KR20090007110A - Control system of water tank for live fish - Google Patents

Abstract

A control system of a live fish water tub is provided, which maintains the proper salinity according to the kind of the live fish and sustains the freshness of the live fish. A control system of a live fish water tub comprises: a salinity detection sensor(14) sensing the salinity of the live fish water in the inner one side of the water tub(1); a cloudiness detection sensor(15) sensing the cloudiness of the live fish water; second and eighth solenoid valves supplying the fresh water and seawater to the mixer(4) independently; a filter(10) purifying the live fish water through a seventh solenoid valve(27); a second pump(32) which forcibly circulates the live fish water flowed in the water tub; and a control unit(50) maintaining the live fish water salinity of the water tub at the fixed level.

Description

Control system of live tanks

The present invention relates to a control system of live fish tanks for maintaining freshness of live fish in medium and large tanks, such as aquaculture farms and sashimi. It is automatically maintained by the turbidity detection sensor, and when the livestock water introduced into the tank becomes turbid below a certain level, it is forced to circulate through the filter and purified to maintain proper salinity according to the type of live fish. In case of accommodating live fish, the present invention relates to a control system of a live fish tank, which not only provides optimal growth conditions according to fish species, but also maintains fresh water quality by maintaining high quality water.

In general, live fish refers to fish that are kept alive for food. In recent years, due to the development of the food service industry and the increase of costs associated with live fish transportation, most farms or sushi houses have a relatively narrow space. It is a business that adopts a form in which a large amount of live fish is stored in a high density in a live fish tank to be formed, and then fresh fish are sold when needed.

When a large amount of live fish is stored in a high density inside the live fish tank forming a narrow space as described above, dissolved oxygen contained in the live fish is rapidly consumed, and various foreign substances or proteins are removed by the food and excreta of the live fish. Ammonia and nitrogen are accumulated in live fish at high concentration in a short time, which causes the water quality of live fish to deteriorate rapidly, which not only affects the growth condition and freshness of live fish, but also causes severe death It causes a situation.

In addition, if the essential devices used to maintain the freshness of the live fish, such as oxygen supply, water temperature control device, and filtration device, sudden power failure or failure occurs, the manager can not check during the late night time The system of collective management and operation of live fish tanks has been proposed by the Korean Utility Model Registration No. 204966 (Registration Date: September 19, 2000) and Utility Model Registration No. 350037 (Registration Date: April 29, 2004). It has been.

That is, Figure 1a is a control system configuration of a conventional fish tank, the water level sensor 11 for generating a signal proportional to the water level of the live fish on one side of the tank (1), and senses the concentration of oxygen and proportional to it Oxygen detection sensor 12 for generating a signal and a temperature sensor 13 for detecting a water temperature of the live fish water and generates a signal proportional thereto is provided, the first installed outside the lower surface of the water tank (1) Live fish water is discharged to the outside through the solenoid valve 21.

In addition, a fresh water storage tank (2) for storing fresh water and a seawater storage tank (3) for storing seawater containing salt, the water introduced into the fresh water and seawater storage tank (2) (3) is a second solenoid After entering the mixer 4 through the valve 22, it is supplied to the hot water heater 5 and the cold water heater (6).

The hot and cold water through the hot water heater 5 and the cold water heater 6 are supplied to the water tank 1 through the third to fifth solenoid valves 23, 24, 25 and the first pump 31, respectively. , Oxygen generated by the oxygen tank 7 and the oxygen generator 8 is supplied to the water tank 1 through the sixth and fifth solenoid valves 26 and 25, and the state of the water tank 1 is displayed as an image. Surveillance camera 9 to be transmitted has a structure that is connected to the control unit 50.

1B is a block diagram of a control system of a conventional live fish tank, and a signal transmission unit for concentrating and transmitting an analog signal, which is an input signal, on an output side of the water level sensor 11, the oxygen sensor 12, and the temperature sensor 13; 51 is connected, the output terminal of the signal transmission unit 51 through the drive 53, the oxygen, according to the output information of the water level sensor 11, oxygen sensor 12, temperature sensor 13 The first to sixth solenoid valves 21, 22, 23, 24, 25, 26 and the hot and cold water coolers 5, 6, and the first pump A micro process unit (hereinafter referred to as 'MPU') 54 that controls 31 is connected.

In addition, an SMS / ARS processing unit 56 which bidirectionally communicates with the MPU 54 through an image processing unit 55 is connected to the output side of the surveillance camera 9, and a system error is output to the output side of the SMS / ARS processing unit 56. CDMA terminal 57 for notifying an administrator of an abnormal condition by text and voice through a mobile phone and a phone is connected, and an alarm 52 for transmitting an alarm sound when a system error occurs is connected to the other output terminal of the MPU 54. It is composed.

Referring to the operation of the control system of the conventional live fish tank as described above are as follows.

First, the process of supplying the live fish water to the water tank 1 at a constant level, when instructing the live fish water supply command to the water tank 1 through an operation unit not shown, the second to fifth solenoid valves (MPU) 54 ( 22) (23) (24) (25) is opened and the first pump 31 is driven at the same time, so that fresh water and seawater introduced into the freshwater reservoir 2 and the seawater reservoir 3 are connected to the second solenoid valve ( It is discharged through 22 and introduced into the mixer 4 to mix fresh water and seawater, and then simultaneously supplied to the water heater 5 and the cold water heater 6.

The live fish water introduced into the hot water heater 5 and the cold water heater 6 is discharged through the third and fourth solenoid valves 23 and 24 while maintaining a constant temperature, and is pumped by the first pump 31. It flows into the water tank 1 via the 5th solenoid valve 25.

Through the above process, the water level of the live fish continuously introduced into the water tank 1 is detected by the water level sensor 11 and outputs a signal proportional to the water level, and this water level signal is transmitted through the signal transmission unit 51. As it transmits to the MPU 54, the MPU 54 reads and calculates the information of the water level sensor 11 and reads the water level. When it is recognized that the read water level has reached a predetermined level, the second to the fifth By closing the solenoid valves 22, 23, 24, 25 and stopping the driving of the first pump 31, the water level in the tank 1 is always maintained.

In addition, the water temperature and oxygen concentration of the live fish water introduced into the water tank 1 by the temperature sensor 13 and the oxygen sensor 12 is constantly maintained at all times.

That is, the temperature sensor 13 senses the water temperature of the live fish water introduced into the water tank 1 and outputs a signal proportional thereto. The water temperature signal is transmitted to the MPU 54 through the signal transmission unit 51. As it transmits, the MPU 54 reads and calculates information of the temperature sensor 13 to read the water temperature. When the read water level is below or exceeds the set temperature, the first pump 31 is driven and driven. The solenoid valve 25 is opened, and the third and fourth solenoid valves 23 and 24 are selectively opened to selectively supply hot water or cold water to the water tank 1 to flow into the water tank 1. The water temperature of the live fish is always kept constant.

The oxygen sensor 12 senses the oxygen concentration remaining in the live fish water introduced into the water tank 1 and outputs a signal proportional thereto. The water temperature signal is transmitted to the MPU 54 through the signal transmission unit 51. The MPU 54 reads and calculates the information of the oxygen sensor 12 to read the oxygen concentration. When the read oxygen concentration falls below or exceeds the set range, the sixth and fifth solenoid valves are transmitted. By opening and closing (26) and (25), the oxygen supplied from the oxygen tank 7 and the oxygen generator 8 is supplied to and blocked by the water tank 1, thereby maintaining a constant oxygen concentration in the water tank 1.

Meanwhile, the peripheral image of the tank 1 photographed by the surveillance camera 9 is transmitted to the SMS / ARS processing unit 56 via the image processing unit 55, and the MPU 54 at the time of power failure or the water tank management system. Control the SMS / ARS processing unit 56 in case of a malfunction of the alarm through the CDMA terminal 57 and alerts the administrator 52 a text or voice related to the video and alarm of the surveillance camera 9 as a mobile phone or telephone. It will inform you that it is abnormal by driving.

In the conventional fish tank control system as described above, the water level, temperature, and oxygen concentration in the tank are properly maintained, but not only the salinity that can contribute to the activity and freshness of the fish can be kept constant, but also the excretion of the fish If the live fish is turbid by the turbidity there is no automatic filtering device there is a problem that brings down the reliability of the live fish tank.

In particular, when various kinds of live fish such as marine fish and freshwater fish are inhabited in each tank, the salinity that can maintain the optimum freshness for each fish species is different, and such salinity plays a decisive role in maintaining the activity and freshness of live fish Therefore, a device for automatically adjusting salinity of each tank and a device for filtering live fish at an appropriate time are required.

The present invention is to install the salinity detection sensor and turbidity sensor in the tank in the medium and large tanks, such as aquaculture farm and sashimi to automatically maintain the salinity of live fish water introduced into the tank by the salinity detection sensor at the appropriate level and at the same time turbidity detection If the live fish flows into the tank by the sensor to become below a certain level, it can be circulated through the filter and purified to maintain proper salinity according to the type of live fish. It is a technical task to not only provide optimal growth conditions but also to maintain fresh water quality by maintaining high quality water quality.

The present invention is a water level sensor, an oxygen sensor, a temperature sensor is installed on one side of the tank in which the live fish flows, a mixer is installed between the fresh water reservoir and the seawater reservoir via a second solenoid valve, the other side of the mixer The water heater and cold water machine are installed to supply live fish water to the water tank through the third to fifth solenoid valves and the first pump, supply oxygen to the water tank from the oxygen tank and the oxygen generator, and control the live fish water in the water tank under the control of the control unit. In the live fish tank control system to maintain a constant water level and temperature and oxygen concentration, and to notify the administrator through the mobile phone or phone text or voice related to the image information and alarm in case of power failure and abnormality, the live fish water flows in Salinity detection sensor that senses the salinity of live fish on one side of the tank and generates a signal proportional to it; A turbidity sensor for sensing turbidity of water and generating a signal proportional thereto is installed, and second and eighth solenoid valves for supplying fresh water and seawater independently to the mixer are installed at the other side of the freshwater storage tank and the seawater storage tank, respectively. And a filter for purifying live fish water through a seventh solenoid valve at a lower side of the tank, and a second pump for forcibly circulating live fish water introduced into the water tank is installed between the filter and the mixer. The second and eighth solenoid valves are controlled as the output signal of the salinity detection sensor to maintain the salinity of the live fish in the tank at a constant level, and the control unit controls the seventh solenoid valve and the second pump as the output signals of the turbidity detection sensor. By controlling the turbidity is characterized in that even below a certain level.

The present invention by installing a salinity detection sensor and turbidity detection sensor in the tank in the medium and large tanks, such as aquaculture farm and sashimi automatically maintains the salinity of live fish water introduced into the tank by the salinity detection sensor to the appropriate level and at the same time When the live fish flows into the tank by turbidity detection sensor below a certain level, it is forced to circulate through the filter and purified to maintain proper salinity according to the type of live fish. According to the optimum growth conditions can be given, as well as maintaining the quality of the water can maintain the freshness of the live fish.

Hereinafter, a control system of a live fish tank according to the present invention will be described in detail with reference to FIGS. 2A and 2B.

2A is a configuration diagram of a control system of a live fish tank according to the present invention, and a level sensor 11 for generating a signal proportional to the level of the live fish water on one side of the water tank 1, and senses the concentration of oxygen thereon Oxygen detection sensor 12 for generating a proportional signal, temperature sensor 13 for sensing the water temperature of the live fish water and generates a signal proportional thereto, and salinity of the live fish water is sensed to generate a signal proportional thereto A salinity detection sensor 14 and a turbidity detection sensor 15 for sensing a turbidity of the live fish and generating a signal proportional thereto are installed, and a first solenoid valve 21 installed outside the lower surface of the water tank 1. ) Is to discharge live fish to the outside.

In addition, a fresh water storage tank (2) for storing fresh water and a seawater storage tank (3) for storing seawater containing salts is provided, and the other side of the fresh water and seawater storage tank (2) (3) is provided with seawater and fresh water After entering the mixer 4 through the second and eighth solenoid valves 22 and 28, respectively, the second and eighth solenoid valves 22 and 28 are supplied to the water heater 5 and the cold water machine 6, respectively. The salinity of the mixer 4 is adjusted according to the degree of opening.

The hot and cold water through the water heater (5) and the cold water heater (6) is a water tank (3) through the third, fourth solenoid valves (23), 24, the first pump (31) and the fifth solenoid valve (25), respectively. 1), the oxygen generated by the oxygen tank 7 and the oxygen generator 8 is supplied to the water tank 1 through the sixth and fifth solenoid valves 26, 25, the water tank (1) Surveillance camera 9 for transmitting the state of the image is connected to the control unit 50.

In addition, the lower end of the water tank 1 is provided with a filter 10 for removing and purifying the foreign matter of the live fish through the seventh solenoid valve 27, the live fish water between the filter 10 and the mixer (4) A second pump 32 forcibly circulated for purification is configured.

Figure 2b is a block diagram of the control system of the live fish tank according to the present invention, the water level sensor 11, oxygen sensor 12, temperature sensor 13, salinity sensor 14, turbidity sensor 15 Is connected to a signal transmission unit 51 for focusing and transmitting the output signal of each sensor, and the output level of the signal transmission unit 51 through the drive 53 through the level sensor 11, oxygen detection First to eighth solenoid valves for adjusting oxygen, hot / cold water, supplementary water supply and salinity according to the output information of the sensor 12, the temperature sensor 13, the salinity sensor 14, and the salinity sensor 14 (21) (22) (23) (24) (25) (26) (27) (28) and hot / cold water (5) (6) and the first and second pumps (31) (32) The controlling MPU 54 is connected.

In addition, an SMS / ARS processing unit 56 which bidirectionally communicates with the MPU 54 through an image processing unit 55 is connected to the output side of the surveillance camera 9, and a system error is output to the output side of the SMS / ARS processing unit 56. CDMA terminal 57 for notifying an administrator of an abnormal condition by text or voice through a mobile phone or a phone is connected to the manager, and an alarm 52 for transmitting an alarm sound when a system error occurs is connected to the other output terminal of the MPU 54. It is composed.

Referring to the operation of the conventional live fish tank control system according to the present invention made as described above are as follows.

First, the process of supplying live fish water to the water tank 1 at a constant level may be performed by the MPU 54 when the manager issues a fresh water supply command to the water tank 1 through an operation unit (not shown). 8 Fresh water flowing into freshwater reservoir (2) and seawater reservoir (3) by opening the solenoid valves (22), (23), (24), (25) and (28) and driving the first pump (31). And the seawater are discharged through the eighth and second solenoid valves 28 and 22 and introduced into the mixer 4 to mix fresh water and seawater, and then simultaneously supplied to the water heater 5 and the cold water heater 6, respectively. .

The live fish water introduced into the hot water heater 5 and the cold water heater 6 is discharged through the third and fourth solenoid valves 23 and 24 while maintaining a constant temperature, and is pumped by the first pump 31. It flows into the water tank 1 via the 5th solenoid valve 25.

Through the above process, the water level of the live fish continuously introduced into the water tank 1 is detected by the water level sensor 11 and outputs a signal proportional to the water level, and this water level signal is transmitted through the signal transmission unit 51. As it transmits to the MPU 54, the MPU 54 reads and calculates the information of the water level sensor 11 and reads the water level. When it is recognized that the read water level has reached a predetermined level, the second to the fifth By closing the eighth solenoid valves 22, 23, 24, 25, 28 and stopping the driving of the first pump 31, the tank 1 always maintains a constant level of live fish. Will be.

In addition, the temperature sensor 13, the oxygen sensor 12, the salinity detection sensor 14 to maintain a constant water temperature, oxygen concentration, salinity of live fish water introduced into the water tank (1) at all times.

That is, the temperature sensor 13 senses the water temperature of the live fish water introduced into the water tank 1 and outputs a signal proportional thereto. The water temperature signal is transmitted to the MPU 54 through the signal transmission unit 51. As it transmits, the MPU 54 reads and calculates information of the temperature sensor 13 to read the water temperature. When the read water level is below or exceeds the set temperature, the first pump 31 is driven and driven. 5 The solenoid valve 25 is opened and the third and fourth solenoid valves 23 and 24 are selectively opened to selectively supply hot water or cold water to the water tank 1 to flow into the water tank 1. The water temperature of the live fish is always kept constant.

This process is repeated until the temperature value sensed by the temperature sensor 13 reaches a set level.

The oxygen sensor 12 senses the oxygen concentration remaining in the live fish water introduced into the water tank 1 and outputs a signal proportional thereto. The water temperature signal is transmitted to the MPU 54 through the signal transmission unit 51. The MPU 54 reads and calculates the information of the oxygen sensor 12 to read the oxygen concentration. When the read oxygen concentration falls below or exceeds the set range, the sixth and fifth solenoid valves are transmitted. By opening and closing (26) and (25), the oxygen supplied from the oxygen tank 7 and the oxygen generator 8 is supplied to and blocked by the water tank 1, thereby maintaining a constant oxygen concentration in the water tank 1.

This process is repeated until the oxygen concentration value sensed by the oxygen sensor 12 reaches a set level.

The salinity detection sensor 14 senses the salinity remaining in the live fish water introduced into the water tank 1 and outputs a signal proportional thereto. The salinity signal is transmitted to the MPU 54 through the signal transmission unit 51. As the transmission, the MPU 54 reads and calculates the salinity of the salinity sensor 14 by reading and calculating the salinity, and when the salinity of the read freshwater falls below or exceeds the set range, the second and eighth solenoid valves. By selectively opening and closing the (22) and (28) to adjust the amount of fresh water and seawater supplied to the mixer (4) to maintain a constant salinity in the water tank (1).

The turbidity sensor 15 senses the turbidity of the live fish introduced into the tank 1 and outputs a signal proportional thereto. The turbidity signal is transmitted to the MPU 54 through the signal transmitter 51. Therefore, the MPU 54 reads and calculates the information of the turbidity sensor 15 to calculate turbidity, and when the turbidity of the read fish is greater than the set range, the third to fifth and seventh. The solenoid valves 23, 24, 25 and 27 are opened and the first and second pumps 31 and 32 are driven.

Therefore, the live fish water introduced into the water tank 1 is purified by filtering the feed, excreta, various foreign substances, etc. of the live fish existing in the water tank 1 through the filter 10 by the second pump 32, and then the mixer. (4) and then into the water tank (1) through the hot and cold water (5) (6) and the third to fifth solenoid valves (23) (24) (25) and the first pump (31). This circulation process is repeated until the turbidity value sensed by the turbidity sensor 15 falls below a set level.

In the present invention, the water level sensor 11 is a conventional one for controlling the water level by receiving a limiter switch contact signal using an object having buoyancy in the water tank, or adjusting the water level by energizing a plurality of electrodes, and is sold on the market. Detailed configuration and operation description will be omitted.

The oxygen sensor 12 measures a signal from oxygen that diffuses into the solution through an impregnation with a gold plate on the cathode, a platinum plate on the anode, and an electrode coated with a film of Teflon or polyethylene having good permeability on the anode. By using the diaphragm oxygen electrode method for detecting dissolved oxygen, which is commercially available, and detailed configuration and operation description thereof are omitted.

The temperature sensor 13 is a sensor having a resolution of 0.1 ° or less, and outputs a voltage value of 10 mV at 1 ° and amplifies it at an appropriate ratio, and the salinity detection sensor 14 is included in seawater. It is common to use the conductivity measurement method to measure by using the point that the electrical conductivity is different depending on the amount of salinity and is sold on the market, and detailed configuration and operation description are omitted.

In addition, the output of the oxygen sensor 12, the temperature sensor 13, the salinity sensor 14, the turbidity sensor 15 is 10 bits (bit :) to the MPU 54 with an A / D converter 1024) resolution is used as a control value to improve the precision.

Meanwhile, the peripheral image of the tank 1 photographed by the surveillance camera 9 is transmitted to the SMS / ARS processing unit 56 via the image processing unit 55, and the MPU 54 at the time of power failure or the water tank management system. In response to the SMS / ARS processing unit 56 controlling the SMS / ARS processing unit 56, the alarm 52 is simultaneously notified to the administrator as a mobile phone or a text or voice related to the video and alarm of the surveillance camera 9 through the CDMA terminal 57. It will inform you that it is abnormal by driving.

Figure 1a is a block diagram of a conventional live fish control system.

Figure 1b is a control system block diagram of a conventional live fish tank.

Figure 2a is a block diagram of a control system of a live fish tank according to the present invention.

Figure 2b is a control system block diagram of a live fish tank according to the present invention.

[Description of Symbols for Major Parts of Drawing]

1: tank 2: freshwater reservoir

3: seawater reservoir 4: mixer

5: water heater 6: cold water heater

7: oxygen tank 8: oxygen generator

9: surveillance camera 10: filter

11: water level sensor 12: oxygen sensor

13: Temperature sensor 14: Salinity sensor

15: Turbidity sensor

21-27: 1st-7th solenoid valve

31 ~ 32: 1st, 2nd pump 50: Control part

51: signal transmission unit 52: alarm

53: drive 55: image processor

56 SMS / ARS processing unit 57: CDMA terminal

Claims (1)

A water level sensor 11, an oxygen sensor 12, and a temperature sensor 13 are installed at one side of the water tank 1 into which the live fish water is introduced, and is disposed between the fresh water storage tank 2 and the seawater storage tank 3. The mixer 4 is installed through the two solenoid valves 22, and the water heater 5 and the cold water heater 6 are installed at the other side of the mixer 4 so that the third to fifth solenoid valves 23 and the first are installed. The live fish water is supplied to the water tank 1 through the pump 31, oxygen is supplied to the water tank 1 from the oxygen tank 7 and the oxygen generator 8, and the control part 50 controls the water tank ( 1) In the control system of the live fish tank, which maintains the constant water level, temperature, oxygen concentration in the live fish water, and informs the administrator through the mobile phone or phone the text or voice related to the video information and alarm in case of power failure or abnormality. , The salinity detection sensor 14 for sensing the salinity of the live fish water on one side of the inside of the tank (1) into which the live fish water flows and a signal proportional thereto by sensing the turbidity of the live fish water Turbidity sensor 15 is installed, On the other side of the fresh water storage tank (2) and the seawater storage tank (2) (3), second and eighth solenoid valves (22, 28) for supplying fresh water and seawater independently to the mixer (4) are installed, respectively, A filter 10 for purifying live water through the seventh solenoid valve 27 is installed below the water tank 1, Between the filter 10 and the mixer 4, a second pump 32 for forcibly circulating live fish water introduced into the water tank 1 is installed, The control unit 50 controls the second and eighth solenoid valves 22 and 28 as the output signal of the salinity detection sensor 14 to maintain the freshwater salinity of the water tank 1 at a constant level. Live fish characterized in that the control unit 50 to maintain the turbidity below a certain level by controlling the seventh solenoid valve 27 and the second pump 32 as the output signal of the turbidity sensor 15 Tank control system.

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