KR20190011040A - Apparatus for continuous monitoring change in depth-specific aquatic environment - Google Patents

Abstract

The present invention relates to an apparatus for continuously monitoring a change in a depth-specific aquatic environment. The apparatus comprises: a buoy continuously floating on the water surface regardless of water levels and including a through hole formed in the lower part; a chain having the upper part tied with the through hole or a first shackle-shaped ring combined with the through hole; a connection rope having the upper part tied with the through hole or the first shackle-shaped ring combined with the through hole, while having the lower part connected with the chain; an anchor, which is a weight fixed to the bottom and including at least one second ring penetrated by the connection rope, making the chain and the connection rope located on a predetermined spot; a hanger combined with a connection spot between the chain and the connection rope, and preventing the chain from penetrating the second ring; and a plurality of measurement sensors fixed to the chain at equidistant or different intervals to continuously obtain depth-specific data in regard to an absolute water level, which does not vary, even if the level of the water surface is changed to identify a change in a depth-specific aquatic environment. Thus, the present invention is capable of having excellent workability by lifting only chains including measurement sensors without salvaging the whole apparatus when obtaining data of the measurement sensors.

Description

[0001] The present invention relates to a continuous observation apparatus,

More particularly, the present invention relates to a continuous observation device for changing the water environment of a water depth, and more particularly, The depth of water in which the plurality of measurement sensors are located does not change with respect to the water surface even if the water level fluctuates or the bottom surface is raised or settled, so that data collection can be continuously performed for each water depth from the water depth. .

The environmental changes including water temperature, water depth, flow rate and water quality in the water and the lake due to the dam construction and underwater construction have caused disturbance of ecological environment such as occurrence of green algae and death of fish population. In addition, the water quality sector is of particular concern for the supply of drinking water.

However, there has been no quantitative observation method to observe the underwater environment. Therefore, if observations of water depths are performed at important depths of water indices, not only the protection of water sources but also ecological environmental disturbances The prevention and countermeasures and the identification of the cause can be performed quickly.

In general, in order to acquire data on the underwater environment in the past, the water quality was directly measured at rivers, lakes, and water sources, or by using various kinds of portable observation devices. In addition, various sensors are put into water to collect various data according to the depth of the water. However, it is difficult to acquire accurate data of the depth of water, and it is troublesome to the operator, and the cost is excessively increased.

On the other hand, Korean Patent Registration No. 10-1227892 (published on Jan. 30, 2013) discloses a GPS unit for generating position information by specifying a current position; A buoyancy member provided at a lower portion of the GPS unit and having an internal space and having an internal volume changed according to increase or decrease of air to increase or decrease buoyancy; A pressure tank provided at a lower portion of the buoyancy member and supplying air stored in the internal space to the buoyancy member by a pressure difference; A plurality of state measuring units provided at a lower portion of the pressure tank and including a flow rate measuring sensor for measuring a flow rate; And a distance measuring unit provided at a lower portion of the state measuring unit and measuring a distance to the bottom of the water, wherein the state measuring unit measures a flow velocity with respect to the water depth, And an air supply valve provided between the member and the pressure tank for connecting the buoyancy member and the pressure tank, wherein the distance measuring unit measures the distance from the bottom of the water in real time, When the emergency signal is received from the distance measuring unit, the control unit opens the air supply valve to supply the air stored in the pressure tank to the buoyancy member And the measurement of the underwater environment is performed.

However, in the related art, it is difficult to continuously collect measurement data at a specific water depth from the water level due to a rise and fall of the measurement device in accordance with a change in the amount of air in the buoyancy member. In order to acquire the measurement data stored in the sensor, It is troublesome to pull up the entire measuring device from the water.

Korean Registered Patent No. 10-1227892 (Publication date: 2013.01.30, name of invention: apparatus for measuring underwater environment and method for measuring underwater environment using the apparatus)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a measurement sensor, The water depth in which the plurality of measurement sensors are located does not change on the basis of the water surface even if the water level of the water surface is excellent and the water level of the water surface is fluctuated or the bottom surface is raised or settled. And a continuous observation device for changing the water depth.

It is another object of the present invention to provide a continuous observation apparatus for changing the water depth environment without the possibility of fluctuation of the observation point when the measurement sensor is reloaded into the water after salvage, and which does not require much manpower and expense.

According to an aspect of the present invention, there is provided an air conditioner comprising: a body which is always floating on a water surface regardless of a change in water level; A chain connecting the upper end to the through hole or coupling a first annular ring to the through hole and connecting the upper end to the first annular ring; A connection rope connecting the upper end to the through hole or connecting the lower end to the chain while the upper end of the connection rope is connected to the first annular ring by coupling the first annular ring to the through hole; An anchor for holding the chain and the connecting rope at a predetermined point, the weight being seated and fixed to the lower surface while having at least one second loop through which the connecting rope penetrates; A hook which is coupled to a connecting point between the chain and the connecting rope and prevents the chain from penetrating the second loop due to the hooking of the second loop, And a plurality of measurement sensors for continuously acquiring depth-dependent data with respect to an absolute depth of water whose depth does not change with respect to the water surface even if the water level changes in order to grasp the water environment change.

In addition, in the present invention, the chain is made of a material and shape of a chain so that movement due to the flow of water is minimized in the water and sufficient tensile force acts in the depth direction by its own weight.

In the present invention, the fixed installation position of the measurement sensor on the chain is determined in consideration of the observation depth from the determined water surface and the height of the buoy.

The length of the chain and the connecting rope must be longer than the depth of the lower surface from the surface of the water because the depth of the lower surface of the lower surface changes and the lifting of the chain is required to obtain measurement data stored in the measurement sensor.

In the present invention, the water depth data is data on at least one of water temperature, turbidity, DO, pH, electric conductivity, and chlorophyll- a (Chl- a ).

Further, the present invention is characterized in that a metal rod is inserted and fixed in the through hole, the chain and the connecting rope are connected to each other, or the metal rod is connected to the first hook of the shackle, Tie them together.

Further, in order to measure water temperature or water quality at the lower surface, the present invention is characterized in that one side is passed through a first shackle-shaped ring coupled to a through hole or a through hole of the buoy, and the other side is passed through a second ring of the anchor With other connecting ropes; A measurement sensor fixed to the other connecting rope and measuring a water temperature or a water quality at a lower surface; The measuring sensor is coupled to the other connecting rope in the vicinity of the measuring sensor, and when the other connecting rope is pulled, a latching part for catching the second loop can be added.

Further, the present invention is additionally fixed and fixed to a chain between the plurality of measurement sensors.

As described above, according to the present invention, there is provided a continuous observation device for changing the water environment according to the water depth, in which only the chain in which the measurement sensor is fixed is lifted up without taking up the entire apparatus in order to acquire data of the measurement sensor in the water, , The water depth at which the plurality of measurement sensors are located does not change with respect to the water surface even if the water level fluctuates or the bottom surface rises or falls, so that the data collection can be continuously performed for each depth of water from the water surface.

Further, in the present invention, there is no possibility of fluctuation of the observation point when the measurement sensor is reloaded into the water after lifting, and it does not require much manpower and expense.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing an embodiment of a continuous water environment change monitoring apparatus according to the present invention. FIG.
2 is a view showing another embodiment of an apparatus for continuously monitoring a change in water environment according to a water depth according to the present invention.
3 is a view showing a state in which a continuous observation apparatus for changing the water environment according to the present invention is dropped into water.
4 is a view showing a method for determining a position where a measurement sensor is fixedly installed on a chain in the present invention.
FIG. 5 is a graph showing that the absolute depth of the water in which the measurement sensor is located in the present invention does not change even if the water level varies. FIG.
FIG. 6 is a graph showing water temperature data obtained in a time-series manner by the absolute depth of water from the water surface by a continuous observation device for changes in water environment according to the present invention.
FIG. 7 is a graph showing water temperature data acquired at an absolute depth of water, which is the depth from the surface of water, at three observation points having different lower surface water depths by a continuous observation device for changing the water environment according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood that the appended drawings and foregoing description are intended for purposes of illustration only and are not intended to limit the scope of the present invention. .

2 is a view showing another embodiment of a continuous water environment change monitoring apparatus according to the present invention, wherein FIG. 3 FIG. 4 is a view illustrating a method of determining a position where a measurement sensor is fixedly installed on a chain according to an embodiment of the present invention, and FIG. FIG. 5 is a graph showing the absolute depth at which the measurement sensor is located in the present invention, even if there is a variation in the water level, and FIG. 6 is a graph showing the water depth from the water surface FIG. 7 is a graph showing the water temperature data obtained in a time-dependent manner by the absolute water depth, and FIG. 7 is a graph showing the water depth data obtained by the water depth- Fig. 3 is a graph showing water temperature data acquired at an absolute depth of water from a water surface at three different observation points. Fig.

As shown in FIGS. 1 and 3, the main components of the embodiment of the present invention include a buoy 10, a chain 20, a connecting rope 30, an anchor 40 and a measurement sensor 50.

The buoy (10) is a subject floating on the water surface regardless of the change of the water level, and basically functions as a position display of the observation device of the present invention, and also the chain (20) and the connecting rope .

A through hole 11 is formed in the lower portion of the buoy 10 so as not to affect the function of the buoy 10. The chain 20 and the connecting rope 30 And the shackle-shaped first ring 60 is coupled to the through hole 11. The chain 20 and the connecting rope 30 are connected to the first ring 60 by bundling them.

The chain 20 has a structure in which the measurement sensor 50 is fixedly installed. Since the movement of the chain 20 is minimized by the flow of water in the water and a sufficient tensile force acts in the direction of the water depth by its own weight, The upper end of the chain 20 is directly or indirectly connected to the buoy 10 and the lower end of the chain 20 is indirectly connected to the anchor 40 and connected to the lower end of the connecting rope 30.

In the chain 20, a plurality of measurement sensors 50 are fixedly installed at equal intervals or at different intervals. Before dropping the observation device of the present invention into the water at a position to measure a river or a lake, And a plurality of measurement sensors 50 are fixedly installed at intervals in consideration of the observation depth determined in the longitudinal direction of the chain 20 in consideration of the locking height of the buoy 10.

4, when the first observation depth from the water surface is A and the lock height of the buoy 10 is B, the position where the first measurement sensor 50 is fixed to the chain 20 is a chain (= AB) at the upper end of the base 20. The first and subsequent measurement sensors 50 are fixed on the ground at intervals in the longitudinal direction of the chain 20 in consideration of a plurality of observation depths determined from the position of the first measurement sensor 50.

In addition, since the depth of the lower surface varies, the length of the chain 20 should be sufficiently longer than the depth of the lower surface from the water surface at the position where the observation device is dropped.

The connecting rope 30 is connected to the connecting rope 30 in order to prevent the loss of the chain 20 in which the measuring sensor 50 is fixed and to place the measuring sensor 50 together with the anchor 40 at a constant point in the stream or in the lake The upper end of the rope 30 is directly or indirectly connected to the buoy 10 and the lower end of the connecting rope 30 is indirectly connected to the anchor 40 and connected to the lower end of the chain 20, When the chain 20 is lifted out of the water to obtain the measurement data stored in the chain 20, the connecting rope 30 connected to the chain 20 must be sufficiently longer than the lower surface water depth from the water surface, This is possible.

The anchor 40 is fixed to the lower surface so that the observation apparatus of the present invention can not move in water, and it is preferable that the anchor 40 has a wide ground surface area.

The anchor 40 has one or more second rings 61 in the present invention and the connecting ropes 30 penetrate the second rings 61 and are connected to the lower ends of the connecting ropes 30, The lower end of the chain 20 is connected so that the chain 20 and the connecting rope 30 can be erected between the buoy 10 and the anchor 40.

A hooking hole 70 which can not penetrate the second hook 61 is coupled to the connection point between the chain 20 and the connecting rope 30 so that the hooking hole 30 So that the chain 20 can not penetrate through the second loop 61 due to the engagement of the second chain 60 with the second chain 61. The connecting rope 30 must be able to penetrate through the second loop 61 so that the hook 20 can be pulled out of the second loop 61, Only one chain is provided on the chain 20 side. The hook 70 may be sufficiently large that it can not pass through the second hook 61, and may have various shapes, such as an annular shape or a spherical shape.

The measurement sensor 50 is for sensing a change in the water environment depending on the depth of water in a river or a lake. The water temperature, water quality (turbidity, dissolved oxygen (DO), pH, Electric conductivity, chlorophyll- a (Chl- a ), etc.), a plurality of sensors suitable for various measurement items are fixedly installed on the chain 20 for each water depth.

In the present invention, the plurality of measurement sensors 50 automatically measure the water temperature or the water quality at a predetermined time interval, and store the data. If necessary, the chain 20 having the measurement sensor 50 fixed thereto And fetches the stored data. Meanwhile, in the present invention, in order to minimize the production cost of the observation apparatus, a data transmission unit for transmitting the stored data through a wireless communication network, a control unit for controlling the data transmission unit and the measurement sensor, or a GPS reception unit for generating current location information is omitted do.

2, in another embodiment of the present invention, a metal rod 12 is inserted and fixed in a lower through-hole 11 of the buoy 10, and the metal rod 12 is connected to the chain 20 The first and second shafts 60 and 60 are connected to the metal rods 12 and the chain 20 and the connecting ropes 30 are respectively connected to the first and second shafts 60 and 60, It is possible.

When it is necessary to measure the water temperature or the water quality at the lower surface, another connecting rope 30 'having an elongated annular shape, which is sufficiently longer than the lower surface water depth from the water surface, Or through the first ring 60 of the shackle shape coupled to the through hole 11 and the other side through the second ring 61 'of the anchor 40. Alternatively, a metal rod 12 may be inserted into and fixed to the lower through-hole 11 of the buoy 10 and the other connecting rope 30 'may be connected to the metal rod 12, The first loop 60 may be coupled and one side of the other connecting rope 30 'may be tied to the first loop 60. Here, the other connecting rope 30 'is provided with a measurement sensor 50' for measuring the water temperature or water quality at the lower surface thereof and fixed to the other connection rope 30 'adjacent to the measurement sensor 50' The other connecting rope 30 'is hooked so that the hook 70' is caught by the second hook 61 'in a state in which the hook 70' which can not penetrate the hook 61 ' The measurement sensor 50 'is positioned on the lower surface and can measure water temperature or water quality in the lower surface.

The chain 20 is tensioned in the depth direction by its own weight and can stand upright between the buoy 10 and the anchor 40. The depth of the chain 20 from the water surface is shallow, The weights 80 can be fixedly attached to the chain 20 between the measurement sensors 50 in case the chain 20 is not upright and loosens sideways due to a raised and unpredicted rapid flow rate have. However, if the chain 20 is not upright and loosens to the side due to the occurrence of a rapid flow velocity due to flood, etc., the water temperature and the water quality will become almost uniform in the water of the river or lake, It does not matter.

Hereinafter, the operation and effect of the continuous water environment change monitoring device according to the present invention will be described in detail.

A plurality of the - (such as a (Chl- a) the water temperature, turbidity, dissolved oxygen (DO), pH, electric conductivity, chlorophyll) for which the inventors depth by environmental changes can continuously observing apparatus consisting of the above-described configuration is to be measured A plurality of measurement sensors 50 are fixedly installed at predetermined intervals in a chain 20 and dropped into water such as a river or a lake to obtain related data for each water depth from a water surface to be measured.

The present invention is different from the above-described prior art in that the connecting rope 30 is connected to the chain 20 and the connecting rope 30 can pass through the second loop 61, It is not necessary to hoist the entire observation apparatus including the anchor 40 to pull up the data to acquire data, and only the chain 20 to which the measurement sensor 50 is fixed is pulled up and pulled up. That is, the above-described prior arts (Patent Literature) have an inconvenience that the entire measuring apparatus must be lifted in order to acquire data of the state measuring section including the sensor.

In addition, unlike the prior art (Patent Literature 1), the present invention is not limited to the above-described prior arts (Patent Literature), and the water depth at which the plurality of measurement sensors 50 fixed to the chain 20 are located, Since it is an absolute water depth which is a planned water depth at the time of installation, there is no need for a separate water level meter for sensing the water depth at which the measurement sensor 50 is located and a plurality of measurement sensors 50 are continuously provided for the same water depth from the water surface Data collection is possible for each depth of water (see Fig. 5). That is, in the above-mentioned prior arts (patent document), since the volume of the buoyancy member included in the measuring apparatus during the movement of the measuring apparatus changes according to the supply of air and the measuring apparatus is raised and lowered uniformly, It is impossible. For reference, the observation device of the present invention is manufactured with a spare portion in the length of the chain 20 in order to cope with water level fluctuation of the water surface and fluctuation of the water depth of the lower surface because data can be collected for the same depth from the water surface. This is because a part of the chain 20 may be hanged on the lower surface.

FIG. 6 and FIG. 7 are graphs showing the water temperature data obtained by time series according to the absolute water depths, which are the water depths from the water surface, using the contour, This is a graph showing water temperature data acquired by absolute depths, which are depths from the surface of water at three different observation points. It is suitable for analyzing long-term variations with respect to water temperature because water temperature data processing is possible for absolute depths. The measurement depth is not constant and thus the analysis of the long-term variation of the data is limited.

In addition, since the movement of the buoy 10 is insignificant by the anchor 40, there is no possibility of fluctuation of the observation point when the measurement sensor 50 is lifted into water after lifting, and it is necessary to lift the entire observation apparatus There is not much manpower needed.

The reason why the hook 20 is hooked on the second hook 61 and the chain 20 can not pass through the second hook 61 is that the entire length of the chain 20 The chain 20 is fixed to the chain 20 through the second loop 61 for various reasons such as a rapid flow rate in water or unintentional pulling of the connecting rope 30, This is to prevent the measurement sensor 50 from colliding with the second loop 61 or being stuck in the second loop 61 and failing.

10: Buoy 11: Through-hole
12: metal rod 20: chain
30, 30 ': connecting rope 40: anchor
50, 50 ': measuring sensor 60: first ring
61, 61 ': second ring 70, 70': hook
80: Weights

Claims (8)

A buoy (10) which is always floated on the water surface regardless of the change of the water level and in which a through hole (11) is formed at the bottom;
A chain 20 connecting the upper end of the through hole 11 to the through hole 11 and coupling the upper end of the first annular ring 60 to the upper end of the first annular ring 60;
The upper end of the shank-like first ring 60 is connected to the through hole 11 or the upper end of the shank-like first ring 60 is coupled to the through hole 11, A connecting rope 30 connecting the lower end to the lower end;
And an anchor 40 for positioning the chain 20 and the connecting rope 30 at a predetermined position with a weight having at least one second loop 61 through which the connecting rope 30 passes, )Wow;
And a stopper 70 (not shown) which is coupled to the connecting point of the chain 20 and the connecting rope 30 and prevents the chain 20 from penetrating through the second loop 61 due to the hooking of the second hook 61 ), And
In order to grasp the water environment change in the water depth in the chain 20 equally spaced or at different intervals, the water depth data for continuous water depth continuously varying with respect to the water surface even if the water level changes, And a plurality of measurement sensors (50) for acquiring the water depth.
The method according to claim 1,
Wherein the chain (20) is made of a material and a shape of a chain so that the movement of the chain in the water is minimized and a sufficient tensile force acts in the water depth direction by its own weight.
The method according to claim 1,
Wherein the fixed installation position of the measurement sensor (50) on the chain (20) is determined in consideration of the observation depth from the determined water surface and the locking height of the buoy (10).
The method according to claim 1,
The depth of the lower surface changes and the lifting of the chain 20 is required to obtain the measurement data stored in the measurement sensor 50. Therefore, the length of the chain 20 and the connecting rope 30 is set to be lower Wherein the water depth is greater than the water depth.
The method according to claim 1,
Wherein the water depth data is data on at least one of water temperature, turbidity, DO, pH, electric conductivity, and chlorophyll- a (Chl- a ).
The method according to claim 1,
The metal rods 12 are inserted and fixed in the through holes 11 and the chain 20 and the connecting ropes 30 are connected to the metal rods 12 respectively or the metal rods 12 are connected to the shackle- 60) are connected to each other and the chain (20) and the connecting rope (30) are connected to the first ring (60).
The method according to claim 1,
One side of the water jacket is passed through a first shark-like ring (60) coupled to the through hole (11) or the through hole (11) of the buoy (10) and the other side is connected to the anchor Another connecting rope 30 'passing through the second loop 61' of the second connecting member 40;
A measurement sensor 50 'fixed to the other connection rope 30' and measuring the water temperature or water quality at the lower surface;
Is coupled to the other connecting rope 30 'in the vicinity of the measuring sensor 50' and when the other connecting rope 30 'is pulled, a hooking hole 70' for catching the second hook 61 'is added Wherein said at least one of said at least two of said at least one of said at least two of said at least one of said at least one of said at least two observers.
The method according to claim 1,
Wherein a weight (80) is fixedly installed on a chain (20) between the plurality of measurement sensors (50).

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