JPH06129746A - Method for controlling sea water cooling device - Google Patents

Abstract

PURPOSE:To provide a controlling method for getting sea water of a low temperature having a smaller variation in temperature in a sea water cooling machine using a freezer and prevent sea water from being freezed in a heat exchanger. CONSTITUTION:A sea water cooling device having double-pipe type heat exchangers 2 of a plurality of stages connected in series is constituted such that each of temperature adjusting devices 4 including a temperature sensor is arranged in a sea water communication pipe between each of the heat exchangers 2. When sea water shows a temperature lower than each of set values, refrigerant flowing into the heat exchanger 2 at that stage is shielded with a solenoid valve 3 and further the temperature is lower than 0 deg.C, flowing-in of refrigerant into the heat exchangers 2 at all stages before that specified stage is shielded by the solenoid valve 3.

Description

Detailed Description of the Invention

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to equipment arrangement and control of a seawater cooling device used in fisheries. Low-temperature seawater is used to keep the level of metabolism of live fish and juveniles low, maintain their freshness, and improve the yield during transportation. In addition, currently, the captured fish are often washed with tap water, but there is a problem in that water penetrates into the fish body due to the osmotic pressure, resulting in a loss of taste and a loss of freshness. A low-temperature seawater that can be produced is desired.

2. Description of the Related Art Conventionally, as a method for obtaining low-temperature seawater, it is widely practiced to make seawater ice in a freezer, crush it and use it as it is, or to drop it in pumped seawater to lower the temperature. . Further, recently, a method has been adopted in which a refrigerator is used to instantly produce low-temperature seawater by passing the seawater through a heat exchanger.

The method of making seawater ice in a freezer has the disadvantages that it usually takes about two days to make ice and therefore is not flexible, and that the freezer is corroded quickly by salt. The method of passing seawater through the heat exchanger using a refrigerator is
Since it is currently performed in a single-stage heat exchanger, there is a problem that it is difficult to obtain seawater at 5 ° C. or lower due to the problem of freezing of seawater in the heat exchanger. Further, the conventional apparatus has a drawback that the range of fluctuation with respect to the set temperature is large. Furthermore, in the conventional device, when seawater freezes in the heat exchanger, the entire heat exchanger must be replaced, which causes a problem of high repair cost.

In the present invention, the heat exchangers are provided in a plurality of stages and are connected in series. Feedback control is performed for each stage, in which the seawater outlet temperature of the heat exchanger at each stage is detected by a temperature sensor and compared with a set value to shut off the refrigerant as necessary. In addition, control is performed so that freezing does not occur in each heat exchanger.

[Function] By increasing the number of heat exchangers, it is possible to reduce the seawater temperature drop width per stage, and at the outlet of each stage, compare with the set value, and immediately when it becomes lower than the set value. Since the feedback is applied to, the error from the set temperature can be reduced. Further, when the seawater outlet temperature of each stage becomes 0 ° C. or lower, feedback is applied to all stages before this stage, so it is safe against freezing in the heat exchanger.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a control flow chart of a seawater cooling device having a four-stage heat exchange section in the present invention. Seawater is sent to the heat exchange section by the pump 1 and cooled while passing through the four-stage double-tube heat exchanger 2. Refrigerant pipes are independently provided in the double-pipe heat exchanger 2. An electromagnetic valve 3 is provided at each inlet of the refrigerant pipes so that the refrigerant can be independently blocked from flowing into each double-pipe heat exchanger 2. A temperature controller 4 including a temperature sensor is provided at the outlet of the heat exchanger 2 at each stage, and the solenoid valve 3 is controlled to be shut off when the temperature falls below a set temperature. The set temperature of the temperature controller 4 at the outlet of each stage is, for example, 2 times the final seawater outlet temperature.
If the temperature is ℃, it depends on the seawater inlet temperature, but the first stage is 8 ℃,
The second stage is 6 ° C, the third stage is 3 ° C, and the fourth stage is about 2 ° C. At the same time, set 0 ℃ at the outlet of each stage,
Furthermore, in the fourth stage, -1 ° C is also set. A flow meter 5 is provided in the seawater flow path. The seawater outlet temperature is controlled as follows. When the outlet temperature of each stage falls below the set value of the temperature controller 4 of that stage, the temperature controller 4 sends a signal to shut off the solenoid valve 3 that controls the refrigerant flow of that stage. When a temperature of 0 ° C. or less is detected, a signal is sent to shut off the solenoid valves 3 not only at this stage but also at all stages before that. Refrigerator 6 when -1 ° C is detected in the 4th step
Send a signal to stop the body. Also, when the flow rate becomes equal to or less than the set value, a signal to stop the refrigerator 6 is sent. Further, in the case of pump failure, a signal to stop the refrigerator 6 is sent.

INDUSTRIAL APPLICABILITY As described above, according to the present invention, the number of heat exchangers is increased to reduce the temperature drop width of each stage, and the seawater temperature is detected at the outlet of each stage, which is below the set value. In this case, the inflow of the refrigerant at this stage is immediately shut off, so that the control accuracy of the final seawater outlet temperature can be improved. Furthermore, when the seawater outlet temperature of each stage is below 0 ° C, the refrigerant entering the heat exchangers of all stages before this stage is shut off, or the final seawater outlet temperature is below -1 ° C. When the flow rate of seawater falls below a certain level or when the pump stops operating for some reason, the refrigerator itself is stopped, and measures to prevent freezing in the heat exchanger of seawater are complete. With the cooling device, it became possible to stably cool to the final seawater outlet temperature of 2 ° C., which could not be achieved due to freezing. Further, since the control of the present invention is basically a simple on / off control, it has advantages that the cost of the control unit is low and maintenance and operation are easy. Further, even if seawater freezes in the heat exchanger, only the heat exchanger at that stage needs to be replaced, so the repair cost is low.

[Brief description of drawings]

FIG. 1 is a device / control flow of the present invention.

[Explanation of symbols]

 1 Pump 2 Heat Exchanger 3 Solenoid Valve 4 Temperature Controller 5 Flow Meter 6 Refrigerator 7 Expansion Valve 8 Check Valve 9 Stop Valve

Claims (1)

[Claims] In a seawater cooling device having a plurality of stages of double-pipe heat exchangers 2 connected in series, a temperature controller 4 including a temperature sensor is arranged in each seawater connecting pipe between the heat exchangers 2 so that the seawater temperature is different from each other. When the temperature becomes lower than the set value, the refrigerant flowing into the heat exchanger 2 at that stage is shut off by the solenoid valve 3, and when it becomes 0 ° C. or less, the refrigerant to the heat exchanger 2 at all stages before this stage. A method for controlling a seawater cooling device in which the inflow of water is shut off by a solenoid valve 3.