vertical direction.

According to an embodiment of the present invention, Stability of structure can be maintained even with external force due to external influence such as vibration

According to the embodiment of the present invention, it is possible to efficiently damp vibration due to external force while simplifying the structure of the damper.

The effects of the present invention are not limited to the above-mentioned effects, and the effects not mentioned can be clearly understood by those skilled in the art from the present specification and attached drawings.

1 is a side view showing a conventional solar module device.
2 to 8 are perspective views showing a damper according to the present invention.
9 to 11 are side cross-sectional views sequentially showing the operation of the damper according to the present invention when the external force acts on the upper side.
12 to 15 are side cross-sectional views sequentially showing the internal operation of the damper according to the present invention when the external force acts downward.
16 is a perspective view showing a solar module apparatus according to the present invention.
Figs. 17 to 19 are side views sequentially showing changes of the solar module apparatus, which causes an external force to act on the upper side of the damper.
Figs. 20 to 22 are side views sequentially showing changes of the solar module apparatus, which causes an external force to act on the lower side of the damper.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be construed as being limited to the following embodiments. This embodiment is provided to more fully describe the present invention to those skilled in the art. The shape of the elements in the figures is therefore exaggerated to emphasize a clearer description.

Hereinafter, an example of the present invention will be described in detail with reference to FIG. 2 to FIG. FIGS. 2 to 15 are views of a damper according to the present invention, and FIGS. 16 to 22 are views showing a solar module apparatus according to the present invention.

2 and 8 are views showing a damper according to the present invention.

2 to 8, a damper 10 according to the present invention includes a body 100, a main rod 200, and a buffer part 300.

The body (100) forms the outer shape of the damper (10). The body (100) has an internal space (S). The fluid is stored in the inner space (S). The fluid may be viscous oil. The buffer space 300 described later is located in the inner space S of the body 100.

The main rod 200 transmits an external force to the buffer part 300. External force can be applied by various factors such as wind pressure and earthquake. The main rod 200 is movable up and down with respect to the longitudinal direction of the body 100. One end of the main rod 200 extends to the outside of the body 100. The other end of the main rod 200 is coupled to the buffer part 300 described later. That is, a part of the main rod 200 is exposed to the outside of the body 100, and the remaining part is inserted into the inside of the body 100. Further, the main rod 200 serves as a shaft of an upper valve and a lower valve, which will be described later.

4 is a side sectional view showing an enlarged view of the cushioning portion which is the region A in Fig.

The buffer portion 300 includes an upper valve 310, a support member 320, a piston 330, an elastic member 340, a lower valve 350, and an auxiliary rod 360. The buffering part (300) buffers the movement of the main rod (200). By relaxing the movement of the main rod 200, a buffering effect as the damper 10 is generated.

The upper valve 310 is provided movably along the longitudinal direction of the body 100 in the inner space S of the body 100. The upper valve 310 may be in a disc shape. The upper valve 310 is provided to cover an upper portion of the piston 330, which will be described later. Particularly, when the upper valve 310 is in close contact with the piston 330 to be described later, the upper valve 310 is provided so as to cover and cover a predetermined area of the upper portion of the through hole 332 formed in the piston 330.

Sectional area of the upper valve 310 may be smaller than the cross-sectional area of the piston 330. [ The upper valve 310 may have a vent hole 312 penetrating in the vertical direction. The fluid passes through the vent hole 312. At least one vent hole 312 may be formed. The vent hole 312 is formed at a position corresponding to the through hole 332 so as to be able to communicate with the through hole 332 of the piston 330 which will be described later.

The support member 320 supports the upper valve 310 from above the upper valve 310. That is, the upper limit of the range in which the upper valve 310 moves upward is set so that the vertical movement is possible only within the predetermined height range. In other words, the support member 320 serves as a stopper to prevent the upper valve 310 from moving beyond a certain range. The upper valve 310 can be moved up and down only in the space between the support member 320 on the upper side and the piston 330 on the lower side.

The piston 330 is located below the upper valve 310. On the side surface of the piston 330, a piston ring 331 is provided. The outer surface of the piston 330 is spaced a predetermined distance from the inner surface of the body 100 and the piston ring 331 is in contact with the inner surface of the body 100. When the piston 330 moves up and down, the piston ring 331 contacts the inner surface of the body 100 to prevent the piston 330 from being worn. That is, the piston ring 331 may be worn instead of the piston 330.

The piston 330 may have a center hole, a through hole 332, and a seating groove 334.

An auxiliary rod 360 to be described later is inserted into the center hole. The auxiliary rod 360 is inserted continuously into the center hole of the piston 330 and the lower valve 350. The auxiliary rod 360 can be assembled to the center hole in a bolt-fastening manner. For example, the auxiliary rod 360 may be an assembly screw.

The through hole 332 passes through the piston 330 in the vertical direction. One or a plurality of through holes 332 may be formed. The fluid passes through the through hole (332). The through hole 332 may be formed to have a larger sectional area than the vent hole 312. In this regard, the operation of the damper 10 will be described later.

The seating groove 334 is formed on the upper portion of the piston 330. An elastic member 340, which will be described later, is seated on the seating groove 334. The seating groove 334 may be formed to a depth such that all of the compressed elastic members 340 can be inserted completely. As a result, the upper valve 310 can be contacted without being separated from the piston 330.

Alternatively, the upper valve 310 may be inserted into the seating groove 334 together with the elastic member 340. For example, when the upper valve 310 and the piston 330 have a circular cross section, the diameter of the upper valve 310 may be smaller than the diameter of the piston 330. The upper valve 310 may be formed with a diameter corresponding to the position of the seating groove 334 so that the upper valve 310 can be inserted into the seating groove 334 together with the elastic member 340.

The lower surface of the piston 330 may be formed as an inclined surface inclined at a predetermined angle with respect to the longitudinal direction of the body 100. That is, the contact surface that contacts the lower valve 350 described later may be formed as an inclined surface.

The elastic member 340 is provided in the inner space S of the body 100. The elastic member 340 is provided between the upper valve 310 and the piston 330. The elastic member 340 may be a spring. One end of the elastic member 340 is coupled to the lower portion of the upper valve 310 and the other end is coupled to the upper portion of the piston 330. For example, the other end of the elastic member 340 is engaged with a seating groove 334 provided on the piston 330. When the elastic member 340 is compressed, as described above, the elastic member 340 may be entirely inserted into the seating groove 334 and not exposed to the outside. For example, when the upper valve 310 and the piston 330 come into close contact with each other, the elastic members 340 are all inserted into the seating grooves 334.

The elastic member 340 performs a buffer function when an external force acts on the upper side of the main rod 200. In this regard, the operation of the damper 10 will be described later in detail.

The lower valve 350 is provided in the inner space S of the body 100. The lower valve 350 is provided on the lower side of the piston 330.

The lower valve 350 is formed with at least one through hole 352 penetrating in the up and down direction. The fluid passes through the through hole 352.

At the center of the lower valve 350, a hollow 353 penetrating in the vertical direction is formed. The lower portion of the auxiliary rod 360, which will be described later, is inserted into the hollow. The hollow 353 is formed as an elliptical long hole.

The upper surface of the lower valve 350 is formed to be inclined at a predetermined angle to correspond to the lower surface of the piston 330, and the lower surface of the lower valve 350 is formed flat. This is to make it easier for the lower valve 350 and the piston 330 to be separated from each other while being in contact with each other. This is related to both the shape of the lower valve 350, the elliptical hollow 353, the auxiliary rod 360 described later, and the latching portion 362 of the auxiliary rod 360, Details will be described later.

The through hole 352 is formed at a position corresponding to the through hole 332 when the piston 330 and the lower valve 350 are in contact with each other. When a plurality of through holes 332 are provided, a plurality of through holes 352 may also be formed. At this time, each through hole 352 is formed at a corresponding position so as to communicate with each through hole 332. Therefore, the through hole 352 and the through hole 332 are communicated with each other, and the fluid passes through the through hole 352 and the through hole 332, thereby generating a damping force, that is, a buffering effect.

However, as will be described later, when the lower valve 350 falls due to its own weight, it rotates clockwise or counterclockwise, so that the through hole 352 deviates from the position communicating with the through hole 332 .

The through hole 352 may be formed to have a smaller cross sectional area than the through hole 332. The flow rate through the through hole 352 is smaller than the flow rate through the through hole 332 when comparing the flow rate through which the fluid passes.

On the other hand, in the conventional general damper, the orifice hole formed in the piston has a constant cross-sectional area, so that the damping effect is generated only in a certain section. However, the present invention has the additional configuration of the lower valve 350 separately from the piston 330, and the sizes of the through holes 352 formed in the lower valve 350 and the through holes 332 formed in the piston 330 are different from each other And the through hole 352 and the through hole 330 are communicated with each other, there is an effect of generating a damping force, that is, a buffering effect in the entire section of the damper.

 The number of the through holes 352 may be larger than the number of the through holes 332. In this case, all of the through holes 352 are formed so as to communicate with the through holes 332. The size of the damping force can be adjusted by variously setting the number of the through holes 352 or the cross sectional area of the through holes 352.

The total sum of the cross sectional areas of the through holes 352 is smaller than the sum of the cross sectional areas of the through holes 332 when the through holes 332 and the through holes 352 are plural. As a result, the buffering effect on the falling can be larger than the buffering effect on the rising.

Concretely, a high buffering effect is required because there is generally a risk of breakage when the external force acts downward, that is, when the main rod 200 moves downward. Receiving the resistance of the fluid when the external force acts on the lower side is the lower valve 350 and the fluid rises through the through hole 352 of the lower valve 350. The smaller the cross-sectional area of the through hole 352, the more excellent the buffering effect will be. Therefore, by reducing the through hole 352, the buffering effect at the time of lowering can be increased.

On the other hand, when the external force acts on the upper side, that is, when the main rod 200 moves upward, since there is less risk of breakage generally than when the main rod 200 descends, the buffering effect may be relatively low . On the contrary, when the buffering effect is unnecessarily high, it is disadvantageous in terms of time and so, it is preferable to form the through hole 332 having a larger cross-sectional area than the through hole 352.

The specific sizes of the through holes 352 and the through holes 332 can be set for each device for installing the damper 10 through testing and simulation.

The auxiliary rod 360 supports the lower valve 350 so as not to fall inside the body 100. A screw thread is formed on an upper outer side surface of the auxiliary rod 360. An upper portion of the auxiliary rod 360 is bolted and fixed to a center hole formed at the center of the piston 330. [ In addition, the lower portion of the auxiliary rod 360 is inserted into the elliptical hollow 353 of the lower valve 350. The auxiliary rod 360 is provided in a cylindrical shape having a circular cross section. Accordingly, the lower portion of the auxiliary rod 360 is not fixedly coupled to the hollow 353, and the lower valve 350 can move up and down within a predetermined range.

The upper surface of the lower valve 350 may be formed to be inclined with respect to the longitudinal direction of the body 100. At this time, the degree of inclination is the same as the inclination of the lower surface of the piston 330, and the lower surface of the piston 330 and the upper surface of the lower valve 350 can be in close contact with each other.

A locking portion 362 is formed at the lower end of the auxiliary rod 360. The latching portion 362 is caught by the lower surface of the lower valve 350, so that the lower valve 350 can be supported so as not to fall. Therefore, when the auxiliary rod 360 rises, the latching portion 362 is caught on the lower surface of the lower valve 350, so that the lower valve 350 also ascends.

For example, the cross-sectional area of the latching portion 362 may be larger than the cross-sectional area of the elliptical hollow 353 formed in the lower valve 350. Further, the end surface of the latching portion 362 may be formed in a circular shape. The latching portion 362 covers the entire lower portion of the hollow 353 so that the lower valve 350 can be supported over the latching portion.

The engaging portion 362 at the lower end of the auxiliary rod 360 is exposed to the outside from the lower side of the lower valve 350 while the auxiliary rod 360 is inserted into the hollow 353. The lower edge of the auxiliary rod 360 may be engaged with the lower surface of the lower valve 350 adjacent to the hollow.

Therefore, when the auxiliary rod 360 moves upward, the latching portion 362 supports the lower surface of the lower valve 350, so that the lower valve 350 can also rise. When the auxiliary rod 360 is moved downward, the lower valve 350 is lifted by the fluid and the auxiliary rod 360 is lowered at a higher speed, so that the engagement of the engagement portion 362 and the lower valve 350 The lower surface does not touch. In this regard, the operation of the damper 10 will be described later in detail.

Since the fluid is viscous oil, the lower valve 350 and the piston 330 are separated from each other by the surface roughness and the surface tension at the close contact surface between the lower valve 350 and the piston 330 It is not easy.

However, since the hollow 353 formed in the lower valve 350 is formed as an elliptical long hole, the upper surface of the lower valve 350 is formed to be inclined, while the lower portion is made flat, When the lower valve 350 is in contact with the lower valve 350 and the engaging portion 362 and the lower valve 350 is not in equilibrium and is biased to one side, 350 can be easily separated and separated.

Specifically, the lower surface of the lower valve 350 and the piston 330 are formed as inclined surfaces. In particular, the lower surface of the lower valve 350 is formed flat so that one side and the other side of the lower valve 350 are weighted different. Specifically, one side of the lower valve 350 is heavier than the other side. Here, one side of the lower valve 350 refers to a portion having a relatively higher side as the upper surface among the inclined upper surfaces.

After the upper surface of the lower valve 350 and the lower surface of the piston come into close contact with each other, when the external force is removed and the lower valve 350 is dropped by gravity, one side is heavier and tilted to the heavy side. Since the hollow 353 of the lower valve 350 is elliptic and the area of the cross section of the auxiliary rod 360 is smaller than the area of the hollow 353, the lower valve 350 naturally forms the auxiliary rod 360 In the clockwise or counterclockwise direction. That is, at this time, the outer surface of the lower valve 350 and the inner surface of the hollow 353 are partially in contact with each other so that the lower valve 350 rotates along the auxiliary rod 360.

In addition, while the hollow is oval, the cross section of the engagement portion is circular, so that even if the lower valve is supported by the engagement portion, a relatively small portion is supported on one side and a relatively large portion is supported on the other side. At this time, the lower valve 350 is supported by the latching portion 362, but is not supported horizontally, but is biased toward one side of the heavy valve 350, Is not supported in a balanced state. As a result of this phenomenon, the lower valve 350 is accelerated to descend in a clockwise or counterclockwise direction when it falls due to its own weight. As a result, the lower surface of the piston 330 and the upper surface of the lower valve 350 The surface is easily separated and separated.

Hereinafter, the operation of the damper 10 will be described. Figs. 9 to 11 are diagrams sequentially showing changes in the damper 10 when an external force acts on the upper side. The internal space S of the body 100 is filled with fluid. The fluid may be viscous oil, as described above.

Figs. 9 to 11 are diagrams sequentially showing changes in the damper 10 when an external force acts on the upper side. 9 to 11, the operation of the damper 10 when the external force acts on the upper side will be described. That is, the external force moves the main rod 200 upward.

When the external force moves the main rod 200 upward along the body 100, the piston 330 and the upper valve 310 move upward along the main rod 200. Further, since the auxiliary rod 360 is caught at the lower portion of the lower valve 350, the lower valve 350 also ascends.

The fluid sequentially passes through the vent hole 312 and the through hole 332 to generate a buffering effect. Since the size of the vent hole 312 is smaller than the through hole 332, the resistance by the fluid acting on the upper valve 310 is larger than the resistance acting on the piston 330. Therefore, the upper valve 310 can not be lifted by the rising height of the piston 330, and the separation distance between the upper valve 310 and the piston 330 gradually decreases. As a result, a buffer effect by the fluid occurs. After a certain period of time, the upper valve 310 may contact the upper surface of the piston 330. At this time, as shown in Fig. 10, the elastic member 340 can be compressed until it is completely inserted into the seating groove 334. [

The buffering effect by the elastic member 340 also occurs during the compression of the elastic member 340. Therefore, it is possible to alleviate the problem of breakage of the structure due to external pressure. When the external force is removed, the main rod 200, the upper valve 310, the piston 330, and the lower valve 350 descend again by gravity and return to the initial state. Also, the distance between the upper valve 310 and the piston 330 is returned to the initial state by the elastic force of the elastic member 340.

12 to 15 are diagrams sequentially showing changes in the damper 10 when the external force acts downward. Referring to Figs. 12 to 15, the operation of the damper 10 when the external force acts downward will be described. That is, the external force moves the main rod 200 downward.

When the external force moves the main rod 200 downward along the longitudinal direction of the body 100, the upper valve 310 and the piston 330 also descend along the main rod 200.

13, when the lower valve 350 is in the loaded state by the fluid and the size of the through hole 352 formed in the lower valve 350 is larger than the size of the through hole 332 in the piston 330 Is smaller than the size of the through hole (332), a buffering effect by the fluid occurs. The fluid sequentially passes through the through hole 352 and the through hole 332. The greater the resistance of the fluid acting on the lower valve 350, the shorter the distance between the piston 330 and the lower valve 350 becomes. After a period of time, the lower surface of the piston 330 and the upper surface of the lower valve 350 are in contact.

 When the external force is removed, the process returns to the state of FIG. 15 through the process of FIG. 14, which is tilted to one side by gravity. At this time, the lower valve 350 is lowered by the gravity and is separated from the piston 330. The lower valve 350 has a downward movement in the clockwise or counterclockwise direction and the lower valve 350 is rotated in the clockwise or counterclockwise direction, 350 and the piston 330 can be easily separated and separated. At this time, the through hole 350 and the through hole 332 are not in communication with each other, and are independent of the function of the damper.

The lower valve 350 is not caught by the latching portion 362 at the lower end of the piston 330 so that the lower valve 350 is no longer dropped and the separation distance between the piston 330 and the lower valve 350 is the initial state Lt; / RTI >

16 is a perspective view showing a solar module apparatus 1000 having a damper 1600 according to the present invention. A solar module apparatus 1000 according to the present invention includes a main frame 1100, a rotation support 1200, an auxiliary support 1300, a support frame 1400, a structure frame 1500, and a damper 1600 .

The main frame 1100 is installed side by side with the ground. The main frame 1100 is rotatably provided. The main frame 1100 is rotatable about its axis as its central axis.

The rotation support part 1200 is installed on the main frame 1100 so that the main frame 1100 can rotate the shaft.

The auxiliary support portion 1300 may be provided to protrude a predetermined distance outside the main frame 1100. The auxiliary support portion 1300 may be installed to interlock with the movement of the main frame 1100 and the rotation support portion 1200. For example, the auxiliary support portion 1300 may be fixedly coupled to the main frame 1100 and the rotation support portion 1200.

A damper 1600 is connected to the auxiliary supporting portion 1300. For example, the end of the main rod 200 of the damper 1600 may be connected. The auxiliary supporting portion 1300 is fixedly coupled to the main frame 1100 so that when the main frame 1100 rotates, the auxiliary supporting portion 1300 also rotates together with the auxiliary supporting portion 1300.

The support frame 1400 is fixedly mounted on the ground to connect the ground and the main frame 1100. The support frame 1400 supports the main frame 1100 from the ground. The main frame 1100 and the support frame 1400 may form a vertical. The support frame 1400 may be provided in the subframe 1410. The end of the damper 1600, which will be described later, can be coupled to the subframe 1410.

In the structure frame 1500, a solar panel is seated. The structure frame 1500 is installed in the main frame 1100. And can be rotated in conjunction with the main frame 1100. In one example, the structure frame 1500 may be fixedly coupled to the main frame 1100. [ The structure frame 1500 can form a vertical with the main frame 1100 and the support frame 1400. [ The structure frame 1500 and the main frame 1100 are interlocked with each other to allow the main frame 1100 to rotate axially.

The damper 1600 buffers the rotation of the main frame 1100 when the main frame 1100 rotates. The damper 1600 has the same damper 1600 as the damper 1600 according to the present invention described above. The damper 1600 operates in conjunction with the main frame 1100. The damper 1600 may be coupled to the auxiliary support 1300 and the support frame 1400. The damper 1600 may be installed at a predetermined angle with respect to the support frame 1400. That is, one end of the damper 1600, for example, one end of the main rod 200 may be coupled to the auxiliary support portion 1300, and the other end of the damper 1600 may be coupled to the support frame 1400. Alternatively, the other end of the damper 1600 may be coupled to the subframe 1410 provided in the support frame 1400. Since the auxiliary support portion 1300 protrudes outside the main frame 1100, the damper 1600 can be installed to be inclined with respect to the support frame 1400.

Hereinafter, the occurrence of the buffering effect by the damper 1600 when an external force acts on the solar cell module device 1000 will be described.

When an external force is applied due to a draft, an earthquake or other factors, the structural frame 1500 rotates. At this time, the rotation is possible by the rotation of the rotary support portion 1200, the main frame 1100, and the auxiliary support portion 1300. One end of the damper 1600 is fixed to the auxiliary supporting portion 1300 and the other end of the damper 1600 is fixedly coupled to the supporting frame 1400. The main rod 200 of the damper 1600 is moved up and down along the longitudinal direction of the body 100 Move.

17 to 19 are side views sequentially showing cases in which an external force such as a draft or the like acts on the upper side of the damper 1600. Fig. At this time, the inside of the damper 1600 can operate in the same or similar manner as in Figs.

20 to 22 are diagrams sequentially showing cases in which external force acts on the lower side of the damper 1600 by an external force. At this time, the inside of the damper 1600 may operate in the same or similar manner as in Figs.

In the above-described embodiment, the solar panel is seated in the structure frame 1500, but the present invention is not limited thereto, and various panels or structures may be seated. The damper 10 described above can be installed not only in a solar module apparatus but also in any other apparatus requiring a damper such as a vehicle.

In general damper, damping force always acts regardless of the magnitude of the external force applied in the upper and lower direction within the damper. However, in the entire upper and lower direction of the damper according to the present invention, But functions only as a damper when an external force equal to or greater than a predetermined magnitude is applied.

That is, in the present invention, only when the upper valve, the piston, and the lower valve move freely in the vertical direction within the damper body and an external force of a predetermined magnitude or more is applied by wind power or the like, Can be generated.

The foregoing detailed description is illustrative of the present invention. In addition, the foregoing is intended to illustrate and explain the preferred embodiments of the present invention, and the present invention may be used in various other combinations, modifications, and environments. That is, it is possible to make changes or modifications within the scope of the concept of the invention disclosed in this specification, within the scope of the disclosure, and / or within the skill and knowledge of the art. The above-described embodiments illustrate the best mode for carrying out the technical idea of the present invention, and various modifications required for specific application fields and uses of the present invention are also possible. Accordingly, the detailed description of the invention is not intended to limit the invention to the disclosed embodiments. It is also to be understood that the appended claims are intended to cover such other embodiments.

10: damper 100: body
200: main load 300: buffer
310: upper valve 320: support member
330: piston 340: elastic member
350: lower valve 360: auxiliary rod
1000: solar module device 1100: main frame
1200: rotation support part 1300: auxiliary support part
1400: Support frame 1500: Structure frame

Claims (8)

A body having an inner space;
A main rod having one end extended to the outside of the body and provided to be movable in the longitudinal direction of the body in the internal space; And
And a buffer that is coupled to the other end of the main rod and is provided to be movable along the longitudinal direction of the body in the internal space,
The buffering portion
An upper valve capable of moving up and down with respect to a longitudinal direction of the body and having a vent hole penetrating in a vertical direction;
A piston provided on the lower side of the upper valve with at least one through hole penetrating in the vertical direction;
An elastic member provided between the upper valve and the piston, one end of which is coupled to a lower portion of the upper valve and the other end is coupled to an upper portion of the piston;
A lower valve through which one or more through-holes penetrating in the up-and-down direction and having a cross-sectional area smaller than the cross-sectional area of the through-hole are formed, and a distance from the piston is changeably provided on the lower side of the piston; And
An upper portion coupled to the piston, and a lower portion inserted into the hollow of the lower valve,
The lower end of the auxiliary rod is provided with a latching portion to be hooked on the lower surface of the lower valve, and when the auxiliary rod rises, the lower valve is also elevatably provided together,
Wherein the fluid filled in the inner space moves through the through hole and the through hole to buffer the movement of the piston and the lower valve.
The method according to claim 1,
When the main rod descends along the longitudinal direction of the body by an external force, the piston descends along the main rod, the separation distance between the piston and the lower valve decreases, and the fluid flows through the through- A buffering effect is generated while passing sequentially,
When the main rod rises along the longitudinal direction of the body by an external force, the piston and the lower valve rise along the main rod, the fluid sequentially passes through the vent hole and the through hole, Wherein a spacing distance between the upper valve and the piston is reduced and the elastic member is compressed so that a buffering effect is generated by the fluid and the elastic member.
3. The method of claim 2,
Wherein an upper end of the elastic member is coupled to the upper valve and an opposite end of the elastic member is coupled to the seating groove,
Wherein when the upper valve is in close contact with the piston, a predetermined region of the upper portion of the through hole is blocked by the upper valve.
The method of claim 3,
Wherein the vent hole is provided so as to be smaller in cross-sectional area than the through hole,
The vent hole
And the damper is formed at a position where the vent hole and the through hole can communicate with each other when the upper valve is in close contact with the piston.
3. The method of claim 2,
The lower surface of the piston is formed to be inclined at a predetermined angle with respect to the longitudinal direction of the body,
Wherein the upper surface of the lower valve is inclined at a predetermined angle with respect to the longitudinal direction of the body,
Wherein an inclination angle and a shape of an upper surface of the lower valve correspond to an inclination angle and a shape of a lower surface of the piston so that an upper surface of the lower valve and a lower surface of the piston are in close contact with each other.
delete 6. The method according to any one of claims 2 to 5,
Wherein a cross-sectional area of the latching portion is larger than a cross-sectional area of the hollow portion of the lower valve, and the lower end of the auxiliary rod is provided to be engaged with a lower surface of the lower valve adjacent to the hollow.
A solar module apparatus comprising a damper according to claim 1,
A main frame provided parallel to the ground and capable of pivoting about a longitudinal axis as a central axis;
A structural frame installed on the main frame and having a solar panel mounted thereon; And
And a support frame installed below the main frame and supporting the main frame from the ground,
Wherein the structural frame and the main frame are interlocked with each other,
Wherein the damper is interlocked with the main frame and is installed at a predetermined angle with respect to the support frame,
Wherein the damper buffers the rotation of the main frame when the main frame rotates.

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