KR102607502B1 - Automatic salinity mixing device - Google Patents

Abstract

The present invention discloses a smart food organism culture system.
The automatic salinity control sensor of the present invention is equipped with a configuration such as a sensor rod, a solenoid valve, and an automatic water level controller, and according to the organic operating state of this configuration, when the salinity in the tank falls below 25% set in the sensor, the solenoid is activated by the sensor. The valve power is cut off and the specific gravity is automatically adjusted. A hose is connected to the 25% seawater tank drain line and supplied to the culture tank. Culture water is prepared without salt. A hose is connected to the 25% seawater tank drain line and the high density culture tank is automatically operated. When connected to the water level control device, 25% of supplementary water is delivered. By applying smart aquaculture technology to cultivating feed organisms for seed-produced fish, manpower savings can be expected, which is an advantage that greatly contributes to creating a stable feed organism culture environment. There is.

Description

Smart food biological culture system {Automatic salinity mixing device}

The present invention relates to a smart food culture system for reducing the manpower required to maintain 25% of the salinity of seawater among the food culture elements required for seed production.

Among the feeding elements necessary for seed production, it is very important to maintain seawater salinity at 25%.

In order to maintain 25% of the culture water or supplemental water required for cultivating food organisms, manpower consumption is required. However, if the smart food culture system is applied, it is expected to have a significant impact on the unit cost of aquaculture production because there is no manpower consumption.

In conventional fish farms, the culture water is made with a salinity of 25%, and the process of receiving a certain amount of seawater, mixing it with fresh water, checking the specific gravity, and turning off the fresh water when it reaches 25% is repeated several times every day. If you adjust the salinity concentration manually like this, it takes 2 to 3 hours a day to create 25% salinity seawater. In addition, even in rotifer high-density culture, supplementary water must be made up to 25%, so labor consumption is unavoidable.

In order to use seawater that changes depending on seasonal rainfall and coastal water flowing in from the land as breeding water for aquaculture tanks, a first pipe for intake and supply of seawater from the sea is formed on one side of the first pipe. It is equipped with a valve capable of controlling the inflow flow rate and a first salinity sensor, and consists of a central processing device capable of controlling the opening and closing of the valve by receiving the measured value of the first salinity sensor; Measures the salinity concentration of seawater flowing into the aquaculture tank through a configuration consisting of a second pipe for supplying fresh water, a flow control valve formed on one side of the second pipe, and a supply pipe connecting the first and second valves. By operating seawater and freshwater pipes and valves based on the measured salinity concentration of seawater, it is possible to easily control the concentration by mixing breeding water with a certain salinity concentration with freshwater even if the salinity concentration of seawater changes depending on the visibility and season. An invention has been proposed that can reduce the manpower and costs required to supply breeding water and enable intensive, high-density aquaculture by stably supplying seawater of a certain concentration.

KR registered patent 10-1423300 (registered on 2014.07.18)

The purpose of the present invention is to maintain the salinity of seawater at 25% among the food culture elements necessary for seed production without using manpower.

A smart food organism culture system is disclosed to solve conventional problems.

According to the present invention, when the smart aquaculture system is applied, when seawater is consumed in the tank in real time, the water level is lowered, and when the water level is lowered, the seawater is automatically filled. In the process, when the salinity of the filled seawater is 25%, the sensor detects Power is connected to the solenoid valve and fresh water is replenished.

When the salinity in the tank falls below 25% set in the sensor, the solenoid valve power is cut off in the sensor and the specific gravity is automatically adjusted.

1 is a configuration diagram of a smart aquaculture system to which the present invention is applied;
Figure 2 is a schematic diagram of supplying a food culture tank to which the present invention is applied.
Figure 3 is a schematic diagram of supplying a rotifer high-density culture tank to which the present invention is applied.

Specific embodiments in which the present invention may be practiced are described below with reference to the accompanying drawings.

While these embodiments are described in sufficient detail to enable any person skilled in the art to practice the invention, it is to be understood that the various embodiments of the invention are different from one another but are not necessarily mutually exclusive.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings in order to enable those skilled in the art to easily practice the present invention.

Figure 1 shows the configuration of a smart aquaculture system to which the present invention is applied. The smart aquaculture system to which the present invention is applied is equipped with a tank 100 formed in a volume in which seawater is stored at a certain volume.
This tank 100 is equipped with a seawater supply pipe 200 at the top of the tank 100 that flows in from the outside and blocks it when filled to an appropriate capacity to maintain the water level in the seawater tank, and the inside of the tank 100 A sensor rod 300 is installed in the space to check the salinity concentration of seawater flowing into the tank 100.
In addition, a solenoid valve 400 is installed at the opposite location where the seawater supply pipe 200 is installed to allow external fresh water to flow into and block the tank 100.
The above sensor rod 300 and solenoid valve 400 are connected to the automatic control sensor 500 to maintain the salinity of seawater at 25%. When the salinity of seawater is checked to be above 25%, external fresh water is The automatic salinity control sensor 500, which sends an electrical signal that opens the inflow solenoid valve 400 and opens the seawater supply pipe 200 when the salinity concentration of the seawater is 25% or less, is installed in the tank 100. It is installed around .
Aeration 600 is installed to ensure that sufficient oxygen is contained in seawater that maintains a 25% salinity concentration supplied to the tank 100.

In this way, the salinity of seawater is maintained at 25% and is used as supplemental water for cultivating food organisms for seed-producing fish. The tank 100 contains supplemental water with the salinity of seawater maintained at 25%. In order to drain, a drain line hose 120 equipped with a valve pipe is provided, and supplemental water with a salt concentration of 25% is supplied to the food organism culture tank 800 through the drain line hose 120.

As shown in FIG. 1, when seawater is consumed in the tank 100 in real time, the water level is lowered, and when the water level is lowered, the seawater is automatically filled. If the salinity of the filled seawater is more than 25%, the automatic salinity control sensor 500 Power is connected to the solenoid valve 400 and fresh water is replenished. However, when the salinity in the tank 100 falls below 25% set in the automatic salinity control sensor 500 as shown in FIG. 1 due to the replenishment of fresh water, the power to the solenoid valve 400 is cut off in the automatic salinity control sensor 500. Since it closes at the same time, the inflow of fresh water is blocked, so the salinity of seawater in the tank 100 is automatically set to 25%.

Figure 2 shows the supply model state of a feed organism culture tank to which the present invention is applied, and Figure 3 shows the supply model state of a rotifer high-density culture tank to which the present invention is applied.
The tank 100 is connected to a drain line hose 120 equipped with a valve that drains and blocks supplementary sea water with a salinity of 25% of the sea water to the food culture tank 800, and the drain line hose is connected to the tank 100. (120) is connected to an automatic water level controller (820) for controlling the level of supplementary water of 25% concentration supplied to the food culture tank (800), and a support (700) is provided on the bottom of the tank (100). , the tank 100 is installed at a higher position than the food culture tank 800.

In this way, when the drain line hose 120 equipped with a valve pipe is connected to the tank 100 and supplemental water of seawater with a salinity concentration of 25% is supplied to the culture tank 800, culture water without salt is prepared, so manpower is required. does not occur, and culture water is formed quickly. In this way, when a lake is connected to the valve pipe 120 of the tank 100 and supplied to the culture tank 800, salt-free culture water is prepared, so no manpower is required, and culture water is quickly formed.
Preparation of culture water with a salinity of 25% of seawater according to the present invention involves the steps of 1) confirming the inflow of seawater, 2) when a certain amount of seawater flows in, it is blocked by a valve, and the seawater is injected in a certain amount of seawater. The salinity measurement step proceeds by measuring the salinity concentration. 3) If the salinity concentration is more than 25% through salinity measurement in the above salinity progress stage, a fresh water inflow signal is applied from the automatic salinity control sensor to the solenoid valve, and if the salinity concentration is less than 25%, a sea water inflow signal is applied to the sea water. The salt concentration maintenance step applied to the supply pipe proceeds. 4) Salt-free culture water is prepared in the supplementary water supply stage in which supplemental water with a salinity of 25% of the seawater filled in the tank is drained to the food culture tank through a drain line hose and the water level is blocked by an automatic water level controller.

According to the above configuration, salinity can be controlled through the salinity setting function of the automatic salinity control tank, the salinity of the automatic salinity control tank can be checked in real time, and the culture water or supplemental water can be set and maintained at the desired salinity.

In addition, since culture water with a certain salinity can be supplied within a short period of time, the manpower required to control seawater salinity is reduced by 100%.

The above-mentioned features are equipped with an automatic salinity control sensor, a sensor rod, a solenoid valve, and an automatic water level controller, and are sufficiently achieved in an organic operating state of this configuration.

The present invention can be expected to reduce manpower consumption by applying smart aquaculture technology to cultivating feed organisms for seed-producing fish, and greatly contributes to creating a stable environment for cultivating feed organisms.

Although embodiments of the present invention have been described above with reference to the attached drawings, the present invention is not limited to the above embodiments and can be manufactured in various different forms, and those skilled in the art will understand that the present invention is not limited to the above embodiments. It will be understood that the present invention may be implemented in other specific forms without changing its technical spirit or essential features.

Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive.

100: Tank 120: Drain line hose 200: Automatic water level regulator
300: Sensor rod 400: Solenoid valve 500: Automatic salinity control sensor
600: Aeration 800: Food culture tank 820: Rotifer high-density culture tank

Claims (3)

A tank having a volume in which a certain amount of seawater is stored;
A seawater supply pipe that allows external seawater to flow in and blocks it when filled to an appropriate capacity to maintain the water level in the tank;
A sensor rod that checks the salinity concentration of seawater flowing into the tank;
A solenoid valve that allows external fresh water to flow into and block the seawater tank;
An automatic salinity adjustment sensor connected to the sensor rod and solenoid valve so that the salinity concentration of seawater is maintained at 25% by supplying seawater and fresh water;
Aeration installed in the tank to supply oxygen to seawater;
A food culture tank that receives salt water with a salt concentration of 25% from the tank; including
In the tank,
A drain line hose equipped with a valve that drains and blocks seawater with a salinity concentration of 25% to the food culture tank;
An automatic water level controller provided in the hose and controlling the water level of seawater with a 25% salinity concentration filled in the food culture tank;
A smart food culture system, characterized in that it is installed on the bottom of the tank and consists of a stand that allows the tank to be installed at a higher position than the food culture tank.
delete Confirming that seawater flows into the tank;
When a certain amount of seawater flows into the tank, it is blocked by a seawater supply pipe and a salinity measurement step of measuring the salinity of the seawater in the certain amount of seawater;
By measuring salinity, if the salinity concentration is more than 25%, a freshwater inflow signal is applied from the automatic salinity control sensor to the solenoid valve, and if the salinity concentration is less than 25%, a seawater inflow signal is applied to the seawater supply pipe. ;
A smart food culture system consisting of a supplementary water supply step in which supplemental water with a salinity of 25% of the seawater filled in the tank is drained and supplied to the food organism culture tank through the drain line hose and is blocked by the automatic water level controller of the hose.