KR102441981B1 - System for sampling of water by adjusting intensity with function for dispersing weight - Google Patents

Abstract

The present invention relates to a water collection system capable of selectively distributing load through arbitrary strength control, comprising: a main board unit that forms a body and is mounted on top of a manhole; a plurality of supporting arm units formed radially from the center of the main board unit; an installation unit provided at a terminal end of each supporting arm unit and configured to form a step from a horizontal position of the supporting arm unit so that a plurality of supporting arm units are mounted from an upper end of the manhole; and a water collecting fixing unit mounted on the main board unit and arranged to extend downward from the main board unit, providing a water collecting device for collecting water from the inside of the manhole to determine the water quality condition inside the manhole.

Description

A water dispensing system capable of selectively dispersing load through arbitrary intensity control {System for sampling of water by adjusting intensity with function for dispersing weight}

The present invention relates to a water collecting system having a selective load distribution function, and more particularly, it is fixedly mounted on the upper part of the manhole to fix the water collecting device, and selectively distributes the load applied from the fixed water collecting device to make it stable on the upper part of the manhole It is a technical field related to a water collection system capable of selectively distributing load through arbitrary strength control that allows it to be mounted as a

Since the sewage conduit is an urban infrastructure for improving living environment, public hygiene, flood prevention, water quality conservation and sound water circulation in public waters, it continuously maintains its role and function as an urban infrastructure and appropriately responds to disasters and crises. In order to cope with this, continuous management and maintenance of sewage pipes is required.

The total length of the sewage pipe in Seoul was 10,228 km in 2005, achieving 100% penetration, but various problems such as pipe damage, burial, and odor generation are occurring due to aging. In addition, an urgent solution is needed since the sewage and sewage are collected in a certain amount from the storm water chamber at the end of the drainage area at the beginning of the rainfall and discharged into the public waters while being transported to the sewage terminal treatment facility.

In Korea, the Ministry of Environment's "General Guidelines for Sewerage Facility Installation Business Process" suggests that measures to maintain the function of the conduit should be devised and a monitoring plan to identify the initial stormwater pollution load should be prepared. However, practical maintenance is not performed.

In order to fully understand the condition of sewage pipe facilities and to establish appropriate countermeasures quickly, monitoring and maintenance are efficient parts for inspection and investigation, repair, accident prevention and countermeasures. was analyzed to be

During sewage pipe monitoring, the upper installation devices include a rainfall meter, flow meter, and water level meter, and the flow meter is installed to check the amount of sewage in the sewage pipe or the situation of overflow water (CSOs) in the combined sewer pipe.

In the case of water collection, there are a method for collecting by manpower and a method for collecting by a water collector. However, in the case of collecting by manpower, the occurrence of errors may increase depending on the change of the sampling tool, method, and period, and there is a problem that time and weather are limited. There is this.

In the case of an automatic water dispenser, the interval between water collection is set in advance during a clean survey, and in case of a rain survey, it is connected to a rain gauge or water level sensor to automatically start water collection so that water collection is performed. The location of the water dispenser is very important because there may be errors in the sample collected depending on the installation location, and it should be continuously installed for regular inspection.

A technical attempt is being made to monitor the sewage pipe in the sewer and collect data on the sample, and a prior patent document for this is "Sewage pipe monitoring system (Registration No. 10-1187998, hereinafter referred to as Patent Literature 1)." also exist

In the case of Patent Document 1, real-time status information of the sewage pipe can be monitored from multiple measurement sensors provided on the sewage pipe, and in particular, a sulfide gas sensor is provided to analyze the corrosion factor of the sewage pipe and measure the accumulation of sediment in the sewage pipe to control the sewage pipe. It relates to a sewage pipe monitoring system that can diagnose and evaluate the sewage pipe and determine the maintenance time, such as the dredging time of the sediment, as well as the old age of the corresponding sewage pipe.

In addition, in the case of Patent Document 1, in the sewage pipe monitoring system for collecting and monitoring status information on a plurality of sewage pipes installed in a specific management target area, a collection unit installed in the sewage pipe to collect various kinds of measurement data; It includes an input means for inputting local information including population and area of the management target area and historical information on a plurality of sewage pipes installed in the area. An operation server for analyzing, storing and outputting the state information of the operation server and the operation server, requesting the state information of the sewage pipe, and receiving the state information data stored in the operation server, characterized in that it comprises a manager terminal for monitoring it It relates to a sewage pipe monitoring system.

As a prior patent document for a device for fixing the sample water and collecting the sample water, there is also a “Sample Water Collecting Device (Registration No. 10-0519582, hereinafter referred to as Patent Document 2)”.

In the case of Patent Document 2, a manhole is constructed on the floor and a submersible pump is installed inside the manhole to pump the inflowed sample water to the measuring station to enable water collection even at low water levels, and filter the sample water flowing into the manhole to filter the manhole. It relates to a sample water collection device that can prevent internal contamination and has a low risk of loss even if the flow rate rapidly increases due to heavy rain or the like because it is installed in a buried form.

In the case of Patent Document 2, it has a hollow body with at least one side open, and is installed at an installation place so that the opening faces upward, and the inlet and outlet are penetrated through the manhole on both sides of the body corresponding to the direction in which water flows; a filtering member installed to correspond to the outside of the inlet of the manhole to filter impurities flowing into the inlet; a submersible pump installed inside the manhole, connected to the measuring station by a pipe, and pumping the sample water collected inside the manhole to the measuring station; It includes a support means for supporting the submersible pump and a cover for removably closing the opening of the manhole so that the submersible pump can be installed in the manhole.

"A sample water collecting device for burial (Publication No. 10-2011-0007276, hereinafter referred to as Patent Document 3)" also exists.

In the case of Patent Document 3, by constructing a manhole on the floor and installing a submersible pump inside the manhole, the sample water flowing in is pumped to the measuring station so that water can be collected even at a low water level. This is to solve the problem that the sediment is easily introduced into the manhole at a low water level and is stacked.

In the case of Patent Document 3, a manhole consisting of a side surface, a lower plate, and an upper plate provided with a mesh-type inlet filtration unit for filtering impurities from the incoming water; a submersible pump installed inside the manhole to pressurize the sample water collected inside the manhole to the outside; and a support means for supporting the submersible pump so that the submersible pump is positioned on the lower plate of the manhole.

In order to minimize the possibility of errors from time and weather restrictions, the location of the water collection, and the point of collection when performing water collection through the water collecting device, the water collecting device is mounted inside the manhole to enable constant water collection. In the case of inventions, they were merely technical attempts through supporting means.

Registration No. 10-1187998 Registration No. 10-0519582 Publication No. 10-2011-0007276

The water collection system capable of selectively distributing load through arbitrary strength control according to the present invention has been devised to solve the problems of the prior art as described above, and presents the following problems to be solved.

First, the water collecting device is mounted on the top of the manhole, and the mounted water collecting device is mounted on the top of the manhole so that the water collecting process can be performed.

Second, selective load distribution is made for fixing the water collecting device, and bending due to fixed mounting can be prevented through load distribution.

Third, by extending the space to be mounted on the upper part of the manhole, it is possible to mount it according to the size of the manhole, and to prevent separation by movement.

The problems to be solved of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

The water collection system capable of selectively distributing load through arbitrary strength control according to the present invention has the following problem solving means for the above problem to be solved.

The water collection system capable of selectively distributing load through arbitrary strength control according to the present invention forms a body, and includes a main board unit mounted on an upper portion of a manhole; a plurality of supporting arm units radially formed from the center of the main board unit; an install unit provided at the end of each supporting arm unit and configured to form a step from a horizontal position of the supporting arm unit so that the plurality of supporting arm units are mounted from an upper end of the manhole; and a water collection fixing unit mounted on the main board unit and arranged to extend downward from the main board unit, providing a water collecting device for collecting water from the inside of the manhole and grasping the water quality condition inside the manhole. can do.

The plurality of supporting arm units of the water collection system capable of selectively distributing load through arbitrary strength control according to the present invention are continuously formed from the body of the main board unit, and the plurality of supporting arm units are formed from the center of the main board unit. It may be characterized in that each of the is arranged to be symmetrical.

The installation unit of the water collection system capable of selectively distributing load through arbitrary strength control according to the present invention forms a step from the horizontal position of the supporting arm unit, and is provided at the top of the manhole by the weight of the main board unit a trapping unit for pressing down the upper end of the manhole; and a side pressing part that interconnects the trapping parts from the supporting arm unit and allows an outer surface to press the inner peripheral surface of the manhole outward.

A plurality of supporting arm units of the water collection system capable of selectively distributing load through arbitrary strength control according to the present invention are disposed on both sides of each supporting arm unit to reduce the bending moment of the supporting arm unit. It may be characterized in that it comprises an enhancement wall (enhance wall) part.

The enhancement wall portion of the water collection system capable of selectively distributing load through arbitrary strength control according to the present invention is disposed under each supporting arm unit, and the enhancement wall portion is disposed so that one end and the other end of the enhancement wall portion correspond to each other It may be characterized in that the lower boundary is set by a continuous function.

The enhancement wall part of the water collection system capable of selectively distributing load through arbitrary strength control according to the present invention reinforces the tensile stress of the lower part of the supporting arm unit due to the load applied from the upper part of the supporting arm unit, The bending moment of the supporting arm unit may be reduced by minimizing the load applied to the center of the arm unit.

The main board unit of the water collection system capable of selectively distributing load through arbitrary strength control according to the present invention is provided in parallel and spaced apart from the lower part of the main board unit, and the main board unit by the load applied from the water collection fixing unit Comprising a backup portion for dispersing the partial tensile force of the board unit, the backup portion, the upper and lower, respectively formed spaced apart from each other, the body portion arranged in parallel; and a connection part disposed to be perpendicular to the main body part and connected to the upper part and the lower part of the main body part.

The trapping part of the water collection system capable of selectively distributing load through arbitrary strength control according to the present invention includes: an external wall part protruding from the trapping part and formed on both sides of the trapping part; and an external roof portion extending from each of the external wall portions and disposed parallel to the trapping portion.

The external wall portion of the water collection system capable of selectively distributing load through arbitrary strength control according to the present invention presses both sides of the extension portion, and guides the extension portion so that the extension portion slides from the upper portion of the trapping portion and extends horizontally. can be done with

The external loop part of the water collection system capable of selectively distributing load through arbitrary strength control according to the present invention presses both sides of the upper part of the extension part to prevent the extension part from being spaced apart from the trapping part while the extension part is horizontally extended. can be characterized as

The water collection system capable of selectively distributing load through arbitrary intensity control according to the present invention having the above configuration provides the following effects.

First, it extends through the supporting arm unit radially connected from the main board unit to be mounted on the top of the manhole, and the installation unit is mounted on the top of the manhole so that it can be fixedly mounted on the top of the manhole.

Second, in order to prevent separation from the upper part of the manhole, it can be mounted and fixed on the upper part of the manhole through an extension part extendable from the installation unit.

Third, an enhancement wall portion may be formed at the lower portion of the supporting arm unit to reduce the bending moment of the supporting arm unit, and a backup portion may be formed at the lower portion of the main board unit to distribute the tensile force of the main board unit.

Fourth, it is possible to set a partition area for a continuous function according to the strength for the desired force of the enhancement wall so that the lower boundary is formed arbitrarily.

Effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a plan view of a water collection system capable of selectively distributing a load through arbitrary intensity control according to an embodiment of the present invention.
2 is an installation cross-sectional view of a water collection system capable of selectively distributing load through arbitrary strength control according to an embodiment of the present invention.
3 is a perspective view illustrating an enhancement wall portion formed at a lower portion of a supporting arm unit of a water collection system capable of selectively distributing load through arbitrary strength control according to an embodiment of the present invention.
4 is a cross-sectional view illustrating that an enhancement wall portion is formed in various forms at the lower portion of the supporting arm unit of the water collection system capable of selectively distributing load through arbitrary strength control according to an embodiment of the present invention.
5 is a diagram illustrating arbitrarily setting a partition area of a function for forming an enhanced wall portion of a water collection system capable of selectively distributing load through arbitrary strength control according to an embodiment of the present invention.
6 is a perspective view illustrating a backup part formed under the main board unit of a water collection system capable of selectively distributing a load through arbitrary strength control according to an embodiment of the present invention.
7 is a partially enlarged perspective view illustrating that an external wall part and an external roof part are formed in the installation unit of a water collection system capable of selectively distributing load through arbitrary strength control according to an embodiment of the present invention, and an installation part is provided.

The water collection system capable of selectively distributing load through arbitrary strength control according to the present invention can have various changes and can have various embodiments, and specific embodiments will be illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to a specific embodiment, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

1 is a plan view of a water collection system capable of selectively distributing a load through arbitrary intensity control according to an embodiment of the present invention. 2 is an installation cross-sectional view of a water collection system capable of selectively distributing load through arbitrary strength control according to an embodiment of the present invention. 3 is a perspective view illustrating an enhancement wall portion formed at a lower portion of a supporting arm unit of a water collection system capable of selectively distributing load through arbitrary strength control according to an embodiment of the present invention. 4 is a cross-sectional view illustrating that an enhancement wall portion is formed in various forms at the lower portion of the supporting arm unit of the water collection system capable of selectively distributing load through arbitrary strength control according to an embodiment of the present invention. 5 is a diagram illustrating arbitrarily setting a partition area of a function for forming an enhanced wall portion of a water collection system capable of selectively distributing load through arbitrary strength control according to an embodiment of the present invention. 6 is a perspective view illustrating a backup part formed under the main board unit of a water collection system capable of selectively distributing a load through arbitrary strength control according to an embodiment of the present invention. 7 is a partially enlarged perspective view showing that an external wall part and an external roof part are formed in the installation unit of a water collection system capable of selectively distributing load through arbitrary strength control according to an embodiment of the present invention, and an installation part is provided.

The water collection system capable of selectively distributing the load through arbitrary strength control according to the present invention is a main board unit (100), a supporting arm unit (200), an install unit (install unit, 300), a water collection fixed It may include a unit 400 .

First, in the case of the main board unit 100 , it forms a body and may be mounted on the manhole 1 .

As shown in FIG. 1 , the main board unit 100 forms a body mounted on the upper part of the manhole 1 to form a fixed body, and the water collecting device can be mounted on the fixed body.

In the case of the supporting arm unit 200 , it is provided radially from the center of the main board unit 100 and may be formed in plurality.

As shown in FIG. 1, the supporting arm unit 200 has a shape extending horizontally and radially from the main board unit 100, and each supporting arm unit 200 is radially arranged symmetrically with each other. can get

The supporting arm unit 200 may have the same horizontal inner width connected to the main board unit 100 and the same horizontal outer horizontal width extending to the outside, and may have different inner or inner widths. .

In the case of the installation unit 300 , it is provided on each supporting arm unit 200 and forms a step difference from the horizontal position of the supporting arm unit 200 so that a plurality of supporting arm units 200 are mounted from the upper end of the manhole 1 . can become

As shown in FIGS. 1 to 2 , the installation unit 300 may form a step at the end of the supporting arm unit 200 to be mounted on the top of the manhole 1 .

The step corresponds to the step with respect to the upper end of the manhole 1 and the main board unit 100, and one side may be provided to be mounted on the upper end of the manhole.

In the case of the water collection fixing unit 400, it is mounted on the main board unit 100 and is arranged to extend downward from the main board unit 100, and a water collection device 10 that detects a change in the fluid inside the manhole and calculates the flow rate. can be provided.

As shown in FIG. 2 , the water collecting fixing unit 400 is disposed to protrude downward from the main board unit 100 , and may include a water collecting device 10 at a lower portion thereof.

The plurality of supporting arm units 200 of the water collection system capable of selectively distributing load through arbitrary strength control according to the present invention are continuously formed from the body of the main board unit 100, and are formed from the center of the main board unit 100. Each of the plurality of supporting arm units 200 may be symmetrically disposed.

The supporting arm units 200 are continuously connected from the main board unit 100 , and each supporting arm unit 200 is symmetrical with respect to the main board unit 100 , that is, from the center of the main board units 100 . It may be arranged so as to be formed.

The reason why the supporting arm unit 200 is symmetrically arranged is to evenly distribute the load of the main board unit 100 from the manhole 1 so that it can be fixedly mounted on the manhole 1 .

That is, if the supporting arm unit 200 is radially symmetrically formed from the main board unit 100, the load of the main board unit 100 is evenly distributed and mounted on the manhole 1, It is desirable to make it so that it can be said that the distribution of the force is performed properly.

The installation unit 300 of the water collection system capable of selectively distributing load through arbitrary strength control according to the present invention may include a trapping unit 320 and a side pressing unit 310 .

In the case of the trapping part 320 , a step is formed from the horizontal position of the supporting arm unit 200 , and it is provided at the upper end of the manhole 1 to close the upper end of the manhole 1 by the weight of the main board unit 100 . can be pressed downwards.

The main board unit 100 has a force to enter the lower part of the manhole 1 by its weight and gravity, and the trapping unit 320 applies the force to enter the lower part of the manhole 1, that is, FIG. 2 As shown in , the cover of the manhole 1 is mounted in the upper space to be covered so that the main board unit 100 is mounted on the top of the manhole 1 .

In the case of the side pressing unit 310, the trapping unit 320 is interconnected from the supporting arm unit 200, and the outer side presses the inner circumferential surface of the manhole so that the main board unit 100 at the upper end of the manhole 1 It is desirable not to be spaced apart or move.

As shown in FIG. 2 , the side pressing part 310 is formed to protrude upward from the supporting arm unit 200 and connects the trapping part 320 .

That is, when the main board unit 100 is mounted on the manhole 1, the side pressing unit 310 presses the outer surface of the side pressing unit 310 to the inner circumferential surface of the manhole so that the supporting arm unit 200 is installed in the manhole. It is preferable to be fixedly mounted from (1) so that the movement does not act.

A plurality of supporting arm units 200 of the water collection system capable of selectively distributing load through arbitrary strength control according to the present invention are disposed on both sides of each supporting arm unit 200, and the supporting arm unit 200 is bent. It may include an enhancement wall unit 210 for reducing a bending moment.

In the case of the enhancement wall part 210, as shown in FIG. 3 , it may be disposed on both side surfaces of the lower portion of the supporting arm unit 200, and both side surfaces may correspond to side surfaces in the longitudinal direction.

For example, the supporting arm unit 200 has a pressing force from the top to the bottom due to a load or a pressure applied from the outside, and each of the supporting arm units 200 may be bent due to the pressing force.

The bending phenomenon may reduce the fixing force from the manhole 1 of the supporting arm unit 200 and the function of fixing the water dispenser 10. Such bending is continuously performed, and in all supporting arm units 200 If it appears, the function of fixing the water collecting device 10 may be lost.

In order to reduce the bending of the supporting arm unit 200 , it is preferable that the enhancement wall part 210 be disposed at the lower portion to reduce the bending moment.

In the case of the enhancement wall part 210 of the water collection system capable of selectively distributing load through arbitrary strength control according to the present invention, it is disposed below each supporting arm unit 200 , and one end and the other end of the enhancement wall part 210 . To correspond to this, the boundary of the lower end of the enhancement wall unit 210 may be set by a continuous function.

Variable factors determining the function of the boundary of the lower end of the enhancement wall 210 include the distance from the center of the main board unit 100 to the installation unit 300 , the radius of the main board unit 100 , and the main board Functions may be set according to the distance of the supporting arm unit 200 from the unit 100 , the thickness of the supporting arm unit 200 , and the like.

For example, when the distance from the center of the main board unit 100 to the installation unit 300 is long, the slope of the curve with respect to the lower boundary of the enhancement wall unit 210 may be gently formed.

In addition, as shown in FIG. 5, the lower portion of the position adjacent to the main board unit 100 may be formed to more protrude, and the partition area for the quadratic function may be set according to the strength of the desired position. have.

In the case of the partition area, in addition to the aforementioned variable factors, the location of the water collection fixing unit 400 or the size of the manhole 1 may also act as a variable factor, and the desired strength may be formed differently depending on the variable factor, Arbitrary setting of the partition area to be partitioned may also be enabled.

That is, in the case of a continuous function, as shown in FIG. 6 , it may correspond to a quadratic function, and the boundary of the lower part of the enhancement wall 210 may be set through setting of an arbitrary partition area among the quadratic functions. Also, the curve of the boundary and its smoothness can be set according to a variable factor that sets the lower boundary.

For example, as shown in FIG. 6(b), the shape of the curve bounded by variable factors among the continuous function graphs can be arbitrarily set, and the enhancement wall part according to the shape of the curve arbitrarily set to y and y'. Reference numeral 210 may be formed under the supporting arm unit 200, and the lower boundary of the enhancement wall unit 210 may be arbitrarily set as shown in FIG. have.

In the case of the enhancement wall part 210 of the water collection system capable of selectively distributing the load through arbitrary strength control according to the present invention, the tensile stress of the supporting arm unit 200 due to the load applied from the upper part of the supporting arm unit 200 is measured. It is reinforced and the bending moment of the supporting arm unit 200 may be reduced by minimizing the load applied to the center of the supporting arm unit 200 .

Through the lower arrangement of the enhancement wall part 210, the supporting arm unit 200 can distribute the force from the load applied to the center thereof, and the supporting arm unit 200 can be bent through the distribution of the force. It is possible to cause the bending of the supporting arm unit 200 to be lowered from the force.

Tensile force is provided below the center of the supporting arm unit 200 or a position where a load is provided to bend the supporting arm unit 200, and fatigue builds up in the supporting arm unit 200 due to repeated loads or external pressure. The supporting arm unit 200 may be bent due to accumulated fatigue, and it is preferable that the enhancement wall unit 210 distributes the force provided to the load to prevent fatigue from accumulating.

It is preferable that the enhancement wall part 210 can prevent bending of the supporting arm unit 200 from continuous pressure as well as bending of the supporting arm unit 200 due to temporary pressure.

The main board unit 100 of the water collection system capable of selectively distributing the load through arbitrary strength control according to the present invention is provided spaced apart from the lower part of the main board unit 100 in parallel, and is applied from the water collection fixing unit 400 . It may include a backup part 110 for dispersing the partial tensile force of the main board unit 100 due to the applied load.

The backup unit 110 may include a body unit 111 and a connection unit 112 . In the case of the body unit 111 , the backup unit 110 may be formed to be spaced apart from each other at the upper and lower portions, and may be disposed in parallel.

In the case of the connection part 112 , it is disposed to be perpendicular to the body part 111 , and the body part 111 may include a connection part 112 connected to an upper end and a lower end thereof.

As shown in FIG. 6 , the main body 111 and the connecting part 112 in the backup part 110 are connected and formed in one configuration, and the body part 111 is formed on both sides at the upper end and the lower end, , is composed of a connection portion 112 connecting the main body portion 111 on both sides.

A plurality of backup units 110 may be formed at the lower portion of the main board unit 100 , and a plurality of backup units 110 are formed in parallel and spaced apart from each other, thereby bending of the main board unit 100 at the lower portion of the main board unit 100 . or to prevent bending.

For example, in the case of the main board unit 100, bending into the inside of the manhole 1 may occur due to the water collecting device 10 or its own weight. This may occur, and to prevent bending in order to solve this problem, the backup unit 110 may be referred to as the backup unit 110 .

As shown in FIG. 7 , the trapping unit 320 of the water collection system capable of selectively distributing load through arbitrary strength control according to the present invention includes an external wall part 321 , an external roof part 322 , and an extension part. (323).

In the case of the extension part 323 , it is spaced apart from the upper part of the trapping part 320 , and may be parallel to the trapping part 320 and disposed on the upper part.

The extension part 323 is formed in a structure extending from the trapping part 320 toward the inner circumferential surface of the manhole, and the extension part 323 extends like the trapping part 320 to press the upper part of the manhole. have.

For example, when the upper size of the manhole is to be fixed to the upper part of the large manhole, it is to be fixed to the upper part of the manhole through extension from the trapping part 320 .

In addition, it is preferable to selectively adjust the extension length in the trapping part 320, and to adjust the horizontal extension length when the trapping part 320 cannot be mounted depending on the size of the manhole.

In the case of the external wall part 321 , it protrudes from the trapping part 320 and may be formed on both sides of the trapping part 320 .

7 , the external wall portion 321 is formed to protrude above the trapping portion 320 and may be formed on both sides of the trapping portion 320 .

The external wall portions 321 formed on both sides may press both sides of the inner side of the extension portion 323 from both sides.

A fixing force from the trapping part 320 is formed in the extension part 323 by the pressing force of the external wall part 321 , and the extension part 323 may selectively maintain a fixed shape with respect to the extended length.

The external wall part 321 may be formed to protrude upwardly from the outside of the trapping part 320 , that is, to the other side of the trapping part 320 fixedly mounted on the manhole, and the length of the extension part 323 is can be formed according to

In the case of the external roof part 322 , it is formed to extend from each external wall part 321 , and may be disposed parallel to the trapping part 320 .

The external roof part 322 is also formed to extend from the external wall part 321 , is formed from the external wall part 321 on the upper part, and may be provided to be parallel to the trapping part 320 .

It is preferable that the external loop part 322 is provided in a form in contact with the upper part of the extension part 323 .

Preferably, the length of the external loop part 322 is provided on both sides so that the external loop part 322 does not exceed the width of the trapping part 320 , and the trapping part is located above the trapping part 320 . It is more preferable not to be formed larger than the width of (320).

In the case of the external wall part 321 , both sides of the extension part 323 may be pressed, and the extension part 323 may slide from the upper part of the trapping part 320 to guide the horizontal extension.

The extension part 323 presses both sides of the external wall part 321 so that it slides and horizontally extends in the trapping part 320 , and the external wall part 321 serves as a guide when the extension part 323 moves horizontally. can be responsible for

That is, the external wall part 321 is disposed to protrude upward from the trapping part 320 and presses both sides of the extension part 323 while the extension part 323 lengthens the trapping part. It is to guide so as not to deviate from (320).

The external wall part 321 of the water collection system capable of selectively distributing the load through arbitrary strength control according to the present invention presses both sides of the extension part 323, and the extension part 323 is the upper part of the trapping part 320. It can be guided so that it slides from the horizontal extension.

The extension part 323 is slid and extended along the inner surface of the external wall part 321 guided by the external wall part 321 .

The external loop part 322 may press both sides of the upper portion of the extension part 323 to prevent the extension part 323 from being spaced apart from the trapping part 320 while horizontally extending.

The external roof part 322 of the water collection system capable of selectively distributing the load through arbitrary strength control according to the present invention presses both sides of the upper part of the extension part 323, while the extension part 323 is horizontally extended. It is possible to prevent separation from the trapping unit 320 .

The external loop part 322 presses the upper part of the extension part 323 and prevents the extension part 323 extending and contracting along the guide of the external wall part 321 from being separated from the trapping part 320 . will guide you in

Since the external roof part 322 is formed to extend from the external wall part 321 , it is preferable to extend along the length of the external wall part 321 .

Due to the external loop part 322 , the extension part 323 can maintain an extended state, and the external loop part 322 is pressed from the upper part to maintain the extended state, and the external wall part 321 is pressed. can be pressed from the side.

The scope of the present invention is determined by the matters described in the claims, and parentheses used in the claims are not described for selective limitation, but are used for clear components, and descriptions in parentheses are also interpreted as essential components. should be

1: Manhole
10: water collecting device
100: main board unit
110: backup unit
111: body part
112: connection
200: supporting arm unit
210: Enhance monthly
300: installed unit
310: side pressing unit
320: trapping unit
321: external monthly payment
322: external loop portion
323: extension part
400: water collection fixed unit

Claims (10)

Forming a body, the main board unit mounted on the upper part of the manhole (main board unit);
a plurality of supporting arm units radially formed from the center of the main board unit;
an install unit provided at the end of each supporting arm unit and configured to form a step from a horizontal position of the supporting arm unit so that the plurality of supporting arm units are mounted from an upper end of the manhole; and
and a water collecting fixing unit mounted on the main board unit and arranged to extend downward from the main board unit to provide a water collecting device that collects water from the inside of the manhole and grasps the water quality condition inside the manhole,
A plurality of supporting arm units,
and an enhancement wall portion disposed on both sides of each supporting arm unit to reduce a bending moment of the supporting arm unit;
A watering system that is continuously formed from the body of the main board unit and is arranged so that each of the plurality of supporting arm units is symmetrical from the center of the main board unit, allowing selective load distribution through arbitrary strength control .
delete According to claim 1, wherein the installation unit,
a trapping part that forms a step from the horizontal position of the supporting arm unit and is provided on the manhole to press down the upper end of the manhole by the weight of the main board unit; and
Selective load distribution through arbitrary strength control, characterized in that it includes a side pressing part that interconnects the trapping parts from the supporting arm unit and allows the outer surface to press the inner peripheral surface of the manhole outward. system.
delete The method of claim 1, wherein the enhancement wall portion,
Selective load through arbitrary strength control, which is disposed under each supporting arm unit, and the boundary of the lower end of the enhancement wall portion is set by a continuous function so that one end and the other end of the enhancement wall portion correspond to each other A decentralized collection system.
The method of claim 5, wherein the enhancement wall portion,
Reinforcing the tensile stress of the lower portion of the supporting arm unit due to the load applied from the upper portion of the supporting arm unit, and minimizing the load applied to the center of the supporting arm unit to reduce the bending moment of the supporting arm unit Characterized, watering system capable of selective load distribution through arbitrary intensity control.
According to claim 5, wherein the main board unit,
A backup part provided to be spaced apart from the lower part of the main board unit in parallel and distributing a partial tensile force of the main board unit by a load applied from the water collection fixing unit is included,
The backup unit,
The upper and lower body portions are formed spaced apart from each other and arranged in parallel; and
It is disposed to be perpendicular to the body part, and the body part comprises a connection part connected to an upper end and a lower end.
The method of claim 3, wherein the trapping unit,
an external wall protruding from the trapping part and formed on both sides of the trapping part;
an external roof portion extending from each of the external wall portions and disposed parallel to the trapping portion; and
A water collection system capable of selectively distributing load through arbitrary strength control, characterized in that it is spaced apart from the upper part of the trapping part and includes an extension extending horizontally from the trapping part.
The method of claim 8, wherein the external wall portion,
A water collection system capable of selectively distributing load through arbitrary strength control, characterized in that it presses both sides of the extension part and guides the extension part to slide horizontally from the upper part of the trapping part.
10. The method of claim 9, wherein the external loop portion,
A water collection system capable of selectively distributing load through arbitrary strength control, characterized in that by pressing both sides of the upper portion of the extension portion, the extension portion is prevented from being separated from the trapping portion while the extension portion is horizontally extended.

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