KR200204965Y1 - A aquarium control system. - Google Patents

Abstract

The present invention relates to a separate tank control device for automatically controlling the temperature, oxygen, etc. of each individual tank effectively and economically to maintain the freshness of the live fish.

To this end, the present invention comprises a controller for recognizing temperature, pressure, humidity, carbonic acid, and oxygen values and dividing a given environment into an arbitrary area (for example, a water tank) to automatically adjust to an environment individually set in each area; A state input / output unit which manually adjusts the setting value of the control area by means such as a key, and sequentially displays the control state by a method such as TFT, LCD, VFD, and voice at a predetermined time interval; A camera unit for visually displaying a state of the individual control region; A three-phase input unit used to check the supply voltage and converting the input voltage and current into mV or mA and sending it to the control unit; A sensor unit which senses temperature, pressure, carbonic acid, humidity, oxygen, an object, etc. and provides information to the control means; A power converter converting the input power into DC and supplying the power to each unit; Each individual tank is configured to include an automatic control unit for distributing the water cooled in the cooler.

Description

Individual Aquarium Control System {A Aquarium Control System.}

The present invention is designed to keep the optimum environment such as temperature and oxygen required for live fish transport vehicles constant through an automated system and to generate a predetermined alarm when an object is detected by a distance sensor. The present invention relates to a state maintenance and alarm device for temperature and oxygen for any environmental composition.

Generally, waiting time for a live fish transporter to enter sea water in a tank and to wait for various live fish (for example, squid in this design) to arrive at sea is at least 1-2 hours. It is well known that the temperature of the bath rises.

Therefore, in this situation, for the survival of the live squid, the sea water must be supplied with a certain amount of temperature, air, oxygen, etc. appropriately or continuously. This case is similarly applied to the process of purchasing and moving the squid locally. This is especially the cause of death of temperature-sensitive species such as squids during transportation.

Therefore, the driver and the merchant will drive excessively for transportation to the destination as soon as possible, while the dying squid will entangle with other surrounding squids, causing a vicious cycle leading to death continuously.

Therefore, the driver is inconvenient to check the tank in order to check the situation of the squid, which is often stopped and transported and transported during transportation. Supply is necessary, which is an excessive waste of oxygen, but can also cause death due to excess oxygen.

In addition, in a live fish storage or an aquarium, one cooler is operated for each tank. This is because each tank has a different set temperature, which is an excessive fuel cost.

In order to solve the above-mentioned general drawbacks, in the present invention live fish transport designed to be able to see the same effect with only a small horsepower cooler 100 that can also be driven by the inverter 620 in a live fish transport vehicle Its purpose is to provide a car and to cool all tanks in a single fish tank or aquarium with just one to two or three times as many chillers as normal chillers.

1 is an overall view of the present invention

2 is a detailed view of a controller

3 is a detailed view of the automatic adjustment unit

<Explanation of symbols on main parts of the drawing>

10.Control unit 20.State input / output unit

30. Automatic control unit 40. Sensor unit

50. Camera unit 60. Power conversion unit

70.Machine 80.Motor

100.Cooler 150.Air Comp

160.Oxygen Generator 90a.1 Tank

90b.2 water tank 90c.3 water tank

90d.4 water tank 110.central processing unit

120.I / O section 140.Data storage section

130. Control unit Power supply unit 210. Set value input unit

220.Display unit 310a.1 water tank discharge valve

310b.2 sump drain valve 310c.3 sump drain valve

310d.4 water tank outlet valve 320a.1 water tank inlet valve

320b.2 water tank inlet valve 320c.3 water tank inlet valve

320d.4 water tank inlet valve 330.Drain valve

340. Filling valve 350a.1 water tank air valve

350b.2 water tank air valve 350c.3 water tank air valve

350d.4 water tank air valve 360a.1 water tank oxygen valve

360b.2 water tank oxygen valve 360c.3 water tank oxygen valve

360d.4 water tank oxygen valve 610.

630. Inverter unit 620. Power converter unit Power unit

640.Generator 170.3 phase input

According to the present invention for achieving the above object, the central processing unit 110, the power conversion unit for controlling the automatic adjustment device unit 30 by comparing and analyzing the data received from the sensor unit 40 with the set value The I / O which transmits display data to the power supply unit 130 and the state input unit 20 that delivers the power applied from the unit 60 to each part, and receives a value set by the user in the state input unit 20. The control unit 10 includes a portion 120 and the data storage unit 140 storing data received from the sensor unit 40 and data received from the state input unit 20.

The air valve units 350a, 350b, 350c, and 350d respectively supplying air to the tanks, the oxygen valve units 360a, 360b, 360c, and 360d respectively supplying oxygen to the tanks, and the cooler 100 to the respective tanks. The discharge valve units (310a, 310b, 310c, 310d) for discharging the water cooled through the through, the inlet valve units (320a, 320b, 320c, 320d), each of which enters the water to be cooled in the water tank, respectively The automatic control device unit 30 is composed of the water drain valve unit 330, the water inlet valve unit 340 to put water in each tank.

The display unit 220 to allow a user to recognize the data received from the control unit 10, the set value input unit 210 receives the desired setting value in each tank and delivers it to the control unit 10 The state input and output unit 20 composed of

The generator unit 640 and the controller 10 for supplying power using the inverter unit 630 and the generator to generate power applied to the automatic control unit 30 using the power of the battery 610. The power conversion unit 60 consisting of the power supply unit 620 to make a power applied to

The sensor unit 40 for transmitting the respective data to the control unit 10 using each sensor in an arbitrary area (eg, a water tank).

The three-phase input unit 170 receives power and converts the value into mV and mA and transmits a state to the controller 10.

The camera unit 50 which transmits an image of a state of an individual control area to the controller 10.

Look at the working state of the present invention configured as described above.

The state input / output unit 20 receives an input of a set value of each tank set by the user and transfers the set value to the control unit 10. For example, when the set temperature of each tank is set, the state input / output unit 20 This value is transmitted to the control unit 10. The set value of each tank transmitted from the state input / output unit 20 is stored in the data storage unit 140. At the same time, the sensor unit 40 transmits the current data, temperature, oxygen, pressure, humidity, and carbonic acid of each tank to the controller 10 in real time. The control unit 30 and the machine unit 70 respectively control the automatic control unit unit 30 and the machine unit 70 in order to compare the setting values received from the state input / output unit 20 and control the optimum state for the environment in which the current state of each tank is set. Set each state by passing.

With the data transmitted from the three-phase input unit 170, the power-on state is determined, and when an abnormal state occurs, it is immediately transmitted to the user as a warning sound and a message.

The sensor unit 40 has an abnormality monitoring control line, and when there is an abnormality, the controller 10 ignores the input value of the sensor unit 40 and immediately transmits it as a warning sound and a message to the user. .

The control unit 10 receives the input data of the sensor unit 40 every 1 second and stores it in the data storage unit 140, and compares this value with the setting value received from the state input unit 20 By controlling the tank with the most optimal environment and error with the highest priority, the error of this tank is reduced.

For example, if the third tank is currently cooled, the third tank discharge valve 310c and the third tank inlet valve 320c may be opened. Tank 1 is 10 degrees, Tank 2 is 11 degrees, Tank 3 is 10.5 degrees, Tank 4 is 12 degrees, and each tank has a value of 10 degrees, Tank 2 is 12 degrees, and Tank 3 is 12 degrees. If the number 1 tank is 10 degrees and the number 4 tank is 12 degrees, the tank 2, which has the most error, is cooled after a certain time (for example, 1 minute). The third water tank discharge valve 310c and the third water tank inlet valve 320c are closed, and the second water tank discharge valve 310b and the second water tank inlet valve 320b are opened to start cooling of the second water tank. Done. This operation is repeated over and over.

The present invention as described above can be achieved through an automated system that can easily achieve the optimal environment required in the case of live fish, there is a useful that can improve the satisfaction of both consumers and sellers through maintaining a good state, In addition, the present invention is given the advantage of being able to combat the intruder by generating a beep when an object is detected within a certain distance by the sensor in the setting of the security system.

On the other hand, the present invention enumerates the best embodiments thereof, but is not limited thereto, and the present invention can be carried out without departing from the scope of the present invention without being limited to the appended claims, in view of changes in the embodiments described so far. Can be.

Claims (1)

Using the inverter with the voltage of the battery of 12V, 24V of the vehicle, or using the generator as a power source, a waterproof camera, a temperature measuring device and an oxygen measuring device are installed in a live fish tank, Equipped with a measuring device, equipped with an object sensor outside the live fish tank, LED and voice notification of the above-mentioned temperature, oxygen, pressure, and detection status around the driver's seat of the live fish vehicle, and the function of showing the camera screen on the TFT , Individual tank control device characterized in that for controlling the seawater of the tank individually by mounting an input / display device that functions as an environment setting function.