KR200450558Y1 - Sensing device for underwater bottom of the river - Google Patents

Abstract

The present invention relates to an underwater bottom detection device that can prevent the water quality measurement sensor from colliding with the underwater bottom.

That is, the present invention and the bottom plate; It is connected to the center of the bottom plate, the connecting rod is formed in the form of a hollow pipe so that the sensor rod of the float sensor can move up and down; The lower part is coupled to the inside of the upper end of the connecting pipe, and the upper inner side is formed with a coupling space for coupling the float of the float sensor, the outer diameter of the sensor rod so that the sensor rod of the float sensor can move up and down from the center of the coupling space to the bottom center A float support having perforated sliding holes corresponding thereto; The upper part is connected to the bottom of the protective cover that protects the water quality sensor connected to the winch by the rope, and the lower part of the sensor rod is installed to move up and down within the connecting pipe through the sliding hole of the float support, A float sensor comprising a float installed at a lower portion of the upper and lower stoppers and a float mounted on a sensor rod between the upper and lower stoppers and coupled to a coupling space of the float support portion to guide sliding operation of the sensor rod up and down; Characterized in that configured to include.

Underwater, floor, reed switch, bottom plate, float sensor

Description

Sensing device for underwater bottom of the river}

The present invention relates to an underwater bottom detection sensor that detects the bottom of the water, and sends a signal to the winch when it touches the bottom, causing the winch to pull up the water quality sensor, thereby preventing the expensive water quality sensor from hitting the water floor. To an underwater bottom detection device.

Conventional water quality measurement apparatus includes a circular floating means 101 is installed on the water surface as shown in FIG. An outer frame 102 formed upwardly from an upper edge of the floating means 101; It is installed at one end of the upper surface edge of the floating means 101, the winch device 103, the data processing device 104 for processing data obtained by the water quality measurement sensor 111, and the energy obtained from the solar panel 107 Various devices such as a power storage device 105 for storing the solar cell and a solar panel 107 installed by a separate support frame 106 installed at the edge of the floating means 101; An inlet port 113 formed at the center of the floating means 101 to inject the water quality sensor 111 into water; It is installed next to the inlet 113 formed in the floating means 101, the support 108 is provided with a support pulley 109 on the top; One end is connected to the winch device 103 and the other end is connected to the wire rope 110 and the protective cover 112 surrounding the water quality measurement sensor 111 is introduced into the water through the support pulley 109 and ; It is configured to include a limit switch 114 for underwater floor detection installed under the protective cover 112.

In this water quality measurement device, the wire rope is released by the operation of the winch device, and the water quality measurement sensor connected to the wire rope is introduced into the water to measure the water quality. In order to prevent this, a limit switch (LIMIT SWITCH) was installed under the protective cover surrounding the water quality measurement sensor so that the variable lever of the limit switch reached the bottom of the water and sent a signal to the winch device to pull up the wire rope.

However, even if the variable lever sends a signal as soon as possible, it takes time for the winch device to receive a signal from the limit switch. During that time, the winch device continues to rotate forward to release the wire rope. Next, due to the loosening of the wire rope, the limit switch is inclined to the bottom of the water, which causes the water quality sensor to approach the bottom of the water, causing the water quality sensor to hit the bottom of the water.

In addition, due to the characteristics of the limit switch, the variable lever is switched to operate, but when the limit switch is put in water, the variable lever frequently causes malfunctions by water current.

In addition, if foreign matter such as plants or moss sticks to the variable lever, the limit switch malfunctions or does not work at all.If the underwater bottom is mud, the variable lever of the limit switch does not work because it is buried in the mud. There was this.

The present invention was devised to solve the above problems, and the object of the present invention is to send a signal to the winch when it touches the bottom of the water so that the winch pulls up the water quality measurement sensor, the expensive water quality measurement sensor It is an object of the present invention to provide a subfloor sensing device that can be prevented from crashing and breaking.

The present invention has been devised to solve the above technical problem, the bottom plate is put in water and in contact with the bottom of the water; A lower portion connected to the center of the bottom plate, the connecting pipe being formed in the form of a hollow pipe so that the sensor rod of the float sensor can move up and down; The lower part is coupled to the inside of the upper end of the connecting pipe, and the upper inner side is formed with a coupling space for coupling the float of the float sensor, the outer diameter of the sensor rod so that the sensor rod of the float sensor can move up and down from the center of the coupling space to the bottom center A float support having perforated sliding holes corresponding thereto; Reed switch is built in the upper part, and the upper part is connected to the bottom of the protective cover that protects the water quality sensor connected to the winch by the rope, and the lower part is installed to move up and down in the connecting pipe through the sliding hole of the float support. An upper stopper formed on the sensor rod upper outer peripheral portion between the protective cover and the float support portion, a lower stopper formed on the lower outer peripheral portion of the sensor rod positioned in the connection pipe through a sliding hole of the float support portion; A float sensor installed in the sensor rod between the upper and lower stoppers, the float sensor being coupled to the coupling space of the float support part to guide the sliding operation of the sensor rod up and down; Characterized in that configured to include.

In addition, the bottom plate is formed of a disc of an outer diameter larger than the outer diameter of the connector, the center of the bottom plate and the lower end of the connector tube to form a screw to match with each other by a screw joint method, the inner upper part of the connector and the bottom of the float support Coupling bands are formed in the coupling grooves in a state in which a floating coupling is formed in the coupling space of the float support by forming a coupling groove for coupling the coupling band in the upper outer periphery of the float support by forming screws matching each other. By pressing the upper portion of the float support from the outside characterized in that to improve the bearing capacity of the float.

In addition, when the lower stopper is in close contact with the bottom surface of the float support part, the winch rotates forward while the reed switch contacts in the sensor rod are attached, and the rope connected to the protection cover of the water quality measurement sensor is released to lower the operation of the water quality measurement sensor. When the bottom plate touches the bottom of the water and the sensor rod slides downward and the lower stopper falls off the bottom of the float support, the contact of the reed switch in the sensor rod is dropped and this signal is transmitted to the winch to reverse the operation of the winch. The rope is pulled as it is converted to the water quality measurement sensor is characterized in that the impression.

In addition, the interval between the upper and lower stopper is ring-shaped moving along the sensor rod to adjust the upper and lower intervals by the distance that the sensor rod sliding downward when the winch is changed from forward rotation to reverse rotation. The body is coupled to a screw hole drilled in the outer periphery of the body to communicate with the inner side of the body, characterized in that consisting of a stop bolt for fixing the body in the position of the desired sensor rod.

The underwater bottom detection device of the present invention has the effect of preventing an expensive water quality sensor from being damaged by hitting the underwater floor by first reaching the underwater floor and transmitting this signal to the winch to cause the winch to pull up the water quality measurement sensor. have.

The present invention is a bottom plate which is put in water and in contact with the bottom of the water; A lower portion connected to the center of the bottom plate, the connecting pipe being formed in the form of a hollow pipe so that the sensor rod of the float sensor can move up and down; The lower part is coupled to the inside of the upper end of the connecting pipe, and the upper inner side is formed with a coupling space for coupling the float of the float sensor, the outer diameter of the sensor rod so that the sensor rod of the float sensor can move up and down from the center of the coupling space to the bottom center A float support having perforated sliding holes corresponding thereto; Reed switch is built in the upper part, and the upper part is connected to the bottom of the protective cover that protects the water quality sensor connected to the winch by the rope, and the lower part is installed to move up and down in the connecting pipe through the sliding hole of the float support. An upper stopper formed at an upper outer peripheral portion of the sensor rod between the protective cover and the float support portion, a lower stopper formed at the lower outer peripheral portion of the sensor rod positioned inside the connection pipe through a sliding hole of the float supporting portion; A float sensor installed in the sensor rod between the upper and lower stoppers, the float sensor being coupled to the coupling space of the float support part to guide the sliding operation of the sensor rod up and down; Characterized in that configured to include.

In addition, the bottom plate is formed of a disc of an outer diameter larger than the outer diameter of the connector, the center of the bottom plate and the lower end of the connector tube to form a screw to match with each other by a screw joint method, the inner upper part of the connector and the bottom of the float support Coupling bands are formed in the coupling grooves in a state in which a floating coupling is formed in the coupling space of the float support by forming a coupling groove for coupling the coupling band in the upper outer periphery of the float support by forming screws matching each other. By pressing the upper portion of the float support from the outside characterized in that to improve the bearing capacity of the float.

In addition, when the lower stopper is in close contact with the bottom surface of the float support part, the winch rotates forward while the reed switch contacts in the sensor rod are attached, and the rope connected to the protection cover of the water quality measurement sensor is released to lower the operation of the water quality measurement sensor. When the bottom plate touches the bottom of the water and the sensor rod slides downward and the lower stopper falls off the bottom of the float support, the contact of the reed switch in the sensor rod is dropped and this signal is transmitted to the winch to reverse the operation of the winch. The rope is pulled as it is converted to the water quality measurement sensor is characterized in that the impression.

In addition, the interval between the upper and lower stopper is a ring-shaped body that moves along the sensor rod so that the upper and lower intervals can be adjusted by the distance the sensor rod slides downward when the winch is changed from forward rotation to reverse rotation. And a stop bolt coupled to a screw hole drilled in the outer circumference of the body so as to communicate with the inner side of the body so as to fix the body at a desired position of the sensor rod.

Figure 2 is a perspective view according to an embodiment of the present invention, Figure 3 is a cross-sectional view according to an embodiment of the present invention, Figure 4 is an operating state diagram according to an embodiment of the present invention, Figure 5 is another embodiment of the present invention As showing the use state diagram according to each, with reference to the accompanying drawings illustrating the configuration of the present invention as follows.

2 and 3, the bottom detection device of the present invention, the bottom plate 10 in contact with the bottom when in the water, and the connection pipe 20 is installed on the top of the bottom plate 10, The float support unit 30 is installed on the connecting pipe 20 and the float sensor 40 is coupled to the float 44 in the coupling space 31 of the float support unit 30.

The bottom plate 10 may be formed in a square, but it is preferable to manufacture in a disk form that is easier to manufacture than in a rectangular shape.

When the bottom plate 10 is hit by the underwater bottom, it is preferable to maintain a state in which the constituent members such as the connection pipe 20 or the float support part 30 installed above the bottom plate 10 are not inclined. Therefore, the outer diameter of the bottom plate 10 may be about 3 to 5 times wider than the outer diameter of the connector (20).

In addition, the connecting pipe 20 is to be installed so that the lower end is connected to the center of the bottom plate 10, formed in the form of a hollow circular pipe sensor rod 43 of the float sensor 40 freely up and down Let's move Let's move.

In addition, the length of the connection pipe 20 is long enough for the sensor rod 43 of the float sensor 40 to move up and down so that the sensor rod 43 of the float sensor 40 does not interfere with moving up and down. To form.

The lower end of the connection pipe 20 and the center of the bottom plate 10 to form a male and female screw corresponding to each other so that the connection pipe 20 and the bottom plate 10 is coupled in a screw manner.

The float support part 30 coupled to the upper end of the connection pipe 20 serves to support the float 44 of the float sensor 40.

A male screw is formed at the lower portion of the float support part 30 and a female screw is formed inside the upper end of the connection pipe 20 corresponding thereto so that the lower portion of the float support part 30 and the inside of the upper end of the connection pipe 20 are screwed together.

The upper portion of the float support 30 is formed with an outer diameter larger than the outer diameter of the connector 20 so as to be located above the connector 20, the float of the float sensor (40) inside the float support (30) A coupling space 31 to which 44 is coupled is formed.

The coupling space 31 is formed in a shape that is fitted to the outer diameter of the float 44 so that the float 44 can be coupled, the sensor rod 43 of the float sensor 40 in the center of the coupling space 31 ) Is formed with a sliding hole 32 corresponding to the sensor rod 43 which can move freely up and down.

The sliding hole 32 is formed to penetrate from the center of the coupling space 31 to the center of the bottom surface of the float support part 30 so as to communicate with the inside of the connecting pipe 20.

On the other hand, in the upper outer circumference of the float support portion 30, the coupling groove 33 for coupling the fastening band 50 is formed to the coupling groove 33 in the state in which the float 44 is coupled to the coupling space 31 Combining the fastening band 50 to press the upper outer periphery of the float support portion 30, it is possible to further increase the support force of the float (44).

On the other hand, since the bottom plate 10, the connecting pipe 20 and the float support 30 is put in water, it is preferable to manufacture a PE (polyethylene) material which is not affected by corrosion rather than a metal material. .

The float sensor 40 is a general sensor in which the reed switch is inserted into the sensor rod 43 and the reed switch is operated by a magnet inside the float 44. The upper end of the float sensor 40 has a protective cover of the water quality measurement sensor 70. (71) consists of a sensor rod 43 connected to the bottom surface, and a float 44 moving up and down along the sensor rod 43 and coupled to the coupling space 31 of the float support portion 30.

That is, the upper end of the sensor rod 43 is connected to the bottom surface of the protective cover 71 of the water quality measurement sensor 70 and the lower end is positioned inside the connecting pipe 20 through the sliding hole 32 of the float support part 30. To be installed.

Upper and lower stoppers 41 and 42 are formed on upper and lower portions of the sensor rod 43.

The position of the upper stopper 41 is formed on the outer periphery of the sensor rod 43 between the protective cover 71 and the float support portion 30 of the water quality measurement sensor 70, and the position of the lower stopper 42 is the float support portion. 30 is formed on the outer peripheral portion of the sensor rod 43 located between the upper end of the connection pipe 20.

Here, in the state where the lower stopper 42 is in close contact with the bottom surface of the float support part 30, the winch 60 rotates forward while the contact of the reed switch in the sensor rod 43 is attached, and thus the water quality measurement sensor 70 The lowering of the water quality measurement sensor 70 is made by releasing the rope 61 connected to the protective cover 71. On the contrary, the bottom plate 10 touches the bottom of the water so that the sensor rod 43 slides downward and the lower stopper ( When 42 is dropped from the bottom of the float support 30, the contact point of the reed switch in the sensor rod 43 is dropped and this signal is transmitted to the winch 60, the forward winch 60 is converted to reverse rotation and the rope ( The water quality measurement sensor 70 rises by pulling 61).

Therefore, the space | interval between the said upper and lower stoppers 41 and 42 is installed in the space | interval same as the distance which the sensor rod 43 slides when the winch 60 changes from forward rotation to reverse rotation.

As such, the upper and lower stoppers 41 and 42 have a ring-shaped body 401 which is slidably movable along the sensor rod 43 to adjust the gap, and the body 401 to communicate with the inside of the body 401. It consists of a stop bolt 403 screwed to the threaded hole 402 perforated on the outer periphery.

As described above, the underwater bottom detection device of the present invention first touches the underwater bottom and transmits this signal to the winch 60 so that the winch 60 pulls up the water quality measurement sensor 70, thereby making it an expensive water quality measurement sensor. As to prevent the 70 from hitting the underwater bottom, with reference to the accompanying drawings will be described the operation of the present invention as follows.

4 and 5, the power is applied to the winch 60 of the present invention, and the water quality measuring sensor 70 equipped with the underwater bottom sensing device is put into the water.

At this time, the winch 60 is connected to the upper end of the protective cover 71 of the water quality measurement sensor 70 by the rope 61. When the winch 60 rotates forward, the rope 61 is released and the water quality measurement sensor 70 ) Is put into the water, and when the winch 60 rotates in reverse, the rope 61 is wound so that the water quality measuring sensor 70 put into the water is pulled up.

On the other hand, when the water quality measurement sensor 70 is put into the water, the lower stopper 42 installed under the sensor rod 43 is in close contact with the bottom of the float support part 30 and the winch 60 is in contact with the reed switch. ) Makes a forward turn.

In this state, the water quality measurement sensor 70 continuously descends to the bottom of the water, and at the moment when the bottom plate 10 touches the water bottom, the sensor rod 43 naturally descends while sliding into the sliding hole 32 so that the lower stopper ( 42 is a state away from the float support portion 30 and the contact of the reed switch is in a state in which the signal is immediately transmitted to the winch 60 to the reverse rotation of the winch 60 is made.

At this time, the winch 60 takes time to receive a signal even if the underwater bottom sensing device sends a signal, so that the rope 61 is released because the winch 60 continuously rotates during this time.

However, even when the rope 61 is released in the state in which the bottom plate 10 touches the underwater bottom, the time when the sensor rod 43 descends and slides, that is, the time until the upper stopper 41 reaches the upper surface of the float 44. And the winch 60 is set so that the time to convert to reverse rotation is the same because the stable downward sliding operation of the sensor rod 43 can maintain the stable state of the underwater bottom without tilting or falling.

Meanwhile, the distance between the upper and lower stoppers 41 and 42 may be adjusted according to the time when the winch 60 converts to the reverse rotation, and the stop bolt (when adjusting the interval between the upper and lower stoppers 41 and 42) is performed. Loosen the 403, and then move the body 401 along the sensor rod 43 to the desired position while tightening the stop bolt 403 to secure the body 401.

When the winch 60 is converted to reverse rotation upon receiving a signal from the underwater bottom sensing device, the rope 61 is wound and the water quality measurement sensor 70 is pulled up to safely recover the water quality measurement sensor 70.

The operation of the underwater bottom detection device is organic, and the underwater bottom detection device and the winch 60 are electrically connected so that the part where the reed switch of the sensor rod 43 is embedded passes through the float 44 with the magnet embedded therein. While the operation signal of the contact of the reed switch is attached or falling occurs, this operation signal is transmitted to the winch 60 so that the winch 60 can be converted from forward rotation to reverse rotation.

Operation control of the winch 60 by the operation signal of the contact of the reed switch is attached or falling, it is preferable to put the control box to control the winch 60 by the control box.

1 is a state diagram of the installation of a conventional underwater floor measuring apparatus.

2 is a perspective view according to an embodiment of the present invention.

3 is a cross-sectional view according to an embodiment of the present invention.

4 is an operating state according to an embodiment of the present invention.

5 is a use state according to another embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10: bottom plate 20: connector 30: float support

31: coupling space 32: sliding hole 33: coupling groove

40: float sensor 41: upper stopper 42: lower stopper

43: sensor rod 44: float 50: fastening band

60: winch 61: rope 70: water quality sensor

71: protective cover 401: body 402: screw thread

403: stop bolt

Claims (4)

A bottom plate that is introduced into water and contacts the bottom of the water; A lower portion connected to the center of the bottom plate, the connecting pipe being formed in the form of a hollow pipe so that the sensor rod of the float sensor can move up and down; The lower part is coupled to the inside of the upper end of the connecting pipe, and the upper inner side is formed with a coupling space for coupling the float of the float sensor, the outer diameter of the sensor rod so that the sensor rod of the float sensor can move up and down from the center of the coupling space to the bottom center A float support having perforated sliding holes corresponding thereto; Reed switch is built in the upper part, and the upper part is connected to the bottom of the protective cover that protects the water quality sensor connected to the winch by the rope, and the lower part is installed to move up and down in the connecting pipe through the sliding hole of the float support. A sensor rod, an upper stopper formed at an upper outer peripheral portion of the sensor rod between the protective cover and the float support portion, a lower stopper formed at a lower outer peripheral portion of the sensor rod positioned inside the connection pipe through a sliding hole of the float support portion; A float sensor installed in the sensor rod between the upper and lower stoppers, the float sensor being coupled to the coupling space of the float support part to guide the sliding operation of the sensor rod up and down; Underwater floor detection device, characterized in that configured to include. The method of claim 1, The bottom plate is formed of a disc of an outer diameter larger than the outer diameter of the connecting pipe, the center of the bottom plate and the bottom of the connecting pipe to form a screw corresponding to each other by a screw joint method, the upper part of the connection pipe and the bottom of the float support is matched with each other Forming a screw to be coupled to the screw joint method, the upper outer periphery of the float support to form a coupling groove for coupling the fastening band to the coupling groove in the state in which the float is coupled to the coupling space of the float support to fill the coupling band outside Underwater floor sensing device characterized in that to improve the bearing capacity of the float by pressing the upper portion of the float support. The method of claim 1, In the state where the lower stopper is in close contact with the bottom of the float support, the winch rotates forward with the contact of the reed switch in the sensor rod, while releasing the rope connected to the protective cover of the water quality measurement sensor, and the lowering operation of the water quality measurement sensor is performed. , If the bottom plate touches the bottom of the water and the sensor rod slides downward while the lower stopper falls off the bottom of the float support, the contact point of the reed switch in the sensor rod falls and this signal is transmitted to the winch, so that the operation of the winch that has been rotated forward is reversed. Underwater detection device characterized in that the rope is pulled along to raise the water quality measurement sensor. The method of claim 1, The interval between the upper and lower stopper is a ring-shaped body moving along the sensor rod to adjust the upper and lower intervals by the distance that the sensor rod is sliding downward when the winch is changed from forward rotation to reverse rotation, Underwater floor sensing device characterized in that it is coupled to the screw hole drilled on the outer periphery of the body to communicate with the inner side of the body to be fixed to the position of the desired sensor rod to stop the body.

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