KR102007265B1 - Sample picking apparatus for examination of water using piers - Google Patents

Abstract

Disclosed is a bridge-type water level variation water sampling device for measuring a water pollutant wherein a water sampling device equipped with a water pump is installed around a pier of a bridge with variable water level and flow rate, and is configured to operate a measuring station by stably collecting water samples in a flood season and a dry season as well as in a small river or a medium river.

Description

SAMPLE PICKING APPARATUS FOR EXAMINATION OF WATER USING PIERS}

The present invention relates to a bridge-type water leveling water collecting device for measuring water pollutants, and more specifically, to install a water collecting device equipped with an underwater pump around a bridge bridge where a change in water level and flow velocity is variable, It is related to a bridge type water level fluctuation system for measuring water pollutants configured to operate a measuring station by stably collecting sample water not only in the spring but also in the flood and dry season.

As environmental pollution is getting worse due to industrial development, it is required to protect and manage the water quality of rivers and rivers cleanly.

Accordingly, a water quality measurement system is installed in rivers or rivers to measure the water quality by sampling the sample water. As shown in FIG. 1, the water sample structure is largely divided into three structures, that is, the water collection structure using the barge 1. And a water collecting structure by the cantilever 2 and a water collecting structure by the water intake port 3.

In the water collection structure using the barge 1 as shown in FIG. 1A, a barge 1 is installed in a river or a river to collect the sample water, and thus the risk of loss of the barge 1 is increased when the flow rate rapidly increases in summer when rainfall is concentrated. There is a high disadvantage.

A water collecting structure using a cantilever (water tower. 2) as shown in FIG. 1B is a method of collecting water by installing a fixed structure on a riverside. Although the cantilever 2 is structurally stable, inundation and breakage occur frequently due to an increase in flow rate during rainfall, and floating materials accumulate around the water intake tower, so the risk of damage to the water collection facility is very high.

The water intake structure by the intake port 3 as shown in FIG. 1C is a method of collecting a sample water by installing a fixed intake port 3 on a river side, and floating material and foreign substances are introduced into the intake port 3 so that the intake port 3 is blocked. The phenomenon occurred and there was a problem that can not be taken when the flow rate decreases.

In addition, by installing certain facilities such as wench, control panel, and reducer on the upper side of the central part of the bridge, the water pipe and pump cable are lowered from the bridge top to the water surface of the river, and the sample water is transferred to the measuring station through the collecting pipe connected to the side of the bridge with an underwater pump. Although there is a structure to collect water, the water harvesting method using such a bridge can maintain the water collecting device to store the pump in the depth of water only when the water depth is maintained at 0.7 m or more except the flooding period, and it is suitable for the center of the dam or the beam which does not change the flow rate. And, the structure of the size that can accommodate the equipment on the side of the bridge top plate should be installed, if the height of the bridge is more than 10M need to increase the pump capacity, there was a problem that the installation cost increase factor and licensing is difficult.

On the other hand, the above-mentioned conventional techniques are a sewage structure in which the measuring station is applied in a place with a large river width and a large flow rate, and it is impossible to collect a sample water in a place with a narrow river width and a small flow rate, especially in a dry season. It is water structure.

Therefore, there is a need for a technology capable of stably collecting sample water and operating a measuring station even in places where the river width is narrow and flow rate is small, especially in dry season, to small rivers or heavy rivers.

The present invention has been made to solve the above problems, the object is to install a water collecting device equipped with a water pump on the pier main surface of the bridge of variable water level and flow rate, the sample not only in small rivers or heavy rivers, but also in the flood and dry season It is to provide a bridge-type water level fluctuation system for measuring water pollutants that allows the station to operate with stable water collection.

In addition, the purpose is to filter the sample water flowing into the water collection device through the primary, secondary, and tertiary mesh network to prevent the inflow of sand, foreign matter, and the water pump to collect the sample water Accordingly, it is to provide a bridge-type water level fluctuation device for measuring water pollutants to improve the reliability by measuring the contamination level of sample water by securing the accurate water quality data by varying the height.

An object of the present invention is a bottom plate installed on the bottom of the river, a front plate extending upward from the front of the bottom plate and installed in close contact with the piers, and extending from the side and rear of the bottom plate and piercing through the fixing member A water collecting housing fixedly installed in the cover and having a cover formed with an inlet through which sample water flows into the lower end of the rear surface, and a cover closing the upper side of the cover and the front plate; A filtering member installed at the inlet to filter sand and foreign substances from the sample water flowing through the inlet; An underwater pump installed inside the water collecting housing and installed to be height-adjustable through an elevating means, and pumping the sample water introduced into the water collecting housing through the inlet to be pumped to a measurement station; And a water collection pipe connected to the submersible pump and extending to the measurement station along the outer surface of the bridge to collect the sample water. .

Here, the front plate is preferably formed with the same installation grooves on the front surface of the pier so as to be in close contact with the outer surface of the pier.

And, the fixing member is composed of a pair of fixing bands one end is coupled to both front ends of the cover to surround the outer surface of the piers, the other end of the pair of fixing straps is configured to be coupled to each other through a fastening member, the fixing It is preferable that the water collecting housing be fixedly installed on the piers without damaging the piers through the members.

And, the filtering member is installed in the center portion of the inlet port and the fibers are randomly entangled and stacked, such as the thread, the thread filter sheet is disposed on the front and rear of the thread filter sheet and the mesh line is arranged in the "X" shape It is preferably configured to be composed of a front and rear mesh network is formed so that a plurality of inlet holes therein.

The lifting means includes a support plate protruding from the upper end of the front plate to the rear, a guide rod fixedly installed between the support plate and the bottom plate, and a forward or reverse rotation of the support plate and the bottom plate toward the rear side of the guide rod. A TM screw rod that is rotatably installed, a handle coupled to an upper end of the TM screw rod to the upper side of the support plate to rotate the TM screw rod forward or reverse, and a guide hole inserted into the guide rod at the rear end thereof and guided thereto; The lifting plate is coupled to the TM screw rod in front of the guide hole and coupled to the TM nut, which is configured to be movable up and down along the TM screw rod by the rotation of the TM screw rod, and has a cylindrical shape with an open upper portion. Two water holes are formed and the submersible pump is installed therein, and the elevating plate is installed on the upper surface of the front end of the elevating plate. Together preferably comprise a motor that is installed barrel possibly installation move up and down.

In addition, an opening and closing hole is formed at a lower side of the cover, and guide rails are installed at both sides of the opening and closing direction, and both ends of the opening and closing door are slidably fitted to the guide rail to selectively open and close the opening and closing door. A first opening and closing valve is installed at a part of the intake pipe and configured to selectively open and close the intake pipe, and the intake pipe is connected to a cleaning pipe selectively opened by a second open and close valve under the first open and close valve. By sliding the opening and closing the door to the upper side to open the opening and closing, the first opening and closing valve, the second opening and closing the valve in the state, by pumping the water through the submersible pump by spraying the water through the cleaning pipe Cleaning the inside of the water collecting housing and the cleaned water is discharged through the opening and closing, It is configured such that it can be discharged to the internal deposits ranging in chaesu housing outside is preferred.

Bridge type water level fluctuation water collecting device for measuring water pollutants according to the present invention is installed in the water collecting device equipped with a water pump around the bridge pier of the variable water level and flow rate, not only in small rivers or heavy rivers, but also flood and dry season There is an effect that the measuring station can be operated by stably collecting the sample water.

In addition, the bridge-type water level fluctuation device for measuring water pollutants according to the present invention is filtered through the primary, secondary, and tertiary mesh network to prevent the inflow of sand and foreign substances by filtering the sample water flowing into the intake system In addition, the height of the submersible pump to take the sample water is variable according to the water level to ensure accurate water quality data has an effect that can improve the reliability according to the measurement of the contamination of the sample water.

1 is a view for explaining a conventional water collecting device,
Figure 2 is an exploded perspective view showing a bridge type water level fluctuation device for measuring water pollutants according to the present invention,
3 is a rear view showing a state in which a bridge-type water level fluctuation collecting device for measuring water pollutants according to the present invention is installed on a pier;
4 is a side view showing a state in which a bridge-type water level fluctuation collecting device for measuring water pollutants according to the present invention is installed in a pier;
5 is a view showing another preferred embodiment of the bridge type water level fluctuation device for measuring water pollutants according to the present invention;
6 and 7 are views for explaining the filtration member in the present invention,
8 is a view for explaining the lifting means in the present invention,
9 and 10 are views for explaining the operation of the lifting means according to the water level in the present invention,
11 is a view showing another preferred embodiment of the bridge type water level fluctuation device for measuring water pollutants according to the present invention;
12 is a view for explaining the state of use of the bridge type water level change device for measuring water pollutants in accordance with the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail the bridge type water leveling water collecting device for measuring water pollutants according to the present invention.

Attached Figure 2 is an exploded perspective view showing a bridge type water level changing device for measuring water pollutants in accordance with the present invention, Figure 3 is a bridge type water level variable water collecting device for measuring water pollutants in accordance with the present invention is installed in the piers Figure 4 is a rear view showing a state, Figure 4 is a side view showing a state in which the bridge-type water level change intake device for measuring water pollutants in accordance with the present invention installed on the bridge.

Referring to this, the bridge-type water level fluctuation device for measuring water pollutants according to the present invention includes a water collecting housing 100, a filtering member 200, an underwater pump 300 and a water collecting pipe 400.

The water collecting housing 100 is a portion in which an underwater pump 300, which will be described later, is installed to collect the sample water. Here, according to the present invention, the installation point of the non-point pollutant measuring station is characterized in that the river width is narrow to small rivers or heavy rivers, and the flow rate is small, so that water can be collected at the center of the river. Therefore, as shown, the water collecting housing 100 is preferably installed near the center pier 10 of the bridge that can maintain a constant water level and flow rate to reliably collect the sample water.

And, the water collecting housing 100 can be installed in any part of the outer surface of the pier 10, as shown, it is installed on the downstream side (behind the pier) does not affect the flow of water in the pier 10 It is desirable to be configured such that the impact on the vortex downstream of the piers is minimized.

More specifically, the water collecting housing 100 is the bottom plate 110 is installed on the bottom of the underwater, the front plate 120 extending upward from the front of the bottom plate 110 and installed in close contact with the piers 10 and The cover 130 extends upward from the side and rear of the bottom plate 110 and is fixedly installed in the piers 10 through the fixing member 131, and an inlet 132 is formed in which the sample water flows into the lower end of the rear plate 110. , The cover 130 and the cover 140 which closes the upper side of the front plate 120 is configured.

Here, the inlet 132 is installed on the cover 130 is located above 0.3M from the bottom of the river is composed of sand or 뻘 normally flowing from the bottom of the inlet is inherently impossible to inflow, even in the dry season stably measuring station (1) It is preferable that it is configured to be operable, and the cover 140 is separated into two and is configured to open and close by half, so that the operator can be configured to open and close the water intake housing 100 without effort. And, as shown in Figure 5, the back of the cover 130 is formed with a round portion 133, the water of the piers 10 guides smoothly along the round portion 133 on the side of the cover 130 Then, it is preferable to have a structure that can be easily introduced into the inlet 132 formed on the back of the cover 130.

On the other hand, the front plate 120 is preferably formed in the front surface of the installation groove 121 is the same as the outer surface shape of the piers so as to be closely supported on the outer surface of the piers (10). That is, even if the outer shape of the piers 10 is provided in various shapes such as circular, oval and square, by providing the installation grooves 121 of circular, oval and square corresponding to the outer surface of the piers in front of the front plate 120 , The front plate 120 is supported to be in close contact with the outer surface of the piers 10 through the installation groove 121 is configured to be installed firmly.

In addition, the intake housing 100 is preferably installed without damaging the bridge structure through the fixing member 131 as described above. More specifically, the fixing member 131 is composed of a pair of fixing belts 131, one end of which is coupled to both front ends of the cover 130 to surround the outer surface of the piers 10, and the pair of fixing The other end of the belt 131 is configured to be coupled to each other through the fastening member (B). Therefore, according to the present invention, the pier without damaging the pier 10 through the fixing member 131 without a portion directly fastened to the pier 10 to fix the water collecting housing 100 to the pier 10. There is an advantage in that the sewage housing can be fixedly installed.

The filtering member 200 is installed in the inlet 132 is configured to filter the sand and foreign matter from the sample water flowing through the inlet. That is, the filtration member 200 is installed in the inlet 132, and only the pure sample water flows into the intake housing 100, and performs the role of filtering sand and foreign matter not to enter the intake housing 100.

More specifically, as shown in FIGS. 6 and 7, the filtration member 200 is installed at the center of the inlet 132 and the thread filter sheet 210 in which fibers are randomly entangled and stacked like a thread. And, it is disposed on the front and rear of the thread filter sheet 210 and the mesh line is configured to be arranged in the "X" shape is composed of the front and rear mesh network (220,230) is formed a plurality of inlet holes therein. Here, the sift filter sheet 210 is supported by the front and rear through the front and rear mesh network (220,230) is installed replaceably in the inlet (132).

The filtration member 200 configured as described above filters the large foreign substances while the front and rear mesh networks 220.230 support the thread filter sheet 210 in the center portion, and filter only the sample water through the inflow hole into the housing 100. The thread filter sheet 210 filters the fine foreign substances such as sand and sand so that only pure sample water is introduced into the intake housing 100. Therefore, since the sample water flowing through the inlet 132 is filtered through the sieve filter sheet, the front and rear mesh networks 220 and 230 for 1, 2, 3, and then flows into the water collecting housing 100, There is an advantage in that foreign matter is deposited in the water collecting housing 100 is minimized. In addition, the filtration member 200 has the advantage that the manager can easily clean and reuse because it is a removable structure at the inlet 132.

The submersible pump 300 is installed in the water collecting housing 100 and installed to be height-adjustable through the elevating means 350, and the sample water flowing into the water collecting housing 100 through the inlet 132. It is configured to pump and pump to the measuring station (1). Here, it is preferable that the measuring station 1 is installed on the bridge directly above the submersible pump 300 and installed at the shortest distance from the submersible pump.

According to the present invention, the submersible pump 300 is installed to be height-adjustable through the elevating means 350 in accordance with the water level of the river, as shown in Figure 8, the elevating means 350, the front A support plate 351 protruding from the top of the plate 120 to the rear, a guide rod 352 fixedly installed between the support plate 351 and the bottom plate 110, and a rear of the guide rod 352. TM screw rod (353) that is installed to be capable of forward or reverse rotation to the support plate and the bottom plate to the side, and coupled to the upper end of the TM screw rod (353) to the upper side of the support plate 351 to rotate the TM screw rod forward Alternatively, a handle 354 for rotating in reverse and a guide hole 355a guided by being guided to the guide rod 353 at the rear end thereof are formed and engaged with the TM screw rod 353 toward the guide hole 355a. TM configured to be movable up and down along the TM threaded rod 353 by the rotation of the screw rod Lift plate 355 is coupled to the 355b, and the upper portion is formed in an open cylindrical shape and a plurality of water passages (356a) is formed on the outer surface is configured to be installed inside the water pump, the lifting plate 355 It is configured to include a motor installation cylinder 356 is installed on the front end of the front end portion and installed to be movable up and down with the lifting plate.

The lifting means 350 configured as described above is configured such that when the handle 354 is operated, the TM nut 355b moves up and down along the TM screw rod 353 according to the rotation of the TM screw rod 353. As the TM nut 355b moves forward and backward, the elevating plate 355 is moved up and down, and in accordance with the vertical movement of the elevating plate 355, the motor installation cylinder 356 provided with the submersible pump 300 is provided. It is configured to move in the vertical direction.

Therefore, as shown in Figures 9 and 10, it is possible to adjust the installation height of the submersible motor 300 in the intake housing 100 according to the water level of the river, it is possible to easily collect the sample water not only in the flooding period but also in the dry season. By securing accurate water quality data, it is possible to improve the reliability of measuring the contamination of sample water. In addition, even when the submersible pump 300 needs to be replaced, the submersible pump 350 has an advantage of being easily replaced by raising the submersible pump 300 to the upper portion of the water collecting housing 100.

The collection pipe 400 is connected to the submersible pump 300 and extends to the measuring station 1 along the outer surface of the piers 10 to collect the sample water. Here, one side of the water pipe 400 is connected to the measurement station 1 and the submersible pump 300 is provided with a conduit pipe 410 is piped for supplying power to the submersible pump. In addition, the collection pipe 400 and the conduit 410 is finished through a protective cover 430 attached to the pier to prevent foreign substances from being caught in the collection pipe 400 and the conduit 410 even during flooding 400 and the conduit 410 is preferably configured to be firmly protected from damage.

On the other hand, according to the invention, it is characterized in that it is configured to easily clean the deposits in the water intake housing (100).

To this end, as shown in FIG. 11, the opening and closing hole 134 is formed at the lower end side of the cover 130, the guide rails 135 are installed at both sides of the opening and closing hole 134 in the vertical direction, and the guide Both ends of the opening and closing door D are slidably fitted to the rail 135 so as to selectively open and close the opening and closing door 134.

A first opening / closing valve (V1) is installed at a portion of the water collecting pipe (400) to selectively open and close the water collecting pipe (400), and the first opening / closing valve (V1) at the water collecting pipe (400). The cleaning tube 450 that is selectively opened by the second opening and closing valve (V2) is connected to the lower side of the.

By such a configuration, the water door is opened by sliding the opening / closing door D upward, the first opening / closing valve V1 is locked, and the second opening / closing valve V2 is opened. By pumping water through the pump 300 to spray water through the cleaning pipe 450, the inside of the water collecting housing 100 is cleaned and the cleaned water is discharged through the opening and closing hole 134. Therefore, since the sediment inside the sewage housing 100 can be easily pushed out of the sewage housing 100 and discharged, there is an advantage that the sediment inside the sewage housing 100 can be easily cleaned.

The bridge-type water level fluctuation water collecting device for measuring water pollutants according to the present invention configured as described above is installed around the bridge pier where the water level and flow rate are variable, as shown in FIG. Even in the dry season, there is an advantage that the measuring station can be operated by collecting the sample water stably.

While the invention has been shown and described in connection with specific embodiments, it will be understood that various modifications and variations can be made without departing from the spirit and scope of the invention as indicated by the claims. Anyone can grow up easily.

100: water intake housing 200: filtration member
300: submersible pump 400: water pipe

Claims (6)

A bottom plate installed at the bottom of the river, a front plate extending upward from the front of the bottom plate and installed in close contact with the pier, and extending from the side and the rear of the bottom plate and fixedly installed at the pier through the fixing member. A water collecting housing comprising a cover having an inlet through which sample water is introduced at a lower end thereof, and a cover closing an upper side of the cover and the front plate;
A filtering member installed at the inlet to filter sand and foreign substances from the sample water flowing through the inlet;
An underwater pump installed inside the water collecting housing and installed to be height-adjustable through an elevating means, and pumping the sample water introduced into the water collecting housing through the inlet to be pumped to a measurement station; And
It is connected to the submersible pump and extends to the measuring station along the outer surface of the bridge is configured to include a collecting pipe for collecting the sample water,
The elevating means may include a support plate protruding from the top of the front plate to the rear, a guide rod fixedly installed between the support plate and the bottom plate, and a forward or reverse rotation to the support plate and the bottom plate toward the rear of the guide rod. TM screw rod is installed to be installed, the handle is coupled to the upper end of the TM screw rod to the upper side of the support plate for forward or reverse rotation of the TM screw rod, and the guide hole is inserted into the guide rod to guide the rear end is formed and the guide ball A lifting plate coupled to the TM screw rod forward and coupled with a TM nut configured to be movable up and down along the TM screw rod by rotation of the TM screw rod, and having a cylindrical shape with an open top, and having a plurality of water passages on the outer surface. The ball is formed and configured to be installed inside the water pump, the upper surface of the front end of the elevating plate is installed with the elevating plate Bridge type water level fluctuation collection device for measuring water pollutants, characterized in that it comprises a motor installation can be installed to move downward.
The method of claim 1,
The front plate is a bridge-type water leveling water collecting device for measuring water pollutants, characterized in that the installation grooves are formed in the same shape as the outer surface of the piers so as to be closely adhered to the outer surface of the piers.
The method of claim 1,
The fixing member is composed of a pair of fixing bands one end is coupled to both front ends of the cover to surround the outer surface of the piers, the other end of the pair of fixing straps is configured to be coupled to each other through a fastening member,
Bridge type water level fluctuation collection device for measuring water pollutants, characterized in that configured to be fixed to the pier without damaging the pier through the fixing member.
The method of claim 1,
The filtration member,
Skeletal filter sheet is installed in the central portion of the inlet and the fibers are randomly entangled and stacked like a thread,
Bridge type for measuring water pollutants, characterized in that consisting of the front and rear mesh network is arranged on the front and rear of the thread filter sheet and the mesh line is arranged in the "X" shape to form a plurality of inlet holes therein. Water level change catcher.
delete The method of claim 1,
Opening and closing holes are formed in the lower side of the cover, guide rails are installed on both sides of the opening and closing direction, and both ends of the opening and closing doors are slidably fitted to the guide rails so as to selectively open and close the opening and closing doors.
A first opening / closing valve is installed at a part of the intake pipe and configured to selectively open and close the intake pipe, and the intake pipe is connected to a cleaning pipe selectively opened by a second open / close valve to the lower side of the intake pipe. Became,
By sliding the opening and closing door to the upper side to open the opening and closing, locking the first opening and closing valve, the second opening and closing valve in the state, by pumping water through the submersible pump to inject water through the cleaning pipe, Bridge type water level fluctuation device for measuring water pollutants, characterized in that the inside of the water collecting housing is cleaned and the cleaned water is discharged through the opening and closing to discharge sediment inside the water collecting housing to the outside of the water collecting housing. .

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