KR101246564B1 - Total residual oxidant measuring devices - Google Patents

Abstract

PURPOSE: A TRO(Total Residual Oxidant) measuring device is provided to measure recent TRO by using a by-pass pipe. CONSTITUTION: A TRO measuring device comprises a water sampling pipe(10), a housing(110), a TRO sensor(120), U-shaped inlet and outlet water seals(130,140), a glove valve(150), a 3-way solenoid valve(160), first and second check valves(170,180), and a terminal box(190). The housing is placed on the lateral side of the water sampling pipe. The TRO sensor is placed inside the housing and measures TRO. The U-shaped inlet and outlet water seals connect the water sampling pipe and the TRO sensor.

Description

Tialoh Measuring Device {Total Residual Oxidant Measuring Devices}

The present invention relates to a measuring device, and more particularly, to a total residual oxidant (TRO) measuring device for measuring the residual oxidant concentration in electrolyzed ballast water or water treatment water.

Conventional electrolysis water treatment apparatus further includes a measuring device for measuring the concentration of the oxidant generated during the electrolysis of the ballast water or treated water.

Such a conventional measuring device is configured to be separated from the collecting pipe to which the ballast water or the processing water is transferred, and thus, sample water is not introduced into the measuring device according to the vertical installation height or length of the collecting pipe and the suction pump. There was a problem that might not.

In addition, there was a problem in that real-time measurement was not possible due to the previously treated water taken in the pipe according to the length of the water pipe.

Inlet and outlet pipes are directly connected to the measuring device installed at a long distance from the intake pipe, so that gas generated in the intake pipe can be introduced into the measurement device in which the instrument part and the electronic part are integrated, which may cause flammability. .

An object of the present invention for solving the above-described problems is to provide a TRO measuring device that can be smoothly introduced (Sample Water) by implementing a water pipe (conventional water pipe) as a short-range pipe.

Still another object of the present invention is a structure in which water is always flowed through the inlet u-water seal to the outlet u-water seal even when the TRO measuring device is not used by the bypass pipe. The purpose of the present invention is to provide a TRO measuring device capable of always measuring the latest TRO.

Still another object of the present invention is to provide a TRO measuring apparatus that can block the inflow of gas by designing the inlet and the outlet water seal in a U-shape.

The TRO measuring apparatus according to an embodiment of the present invention to solve the above-mentioned conventional problems and to achieve the above object is to measure the oxidant concentration of the electrolyzed ballast water or water treatment water transported in the sewage pipe: Total Residual Oxidant: A total residual oxidant), comprising: a housing located on the side of the intake pipe; A TRO sensor located inside the housing and measuring TRO; Inlet and Outlet U-Water Seal which is separately formed in a U-shape and connects the intake pipe and the TRO sensor; A glove valve positioned at one side of the inlet water seal and configured to adjust a flow rate of sampling water flowing into the TRO sensor; A three-way solenoid valve positioned between the glove valve and the TRO sensor in the inlet water seal and including a bypass pipe connected to one side of the outlet water seal; First and second check valves (Check Valve-1 and Check Valve-2) which are located before and after a portion connected to the bypass pipe in the outlet water seal and prevent backflow of water; And a terminal box for controlling power supply to the TRO sensor, and operation of a glove valve, a three branch solenoid valve, and first and second check valves.

Here, the intake pipe is characterized in that it is implemented as a short-range pipe of the pipe / wall mount type (Pipe / Flange / Wall Mount Type).

In addition, the inlet water seal is located between the three-prong solenoid valve and the TRO sensor, characterized in that it further comprises a strainer (Strainer) for filtering foreign matter in the water.

The outlet water seal may further include a flow switch located between the first check valve and the TRO sensor, the flow switch being a sensor for detecting whether the water flows from the fresh water.

In addition, the U-shaped inlet and outlet water seal can be implemented in the form of S-shaped or P-shaped pipes to prevent the inflow of gas, the shape is characterized in that the single pipe or a plurality of combinations thereof.

Here, the TRO measuring device may be installed in a vertical type in addition to the horizontal type.

In addition, the housing is characterized in that it further comprises a suction pump or discharge pump or eductor (Eductor) to facilitate the intake and discharge of the sewage on the inner or outer side.

In addition, the inlet water seal is characterized in that it further comprises a pressure reducing valve for protecting the device in the housing.

In addition, the outlet water seal is characterized in that it further comprises a pressure valve for improving the discharge performance.

As described above, the TRO measuring apparatus according to an embodiment of the present invention implements a water pipe (conventional water pipe) as a short distance pipe, and thus, smooth water may be smoothly introduced.

In addition, the present invention forms a structure in which water is always flowed through the Inlet U-Water Seal to the Outlet U-Water Seal even when the TRO measuring device is not used using a bypass pipe. This has the effect of always measuring the latest TRO.

In addition, the present invention has an effect that the inlet and the outlet water seal in the U-shape can be blocked by the source of gas at the source.

1 is a view showing a TRO measuring apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a TRO measuring apparatus according to an embodiment of the present invention.

As shown in FIG. 1, a total residual oxidant (TRO) measuring apparatus 100 according to an embodiment of the present invention includes a water collecting pipe 10, a housing 110, a TRO sensor 120, an inlet, Outlet and Outlet U-Water Seals (130 and 140), Glove Valves (150), 3 Ways Solenoid Valves (160), First and Second Check Valves 1 and Check Valve-2, 170 and 180), and Terminal Box (190).

Here, the intake pipe 10 is implemented as a short-range pipe of a pipe / wall mount type (Pipe / Flange / Wall Mount Type), and the electrolyzed ballast water or water treatment water is transferred therein.

And, the housing 110 is located on the side of the water pipe 10, the TRO sensor 120 for measuring the TRO therein is located.

The inlet and outlet water seals 130 and 140 connect the intake pipe 10 and the TRO sensor 120, and are individually formed and have a U-shape to prevent or block gas inflow.

In this case, the inlet and the outlet water seals 130 and 140 may be implemented in an S-shape or P-shape pipe shape, and the shape is configured by a single pipe or a plurality thereof.

The glove valve 150 is located on one side of the inlet water seal 130 and adjusts the flow rate of sampling water flowing into the TRO sensor 120.

The three-prong solenoid valve 160 is located between the glove valve 150 and the TRO sensor 120 in the inlet water seal 130 and includes a bypass pipe 161 connected to one side of the outlet water seal 140. do.

In addition, the first and second check valves 170 and 180 are positioned before and after a portion connected to the bypass pipe 161 in the outlet water seal 140 to prevent backflow of water.

In addition, the terminal box 190 controls power supply to the TRO sensor 120 and operations of the glove valve 150, the three-way solenoid valve 160, and the first and second check valves 170 and 180.

The inlet water seal 130 is located between the three-way solenoid valve 160 and the TRO sensor 120, and further includes a strainer (130) for filtering foreign matter in the water.

The outlet water seal 140 further includes a flow switch 141 which is positioned between the first check valve 170 and the TRO sensor 120 and detects whether or not fluid flows from the fresh water.

The TRO measuring device 100 configured as described above can be installed in a vertical type in addition to the horizontal type, and a suction pump or discharge for smoothly inflowing and discharging water into the housing 110 or one side thereof. It further includes a pump or an eductor.

In addition, the inlet water seal 130 may further include a pressure reducing valve for protecting the device in the housing 110, and the outlet water seal 140 may further include a pressure valve for improving discharge performance.

As described above, the TRO measuring apparatus 100 according to an embodiment of the present invention implements a sewage pipe (conventional sewage pipe) as a short distance pipe, and thus, smooth water may be introduced.

In addition, according to the present invention, even when the TRO measuring device is not used by the bypass pipe 161, the water is always flowing through the inlet water seal 130 to the outlet water seal 140, thereby always providing the latest TRO. There is an effect that can be measured.

In addition, the present invention has an effect that the inlet and the outlet water seals 130 and 140 can be U-shaped to block the gas inlet.

While the present invention has been particularly shown and described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of course, this is possible. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the equivalents as well as the claims that follow.

10: collection pipe 100: TRO measuring device
110: housing 120: TRO sensor
130: Inlet U-Water Seal
131: strainer
140: Outlet U-Water Seal
141: Flow Switch 150: Glove Valve
160: 3 Way Solenoid Valve
161: bypass pipe 170: the first check valve (Check Valve-1)
180: second check valve (Check Valve-2) 190: terminal box (Terminal Box)

Claims (9)

In the Total Residual Oxidant (TRO) measuring device, which measures the oxidizer concentration of electrolyzed ballast water or water treatment water transported in a collecting pipe,
A housing located on a side of the water collecting pipe;
A TRO sensor located inside the housing and measuring TRO;
Inlet and Outlet U-Water Seal which is separately formed in a U-shape and connects the intake pipe and the TRO sensor;
A glove valve positioned at one side of the inlet water seal and configured to adjust a flow rate of sampling water flowing into the TRO sensor;
A three-way solenoid valve positioned between the glove valve and the TRO sensor in the inlet water seal and including a bypass pipe connected to one side of the outlet water seal;
First and second check valves (Check Valve-1 and Check Valve-2) which are located before and after a portion connected to the bypass pipe in the outlet water seal and prevent backflow of water;
And a terminal box for controlling power supply to the TRO sensor, and operation of a glove valve, a three branch solenoid valve, and first and second check valves.
The method of claim 1,
The collection pipe is a TRO measuring apparatus, characterized in that implemented as a short-range pipe of the pipe / wall mount type (Pipe / Flange / Wall Mount Type).
The method of claim 1,
The inlet water seal is located between the three branch solenoid valve and the TRO sensor, the TRO measuring apparatus further comprises a strainer (Strainer) for filtering foreign matter in the water.
The method of claim 1,
The outlet water seal is located between the first check valve and the TRO sensor, the TRO measuring apparatus further comprises a flow switch (Flow Switch) that is a sensor for detecting the flow of fluid.
The method of claim 1,
The U-shaped inlet and outlet water seals can be implemented in the form of S-shaped or P-shaped pipes to prevent the inflow of gas, the form is a single pipe or TRO measuring apparatus characterized in that a combination of a plurality.
The method of claim 1,
The TRO measuring device is a TRO measuring device, characterized in that can be installed in a vertical type (Vertical Type) in addition to the horizontal type (Horizontal Type).
The method of claim 1,
The housing TRO measuring apparatus further comprises a suction pump or discharge pump or eductor (Eductor) to facilitate the intake and discharge of the sewage on the inner or outer side.
The method of claim 1,
The inlet water seal further comprises a pressure reducing valve for protecting the device in the housing.
The method of claim 1,
The outlet water seal TRO measuring apparatus further comprises a pressure valve for improving the discharge performance.

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