KR20200021159A - System for measuring the dissolved oxygen concentration in water tank - Google Patents

Abstract

According to an embodiment of the present invention, a system for measuring a dissolved oxygen concentration comprises: a plurality of water tanks having fish or shellfish accommodated therein; a measurement water tank; a dissolved oxygen concentration measuring unit for measuring a dissolved oxygen concentration of water stored in the measurement water tank; a first pipe unit having one end connected to an inlet of the measurement water tank and the other end branched to be separately connected to outlets of the water tanks; a first opening and closing valve unit for selectively connecting the measurement water tank and one of the water tanks; a first pump for flowing water of one of the water tanks to the measurement water tank by an operation of the first opening and closing valve unit; and a control unit for controlling the first pump and the first opening and closing valve unit to sequentially store the water in the water tanks in the measurement water tank by sequentially connecting the measurement water tank with one of the water tanks, and controlling the dissolved oxygen concentration measuring unit to measure the dissolved oxygen concentration of the water sequentially stored in the measurement water tank.

Description

System for measuring the dissolved oxygen concentration in water tank

The present invention relates to a dissolved oxygen concentration measuring system, and more particularly, to provide a dissolved oxygen concentration measuring system capable of sequentially measuring the dissolved oxygen concentrations of a plurality of tanks using one dissolved oxygen concentration measuring unit. .

As the technology of aquaculture for marine life develops day by day, not only fish but also shellfish such as abalone can be farmed and produced in large quantities. Live fish tea is used to keep fish and shellfish alive.

In general, a large number of species (by species) or aquatic products (live fish) are used for living or catering to live animals, fish farms, bonded warehouses, and fixed storages. It is stored in a tank consisting of a certain period of time, and the amount of dissolved oxygen required for survival and activity in the tank differs depending on the type of seafood.

When transporting aquatic products by live car, the liquids or gas cylinders are mainly used to inject the oxygen of the required concentrations into the tanks by experience, and then the transport begins.

 Most tanks installed in live fishing vehicles remain closed and cannot detect fish in the cockpit or cockpit. Accordingly, live fishing cars have a lot of accidents during driving due to speeding and fuel consumption due to the need to transport them to the destination in the fastest way from the moment of loading the marine products.

When food companies store aquatic products in tanks, they simply generate bubbles to supply oxygen in the tanks, so the supply amount and dissolved oxygen concentration are unclear, which makes it difficult to store aquatic products for a long time.

Since dissolved oxygen consumption can vary depending on the number of fish loaded in the tank, when the dissolved oxygen drops below a certain level, the aquatic products will die due to its lack, and the loss may occur due to shock due to oversupply. Monitoring of dissolved oxygen and proper supply of aquatic products is desirable. According to the conventional dissolved oxygen monitoring method because the expensive dissolved oxygen measuring sensor is installed one by one according to the number of compartments of the tank, there is a problem that is not cost effective.

In addition, a high density of fish and shellfish introduced into the aquaculture tank in order to increase the efficiency of aquaculture has been posted variously, such as domestic Patent No. 10-0883802 to supply oxygen into the tank to prevent the death of fish and shellfish caused by oxygen shortage. . However, the method of continuously supplying oxygen regardless of the dissolved oxygen concentration of water in the tank has a disadvantage of causing unnecessary waste of energy.

Figure 1 discloses an oxygen supply system of a fish and shellfish farm according to the prior art. The oxygen supply system of the conventional fish and shellfish farm shown in FIG. 1 is provided with a plurality of tanks and is for explaining a method of measuring dissolved oxygen for each tank.

As shown in FIG. 1, the oxygen supply system 10 of the conventional fish and shellfish farm includes a plurality of tanks 41 to 43, a plurality of dissolved oxygen concentration measuring units 20a to 20c, a plurality of oxygen supply units, and a controller 30. ).

Dissolved oxygen concentration measuring units 20a to 20c are provided for each of the tanks 41 to 43. Dissolved oxygen concentration measuring unit 20a to 20c The dissolved oxygen concentration measuring unit 20a to 20c includes a dissolved oxygen measuring sensor 21 and a signal processing terminal 22. Here, the dissolved oxygen measuring sensor 21 is a sensor inserted into the water in the water tanks 41 to 43 and measuring the dissolved oxygen amount in the water tanks 41 to 43. The signal processing terminal 22 is connected to the dissolved oxygen measuring sensor 21 to signal-process the information measured by the dissolved oxygen measuring sensor 21. The signal processing terminal 22 may be connected to the control unit 30 to transmit the signal processed information to the control unit 30. The control unit 30 controls the operation of the oxygen supplier installed in each of the tanks 41 to 43 according to the signal received from the dissolved oxygen concentration measuring unit 20a to 20c.

Oxygen supply system 10 of the fish and shellfish farm according to the prior art can increase the measurement accuracy of the dissolved oxygen concentration can efficiently perform the oxygen supply control in the culture tank (41 ~ 43).

Despite the above advantages, the oxygen supply system 10 of the fish and shellfish farm according to the prior art has the following problems.

The number of installations of the water tanks 41 to 43 may vary depending on the size of the fish farm, but since the dissolved oxygen concentration measuring units 20a to 20c are expensive, the dissolved oxygen concentration measuring unit for each tank 41 to 43 installed in the fish farm 20a ~ 20c) installation costs more than tens of millions of won. Each of the commercially available dissolved oxygen measuring sensor 21 and the signal processing terminal 22 has a price difference depending on the usage specifications, but the product sales price is about 1 million to millions of dollars.

In addition, the control unit 30 receives the information on the dissolved oxygen measurement amount transmitted from the plurality of dissolved oxygen concentration measuring units 20a to 20c in real time, and thus a plurality of oxygen supplies installed in each of the tanks 41 to 43. Because of the need to individually control the operation of the signal, signal processing efficiency and accuracy may be reduced.

Therefore, the present invention has been made to solve the above problems, and do not separately install the dissolved oxygen concentration measuring unit for each of the plurality of tanks in which fish and shellfish are farmed, but is dissolved in one measuring tank connected to the plurality of tanks, respectively. It is an object of the present invention to provide a dissolved oxygen concentration measuring system in which an oxygen concentration measuring unit is provided and the dissolved oxygen concentration of each of the plurality of tanks can be sequentially measured in the measuring tank.

Compared with conventionally, a plurality of dissolved oxygen concentrations measured in a dissolved oxygen concentration measuring unit respectively installed in a plurality of tanks are simultaneously transmitted to a control unit, and the control unit simultaneously controls the operation of each oxygen supply unit according to the dissolved oxygen concentration. The dissolved oxygen concentration of each of the plurality of tanks is sequentially measured by one dissolved oxygen concentration measuring unit installed in the measuring tank, and the operation of each oxygen supply unit installed in the plurality of tanks is controlled, so that the signal processing efficiency and accuracy of the controller The aim is to provide a dissolved oxygen concentration measurement system that can improve the

Dissolved oxygen concentration measuring system according to an embodiment of the present invention, a plurality of tanks for receiving fish or shellfish; Measuring tank; Dissolved oxygen concentration measuring unit for measuring the dissolved oxygen concentration of the water stored in the measuring tank; A first pipe part connected at one end to an inlet of the measuring tank and connected at another end to the outlets of the plurality of tanks; A first opening / closing valve unit selectively connecting any one of the measuring tank and the plurality of tanks; A first pump for flowing water of any one of the plurality of tanks to the measurement tank according to the operation of the first opening / closing valve unit; And one of the plurality of tanks and the measurement tank are sequentially connected to control the first pump and the first opening / closing valve unit so that water in the plurality of tanks is sequentially stored in the measurement tank, and dissolved oxygen of the water sequentially stored in the measurement tank. It is preferable to include a control unit for controlling the dissolved oxygen concentration measuring unit so that the concentration is measured.

In one embodiment of the present invention, one end is connected to the outlet of the measuring tank, the other end is branched second pipe portion connected to each of the inlets of the plurality of tanks; And a second opening / closing valve unit for selectively connecting any one of the measuring tank and the plurality of tanks when discharging the water of the measuring tank.

In one embodiment of the present invention, it is preferable to further include a second pump for flowing the water of the measuring tank to any one of the plurality of tanks in accordance with the operation of the second opening and closing valve unit.

In one embodiment of the invention, the measuring tank is located above in the gravity direction than the plurality of tanks; According to the operation of the second opening / closing valve part, it is preferable that water in the measuring tank can flow by gravity to the corresponding tank.

In one embodiment of the present invention, the measuring tank is further provided with a water level sensor for measuring the water level of the water stored in the measuring tank and providing it to the control unit, the control unit, if the water level is measured by the water level sensor, the water tank from the water level Calculate the amount of water stored in the water, calculate the discharge time required to discharge all the water stored in the measuring tank from the discharge amount per hour when the measuring tank is opened, and selectively open the second opening and closing valve unit to measure during the discharge time It is desirable to allow the water in the tank to flow into the tank.

The present invention does not provide a dissolved oxygen concentration measuring unit individually in each of a plurality of tanks in which fish and shellfish are farmed, but by installing a dissolved oxygen concentration measuring unit in one measuring tank and using a single dissolved oxygen concentration measuring unit. Dissolved oxygen concentration can be measured sequentially.

Compared to the case where the dissolved oxygen concentration meter is installed for each tank in the oxygen supply system of a conventional fish and shellfish farm, the present invention can separately measure the dissolved oxygen concentration of a plurality of tanks by installing the dissolved oxygen measuring unit only in the measuring tank. The number of dissolved oxygen concentration measurement units can be reduced to 1 / N. For this reason, the present invention can significantly reduce the equipment cost consumed in order to measure the dissolved oxygen amount of each tank, and the economic efficiency is large.

In addition, in the present invention, the dissolved oxygen concentration of each of the plurality of tanks is sequentially measured by one dissolved oxygen concentration measuring unit installed in the measuring tank, and the operation of each oxygen supply unit installed in the plurality of tanks is controlled to control the signal of the controller. The processing efficiency and accuracy can be improved. Accordingly, the present invention does not require the use of a high specification control unit, thereby reducing the cost of equipment.

Figure 1 schematically shows the configuration of the oxygen supply system of the fish and shellfish farm according to the prior art.
Figure 2 schematically shows the configuration of the oxygen supply system of the fish and shellfish farm according to an embodiment of the present invention.
3a to 5b are views for explaining the operating state of the dissolved oxygen concentration measuring system according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, it will be described for the dissolved oxygen concentration measuring system according to a preferred embodiment of the present invention.

The present invention can be used to measure the dissolved oxygen concentration of a tank containing fish and / or shellfish in a live state, such as live fish carriers or fish farms.

As shown in FIG. 2, the dissolved oxygen concentration measuring system 100 according to an embodiment of the present invention includes a plurality of tanks 111, 112, and 113, a plurality of oxygen supply units 121, 122, and 123, and a measuring tank. 114, the first opening and closing valve 130a, the second opening and closing valve 130b, the first piping 141 ~ 144, the second piping 151 ~ 154, the first pump 161, the first 2 pump 162, the dissolved oxygen concentration measuring unit 170 and the controller 180.

The present invention is to measure the dissolved oxygen concentration of each of the plurality of tanks (111, 112, 113) by installing the dissolved oxygen concentration measuring unit 170 in the measuring tank connected to the plurality of tanks (111, 112, 113). .

The plurality of tanks 111, 112, and 113 are for accommodating fish or shellfish in a living state. 2 to 5, in the present embodiment, for convenience of description, the plurality of tanks 111, 112, and 113 may be referred to as being divided into the first tanks 111 to the third tank 113. do.

The measuring tank 114 is a tank in which water discharged from any one of the first tank 111 to the third tank 113 is stored. The measuring tank 114 is connected to the first tank 111 to the third tank 113 by the first pipe part and the second pipe part.

The dissolved oxygen concentration measuring unit 170 and the water level sensor 190 are installed in the measurement tank 114. Dissolved oxygen concentration measuring unit 170 is a device for measuring the dissolved oxygen concentration of the water stored in the measuring tank (114). The dissolved oxygen concentration measuring unit 170 includes a dissolved oxygen measuring sensor 171 and a signal processing terminal 172.

The dissolved oxygen measuring sensor 171 is in contact with the water stored in the measuring tank 114 to measure the dissolved oxygen concentration. The signal processing terminal 172 signals the dissolved oxygen concentration measured by the dissolved oxygen measuring sensor 171 and transmits the signal to the controller 180. The signal processing terminal 172 and the controller 180 may be connected by wire or wirelessly. Various types of dissolved oxygen measuring sensor 171 and signal processing terminal 172 may be used according to technology development, and the present specification does not specifically limit the types of dissolved oxygen measuring sensor 171 and signal processing terminal 172. Do not.

The water level sensor 190 measures the level of water stored in the measuring tank 114 and provides it to the controller 180.

The measuring tank 114 is located above the plurality of tanks 111 to 113 in the direction of gravity, even if the second pump 162 is not installed, the measuring tank 114 according to the operation of the second opening / closing valve unit 130b. The water in) can be made to flow into the corresponding tank by gravity.

Meanwhile, oxygen supply units 121, 122, and 123 are installed in the first to third tanks 111 to 113, respectively. In the present embodiment, for convenience of description, the plurality of oxygen supply units 121, 122, and 123 will be referred to as a first oxygen supply unit 121 to a third oxygen supply unit 123. The first oxygen supply unit 121 is installed in the first water tank 111. The second oxygen supply unit 122 is installed in the second water tank 112. In addition, the third oxygen supply unit 123 is installed in the third water tank 113. Oxygen supply unit 121, 122, 123 is a device for supplying oxygen to the water tank (111, 112, 113). The oxygen supply unit controls the on / off operation by the controller 180.

The plurality of water tanks 111 to 113 are provided with outlets through which water is discharged and inlets through which water is introduced. In the present embodiment, for convenience of description, the first outlet 111a for the outlet of the first water tank 111 is referred to as the first inlet 111b for the inlet of the first water tank 111. The outlet of the second tank 112 is referred to as a second outlet 112a and the inlet of the second tank 112 is referred to as a second inlet 112b. The third outlet 113a is referred to as the outlet of the third tank 113 and the third inlet 113b is referred to as the inlet of the third tank 113.

The plurality of tanks are provided with first pipe parts 141 to 144 and second pipe parts 151 to 154. The first pipe parts 141 to 144 and the second pipe parts 151 to 154 are pipes connecting the plurality of water tanks 111 to 113 and the measurement water tank 114.

One end of the first pipe portion (141 ~ 144) is connected to the inlet of the measuring tank 114, the other end is branched into several branches are connected to the outlet of the plurality of tanks (111 ~ 113), respectively.

The first pipe part includes a first reference pipe 141 and a plurality of first branch pipes 142 to 144. The first reference pipe 141 and the plurality of first branch pipes 142 to 144 are connected to the first open / close valve unit 130a, respectively.

The first reference pipe 141 connects the inlet port 114a of the measuring tank and the first opening / closing valve unit 130a. The first reference pipe 141 is provided with a first pump 161. The first pump 161 sucks water stored in the water tank connected to any one branch pipe opened by the first opening / closing valve unit 130a during operation.

The plurality of first branch pipes 142 to 144 are connected to the respective outlets 111a, 112a, and 113a of the plurality of tanks and the first opening / closing valve unit 130a. One of the first branch pipes of the plurality of first branch pipes is connected to the first reference pipe 141 and the water in a flowable manner by selective opening and closing of the first opening / closing valve part by a control signal of the controller 180. .

In this embodiment, the number of the plurality of first branch pipes is varied according to the number of installation of the plurality of tanks. However, in the present embodiment, for convenience of explanation, the plurality of first branch pipes 142 to 144 may be connected to the first branch pipes 142, the first branch pipes 143, and the first branch pipes 144. This will be referred to separately.

The first a branch pipe 142 connects the first water tank 111 and the first opening / closing valve unit 130a. The first branch pipe 142 is preferably installed in the first tank 111 so that the water stored in the first tank 111 can be discharged to the outside during the operation of the first pump 161. The first branch pipe 142 is installed in the first water tank 111 through the first discharge port 111a.

The second a branch pipe 143 connects the second water tank 112 and the first open / close valve unit 130a. The second a branch pipe 143 is preferably installed in the second water tank 112 so that the water stored in the second water tank 112 can be discharged to the outside when the first pump 161 operates. The second branch pipe 143 is installed in the second water tank 112 through the second outlet 112a.

The third branching pipe 144 connects the third water tank 113 and the first opening / closing valve unit 130a. The third branch pipe 144 is preferably installed in the third tank 113 so that water stored in the third tank 113 can be discharged to the outside when the first pump 161 is operated. The third branch pipe 144 is installed in the third water tank 113 through the third discharge port 113a.

Each of the first branching pipe 142, the first branching pipe 143, and the first branching pipe 144 is selectively opened and closed by the first opening / closing valve unit 130a.

The first opening and closing valve unit 130a is installed such that the first reference pipe 141, the first a branch pipe 142, the first b branch pipe 143, and the first c branch pipe 144 are connected to each other.

The first opening / closing valve unit 130a may be any one of the first a branch pipe 142, the first b branch pipe 143, and the first c branch pipe 144 by the control signal of the controller 180. A valve for selectively opening or closing the first reference pipe 141, the first a branch pipe 142, the first b branch pipe 143, and the first c branch pipe 144 so as to be connected to 141.

One end of the second pipe parts 151 to 154 is connected to the outlet of the measuring tank 114, and the other end thereof is branched into several branches and connected to the inlets of the plurality of tanks 111 to 113, respectively.

The second pipe part includes a second reference pipe 151 and a plurality of second branch pipes 152 to 154. The second reference pipe 151 and the plurality of second branch pipes 152 to 154 are respectively connected to the second open / close valve unit 130b.

The second reference pipe 151 connects the outlet 114b of the measurement tank and the second open / close valve unit 130b. The second reference pipe 151 is provided with a second pump 162. The second pump 162 sucks water stored in the measurement tank 114 to the second reference pipe 151 during operation. The operation of the second pump 162 is controlled by the controller 180. The second pump 162 has a measuring tank 114 installed above the first tank 111 to the third tank 113 according to the arrangement structure of the plurality of tanks 111 to 113 and the measuring tank 114. In that case it may not be installed.

The plurality of second branch pipes 152 to 154 are connected to the respective inlets 111b 112b and 113b and the second open / close valve unit 130b of the plurality of tanks. In any one of the plurality of second branch pipes, the second reference pipe 151 and water flow by selective opening and closing of the b opening / closing valve unit 130b according to a control signal of the controller 180. Possibly connected.

In this embodiment, the number of the plurality of second branch pipes is varied according to the number of installation of the plurality of tanks. However, in the present embodiment, for convenience of explanation, the second branch pipe 152, the second branch b pipe 153 and the second branch pipe 154 to the plurality of second branch pipes (152 to 154). This will be referred to separately.

The second branch pipe 152 connects the first inlet 111b of the second tank and the second open / close valve unit 130b. The second b branch pipe 153 connects the second inlet 112b and the second open / close valve unit 130b of the second tank. The second c branch pipe 154 connects the third inlet 113b and the second open / close valve unit 130b of the third tank.

Each of the 2a branch pipe 152, the 2b branch pipe 153, and the 2c branch pipe 154 is selectively opened and closed of the second open / close valve unit 130b.

The second open / close valve unit 130b is installed such that the second reference pipe 151, the second a branch pipe 152, the second b branch pipe 153, and the second c branch pipe 154 are connected to each other.

The second opening / closing valve unit 130b may be any one of the second a branch pipe 152, the second b branch pipe 153, and the second c branch pipe 154 by the control signal of the controller 180. A valve for selectively opening or closing the second reference pipe 151, the second a-branch pipe 152, the second b-branch pipe 153, and the second c-branch pipe 154 to be connected to 151.

The second opening / closing valve unit 130b blocks the discharge of the water from the measuring tank 114 while closing when the water enters the measuring tank 114. When the dissolved oxygen concentration measurement is completed in the dissolved oxygen concentration measuring unit 170, the second opening / closing valve unit 130b is connected to the second reference pipe any one second branch pipe, according to the control signal of the controller, It is selectively opened and closed.

On the other hand, the controller 180 is connected to any one of the plurality of tanks (111 ~ 113) and the measuring tank 114 in sequence so that the water in the plurality of tanks are sequentially stored in the measuring tank 114, the first pump (161) And the first opening / closing valve unit 130a and controlling the dissolved oxygen concentration measuring unit 170 to measure the dissolved oxygen concentration of the water sequentially stored in the measuring tank 114.

When the water level is measured by the water level sensor 190, the controller 180 stops the operation of the first pump 161 and closes the first opening / closing valve unit 130a so that the inflow of water into the measuring tank 114 is blocked. To control.

 The controller 180 calculates the amount of water stored in the measurement tank 114 from the water level. The controller 180 calculates a discharge time required for discharging all the water stored in the measurement tank 114 from the discharge amount discharged per hour when the measurement tank 114 is opened.

The controller 180 controls the opening and closing of the second opening / closing valve unit 130b so that the water stored in the measuring tank returns to the original tank again. For example, if the water stored in the measuring tank is the water of the first tank, the water stored in the measuring tank 114 is stored in the first tank 111 again, so that the water of the measuring tank 114 is the first tank. In order to flow to the 111, the controller 180 controls the operation of the second open / close valve unit 130b. The controller 180 controls the on / off operation of the oxygen supply unit according to the dissolved oxygen concentration measured in the measurement tank.

Hereinafter, an operating state of the dissolved oxygen concentration measuring system according to an embodiment of the present invention will be described with reference to FIGS. 3A to 5B.

3A is a view for explaining the flow of water from the first tank to the measuring tank 114 to measure the dissolved oxygen concentration of the first tank 111 in the measuring tank 114, Figure 3b is the dissolved oxygen concentration It is a figure for demonstrating the process returning to a 1st tank after measuring in a measuring tank.

Referring to FIG. 3A, the first opening / closing valve unit 130a is selectively opened such that the first a branch pipe 142 is connected to the first reference pipe 141 according to a control signal of the controller. At this time, the first b branch pipe 143 and the first c branch pipe 144 are disconnected from the first reference pipe 141 by the first open / close valve unit 130a. At this time, the second opening and closing valve unit 130b is operated to close the second reference pipe 151, and the second pump 162 is in an operation stop state.

When the first pump 161 is operated, water in the first water tank 111 is discharged from the first water tank 111 through the first a branch pipe 142, and the measurement water tank through the first reference pipe 141 ( 114). The flow of water in the first tank 111 follows F1a.

The water of the first tank 111 is stored in the measurement tank 114. When water is detected by the water level sensor 190, the operation of the first pump 161 is stopped, and the first opening / closing valve part 130a is operated to close the first reference pipe 141.

The dissolved oxygen concentration measuring unit 170 measures the dissolved oxygen concentration of the water stored in the measuring tank 114. The dissolved oxygen concentration of the measured first tank 111 is provided to the controller 180.

As shown in FIG. 3B, the water discharged from the measuring tank 114 flows to the first tank 111 according to the F1b flow. At this time, the second open / close valve unit 130b is operated to connect the second reference pipe 151 and the second a branch pipe 152 according to the control signal of the controller. In this case, the second b branch pipe 153 and the second c branch pipe 154 are disconnected from the second reference pipe 151 by the second open / close valve unit 130b.

In addition, the controller 180 controls the on / off operation of the first oxygen supply unit 121 according to the dissolved oxygen concentration of the water in the first tank 111. The operating time of the first oxygen supply unit 121 varies depending on the dissolved oxygen concentration.

4A is a view for explaining the flow of water in the first tank to the measuring tank 114 to measure the dissolved oxygen concentration of the second tank 112 in the measuring tank 114, Figure 4b is the dissolved oxygen concentration It is a figure for demonstrating the process returning to a 1st tank after measuring in a measuring tank.

Referring to FIG. 4A, the first opening / closing valve unit 130a may be selectively opened to connect the first b branch pipe 143 to the first reference pipe 141 according to a control signal of the controller. At this time, the first a branch pipe 141 and the first c branch pipe 144 is disconnected from the first reference pipe 141 by the first opening and closing valve 130a. At this time, the second opening and closing valve unit 130b is operated to close the second reference pipe 151, and the second pump 162 is in an operation stop state.

When the first pump 161 is operated, the water in the second water tank 112 is discharged from the second water tank 112 through the first branch pipe 143, the measurement tank (1) through the first reference pipe 141 ( 114). The flow of water in the second tank 112 follows F2a.

The water of the second tank 112 is stored in the measurement tank 114. When water is detected by the water level sensor 190, the operation of the first pump 161 is stopped, and the first opening / closing valve part 130a is operated to close the first reference pipe 141.

The dissolved oxygen concentration measuring unit 170 measures the dissolved oxygen concentration of the water stored in the measuring tank 114. The measured dissolved oxygen concentration of the second bath 112 is provided to the controller 180.

As shown in FIG. 4B, the water discharged from the measuring tank 114 flows to the second tank 112 according to the F2b flow. At this time, the second open / close valve unit 130b is operated to connect the second reference pipe 151 and the second b branch pipe 153 according to the control signal of the controller. At this time, the second a branch pipe 152 and the second c branch pipe 154 is disconnected from the second reference pipe 151 by the second opening and closing valve 130b.

In addition, the controller 180 controls the on / off operation of the second oxygen supply unit 122 according to the dissolved oxygen concentration of the water in the second tank 112. The operating time of the second oxygen supply unit 122 varies depending on the dissolved oxygen concentration.

5A is a view for explaining the flow of water from the first tank to the measuring tank 114 to measure the dissolved oxygen concentration of the third tank 113 in the measuring tank 114, Figure 5b is the dissolved oxygen concentration It is a figure for demonstrating the process returning to a 1st tank after measuring in a measuring tank.

Referring to FIG. 5A, the first opening / closing valve unit 130a is selectively opened such that the first c branch pipe 144 is connected to the first reference pipe 141 according to a control signal of the controller. In this case, the first a branch pipe 141 and the first b branch pipe 143 are disconnected from the first reference pipe 141 by the first open / close valve unit 130a. At this time, the second opening and closing valve unit 130b is operated to close the second reference pipe 151, and the second pump 162 is in an operation stop state.

When the first pump 161 is operated, the water in the third tank 113 is discharged from the third tank 113 through the first c branch pipe 144, the measurement tank (141) through the first reference pipe (141) 114). The flow of water in the third tank 113 follows F3a.

The water of the third tank 113 is stored in the measurement tank 114. When water is detected by the water level sensor 190, the operation of the first pump 161 is stopped, and the first opening / closing valve part 130a is operated to close the first reference pipe 141.

The dissolved oxygen concentration measuring unit 170 measures the dissolved oxygen concentration of the water stored in the measuring tank 114. The measured dissolved oxygen concentration of the third bath 113 is provided to the controller 180.

As shown in FIG. 5B, the water discharged from the measuring tank 114 flows to the third tank 113 according to the flow of F3b. At this time, the second open / close valve unit 130b is operated to connect the second reference pipe 151 and the second c branch pipe 154 according to the control signal of the controller. In this case, the second a branch pipe 152 and the second b branch pipe 153 are disconnected from the second reference pipe 151 by the second open / close valve unit 130b.

In addition, the controller 180 controls the on / off operation of the second oxygen supply unit 122 according to the dissolved oxygen concentration of the water in the third tank 113. The operating time of the second oxygen supply unit 122 varies depending on the dissolved oxygen concentration.

The present invention performs the process shown in Figures 3 to 5 sequentially and repeatedly, through a single dissolved oxygen concentration measuring unit 170 installed in the measuring tank 114, a plurality of tanks (111, 112, 113) The dissolved oxygen concentration of) can be measured.

For this reason, compared with the oxygen supply system of the conventional fish and shellfish farm, the present invention reduces the installation number of the dissolved oxygen concentration measuring unit 170 to 1 / N, the equipment cost consumed to measure the dissolved oxygen amount of each tank Can be significantly reduced, and the economic utility is large.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

100: dissolved oxygen concentration measuring system
111, 112, 113: Multiple Tanks
114: measuring tank 121, 122, 123: oxygen supply unit
130a: first open / close valve section 130b: second open / close valve section
141: first standard piping 142: first branch piping
143: branch 1b piping 144: branch 1c piping
151: second standard piping 152: branch 2a piping
153: branch 2b branch pipe 154: branch 2b branch pipe
161: first pump 162: second pump
170: dissolved oxygen concentration measurement unit 180: control unit
190: water level sensor

Claims (5)

A plurality of tanks in which fish or shellfish are accommodated;
Measuring tank;
Dissolved oxygen concentration measuring unit for measuring the dissolved oxygen concentration of the water stored in the measuring tank;
A first pipe part having one end connected to an inlet of the measuring tank and the other end being branched to each of the outlets of the plurality of tanks;
A first opening / closing valve unit selectively connecting any one of the measuring tank and the plurality of tanks;
A first pump for flowing water of any one of the plurality of tanks into the measurement tank according to the operation of the first opening / closing valve unit; And
One of the plurality of tanks and the measuring tank are sequentially connected to control the first pump and the first opening / closing valve unit to sequentially store water in the plurality of tanks in the measuring tank, and sequentially to the measuring tank. Dissolved oxygen concentration measurement system comprising a control unit for controlling the dissolved oxygen concentration measuring unit to measure the dissolved oxygen concentration of the water stored in the. The method of claim 1,
A second pipe part of which one end is connected to the outlet of the measuring tank and the other end thereof is branched and connected to the inlets of the plurality of tanks, respectively; And
And a second open / close valve unit for selectively connecting any one of the measuring tank and the plurality of tanks when discharging the water of the measuring tank. The method of claim 2,
And a second pump for flowing the water of the measuring tank into any one of the plurality of tanks according to the operation of the second opening / closing valve unit. The method of claim 2,
The measuring tank is located above in the gravity direction than the plurality of tanks;
Dissolved oxygen concentration measuring system, characterized in that the water in the measuring tank can flow by gravity to the corresponding tank in accordance with the operation of the second opening and closing valve. The method of claim 2,
The measuring tank is further provided with a water level sensor for measuring the level of water stored in the measuring tank to provide to the control unit,
The control unit,
When the water level of the water is measured by the water level sensor, the amount of water stored in the measuring tank is calculated from the water level,
By calculating the discharge time required to discharge all the water stored in the measuring tank from the discharge amount per hour when the measuring tank is opened,
And selectively opening the second opening / closing valve to allow the water of the measuring tank to flow into the corresponding tank during the discharge time.

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