JP7251209B2 - Water quality meter landing confirmation device - Google Patents

Description

The present invention relates to a water quality meter contact confirmation device. In particular, the present invention relates to the structure of a water quality meter landing confirmation device that can easily confirm that a sensor unit constituting a water quality meter has landed on the water in order to measure the water quality of a river or the like from the ground.

A water quality meter can measure the physical, chemical and biological water quality of rivers and the like. For example, by immersing a sensor part constituting a water quality meter in water from the ground, the water quality of a river or the like can be investigated on site. When continuously measuring the water quality of rivers, etc. from the ground (so-called fixed-point observation), the sensor is immersed in water for a long period of time. I have something to do. Moreover, since the sensitivity of the sensor unit changes over time, it has been necessary to periodically calibrate it using a standard solution.

If the sensor section of the water quality meter is immersed in water for a long period of time, the problems described above will occur. A water quality measuring device for cleaning or calibrating a sensor unit by supplying a cleaning liquid or a standard liquid for calibration to the water quality measuring device is disclosed (see, for example, Patent Document 1).

However, when measuring the water quality of lakes and marshes, the water quality is measured at a deep point from the surface of the water. In this case, if the cylindrical holder is lifted up as disclosed in Japanese Patent Laid-Open Publication No. 2002-200011, a large-scale drive cylinder is required for lifting. In addition, there is a problem that the missing measurement time becomes long because the time required for pulling up is long.

Since the water quality measuring device according to Patent Document 1 has the problems described above, a water quality measuring device is disclosed that can shorten the missing measurement time even when measuring a deep point (see, for example, Patent Document 2).

JP-A-9-269311 JP 2007-178394 A

FIG. 5 is a side view showing the configuration of a water quality measuring device according to the prior art, and is a diagram showing a state in which a sensor module is arranged at the lower end of a cylindrical holder. FIG. 6 is a side view showing the configuration of the water quality measuring device according to the prior art, and is a state view showing the sensor module pulled up from the cylindrical holder. FIG. 7 is a side view showing the configuration of the water quality measuring device according to the prior art, and shows a state in which the sensor module lifted from the cylindrical holder is turned to the ground side.

FIG. 8 is a longitudinal sectional view showing the configuration of a conventional water quality measuring device, and is an enlarged view of a sensor module and a cylindrical holder provided in the water quality measuring device. 5 to 8 of the present application correspond to FIGS. 1 to 4 of Patent Document 2. FIG.

5 to 8 , the prior art water quality measuring device 9 comprises a sensor module 91 and a measuring section 92 . The water quality measuring device 9 also includes a support base 93 and an operation/control section 94 .

5 or 8, the sensor module 91 is electrically connected to one end of a cable 91c. 5 or 6, the other end of the cable 91c is electrically connected to the operation/control section 94. As shown in FIG. The measuring part 92 is installed at the lower end of a cylindrical holder 92h (see FIGS. 5 to 8).

5 to 7, the support base 93 is installed on the bank protection Wr that protects the river or lake. The support base 93 includes a stand 93a, a first support member 93b, and a pair of second support members 93c, 93c.

5 to 7, the stand 93a is fixed to the bank protection Wr in an upright state. The first support member 93b is cantilevered on the top of the stand 93a. The base end of the first support member 93b is connected to the stand 93a so as to be freely rotatable in the horizontal direction. A pair of second support members 93c, 93c are fixed in a cantilevered manner to the lower portion of the stand 93a. A pair of second support members 93c, 93c support the upper side of the holder 92h so that the holder 92h extends below the water surface of the river or lake.

5 to 7, the support base 93 includes a fixed pulley 931, a movable pulley 932, and a hoisting device 933. As shown in FIG. The fixed pulley 931 is attached to the tip of the first support member 93b. A cable 91 c is wound around the fixed pulley 931 . The cable 91 c is anchored to the operation/control section 94 via a movable pulley 932 .

5 or 6, a fixed pulley 931 is wound with a wire 93w. The wire 93w is connected to the winding device 933. When the hoisting device 933 is driven in one direction, the fixed pulley 931 can be rotated in one direction, and the sensor module 91 can be lifted from the holder 92h (see FIG. 6). When the hoisting device 933 is driven in the other direction, the fixed pulley 931 can be rotated in the other direction, and the sensor module 91 can be moved under the holder 92h by its own weight (see FIG. 5). The operation of the hoisting device 933 is controlled by commands from the operation/control section 94 .

5 or 6, the operation/control section 94 is electrically connected to the sensor module 91 via a cable 91c. The operation/control unit 94 can instruct the sensor module 91 to start measurement and receive data such as measurement results from the sensor module 91 via the cable 91c.

5 or 6, by controlling the winding device 933, the sensor module 91 can be moved into and out of the holder 92h from the upper end 921 of the holder 92h. Further, by controlling the hoisting device 933, the sensor module 91 can move up and down in the central portion of the holder 92h. Furthermore, by controlling the hoisting device 933, the sensor module 91 can be held in a submerged state in the water W at an arbitrary position.

Referring to FIG. 7, when the first support member 93b is turned around the stand 93a, the sensor module 91 can be moved from the river/lake to the bank protection Wr. Thereby, the sensor module 91 can be easily maintained on the ground side. In addition, in order to prevent the cable 91c from being damaged as the first support member 93b turns, a cable holder 93m is provided on one of the second support members 93c.

Referring to FIG. 8, the sensor module 91 includes a cylindrical main body 911 and a bridging member 912 . The sensor module 91 also includes a columnar partition member 913 and a sensor section 914 . The body portion 911 has a cable 91c connected to its upper surface. The bridging member 912 bridges the body portion 911 and the partition member 923 . The partition member 913 has an outer diameter substantially the same as the outer diameter of the main body portion 911 and is arranged to face the sensor portion 914 . The sensor section 914 protrudes toward the partition member 913 .

5 or 8, when the sensor module 91 is immersed in the water W via the holder 92h, the sensor section 914 can measure the water quality of rivers, lakes, or the like.

Referring to FIG. 8, the sensor module 91 is called a multi-item water quality meter, and the sensor section 914 includes a temperature sensor, pH electrode, electrical conductivity cell, turbidity cell, DO electrode and the like. In the sensor section 914, these sensors are integrated with the main body section. A temperature sensor can measure the water temperature. A pH electrode can measure the pH of sample water. A conductivity cell can measure the electrical conductivity of sample water. A turbidity cell can measure the turbidity of sample water. The DO electrode can measure dissolved oxygen in sample water.

Referring to FIG. 8, it is formed in the lower part of the holder 92h and divided into a protective cylinder part 92p and a calibrating cylinder part 92t2. The protective cylinder portion 92p can protect the sensor portion 914 by covering the periphery of the sensor portion 914 . A calibration liquid can be introduced into the calibration cylinder portion 92t.

Referring to FIG. 8, the calibration tube portion 92t includes an inwardly extendable annular first tube 92a and an inwardly extendable annular second tube 92b. The first tube 92a is arranged above the calibration tube portion 92t. The second tube 92b is arranged below the calibration tube portion 92t. Further, a plurality of level sensors 92s are attached to the calibration tube portion 92t. The plurality of level sensors 92s can detect whether the inside of the calibration tube portion 92t is in a liquid phase state or a vapor phase state.

Referring to FIG. 8, the sensor module 91 is pulled up so that the lower portion of the main body portion 911 faces the first tube 92a and the partition member 913 faces the second tube 92b. When air is supplied to the second tube 92b, the first tube 92a and the second tube 92b are expanded, so that the sensor section 914 can be sealed inside the calibration cylinder section 92t.

Referring to FIG. 8, first, in a state in which the first tube 92a is inflated and the second tube 92b is contracted, air is supplied from the lower portion of the calibration cylinder portion 92t, and the inside of the calibration cylinder portion 92t is filled with air. It can be phased. Next, by inflating the second tube 92b, the inside of the calibration tube portion 92t can be used as a calibration chamber isolated from the water to be measured. Further, the water quality measuring device 9 can remove stains on the detection surface of the sensor section 914 in water by injecting cleaning liquid toward the detection surface of the sensor section 914 .

In this way, the water quality measuring device 9 according to Patent Document 2 is described as being able to form a calibration space with an easy and simple configuration, and to shorten the missing measurement time even when measuring a deep spot.

By the way, in addition to fixed-point observation, we use a multi-item water quality meter with a cable to conduct on-site surveys of the water quality of rivers, etc. by immersing the multi-item water quality meter in water from the ground toward rivers. In this case, in the observation at the water depth "0 (zero)" point, it is visually confirmed that the detection surface of the sensor unit has landed on the water surface.

However, when a multi-item water quality meter is suspended from a bridge toward the water surface of a river, the distance from the bridge to the water surface of the river is long, and it is not possible to visually confirm that the detection surface of the sensor has landed on the water surface. The problem was that it was difficult. In addition, if the cable is suspended from the railing installed on the bridge, the multi-item water quality meter is quite heavy when the cable is sent out or pulled up, so there is a risk that the cable will interfere with the railing and damage the cable. was there.

There is a demand for a water quality meter landing confirmation device that can easily confirm that the detection surface of a sensor unit that measures the water quality of a river or the like has landed on the water surface. In addition, there is a demand for a water quality meter immersion confirmation device that does not cause an excessive load on cables and does not interfere with fence-like members such as balustrades. And the above may say the subject of this invention.

SUMMARY OF THE INVENTION The present invention has been made in view of such problems. It is an object of the present invention to provide a verification device.

The present inventors suspended a water quality meter connected to a long cable from the ground toward a distant water surface, and used a periscope (periscope) to easily confirm from the ground that the water quality meter had landed on the water. I thought that it was possible, and based on this, I came to invent a new water quality meter landing confirmation device as follows.

(1) A water quality meter landing confirmation device according to the present invention suspends a water quality meter connected to a long cable from the ground toward a distant water surface, and confirms that the water quality meter has landed on the water. A device for confirming landing in water, comprising an eyepiece tube having an eyepiece window at one end, and an objective lens tube bent with the eyepiece tube and having an objective window at the other end, the objective window A periscope that can reflect the light path from the above multiple times to check the water quality meter through the eyepiece window, and a periscope that allows the other end of the objective tube to be placed facing the water surface, and the eyepiece tube to be placed in a substantially horizontal state on the ground. and a winding device for winding the cable along the outer surface of the objective lens barrel so that the water quality meter can move up and down. It consists of a plurality of telescopic cylinders with different outer diameters.

(2) It is preferable that the objective lens barrel further includes a cylindrical bellows member that surrounds the outer periphery of the plurality of telescopic barrels and applies force in the direction in which the plurality of telescopic barrels extends.

(3) In the water quality meter landing confirmation device according to the present invention, one end of a wire is anchored to the other end of the objective lens barrel, the other end of the wire is wound, and the plurality of telescopic cylinders are contracted. Preferably, it further comprises a hoisting device that allows the

(4) It is preferable that the periscope connects the eyepiece tube to the objective tube so that the eyepiece tube can be folded.

(5) It is preferable that the support device has a fastening device that can be detachably fastened to a fence-like object installed on the ground.

Since the water quality meter landing confirmation device according to the present invention has a periscope composed of an eyepiece tube and an objective tube bent from the eyepiece tube, it can be easily confirmed that the water quality meter has landed on the water through the eyepiece window.

1 is a perspective view showing the configuration of a water quality meter landing confirmation device according to an embodiment of the present invention; FIG. It is a front view which shows the structure of the water quality meter landing confirmation apparatus by the said embodiment. It is a diagram showing the configuration of the water quality meter landing confirmation device according to the embodiment, FIG. 3 (A) is a longitudinal sectional view of the water quality meter water landing confirmation device, FIG. It is a top view. 4A is a front view of the support device, FIG. 4B is a right side view of the support device, and FIG. 4(C) is a left side view of the supporting device. FIG. 4 is a side view showing the configuration of a water quality measuring device according to the prior art, and is a state diagram showing a state in which a sensor module is arranged at the lower end of a cylindrical holder. It is a side view showing the configuration of the water quality measuring device according to the prior art, and is a state diagram showing the sensor module pulled up from the cylindrical holder. FIG. 10 is a side view showing the configuration of the water quality measuring device according to the prior art, and is a state diagram in which the sensor module pulled up from the cylindrical holder is turned to the ground side. It is a vertical cross-sectional view showing the configuration of a conventional water quality measuring device, and is an enlarged view of a sensor module and a cylindrical holder provided in the water quality measuring device.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

[Configuration of Water Quality Meter Landing Confirmation Device]
(overall structure)
First, the overall configuration of a water quality meter landing confirmation device according to an embodiment of the present invention will be described. 1 to 3, a water quality meter landing confirmation device (hereinafter abbreviated as a confirmation device) 10 according to one embodiment of the present invention extends a long cable Cb from the ground toward a distant water surface Wf. By hanging down the connected water quality meter Mw, it can be confirmed that the water quality meter Mw has landed on the water.

With reference to FIGS. 1 to 4 , the verification device 10 comprises a periscope 1 , a support device 2 and a winding device 3 . The periscope 1 has an eyepiece tube 11 and an objective tube 12 . The periscope 1 has an objective tube 12 bent with respect to an eyepiece tube 11 .

1 to 3, the eyepiece tube 11 has an eyepiece window 11w at one end. The objective lens barrel 12 has an objective window 12w at the other end. Referring to FIG. 3, the periscope 1 has a first reflecting mirror M1 and a second reflecting mirror M2 arranged therein. The periscope 1 reflects twice the optical path Lp from the objective window 12w by 90 degrees, and the image of the objective window 12w can be confirmed from the eyepiece window 11w. That is, the periscope 1 can confirm the water quality meter Mw from the eyepiece window 11w.

1 to 4, the support device 2 can support the eyepiece tube 11 in a substantially horizontal state on the ground so that the other end of the objective tube 12 can be arranged facing the water surface Wf. In the embodiment, the support device 2 sandwiches a fence-like object F such as a railing installed at the end of the bridge Bg, and supports the eyepiece tube 11 in a detachable manner.

1 to 3, the winding device 3 can wind the cable Cb along the outer surface of the objective lens barrel 12 so that the water quality meter Mw can move up and down. Referring to FIG. 3, the objective lens barrel 12 is composed of a plurality of telescopic barrels 121, 122, 123 with different outer diameters that are extendable toward the water surface Wf.

Referring to FIGS. 1 to 4, the confirmation device 10 according to the embodiment includes a periscope 1 that can confirm the water quality meter Mw through an eyepiece window 11w, an objective tube 12 that can be arranged so that the other end faces the water surface Wf, and an eyepiece. A support device 2 for supporting the cylinder 11 in a substantially horizontal state on the ground, and a winding device 3 for winding a cable Cb along the outer surface of the objective lens barrel 12 so that the water quality meter Mw can move up and down. Since the cylinder 12 is composed of a plurality of telescopic cylinders 121, 122, 123 with different outer diameters, which can be stretched toward the water surface Wf, it is possible to easily confirm that the water quality meter Mw has landed on the water through the eyepiece window 11w. .

(Configuration of water quality meter)
Next, the configuration of the water quality meter Mw according to the embodiment will be described. 1 to 3, the water quality meter Mw substantially corresponds to the sensor module 91 shown in FIG. The water quality meter Mw is preferably a multi-item water quality meter, and by immersing the water quality meter Mw in the water surface Wf, it is possible to measure the water quality of rivers, lakes, etc. over multiple items.

Referring to FIGS. 1 to 3, cable Cb electrically connects a measuring instrument (not shown) at its distal end. A measuring device (not shown) can instruct the water quality meter Mw to start measurement via the cable Cb, and can receive data such as measurement results from the water quality meter Mw.

(periscope configuration)
Next, the configuration of the periscope 1 according to the embodiment will be described. 1-3, the objective tube 12 includes a pair of cylindrical bellows members 12b, 12b. A pair of bellows members 12b, 12b surrounds the outer circumferences of a plurality of telescopic cylinders 121, 122, 123. As shown in FIG.

1 to 3, the objective barrel 12 further includes a first barrel frame 12s, a second barrel frame 12t, and a barrel frame 12m. The first cylinder frame 12 s is fixed to the tip side of the telescopic cylinder 121 . The second cylinder frame 12 t is fixed to the tip side of the telescopic cylinder 122 . The lens barrel frame 12m is fixed to the tip of the telescopic barrel 123. As shown in FIG.

Referring to FIG. 3, one bellows member 12b is interposed between the first cylinder frame 12s and the second cylinder frame 12t. One bellows member 12b applies force to the telescopic cylinder 121 in the direction in which the telescopic cylinder 121 extends in the axial direction. The other bellows member 12b is interposed between the second barrel frame 12t and the lens barrel frame 12m. The other bellows member 12b applies force to the telescopic cylinder 122 in the direction in which the telescopic cylinder 123 extends in the axial direction.

Thus, referring to FIG. 3, the pair of bellows members 12b, 12b exert a force in the direction in which the telescopic tubes 121, 122, 123 extend. It is preferable that the thick portion of the bellows member 12b include a compression coil spring (not shown).

Referring to FIG. 3, the barrel frame 12m has a second reflecting mirror M2 inside. It is preferable to waterproof the objective window 12w with a transparent glass plate so that the second reflecting mirror M2 is not flooded. Moreover, it is preferable to waterproof the gap between the telescopic barrel 123 and the barrel frame 12m so that the second reflecting mirror M2 is not flooded.

1 to 3, the periscope 1 comprises a hinge portion 1h and a locking portion 1r. The hinge portion 1h rotatably connects the eyepiece tube 11 to the objective tube 12. As shown in FIG. The locking portion 1 r can maintain the state in which the eyepiece tube 11 is perpendicular to the objective tube 12 .

1 to 3, eyepiece tube 11 has a double clevis-shaped first support 11h at the other end. The objective barrel 12 has a single clevis-shaped second support portion 12h at one end. By inserting a connecting pin into the through hole penetrating through the first support portion 11h and the second support portion 12h, the hinge portion 1h rotatably connects the eyepiece tube 11 to the objective lens barrel 12. there is

1 to 3, the eyepiece tube 11 has a double clevis-shaped third support 11r at the other end. The objective barrel 12 has a single clevis-shaped fourth support portion 12r at one end. By inserting the connecting pin into the through hole penetrating through the third support portion 11r and the fourth support portion 12r, the locking portion 1r can maintain the state in which the eyepiece tube 11 is orthogonal to the objective lens barrel 12.

Referring to FIG. 3, when the connecting pin is removed from the locking portion 1r, the eyepiece tube 11 can be rotated clockwise with respect to the objective tube 12. As shown in FIG. By rotating the eyepiece tube 11 clockwise by 270 degrees with respect to the objective tube 12 , the eyepiece tube 11 can be folded with respect to the objective tube 12 . As a result, the periscope 1 can be transported in a reduced outer shape.

In addition, referring to FIG. 3, when the eyepiece tube 11 is folded relative to the objective lens barrel 12, the first reflecting mirror M1 is arranged so as not to protrude from the opening surface of the objective lens barrel 12. M1 is rotatably arranged inside the objective lens barrel 12 .

(Configuration of winding device)
Next, the configuration of the winding device 3 according to the embodiment will be described. 1 to 3, the winding device 3 includes one or more guide members 3g, a fixed pulley 3p and a winding drum 3d. The guide member 3g employs a pantograph structure in which both ends of four link members are rotatably connected to each other. When the four link members are opened, the water quality meter Mw can be inserted through the guide member 3g.

1 to 3, the confirmation device 10 has three guide members 3g arranged along the axial direction of the objective barrel 12. As shown in FIG. As a result, the water quality meter Mw can be moved along the axial direction of the objective barrel 12 without separating the water quality meter Mw from the objective barrel 12 .

1 to 3, the fixed pulley 3p is arranged directly below the eyepiece tube 11. As shown in FIG. Further, the fixed pulley 3p is cantilever-supported on the outer circumference of the eyepiece tube 11 at its rotating shaft. The fixed pulley 3p changes the direction of the cable Cb let out from the winding drum 3d toward the inside of the three guide members 3g.

1 to 3, the winding drum 3d is arranged directly below the eyepiece tube 11. As shown in FIG. The winding drum 3d winds the cable Cb. A grip 3Gp is rotatably attached to the winding drum 3d. The winding drum 3d can be manually rotated by gripping the grip 3Gp.

1 to 3, when the winding drum 3d is rotated in one direction, the water quality meter Mw can be suspended via the fixed pulley 3p. When the winding drum 3d is rotated in the other direction, the water quality meter Mw can be pulled up via the fixed pulley 3p. Thus, the winding device 3 can move the water quality meter Mw vertically by operating the winding drum 3d.

(Configuration of hoisting device)
Next, the configuration of the hoisting device 4 provided in the confirmation device 10 according to the embodiment will be described. Referring to FIG. 1 or FIG. 2 and FIG. 3B, the winding device 4 includes a plurality of eyebolts 4b each having a ring-shaped head, a wire member 4w, and a winding drum 4d.

Referring to FIG. 1 or 2 and FIG. 3B, a plurality of eyebolts 4b are fixed to the outer periphery of the objective lens barrel 12. As shown in FIG. These eyebolts 4 b are arranged in a row along the axial direction of the objective barrel 12 . Some of the eyebolts 4b are fixed to the outer periphery of the eyepiece tube 11. As shown in FIG.

1 or 2 and 3B, one end of the wire member 4w is anchored to an eyebolt 4b fixed to the lens barrel frame 12m. The other end of the wire member 4w is wound around the winding drum 4d. An intermediate portion of the wire member 4w is inserted through the heads of the plurality of eyebolts 4b.

Referring to FIG. 1 or 2 and FIG. 3B, the winding drum 4 d is arranged on the outer periphery of the eyepiece tube 11 . The winding drum 4 d has its rotating shaft cantilevered on the outer circumference of the eyepiece tube 11 . A grip 4Gp is rotatably attached to the winding drum 4d. By gripping the grip 4Gp, the winding drum 4d can be manually rotated.

1 to 3, when the take-up drum 4d is rotated in one direction, the plurality of telescopic cylinders 121, 122, 123 can be contracted against the biasing force of the pair of bellows members 12b, 12b.

Referring to FIG. 1 or 2 and FIG. 3(B), the winding drum 4d has a ratchet mechanism 4r formed of a ratchet gear and a ratchet pawl at its base end. When the winding drum 4d is rotated in one direction, the ratchet pawl engages with the ratchet gear to prevent the winding drum 4d from rotating in the other direction. Releasing the ratchet pawl from the ratchet gear allows the winding drum 4d to rotate in the other direction.

1 to 3, the hoisting device 4 can adjust the amount of expansion and contraction of the plurality of telescopic cylinders 121, 122, 123 by operating the hoisting drum 4d.

(Configuration of support device)
Next, the configuration of the support device 2 according to the embodiment will be described. Referring to FIG. 4, the support device 2 includes a mounting base 21 and a tube receiver main body 22. As shown in FIG. The mount 21 can be detachably fixed to a fence-like object F such as a railing installed on a bridge Bg (see FIGS. 1 to 3). The tube support main body 22 is erected from the upper surface of the mounting base 21 and can detachably fix the eyepiece tube 11 .

Referring to FIG. 4, the mounting base 21 includes a rectangular mounting plate 211, a fixed clamping plate 212, and a pair of rectangular rod-shaped movable clamping members 213,213. The tube receiving main body 22 is composed of a pole member 22p and an arc member 22s. A base end portion of the pole member 22p is fixed to the central portion of the mounting plate 211 . A circular arc member 22s is fixed to the tip of the pole member 22p.

Referring to FIG. 4, the eyepiece tube 11 can be introduced into the circular arc member 22s from the outer peripheral direction. With the arc member 22s in contact with the outer circumference of the eyepiece tube 11, the eyepiece tube 11 can be fixed to the arc member 22s using a screw member (not shown).

Referring to FIG. 4, the fixed-side clamping plate 212 is fixed to one end of the mounting plate 211 in a hanging state. The fixed-side clamping plate 212 has a pair of bent pieces with both ends bent. A cylindrical stay 21s bridges these bent pieces. The stay 21s is rotatably connected to a pair of meshing plates 21g, 21g having tooth surfaces on one side thereof. The pair of engagement plates 21g, 21g can abut on one side of the fence-like object F. As shown in FIG.

Referring to FIG. 4, the support device 2 further comprises a pair of guide rods 214,214. One end of the guide rod 214 is fixed to the lower surface of the mounting plate 211 by welding or the like. The other end of the guide rod 214 protrudes from the other end of the mounting plate 211 . A portion of the guide rod 214 protruding from the other end of the mounting plate 211 is formed with a spiral groove.

Referring to FIG. 4, the movable-side holding member 213 has a guide hole at its upper portion through which the guide rod 214 can be inserted. The movable-side holding member 213 can move while being guided by the guide rod 214 . Further, the movable-side holding member 213 has an L-shaped stopper plate 215 fixed to its upper surface. The stopper plate 215 has an elongated hole at the other end that engages with the spiral groove of the guide rod 214 .

Referring to FIG. 4, a compression coil spring s1 is arranged between the other end of the stopper plate 215 and the movable-side holding member 213. As shown in FIG. When the other end of the stopper plate 215 is brought closer to the movable-side holding member 213 against the biasing force of the compression coil spring s1, the engagement between the spiral groove of the guide rod 214 and the stopper plate 215 can be released, and the movable-side holding member 213 can be disengaged. can move along the guide rod 214 . When the stopper plate 215 is released, the meshing state between the spiral groove of the guide rod 214 and the stopper plate 215 can be restored.

Referring to FIG. 4, the movable clamping member 213 has a tightening bolt 23 at its bottom. The tightening bolt 23 is screwed with the movable-side holding member 213 at its threaded portion. The tightening bolt 23 has a knob 23a at its base end and a rotating disc 23b at its tip end.

Referring to FIG. 4, when the knob 23a is gripped and the tightening bolt 23 is rotated in one direction, the rotating disk 23b can be moved toward the other side of the fence F. As shown in FIG. As a result, the fence-like object F can be sandwiched between the tightening bolts 23 and the engaging plate 21g. On the other hand, when the knob 23a is gripped and the tightening bolt 23 is rotated in the other direction, the rotary disk 23b can be retracted from the fence F, and the support device 2 can be removed from the fence F.

With reference to FIG. 4, the support device 2 thus comprises a clamping device that can be detachably clamped to a railing F installed on the ground.

[Operation of Water Quality Meter Landing Confirmation Device]
Next, the operation and effects of the confirmation device 10 will be described while explaining the operation method of the confirmation device 10 according to the embodiment.

First, the support device 2 is fixed to the railing F, referring to FIGS. Next, the confirmation device 10 is attached to the support device 2 . In this case, it is preferable to insert the water quality meter Mw through the plurality of guide members 3g. Note that the supporting device 2 may be fixed to the fence-like object F after the supporting device 2 is attached to the confirmation device 10 .

Next, referring to FIGS. 1 to 3, the take-up drum 4d is operated to move the barrel frame 12m toward the water surface Wf. In this case, it is preferable that the objective window 12w is slightly submerged from the water surface Wf (see FIG. 3), and this situation can be confirmed from the eyepiece window 11w.

Next, referring to FIGS. 1 to 3, the winding drum 3d is operated to lower the water quality meter Mw toward the water surface Wf. In this process, it can be confirmed from the eyepiece window 11w that the water quality meter Mw has landed on the water surface Wf. After confirming that the water quality meter Mw has landed on the water surface Wf, the measurement of the water quality at the water depth "0 (zero)" is started.

Referring to FIGS. 1 to 3, the confirmation device 10 according to the embodiment includes a periscope 1 composed of an eyepiece tube 11 and an objective tube 12 arranged orthogonally. You can easily check what you have done.

Referring to FIGS. 1 to 3, the confirmation device 10 according to the embodiment includes a winding device 3 that winds a cable Cb along the outer surface of the objective lens barrel 12 so that the water quality meter Mw can move up and down. , the cable Cb can be protected without interfering with a fence-like object F such as a railing.

Referring to FIGS. 1 to 3, the confirmation device 10 according to the embodiment includes a periscope 1 that foldably connects an eyepiece tube 11 to an objective tube 12, so that it can be easily transported. has the effect of

1 Periscope 2 Support Device 3 Winding Device 10 Confirmation Device (Water Quality Meter Landing Confirmation Device)
11 eyepiece tube 11w eyepiece window 12 objective tube 12w objective window 121, 122, 123 telescopic tube Cb cable Mw water quality meter Wf water surface

Claims (4)

A water quality meter landing confirmation device for confirming that the water quality meter (Mw) has landed on the water by hanging a water quality meter (Mw ) connected to a long cable (Cb) from the ground toward a distant water surface. (10) ,
An eyepiece tube (11) provided with an eyepiece window (11w) at one end, and an objective lens tube (12) bent with the eyepiece tube (11) and provided with an objective window ( 12w) at the other end. a periscope (1) capable of confirming the water quality meter (Mw) through the eyepiece window (11w) by reflecting the optical path from the objective window (12w) multiple times;
a support device (2) for supporting the eyepiece tube (11 ) in a substantially horizontal state on the ground so that the other end of the objective lens tube (12) can be arranged facing the water surface;
A winding device (3) that winds the cable (Cb) along the outer surface of the objective lens barrel (12) so that the water quality meter (Mw) can move up and down,
The objective lens barrel (12) is composed of a plurality of telescopic barrels (121, 122, 123) with different outer diameters, which are extendable toward the water surface,
One end of a wire member (4w) is anchored to the other end of the objective lens barrel (12) , and the other end of the wire member (4w) is wound to form a plurality of telescopic cylinders (121, 122, 122). 123) , further comprising a winding device (4) for retracting the water quality meter water contact confirmation device (10). A water quality meter landing confirmation device for confirming that the water quality meter (Mw) has landed on the water by hanging a water quality meter (Mw ) connected to a long cable (Cb) from the ground toward a distant water surface. (10) ,
An eyepiece tube (11) provided with an eyepiece window (11w) at one end, and an objective lens tube (12) bent with the eyepiece tube (11) and provided with an objective window ( 12w) at the other end. a periscope (1) capable of confirming the water quality meter (Mw) through the eyepiece window (11w) by reflecting the optical path from the objective window (12w) multiple times;
a support device (2) for supporting the eyepiece tube (11 ) in a substantially horizontal state on the ground so that the other end of the objective lens tube (12) can be arranged facing the water surface;
A winding device (3) that winds the cable (Cb) along the outer surface of the objective lens barrel (12) so that the water quality meter (Mw) can move up and down,
The objective lens barrel (12) is composed of a plurality of telescopic barrels (121, 122, 123) with different outer diameters, which are extendable toward the water surface,
The objective lens barrel (1) has a cylindrical shape that surrounds the outer circumference of the plurality of telescopic barrels (121, 122, 123) and applies force in the direction in which the plurality of telescopic barrels (121, 122, 123 ) extend. further comprising bellows members (12b, 12b) of
One end of a wire member (4w) is anchored to the other end of the objective lens barrel (12) , and the other end of the wire member (4w) is wound to form a plurality of telescopic cylinders (121, 122, 122). 123) , further comprising a winding device (4) for retracting the water quality meter water contact confirmation device (10) . 3. The water quality meter landing confirmation device (10) according to claim 1 or 2, wherein the periscope (1) connects the eyepiece tube (11) to the objective tube (12) in a foldable manner. . 3. The water quality meter landing confirmation device (10) according to claim 1 or 2, wherein said support device (2) comprises a tightening device that can be detachably tightened to a fence (F) installed on the ground.

Images