KR101955319B1 - Pipeline drainage in underground distribution line - Google Patents

Abstract

The present invention relates to a pipeline drainage device of an underground distribution line and, more specifically, to a pipeline drainage device of an underground distribution line which increases ventilation efficiency in order to prevent an accident related to safety which can lead to a short circuit and an electric shock accident due to increased humidity from occurring when defects of drainage and ventilation of the distribution line installed underground are generated; and prevents a secondary electrical accident related to safety which is caused by rack damage inside an underground pipe due to external force such as an earthquake and the like. Moreover, the present invention relates to a pipeline drainage device of an underground distribution line which is improved to prevent flooding and the electrical accident related to safety in accordance with the flooding, by rapidly and automatically draining water even when the distribution line is filled with the water due to moisture or inflow of the water. To this end, the pipeline drainage device of an underground distribution line comprises an underground pipe, a baseplate, a support, a plurality of racks and a plurality of underground distribution lines.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a pipeline drainage system,

More particularly, the present invention relates to a pipe drainage system for underground distribution lines, and more particularly, it relates to a distribution line installed in the ground, It is possible to prevent secondary electric safety accidents caused by external damage such as an earthquake inside the underground pipe due to an external force such as an earthquake or the like, To an underground distribution line with an improved drainage system to prevent flooding and prevent electric accidents due to flooding.

In general, electric power lines are installed in electric poles or buried in the ground in order to supply electric power. The ground and airborne type are much more economical than the method of buried in the ground in consideration of the workability, the construction cost and the construction period Although there is an advantage that construction can be simplified, it is disadvantageous that it is difficult to install in a place where buildings are very close to each other, such as a downtown area.

For example, in a power plant including a thermal power plant, a hydroelectric power plant, and a nuclear power plant, electricity generated at a voltage of about 20,000 V is boosted to ultra high voltage (154 KV or 345 KV) suitable for transmission, To the primary substation.

Then, the primary substation lowers the super-high voltage electric power to 22.9 KV, which is the special high voltage, and transmits or distributes electricity to the general customers along the secondary substations or distribution lines located near the large capacity customers.

At this time, the electricity distributed from the first substation or the second substation is transmitted or distributed to the reception facilities of each customer through the transmission and distribution system composed of the processing distribution line and the underground distribution line. Through the special high pressure customer, the high pressure consumer and various outdoor installation transformers, It is used for industrial and home use.

Generally, in the transmission and distribution system using the ground, the underground pipe is placed in the ground so that the gap is maintained in the up, down, left and right directions, and a cable or underground distribution line is installed to transmit electric power to the hole formed in the underground pipe. Transmits high voltage.

The above-mentioned underground pipes must be kept in a constant spacing, and it is difficult to maintain a uniform spacing of the ground.

In the underground pipe, a plurality of shelves for accommodating a plurality of wires (for example, extra high voltage cables, communication cables, etc.) are arranged at regular intervals, and underground distribution lines are mounted on the shelves, Supply.

Regarding such a power supply system, Patent No. 0881352 discloses a technique for preventing the shortening of the service life of a distribution line due to leakage of a concrete structure and an electric accident in advance, and is a technique for preventing the flow of a rotating shaft, a guide member, ≪ / RTI > is disclosed for a "distribution line forming panel of an extra high voltage underground wire"

However, such a configuration is not perfect, so that the shape of the underground pipe is distorted or flowed due to an external force such as an earthquake, so that some underground wires mounted on the shelf fall down to the bottom of the underground pipe, This causes a lot of maintenance costs and time-consuming work because the ground worker can not easily grasp the problem of the underground wires of any underground pipe among many underground pipes.

In addition, due to the nature of the distribution line installed in the ground, the humidity increases during drainage and bad ventilation, and there is a high risk of safety accidents that can lead to short-circuit and electric shock accidents during maintenance work.

Korean Patent Registration No. 10-1673966 (November 26, 2016) 'Manhole drainage and ventilation system in underground distribution line'

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems in the prior art, and it is an object of the present invention to solve the above-mentioned problems, It is possible to prevent secondary electric safety accidents caused by external damage such as an earthquake inside the underground pipe due to an external force such as an earthquake or the like, The main purpose of this system is to provide an improved drainage system of underground distribution line to prevent flooding and to prevent electric accidents caused by flooding.

A base plate 20 installed on an inner bottom surface of the underground pipe 10; a base plate 20 mounted on the base plate 20; And a plurality of underground distribution lines L which are seated on the shelves 24 and which are arranged in the vertical direction at the center of the shelves 24, 1. A pipeline drainage system for an underground distribution line including:
The shelf 24 was prepared by mixing 8.5 wt% of butyl prop-2-propenoate, 4.5 wt% of a mixture of azelic acid and pyrometric acid in a weight ratio of 1: 1, 3.5 wt% of amide, 2.0 wt% of water-soluble SiO ₃ , 1.5 wt% of methacrylic acid, 4 wt% of sodium bicarbonate and 2.5 wt% of borax were added to chromium oxide (Cr ₂ O ₃ ) And the calcined material was wet-crushed with a crusher to have a particle size of 1 μm or less. The resultant was then mixed with 4.5 wt% of an oxide powder dried at 100 ° C. for 10 hours, and a mixture of germanium and gallium arsenide and zinc selenide A resin composition composed of 3.5 wt% of a mixture mixed at a weight ratio of 1: 1: 1, 4.5 wt% of perfluoropolyether, 2.5 wt% of silicon nitride, 3.5 wt% of ytterbium oxide and remaining epoxy resin Molded into a plate shape;
The indoor air blowing box 100 is provided with an indoor air blowing box 100 and an outdoor air blowing box 200 on both sides of the inside of the underground pipe 10 and an indoor air blower 100 for sucking indoor air through the indoor air inlet 110 (120) is installed; The outside air blowing box 200 is provided with an outside air blower 220 for sucking outside air through an outside air inlet 210. An inside air outlet pipe 130 is connected to an outlet end of the inside air blower 120, (130) is piped along the ceiling surface of the underground pipe (10) and the plate heat exchanger (300) is connected to the end thereof; The inside air discharge pipe 140 is connected to the discharge end of the plate heat exchanger 300 and the inside air discharge pipe 140 has a plurality of discharge openings 142 toward the shelf 24 and discharges the heat- To be dispersed and discharged to the entire inside of the pipe (10); The outdoor air discharge pipe 230 is connected to the outlet end of the outdoor air blower 220 and the outdoor air discharge pipe 230 is piped along the ceiling surface of the underground pipe 10 and the end is connected to the plate heat exchanger 300. The outside air discharge pipe (240) is connected to the outflow end of the plate heat exchanger (300) to discharge the heat-exchanged external air to the ground, and the outside air suction pipe (250) Is configured to be able to suck in the outside air of the ground; Way valve 260 as a solenoid valve is further installed in the outside air discharge pipe 230 and the inside air discharge pipe 140 and is periodically opened and closed in accordance with a control signal of the controller while the inside air passing through the plate- (230) to the outside air flow channel of the plate heat exchanger (300), then discharged to the ground by the outside air discharge pipe (240), and the outside air sucked through the outside air suction pipe (250) To be distributed and supplied to the inside of the underground pipe (10) to ventilate,
The outer air discharge pipe 240 and the outdoor air suction pipe 250 are formed such that the upper end of the pipe is welded to the inner circumferential surface of the curled protective cover COV and integrated into a plurality of vent holes HOL around the upper end of the pipe The air is configured to prevent the infiltration of snow or rain while inducing the discharge of air;
The inside air blowing box 100 and the outside air blowing box 200 are made of 15 parts by weight of cellulose acetate, 15 parts by weight of a cellulose acylate so as to visually confirm the state of the built- %, 3.5% by weight of distearmonium hectorite, 30% by weight of transparent silica, 4.5% by weight of ceresin and the rest of the polycarbonate resin, and kept transparent;
The underground pipe 10 is embedded in a U-shaped support plate 510 surrounding the lower end of the underground pipe 10 and a lateral pressure reducing member The support plate 510 includes 25% by weight of an epoxy resin, 1.5% by weight of rosin, 10% by weight of a carbon fiber of 1 to 2 cm in length and 10% by weight of a remaining polycarbonate resin so as to have excellent corrosion resistance and durability The resin composition is molded;
A plurality of buffer side springs 530 are installed between both inner wall surfaces of the support plate 510 and both side surfaces of the lower end of the underground pipe 10; The upper end of the support plate 510 is closed by a skirt 540; The skirt 540 is obtained by molding a resin composition composed of 60% by weight of a silicone resin, 5% by weight of an allopene powder and the remaining EVA (ethylene-vinylalcohol copolymer) in a sheet form;
The underground pipe (10) further includes a drainage unit (700), wherein the drainage unit (700) includes a drainage guide plate (710) seated and fixed on the upper surface of the base plate (20) A drain blower 720 is installed on one side of the drain guide plate 710; The outlet end of the drainage blower 720 is disposed between the drainage guide plate 710 and the inner bottom surface of the underground pipe 10 so as to be exposed in a space created by the thickness of the base plate 20; A plurality of semicircular exhaust grooves 730 are formed on the upper surface of the base plate 20 except for the position where the support table 22 is fixed; A plurality of check valves 740 are installed on the drainage guide plate 710 opposite to the point where the drainage blower 720 is installed; A drain box 760 is provided at a lower portion of the support plate 510; The drainage box 760 has a structure in which a plurality of drainage holes are formed in the entire peripheral surface and a gravel layer 762 and a mesh layer 764 disposed on the gravel layer 762 are stacked; The drainage box 760 is communicated with a drainage space 750 formed at a lower portion of the drainage guide plate 710 through a drainage connection pipe 770.

According to the present invention, it is possible to increase the ventilation efficiency so as to prevent a safety accident that may lead to a short circuit or an electric shock accident due to the nature of a distribution line installed in the ground, It can prevent secondary electrical safety accidents caused by external damage to the shelf inside the underground pipe. It prevents water flooding and prevents electric safety accidents due to inundation by promptly and automatically discharging water even if it gets wet by moisture or water inflow. The effect can be obtained.

1 is an exemplary sectional view of an underground pipe constituting a pipe drainage device for an underground distribution line according to the present invention.
2 is an exemplary view for explaining an installation example of a pipe drainage device for an underground distribution line according to the present invention.
FIG. 3 (a) is an exemplary view showing the upper structure of the outdoor air discharge pipe and the outdoor air suction pipe of FIG. 2, and FIG. 3 (b) is a conceptual view showing an operation example of the 4-way valve.
4 is an exemplary cross-sectional view showing an installation example of a dustproof unit constituting a pipeline drainage device for an underground distribution line according to the present invention.
5 is an excerpt of an example of the lateral pressure reducing member of FIG.
FIG. 6 is an exemplary view showing an installation example of a drainage unit constituting a pipe drainage device for an underground distribution line according to the present invention. FIG.

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

Before describing the present invention, the following specific structural or functional descriptions are merely illustrative for the purpose of describing an embodiment according to the concept of the present invention, and embodiments according to the concept of the present invention may be embodied in various forms, And should not be construed as limited to the embodiments described herein.

In addition, since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments are illustrated in the drawings and described in detail herein. However, it should be understood that the embodiments according to the concept of the present invention are not intended to limit the present invention to specific modes of operation, but include all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

The pipeline drainage system of the underground distribution line according to the present invention includes an underground pipe 10 as shown in the example of FIG.

At this time, the underground pipe (10) is formed in the form of a rectangular box having an internal space that an operator can enter and maintain.

A base plate 20 is installed on the inner bottom surface of the underground pipe 10 and a support base 22 is installed vertically in the center of the base plate 20. A plurality of shelves 24 are installed.

In addition, the shelf 24 is provided with a plurality of ground distribution lines L at regular intervals.

These underground distribution lines L are held in a state of being mounted on the distribution line seating grooves 26 formed in the longitudinal direction on the upper surface of each shelf 24.

At this time, since the shelf 24 supports and fixes the underground distribution line L to which electricity is energized, it must have corrosion resistance, chemical resistance, and chemical resistance as well as insulation. To this end, butyl prop- 4.5 wt% of a mixture of azelic acid and pyrometric acid in a weight ratio of 1: 1, 3.5 wt% of ethylene bisstearamide, 2.0 wt% of water-soluble SiO ₃ , 1.5 wt% of methacrylic acid By weight of Cr ₂ O ₃ , 4% by weight of sodium bicarbonate and 2.5% by weight of borax are added, and the mixture is calcined at a temperature of 800 to 1200 ° C. and the calcined product is wet-crushed with a crusher to obtain Cr 4.5 wt% of an oxide powder dried at 100 캜 for 10 hours, 3.5 wt% of a mixture of germanium and gallium arsenide and zinc selenide in a weight ratio of 1: 1: 1, 4.5% by weight of polyether (perfluoropolyether), 2.5% by weight of silicon nitride % By weight of yttrium oxide, 3.5% by weight of calcined ytterbium oxide, and the balance epoxy resin is molded into a plate.

Here, the butyl-2-enoate is added to the resin composition in order to increase the bending strength while providing ductility, impact reinforcement and binding property strengthening function.

The mixture of azelaic acid and pyrometric acid in a weight ratio of 1: 1 is added in order to suppress heat shrinkage and to enhance slipperiness, thereby suppressing deformation of the molded article as well as sticking property.

Ethylene Bis Stearamide is added to prevent blocking and scratch by increasing surface smoothness of a molded article while suppressing yellowing.

In addition, the water-soluble SiO ₃ is added in order to eliminate the toxicity and is added in order to eliminate the harmfulness of the human body, and it is added in order to suppress the harmfulness of the human body when the operator enters by removing the six harmful substances, which are inevitably contained, such as heavy metals.

In addition, the methacrylic acid is added to maintain corrosion resistance because it is strong against acids.

Further, the chromium oxide constituting the oxide powder is intended to enhance heat resistance as a component that maintains an infrared reflectance of 30% or more. In sodium bicarbonate, the vaporized sodium gas acts on the oxide to form a glass phase on the surface of the oxide, And borax is a component added to enhance the bonding force while smoothing the oil surface of the oxide surface.

In this case, the reason for the firing is to increase the infrared reflectance. When the firing temperature is less than 800 ° C, the infrared absorption rate is increased and the heat resistance is poor. When the firing temperature exceeds 1200 ° C, magnetization phenomenon occurs. do.

Particularly, when high-temperature firing is performed, oxides are compounded and synthesized in addition to the above-mentioned characteristics, thereby forming a strong crystal structure and also having chemical characteristics excellent in weather resistance, heat resistance, chemical resistance and safety.

In addition, germanium, gallium arsenide and zinc selenide are materials for enhancing electrical insulation, and particularly excellent insulating properties are obtained when they are mixed at the same ratio. The reason why the insulating property is required in the present invention is to prevent an electric shock accident.

The perfluoropolyether is added in order to increase the slip property and to reduce the frictional resistance with the ground distribution line L to prevent peeling of the coating.

In addition, the silicon nitride is dispersed in amorphous nanoparticles of boron nitride and is added in order to absorb the thermal shock to suppress the generation of microcracks and to enhance the erosion resistance.

The calcined ytterbium oxide is added as a rare earth metal in order to increase the chemical resistance and chemical resistance while increasing the durability through grain refinement.

The epoxy resin is added as a base resin to enhance electrical insulation.

2, the indoor air blowing box 100 and the outdoor air blowing box 200 are provided on both sides of the inner side of the underground pipe 10, and the indoor air blowing box 100 is provided with an indoor air inlet 110 A blower 120 for sucking the inside air is installed.

At this time, a suction pipe (PIP) may be further connected to the suction hole 110 to increase the water absorption power dispersed throughout the underground pipe 10.

The outside air blowing box 200 is provided with an outside air blower 220 for sucking outside air through the outside air inlet 210.

The indoor air discharge pipe 130 is connected to the outlet end of the indoor air blower 120. The indoor air discharge pipe 130 is piped along the ceiling surface of the underground pipe 10 and the plate heat exchanger 300 .

In this case, the plate heat exchanger 300 is an indirect heat exchanger fixed to the front surface of the underground pipe 10 between the indoor air blowing box 100 and the outdoor air blowing box 200.

The plate heat exchanger 300 is a known heat exchanger configured to perform indirect heat exchange in a state in which the air flow path and the outside air flow path are separated from each other.

In addition, the inner ventilation pipe 140 is connected to the inner end of the plate-type heat exchanger 300, and the inner ventilation pipe 140 is provided with a plurality of injection openings 142 toward the shelf 24, So that the inside air can be dispersed and discharged to the entire inside of the underground pipe (10).

The outdoor air discharge pipe 230 is connected to the outlet end of the outdoor air blower 220. The outdoor air discharge pipe 230 is piped along the ceiling surface of the underground pipe 10 and the end is connected to the plate heat exchanger 300 .

Outer outlet pipe 240 is connected to the outlet end of the scraped plate heat exchanger 300 to discharge the heat exchanged outdoor air to the ground.

In addition, the outside air intake pipe 210 is connected to the outside air intake pipe 250 so as to be able to suck the outside air on the ground.

3 (a), the upper end of the pipe is welded and integrated with the inner circumferential surface of the protective cover (COV) in the form of a cowl, and the outer pipe suction pipe 250 and the pipe A plurality of ventilation holes (HOL) are formed around the upper end of the ventilation duct so that the ventilation of the outside air can be facilitated and the ventilation of the eyes and the rain can not be performed.

In addition, in the present invention, a four-way valve 260, which is a solenoid valve, is installed in the outside air discharge pipe 230 and the inside air discharge pipe 140 to achieve a ventilation function, And is configured to be able to perform the ventilation function by being periodically opened and closed.

3 (b), when the ventilation mode is switched to the ventilation mode according to the control signal of the controller, the 4-way valve 260 operates to allow the inside air passing through the plate heat exchanger 300 to pass through the outside air discharge pipe 230 The air is sucked through the outside air discharge pipe 240 and then sucked through the outside air suction pipe 250 is introduced into the underground pipe 10 As shown in FIG.

Thus, when the 4-way valve 260 is operated again by a control signal of the controller after a predetermined period of time, the circulation mode of the underground pipe 10, that is, the heat exchanger 300 The discharged air is distributed and supplied to the inside of the underground pipe 10 through the mood pipe 140. The introduced outside air flows through the outside air discharge pipe 230 and the plate heat exchanger 300 to the outside air discharge pipe 240, .

As described above, according to the present invention, not only the ventilation but also the dehumidifying function of drying the interior of the underground pipe 10 by removing the moisture contained in the indoor air by the indirect heat exchange method is performed during the maintenance of the operator An electric shock accident can be prevented.

Particularly, the operator can visually confirm the state of the built-in interior of the inside air blowing box 100 and the outside air blowing box 200 during the maintenance period, The box 100 and the outside air blowing box 200 contain 15% by weight of cellulose acetate, 3.5% by weight of distearmonium hectorite, 30% by weight of transparent silica, Ceresin 4.5 By weight, and the remaining polycarbonate resin so as to be kept transparent.

At this time, the acetic acid cellulose is an acetic acid ester obtained by acetylating a hydroxy group in a cellulose molecule, and is used in the present invention because of its nonflammability, insulation and durability improvement characteristics.

In addition, the distearammonium hectorite not only enhances the floating force through the formation of the coating film on the coated surface, but also improves the moisture resistance, as well as contributes to the control of the viscosity of the resin.

The above-mentioned transparent silica is a material having typical transparency improvement and waterproofing and moisture-proofing properties.

In addition, the ceresin has a property of enhancing emulsion stability, enhancing the bonding force between components, and maintaining the flexibility of the coated surface to enhance crack resistance.

In addition, the polycarbonate resin is a typical transparent resin and a high-strength durable resin, and is added as a base resin in the present invention.

In addition, a dustproof unit (SOCK) as shown in FIGS. 4 and 5 is further installed under the underground pipe 10 to enhance the seismic performance of the underground pipe 10 according to the present invention.

The dustproof unit (SOCK) is a means for absorbing a lateral pressure transmitted by an earthquake to prevent damage to the underground pipe (10). In the present invention, a shock can be buffered not only in lateral pressure but also in vertical pressure .

The dustproof unit SOCK includes a U-shaped support plate 510 to surround the lower end of the underground pipe 10.

The support plate 510 is formed by molding a resin composition composed of 25% by weight of an epoxy resin, 1.5% by weight of pine, 10% by weight of a carbon fiber of 1 to 2 cm in length, and the remaining polycarbonate resin so as to have excellent corrosion resistance and durability .

At this time, the support plate 510 is made larger than the underground pipe 10, and the lower end of the underground pipe 10 is completely inserted through the open top of the support plate 510.

At least two rack bars 520 are fixed to the lower end of the underground pipe 10 so that the rakes are directed downward. A pinion 610 is coupled to the rack bars 520 in a radial direction, The lateral pressure reducing member 600 is provided.

In this case, the lateral pressure reducing member 600 is fixed to the inner bottom surface of the support plate 510.

The lateral pressure reducing member 600 includes a rectangular box-shaped housing 610 having an open upper portion, a hydraulic block 620 fixed in a form embedded in the housing 610, And a filler inlet (INJ) installed through the housing (610) and the hydraulic block (620) so as to fill and fill the fluid inside.

A fixing flange 670 is integrally formed at both ends of the housing 610 in the longitudinal direction and the fastening bolt 680 is fastened to the fixing flange 670 so as to be connected to the upper and lower springs 690, Respectively.

That is, the housing 610 is mounted on the inner bottom surface of the support plate 510, and the bolts 610 are fixed to the support plate 510 by the fastening bolts 680 under the buffer upper and lower springs 690 in this state do.

Thus, the housing 610 is absorbed and buffered in response to the vertical pressure transmitted from the outside by the buffer up and down spring 690.

The hydraulic block 620 is assembled and fixed as a vertically separated structure so as to be able to embed internal products including the drive spur gear 640, the vertical gear 650, and the buffer plate 630.

In particular, the hydraulic block 620 includes a main chamber 622 which is filled with hydraulic pressure and is rotatably assembled in a state where the drive spur gear 640 and the idle gear 650 are gear-engaged with each other, A buffer chamber 626 having a spherical internal space at an interval from the main chamber 622 and a passing chamber 624 for connecting the main chamber 622 and the buffer chamber 626 in the vertical direction are formed.

A portion of the upper portion of the housing 610 is exposed to the outside of the hydraulic block 620 and is fixed coaxially with the driving spur gear 640, And a pinion 660 to be engaged with the rack gear 522 is provided.

At this time, the portion where the passing chamber 624 and the buffer chamber 626 communicate with each other is configured to have a relatively narrow flow passage as compared with the passing chamber 624. This is to induce momentary pressure increase during sudden hydraulic pressure fluctuation (hydraulic flow) so as to serve as a kind of buffer brake.

A buffer plate 630 having a symmetrical shape separated upward and downward is built in the buffer chamber 626 and a coil spring 632 is interposed between the buffer plates 630.

Particularly, the buffer plate 630 has a hemispherical shape, and the upper surface is recessed to a certain depth, so that the portions of the buffer plate 630 when the fluid flows in accordance with the hydraulic pressure fluctuation can be intensively pressed to be close to each other, The resilient repulsive force of the coil spring 632 can be restored to its original position and the fluid can be pushed out.

In addition, a plurality of buffer side springs 530 are provided between the inner wall surfaces on both sides of the support plate 510 and the lower end of the underground pipe 10 so as to be capable of absorbing the buffering force corresponding to the lateral pressure of the earthquake transmitted in the lateral direction .

In addition, it is preferable that the opening formed along the upper circumference of the support plate 510, that is, the space created by the gap with the underground tube 10 is closed by the skirt 540.

The skirt 540 is formed by molding a resin composition consisting of 60% by weight of a silicone resin, 5% by weight of an allophen powder and the remainder of an ethylene-vinyl alcohol copolymer (EVA) in a sheet form in order to enhance waterproofness, water repellency and flexibility desirable.

The vibration-proof unit (SOCK) configured as described above causes the support plate 510 to momentarily move horizontally in a transverse direction when a lateral pressure is applied due to an earthquake.

At this time, the pinion 660 rotates while moving on the rack shaft 522, and the driving spur gear 640, which is coaxial with the pinion 660, also rotates at the same rotational speed.

Accordingly, the idle gear 650 engaged with the driving spur gear 640 rotates at the same speed, so that the fluid filled in the main chamber 622 is pumped to the buffering chamber 624 and flows toward the buffering chamber 626 And absorbs external energy while compressing the buffer plate 630 in the process.

Since the fluid is no longer supplied when the buffer plate 630 is pressed to the maximum, the rotation of the driving spur gear 640 and the descending gear 650 is stopped and the pinion 660 is also stopped, Thereby stopping the flow and safely protecting the underground pipe 10.

In addition, since the buffer side springs 530 are also elastically buffered in this process, the buffer absorbing force is further increased.

Further, the buffer up-and-down spring 690 absorbs and buffers an external force acting in the up-and-down direction, that is, the vertical direction, thereby increasing the vibration resistance.

On the other hand, the present invention further includes a drainage unit 700 as in the example of Fig.

The drainage unit 700 includes a drainage guide plate 710 that is seated and fixed to the upper surface of the base plate 20. [

A drain blower 720 is installed on one side of the drain guide plate 710.

At this time, the outlet end of the drainage blower 720 is disposed between the drainage guide plate 710 and the inner bottom surface of the underground pipe 10 so as to be exposed in a space created by the thickness of the base plate 20.

In addition, a plurality of semicircular exhaust grooves 730 are formed on the upper surface of the base plate 20 except for the position where the support table 22 is fixed.

The exhaust groove 730 is formed to allow air to flow when the wind blower 720 blows air to the opposite side.

A plurality of check valves 740 are installed on the drainage guide plate 710 opposite to the point where the drainage blower 720 is installed.

The check valve 740 is configured such that when the water is accumulated on the upper surface of the water discharge guide plate 710 by weakening the elastic modulus of the spring, the water is automatically opened and it is easy to drain the water therefrom into the downward drainage space 750.

Particularly, the drainage guide plate 710 may be slightly inclined to one side to enhance drainage.

A drainage box 760 is provided at a lower portion of the support plate 510. The drainage box 760 is provided with a plurality of drainage holes through the circumference thereof and a gravel layer 762 and a gravel layer A mesh layer 764 disposed on the upper portion of the substrate 762 is laminated.

Also, the drain box 760 communicates with the drain space 750 through a drain connection pipe 770.

Accordingly, when the drain blower 720 periodically operating in response to the control signal of the controller blows air, the air is supplied to the drainage space 750 through the exhaust groove 730 to pressurize the inside of the drainage space 750 The water present in the drainage space 750 is drained by the drainage connection pipe 770 and then drained into the ground through the drainage drainage 760. [

At this time, since the check valve 740 is closed by the wind pressure, the air blown into the underground pipe 10 can be prevented from flowing backward and the drainage efficiency can be increased. The mesh layer 764 and the gravel layer 762 can be used as underground soil (10) is prevented from flowing into the underground pipe (10).

Therefore, efficient drainage becomes possible.

10: underground pipe 20: base plate
100: Air blowing box 200: Outdoor air blowing box

Claims (1)

A base plate 20 installed on the inner bottom surface of the underground pipe 10; a support 22 installed vertically in the center of the base plate 20; And a plurality of ground distribution lines (L) placed on the shelves (24), wherein the ground distribution lines (L) are installed on the support rods (22)
The shelf 24 was prepared by mixing 8.5 wt% of butyl prop-2-propenoate, 4.5 wt% of a mixture of azelic acid and pyrometric acid in a weight ratio of 1: 1, 3.5 wt% of amide, 2.0 wt% of water-soluble SiO ₃ , 1.5 wt% of methacrylic acid, 4 wt% of sodium bicarbonate and 2.5 wt% of borax were added to chromium oxide (Cr ₂ O ₃ ) And the calcined material was wet-crushed with a crusher to have a particle size of 1 μm or less. The resultant was then mixed with 4.5 wt% of an oxide powder dried at 100 ° C. for 10 hours, and a mixture of germanium and gallium arsenide and zinc selenide A resin composition composed of 3.5 wt% of a mixture mixed at a weight ratio of 1: 1: 1, 4.5 wt% of perfluoropolyether, 2.5 wt% of silicon nitride, 3.5 wt% of ytterbium oxide and remaining epoxy resin Molded into a plate shape;
The indoor air blowing box 100 is provided with an indoor air blowing box 100 and an outdoor air blowing box 200 on both sides of the inside of the underground pipe 10 and an indoor air blower 100 for sucking indoor air through the indoor air inlet 110 (120) is installed; The outside air blowing box 200 is provided with an outside air blower 220 for sucking outside air through an outside air inlet 210. An inside air outlet pipe 130 is connected to an outlet end of the inside air blower 120, (130) is piped along the ceiling surface of the underground pipe (10) and the plate heat exchanger (300) is connected to the end thereof; The inside air discharge pipe 140 is connected to the discharge end of the plate heat exchanger 300 and the inside air discharge pipe 140 has a plurality of discharge openings 142 toward the shelf 24 and discharges the heat- To be dispersed and discharged to the entire inside of the pipe (10); The outdoor air discharge pipe 230 is connected to the outlet end of the outdoor air blower 220 and the outdoor air discharge pipe 230 is piped along the ceiling surface of the underground pipe 10 and the end is connected to the plate heat exchanger 300. The outside air discharge pipe (240) is connected to the outflow end of the plate heat exchanger (300) to discharge the heat-exchanged external air to the ground, and the outside air suction pipe (250) Is configured to be able to suck in the outside air of the ground; Way valve 260 as a solenoid valve is further installed in the outside air discharge pipe 230 and the inside air discharge pipe 140 and is periodically opened and closed in accordance with a control signal of the controller while the inside air passing through the plate- (230) to the outside air flow channel of the plate heat exchanger (300), then discharged to the ground by the outside air discharge pipe (240), and the outside air sucked through the outside air suction pipe (250) To be distributed and supplied to the inside of the underground pipe (10) to ventilate,
The outer air discharge pipe 240 and the outdoor air suction pipe 250 are formed such that the upper end of the pipe is welded to the inner circumferential surface of the curled protective cover COV and integrated into a plurality of vent holes HOL around the upper end of the pipe The air is configured to prevent the infiltration of snow or rain while inducing the discharge of air;
The inside air blowing box 100 and the outside air blowing box 200 are made of 15 parts by weight of cellulose acetate, 15 parts by weight of a cellulose acylate so as to visually confirm the state of the built- %, 3.5% by weight of distearmonium hectorite, 30% by weight of transparent silica, 4.5% by weight of ceresin and the rest of the polycarbonate resin, and kept transparent;
The underground pipe 10 is embedded in a U-shaped support plate 510 surrounding the lower end of the underground pipe 10 and a lateral pressure reducing member The support plate 510 includes 25% by weight of an epoxy resin, 1.5% by weight of rosin, 10% by weight of a carbon fiber of 1 to 2 cm in length and 10% by weight of a remaining polycarbonate resin so as to have excellent corrosion resistance and durability The resin composition is molded;
A plurality of buffer side springs 530 are installed between both inner wall surfaces of the support plate 510 and both side surfaces of the lower end of the underground pipe 10; The upper end of the support plate 510 is closed by a skirt 540; The skirt 540 is obtained by molding a resin composition composed of 60% by weight of a silicone resin, 5% by weight of an allopene powder and the remaining EVA (ethylene-vinylalcohol copolymer) in a sheet form;
The underground pipe (10) further includes a drainage unit (700), wherein the drainage unit (700) includes a drainage guide plate (710) seated and fixed on the upper surface of the base plate (20) A drain blower 720 is installed on one side of the drain guide plate 710; The outlet end of the drainage blower 720 is disposed between the drainage guide plate 710 and the inner bottom surface of the underground pipe 10 so as to be exposed in a space created by the thickness of the base plate 20; A plurality of semicircular exhaust grooves 730 are formed on the upper surface of the base plate 20 except for the position where the support table 22 is fixed; A plurality of check valves 740 are installed on the drainage guide plate 710 opposite to the point where the drainage blower 720 is installed; A drain box 760 is provided at a lower portion of the support plate 510; The drainage box 760 has a structure in which a plurality of drainage holes are formed in the entire peripheral surface and a gravel layer 762 and a mesh layer 764 disposed on the gravel layer 762 are stacked; Wherein the drain box (760) is communicated with a drain space (750) formed at a lower portion of the drain guide plate (710) through a drain connection pipe (770).

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