JP2004132845A - Water sampling apparatus for monitoring water quality - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a water sampling apparatus for monitoring water quality for sampling an oil component floating in a water surface with water and accurately sampling a surface layer water in the water surface or water at any specified water level below the water surface. <P>SOLUTION: The water sampling apparatus 10 comprises a frame 15 mounted to a quay wall 13 or the like; a submerged water pump 20 mounted to the frame 15 and arranged below a water sampling location at which water is sampled; a suction pit 30 mounted to the submerged pump 20 for communicating with a suction opening 21 of the submerged water pump 20; a raising and lowering means 40 mounted to the suction pit 30 for communicating with the suction pit 30; and a float part 50 mounted to the upper end of the raising and lowering means 40. A water sampling opening communicating with the raising and lowering means 40 is provided for the outer circumference of the float part 50. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a water sampling device for water quality monitoring sampling, and more particularly, to a water quality monitoring sampling water sampling device that can sample surface water on the water surface or water at a specified water level below the water surface as water quality monitoring sampling. Water equipment.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there has been known a water sampling apparatus for sampling water quality of a river for sampling the water of a river as a sampling for monitoring the water quality in order to check the state of water contamination of a river or the like.
[0003]
This sampling water sampling device for water quality monitoring floats the float on the surface of the water, takes in surface water from underneath the float, guides the captured surface water from the water intake provided in the float to the suction port of the pump, The surface water guided to the tank was pumped to a water collection tank.
[0004]
[Problems to be solved by the invention]
However, the conventional water sampling device is configured to float the float on the surface of the water and collect surface water from the lower side of the float, so that only water within the area surrounded by the float can be sampled. For example, when the oil component is floating on the water surface outside the float, the oil component could not be taken into the water sampling port. For this reason, there is a problem that the presence of the oil component cannot be detected even though the oil component is floating on the water surface.
[0005]
Further, sampling for water quality monitoring may require not only surface water at the surface of the water but also water at a specified water level below the water surface.
However, the conventional water sampling device has a configuration in which the float is floated on the surface of the water and the surface water is sampled from the lower side of the float.Therefore, there is a problem that water at a specified water level below the surface cannot be sampled. there were.
[0006]
According to the present invention, sampling of a water quality monitor that can reliably sample oil components floating on the water surface and freely sample surface water on the water surface or water at a specified water level below the water surface can be performed. It is an object of the present invention to provide a water device to solve all the above problems.
[0007]
[Means for Solving the Problems]
In order to achieve the above object of the present invention, the invention according to claim 1 is directed to a water sampling apparatus for sampling water quality for sampling surface water on the water surface or water at a specified water level below the water surface as sampling for water quality monitoring. The water sampling device for sampling water quality includes a submersible pump disposed below a water sampling position for sampling water, and a suction pit attached to the submersible pump and connected to a suction port of the submersible pump. Attached to the suction pit, a lifting means connected to the suction pit, and a float portion attached to the upper end of the lifting means and provided with a water sampling port connected to the lifting means provided on the outer periphery, The float part is made to follow the vertical fluctuation of the water surface by the elevating means, and the sampling pit taken from the water sampling port is sucked through the elevating means into the suction pit. Led in, the water led to the suction pit water pump to water sampling tank, characterized in that water.
[0008]
The water sampling device for water quality monitoring sampling according to the present invention described above has a water sampling port provided on the outer periphery of the float portion, so that the water sampling port can be adjusted to the position of the water surface, and the oil component floating on the water surface can be converted into water. Can be taken in from the water intake with certainty.
[0009]
The invention according to claim 2 is characterized in that the float portion is formed in a hollow shape, and the floating height position of the float portion can be adjusted by putting weight water into the float portion.
[0010]
The present invention has a configuration in which the float is provided with a hollow portion and weight water is filled in the hollow portion. By adjusting the buoyancy of the float portion by adding weight water to the hollow portion, the float portion is raised to a designated height below the water surface. It can be floated in the position.
[0011]
The invention according to claim 3 is characterized in that the elevating means is a tubular free arm whose lower end is rotatably attached to the suction pit and whose upper end is rotatably attached to the float portion. I do.
[0012]
By configuring this elevating means with a tube-shaped free arm, it is possible to guide sampling water sampled from a water sampling port through the free arm to the suction pit. In this way, the function of connecting the float portion to the suction pit with only the free arm and the function of the flow path for guiding water to the suction pit can be used together.
[0013]
According to a fourth aspect of the present invention, the elevating means is a bellows-shaped tube having a lower end attached to the outer periphery of the suction pit and an upper end attached to the outer periphery of the float portion.
[0014]
By configuring the elevating means with a bellows-shaped tube, sampling water collected from the water sampling port can be guided to the suction pit through the bellows-shaped tube, and the float part is connected to the suction pit only with the bellows-shaped tube And the function of a flow path for guiding water to the suction pit can be used in combination.
[0015]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of a sampling water sampling apparatus for water quality monitoring according to the present invention will be described in detail with reference to the accompanying drawings.
1 is a side view of a sampling water sampling device for water quality monitoring according to the present invention (first embodiment), FIG. 2 is a plan view of the same, FIG. 3 is a cross-sectional view of the suction pit, and FIG. -A line sectional view, FIGS. 5 and 6 are explanatory diagrams of the operation of the water sampling apparatus (first embodiment) according to the present invention, and FIG. 7 is a sampling water sampling apparatus for water quality monitoring according to the present invention (second embodiment). FIG.
[0016]
The sampling water sampling device 10 for water quality monitoring shown in FIG. 1 is used for sampling surface water located on the water surface 11 and water located at a specified height below the water surface 11 as sampling for water quality monitoring. Device.
[0017]
The water sampling apparatus 10 includes a frame 15 attached to a quay 13 or the like, a submersible pump 20 disposed below a water sampling position when water is sampled by attaching to the frame 15, and a submersible pump 20 A suction pit 30 connected to the suction port 21 (see FIG. 3) of the submersible pump 20 and attached to the suction pit 30, and an elevating means 40 connected to the suction pit 30 and connected to the suction pit 30, A water sampling port 55 (see also FIG. 2) attached to the upper end of the means 40 and communicated with the elevating means 40 is constituted by a float part 50 provided on the outer periphery.
[0018]
According to the water sampling apparatus 10, the float 50 is caused to follow the vertical fluctuation of the water surface 11 by the elevating means 40, and the sampling water sampled from the water sampling port 55 is guided to the suction pit 30 through the elevating means 40. The water guided to the suction pit 30 can be sent to the water collection tank (not shown) by the submersible pump 20.
[0019]
In the frame 15, a horizontal frame member 16 is attached to a surface 13a of the quay 13 with bolts 14, and a vertical frame member 17 is attached to a tip 16a of the horizontal frame member 16, and the vertical frame member 17 is attached to a side wall 13b of the quay 13. The horizontal frame member 16 and the vertical frame member 17 are arranged in a substantially inverted L-shape.
[0020]
A submersible pump 20 is attached to a lower end portion 17a of the vertical frame member 17 with a bracket 18 with a suction port 21 (see FIG. 3) facing downward. The water pump 23 is connected to the upper end of the submersible pump 20, and the water pipe 23 is connected to a water collection tank (not shown) placed on the ground.
Therefore, the water sucked from the suction port 21 of the submersible pump 20 can be collected in the water collection tank through the water supply pipe 23.
[0021]
As shown in FIGS. 3 and 4, a suction pit 30 is attached to the lower end 24 of the submersible pump 20. The suction pit 30 has a cylindrical inner cover 31 having an opening 31 b formed on a bottom surface 31 a along the suction port 21 of the submersible pump 20, and is attached to the lower end 24 of the submersible pump 20 with bolts 32. The outer cover 34 is attached to the flange 31c with bolts 33. Thus, a space 35 (see FIG. 3) is formed by the inner cover 31 and the outer cover 34.
The water flowing into the space 35 is guided from the opening 31 b formed in the bottom surface 31 a of the inner cover 31 to the suction port 21 of the submersible pump 20.
[0022]
Reinforcing plates 36 are attached at equal intervals to the inner wall of the outer cover 34 and the outer wall of the inner cover 31 to reinforce the outer cover 34 and the inner cover 31, and a bottom surface 34a of the outer cover 34 (see FIG. 3). ), Three bolts 37 for horizontally installing the submersible pump 20 are attached at equal intervals.
[0023]
A recess 31d is formed on the bottom surface 31a of the inner cover 31 at the periphery of the opening 31b, and a positioning member 38 attached to the lower end 24 of the submersible pump 20 is inserted into the recess 31d. By fitting the recess 31d into the positioning member 38, the inner cover 31 can be positioned at a desired mounting position.
[0024]
Further, as shown in FIG. 3, a seal member 39 a is attached to a gap between the upper end 31 e of the inner cover 31 and the flange 21 a of the submersible pump 20. Water is prevented from entering the inner cover 31 from the gap between the submersible pump 20 and the flange 21a.
[0025]
In addition, a seal member 39b is attached to a gap between the flange 31c of the inner cover 31 and the flange 34b of the outer cover 34, and thereby, a gap between the flange 31c of the inner cover 31 and the flange 31b of the outer cover 34 is provided. Water is prevented from entering the space 35 from the gap therebetween.
[0026]
As shown in FIGS. 1 and 2, an elevating means 40 is attached to the outer cover 34 of the suction pit 30, and the elevating means 40 includes left and right free arms 41 and 42 as shown in FIG. . The left free arm 41 has a lower horizontal tube 43 connected to a lower end 45 a of a swing tube 45 via a lower elbow 44, and an upper horizontal tube 47 connected to an upper end 45 b of the swing tube 45 via an upper elbow 46. And the entire tube is formed in a substantially U-shape.
Since the right adjustable arm 42 is formed of the same member as the left adjustable arm 41, the same reference numerals are given and the description is omitted.
[0027]
The left and right free arms 41, 42 are rotatably attached to the peripheral wall 34c of the outer cover 34 at the distal ends 43a, 43a of a pair of lower horizontal tubes 43, 43 via left and right lower joints 48a, 48b, respectively. The tips 47a, 47a of the upper horizontal tubes 47, 47 are rotatably attached to the side wall of the water sampling unit 53 of the float unit 50 via left and right upper universal joints 49a, 49b, respectively.
[0028]
Therefore, the left and right free arms 41 and 42 can swing vertically about the lower universal joints 48a and 48b, thereby maintaining the float 50 in the vertical state (the state shown in FIG. 1) while maintaining the float 50 in the vertical direction. Can be raised and lowered.
[0029]
By configuring the elevating means 40 with a tube-shaped free arm, sampling water taken from the water sampling port 55 can be guided to the suction pit 30 through the inside of the free arm. Thus, the function of connecting the float part 50 to the suction pit 30 and the function of the flow path for guiding water to the suction pit 30 can be ensured only by the tube-shaped free arm.
[0030]
As shown in FIG. 1, the float portion 50 is formed in a cylindrical shape in which a cylindrical float main body 51 is closed at upper and lower ends with upper and lower lids 51 a and 51 b, respectively, and is taken over the entire peripheral wall of the float main body 51. The water part 53 is attached, and four arc-shaped punching metals 54 (see FIG. 2) are attached to the opening at the upper end of the water sampling part 53. A water sampling port 55 is formed by a plurality of small holes formed in the punching metal 54.
[0031]
Thereby, water can be sampled from the water sampling port 55 into the water sampling section 53. In addition, by closing the opening of the water sampling unit 53 with the punching metal 54, it is possible to prevent an obstacle such as driftwood from entering the water sampling unit 53.
[0032]
As shown in FIG. 1, an opening 51c is formed in the upper lid 51a of the float body 51, and a plug 57 (see also FIG. 2) is detachably attached to the opening 51c. By putting weight water inside the float main body 51, the buoyancy of the float main body 51 can be adjusted.
[0033]
Next, the operation of the water sampling apparatus 10 for sampling water quality will be described with reference to FIGS.
FIG. 5 shows a state in which weight water is not put into the float main body 51 of the float part 50. Since the water sampling port 55 of the float part 50 can be adjusted to the water surface 11, the surface water of the water surface 11 can be sampled from the water sampling port 55 into the water sampling part 53 as shown by the arrow a.
[0034]
The collected water flows in the left and right free arms 41 and 42 in the direction of arrow b, and the water flowing in the left and right free arms 41 and 42 flows into the suction pit 30 as shown by arrow c. Then, the water flowing inside the suction pit 30 is sucked from the suction port 21 (see FIG. 3) of the submersible pump 20 in the direction of arrow d, and is drawn through the water pipe 23 as shown by arrow e as shown by arrow e. (Not shown).
[0035]
Here, by aligning the water sampling port 55 of the float part 50 with the water surface 11, if the oil component floats on the water surface 11, the oil component floating on the water surface 11 is taken out of the water sampling port 55 together with the water. Can be captured. Therefore, by inspecting the water taken in from the water sampling port 55, it is possible to reliably detect that the oil component is floating on the water surface 11.
[0036]
FIG. 6 shows a state in which weight water is put in the float main body 51 of the float part 50. The stopper 57 is removed from the upper lid 51a of the float main body 51, and weight water is poured into the hollow portion of the float main body 51 from the opening 51c (see FIG. 1) of the upper lid 51a. Thereby, the buoyancy of the float part 50 can be adjusted and the float part can be floated at the specified height position below the water surface.
[0037]
Therefore, water at a designated height position below the water surface 11 can be sampled from the sampling port 55 into the sampling section 53 as shown by the arrow a. The collected water flows in the left and right free arms 41 and 42 as shown by the arrow b, and the water flowing in the left and right free arms 41 and 42 flows through the suction pit 30 as shown by the arrow c. .
[0038]
Then, the water flowing in the suction pit 30 is sucked from the suction port 21 (see FIG. 3) of the submersible pump 20 in the direction of arrow d, and is drawn through the water pipe 23 into the water collection tank as shown by arrow e. Is done.
As described above, it is possible to collect water at an arbitrary designated water level below the water surface 11 by a simple operation of merely putting weight water into the hollow portion of the float portion 50.
[0039]
Next, a second embodiment will be described with reference to FIG.
A water sampling device 60 for sampling for water quality monitoring shown in FIG. 7 includes a submersible pump 62 disposed below a desired water sampling position for sampling water, and a submersible pump 62 attached to the submersible pump 62. A suction pit 65 communicating with the suction port 63, a lifting means 70 attached to the suction pit 65 and communicating with the suction pit 65, and an upper end of the lifting means 70 and communicating with the lifting means 70 A cylindrical casing 85 which accommodates a float portion 75 provided with a water sampling port 79a provided on the outer periphery 79, the float portion 75, the lifting / lowering means 70, and the suction pit 65, and is attached to the suction pit 65 via a reinforcing plate 84. And a frame (not shown) for attaching the tubular casing 85 to a quay (not shown).
[0040]
A cylindrical suction pit 65 is attached to the suction port 63 of the submersible pump 62 via a reinforcing plate 66 with the bottom surface 65a of the suction pit 65 facing the upper end of the suction pit 65. Elevating means 70 is attached to the outer periphery 65b.
[0041]
The elevating means 70 is a bellows-shaped tube in which a lower end 70a is attached to an upper end outer periphery 65b of the suction pit 65, and an upper end 70b is attached to the outer periphery of the float portion 75, that is, the outer periphery 79 of the water sampling portion 78 of the float portion 75. It is configured.
Therefore, when the bellows-shaped tube expands and contracts, the float portion 75 can move in the vertical direction.
[0042]
The float part 75 is formed of a cylindrical body whose upper and lower ends are closed by upper and lower lids 76a and 76b, respectively, and a cylindrical water sampling part 78 is attached to the lower lid 76b of the float main body 76. A plurality of small holes are opened in the outer periphery 79 of the water sampling section 78, and the plurality of small holes form a water sampling port 79a.
[0043]
Therefore, the sampling water sampled from the water sampling port 79a of the water sampling section 78 can be guided to the suction pit 65 through the bellows tube elevating means 70, and the float part 75 can be moved only by the bellows tube elevating means 70. The function of connecting to the suction pit 65 and the function of a flow path for guiding water to the suction pit 65 can be ensured.
[0044]
In addition, similarly to the first embodiment, the buoyancy of the float main body 76 can be adjusted by removing the plug 80 from the upper lid 76a of the float main body 76 and putting weight water into the hollow portion inside the float main body 76. .
In this way, by adjusting the buoyancy of the float main body 76, surface water on the water surface 11 and water at a desired designated water level below the water surface 11 can be arbitrarily sampled as water quality monitoring sampling.
[0045]
According to the water sampling device 60 of the second embodiment described above, the float portion 75 is made to follow the vertical fluctuation of the water surface 11 by the elevating means 70 composed of a bellows-shaped tube, and as shown by the arrow f from the water sampling port 79a. Water for sampling can be sampled.
Then, since the collected water is guided to the suction pit 65 through the elevating means 70 as shown by the arrow g, the water guided to the suction pit 65 is guided by the submersible pump 62 to the position of the water pipe 82 in the direction of the arrow h. Water is supplied through a water supply pipe 82 to a water collection tank (not shown) as indicated by an arrow j.
Of course, according to the water sampling device 60, the same effect as the water sampling device 10 of the first embodiment can be obtained.
[0046]
In the above-described embodiment, an example in which the float bodies 51 and 76 of the float portions 50 and 75 are formed in a cylindrical body is described. However, the present invention is not limited to this, and the float bodies 51 and 76 may be formed in other shapes such as a square. .
Further, the shapes of the suction pits 30 and 65 are not limited to the embodiment shown in the drawings.
[0047]
【The invention's effect】
As described above, according to the water sampling apparatus for sampling water quality according to the first aspect, the water sampling port is provided on the outer periphery of the float portion. Therefore, since the water sampling port can be adjusted to the water surface, the oil component floating on the water surface can be reliably taken in from the water sampling port together with the water. Therefore, by inspecting the taken-in water, it can be accurately detected that the oil component is floating on the water surface.
[0048]
According to a second aspect of the present invention, the float portion has a hollow portion, and the hollow portion is filled with weight water. Thus, by adjusting the buoyancy of the float by adding weight water to the hollow, the float can be floated at a specified height below the water surface. For this reason, it is possible to reliably collect water at an arbitrary designated water level below the water surface by a simple operation of merely putting weight water into the hollow portion of the float portion.
[0049]
According to a third aspect of the present invention, the lifting means is constituted by a tube-shaped free arm, so that water for sampling taken from a water sampling port can be guided to the suction pit through the free arm, and the float portion is formed only by the free arm. Since the function of connecting to the suction pit and the function of the flow path for guiding water to the suction pit can be used together, the configuration of the elevating means can be simplified.
[0050]
According to a fourth aspect of the present invention, since the elevating means is formed of a bellows-shaped tube, the sampling water collected from the water sampling port can be guided to the suction pit through the bellows-shaped tube, and the float portion is formed only by the bellows-shaped tube. Can be used in combination with the function of connecting the water to the suction pit and the function of the flow path for guiding water to the suction pit, so that the structure of the elevating means can be simplified.
[Brief description of the drawings]
FIG. 1 is a side view of a sampling water sampling device (first embodiment) for water quality monitoring according to the present invention.
FIG. 2 is a plan view of the same.
FIG. 3 is a sectional view of the suction pit.
FIG. 4 is a sectional view taken along line AA of FIG. 3;
FIG. 5 is an operation explanatory view of the water sampling apparatus (first embodiment) according to the present invention.
FIG. 6 is an operation explanatory view of the water sampling apparatus (first embodiment) according to the present invention.
FIG. 7 is a sectional view of a sampling water sampling apparatus for water quality monitoring (second embodiment) according to the present invention.
[Explanation of symbols]
10, 60 ... water sampling device 11 ... water surface 13 ... quay 13a ... quay surface 13b ... quay side walls 14, 32, 33, 37 ... bolt 15 ... frame 16 ... horizontal frame member 16a ... tip of horizontal frame member 17 ... vertical Frame member 17a Lower end portion of vertical frame member 18 Bracket 20, 62 Submersible pump 21, 63 Suction port 23, 82 Water pipe 24 Lower end portion 30, 65 of submersible pump Suction pit 31 Inner cover 34 Outer cover 35 ... Spaces 36, 66, 84 ... Reinforcement plate 38 ... Positioning members 40, 70 ... Lifting means 41, 42 ... Free arm 43 ... Lower horizontal tube 44 ... Lower elbow 45 ... Swing tube 46 ... Upper elbow 47 ... Upper horizontal Tubes 50, 75 Float parts 51, 76 Float bodies 53, 78 ... Water sampling part 54 ... Punched metal 55, 79a ... Water sampling port 5 , 80 ... upper end of the outer periphery of the plug 65b ... suction pit (the outer circumference of the suction pit)
70a: Lower end of bellows-shaped tube 70b: Upper end of bellows-shaped tube 79: Outer circumference of water sampling part (outer circumference of float part)
85 ... cylindrical casing

Claims (4)

In a water sampling device for sampling water quality for sampling surface water on the water surface or water at a designated water level below the water surface as sampling for water quality monitoring,
This water sampling device for water quality monitoring includes a submersible pump disposed below a water sampling position for sampling water,
A suction pit attached to this submersible pump and connected to the suction port of the submersible pump,
Elevating means attached to the suction pit and communicated with the suction pit;
A water sampling port connected to the upper end of the elevating means and communicating with the elevating means comprises a float portion provided on the outer periphery,
The float portion is caused to follow vertical fluctuations of the water surface by a lifting means, and sampling water collected from the water sampling port is guided to a suction pit via a lifting means, and water guided to the suction pit is collected by a submersible pump. A sampling water sampling device for water quality monitoring, which sends water to a water tank. The water sampling for water quality monitoring according to claim 1, wherein the float part is formed in a hollow shape, and a floating height position of the float part is adjustable by putting weight water into the float part. apparatus. The said lifting means is a tube-shaped free arm with which the lower end was rotatably attached to the said suction pit, and the upper end was rotatably attached to the said float part, The Claim 1 or Claim 2 characterized by the above-mentioned. The sampling water sampling device for water quality monitoring described in the above. 3. The water quality monitor according to claim 1, wherein the elevating means is a bellows-shaped tube having a lower end attached to an outer periphery of the suction pit and an upper end attached to an outer periphery of the float portion. Sampling water sampling equipment.

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