JP6823858B1 - Brine cooler cleaning method, cleaning equipment, and cleaning liquid manufacturing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for cleaning a brine cooler which can be easily removed by dissolving each fin such as a back fin and a chest fin which has clogged a tube of the brine cooler. A cleaning device for a brine cooler (11) uses a storage tank (33) for storing an aqueous solution for dissolving a protein as a cleaning liquid, and a cleaning liquid in the storage tank (33) for the brine cooler (11) and a storage tank (11). A cleaning liquid pump (31) that circulates between the cleaning liquid and the cleaning liquid pump (31) and a heater (32) that is arranged in the storage tank (33) and heats the cleaning liquid are provided. Heat to ~ 50 ° C. [Selection diagram] Fig. 1

Description

The present invention relates to a method and a cleaning device for a brine cooler for a brine refrigerating device of a fishing boat.

The present invention also relates to a method for producing a cleaning liquid used for cleaning a brine cooler for a brine refrigerating device of a fishing boat.

Conventionally, the fishing boat, in order to keep the fish fresh, such as freshly caught bonito includes a brine cooling KoSo location using brine solution at the brine refrigeration apparatus, after harvest, immediately, for example, -18 ° ~ - It is deep-frozen at a temperature of about 20 degrees. Patent Documents 1 and 2 disclose a brine refrigerating apparatus mounted on a pelagic fishing boat or the like.

Japanese Unexamined Patent Publication No. 61-31870 Japanese Unexamined Patent Publication No. 2006-162096

However, although the fish is frozen by the brine solution, the brine solution itself is an antifreeze solution, so the fish circulates between the brine cooler and the freezing brine solution water tank in which the fish is immersed without freezing. For this reason, if scales, dorsal fins, pectoral fins, tail fins, etc. are removed during freezing of fish, they are carried to the inside of the brine cooler by the brine solution, accumulate in the brine cooler, and adhere to the passage wall surface in the brine cooler. The tube is clogged. When the amount of scales such as fins adhered increases, the flow path area becomes narrower, the heat transfer wall becomes thicker, the flow of brine liquid is hindered, and the heat exchange efficiency decreases. Finally, there is a problem that the flow path of the brine cooler is clogged and the brine cooler itself cannot be used.

The present invention provides a cleaning method and a cleaning apparatus for a brine cooler that can be easily removed by dissolving scales composed of proteins such as scallops and fins that have accumulated or adhered to the brine cooler. It is in.

Further, it is an object of the present invention to provide a method for producing a cleaning liquid used for cleaning a brine cooler for a brine refrigerating apparatus for a fishing boat described above.

According to one aspect of the present invention, a storage tank for storing the cleaning liquid, the cleaning liquid in the reservoir tank, and the washing solution pump for circulating between brine cooler and the storage tank, it is disposed in the reservoir tank The cleaning solution is provided with a heater for heating the cleaning solution to 40 to 50 ° C., and the cleaning solution is an aqueous solution for protein dissolution having a concentration of 20% by mass to 40% by mass, and is sodium carbonate, sodium hexametaphosphate, caustic soda and gluconic acid. It is a cleaning device for a brine cooler containing soda .

The invention according to claim 2 is arranged in a storage tank for storing a cleaning liquid, a cleaning liquid pump for circulating the cleaning liquid in the storage tank between a brine cooler and the storage tank, and the storage tank. A cleaning method using a cleaning device of a brine cooler including a heater for heating the cleaning solution, wherein the cleaning device of the brine cooler is connected to the brine cooler, and the cleaning solution pump uses the cleaning solution. a step of circulating between the storage tank and the brine cooler, the heater, and heating the pre-Symbol cleaning liquid to 40 to 50 ° C., viewed including the said cleaning liquid, the concentration is 20% to 40 mass % Is an aqueous solution for dissolving protein, and is a washing method which is an aqueous solution for dissolving protein containing sodium carbonate, sodium hexametaphosphate, caustic soda and sodium gluconate .

The invention according to claim 3 is a storage tank for storing an aqueous solution for protein dissolution as a cleaning solution, a cleaning liquid pump for circulating the cleaning solution in the storage tank between a brine cooler and the storage tank, and the storage. A method for producing a cleaning solution used in a cleaning device for a brine cooler , which is arranged in a tank and equipped with a heater for heating the cleaning solution to 40 to 50 ° C. the sodium was prepared, and generating a solution for the proteolytic, comprising the steps of: the concentration of the aqueous solution for the protein dissolved with 20% to 40% by weight, in the production method of the cleaning liquid containing.

According to the cleaning method and cleaning device for the brine cooler according to the present invention, it is possible to easily remove the scales such as scallops and fins that have accumulated or adhered to the brine cooler.

It is a schematic of the whole structure of the brine refrigerating apparatus to which the cleaning apparatus of the brine cooler which concerns on one Embodiment of this invention is connected.

Hereinafter, a method for cleaning the brine cooler and an embodiment of the cleaning device according to the present invention will be described with reference to the drawings.

[Embodiment 1]
FIG. 1 is an overall configuration diagram of a brine refrigerating device 1 to which a cleaning device 30 of a brine cooler 11 is connected. First, an outline of the brine refrigerating device 1 will be described with reference to FIG. The brine refrigerating device 1 includes a brine liquid water tank 10 for immersing fish acquired during ocean voyages and the like, and a brine liquid pump (not shown) that supplies the brine liquid at -19 ° C to -20 ° C to the brine liquid water tank 10. A brine liquid storage tank (not shown), a brine cooler 11 for cooling the brine liquid after being used for freezing in the brine liquid water tank 10, and a refrigerant such as ammonia for cooling the brine liquid in the brine cooler 11. A refrigerant supply device (condenser, compressor, etc.) 12 for supplying the above water is provided.

A plurality of air vents 15 are provided on the upper wall of the brine cooler 11, and a drain valve 16 communicating with the inside of the brine cooler 11 is provided on the lower wall of the brine cooler 11.

A brine liquid return port 21 and a brine liquid discharge port 22 are provided above and below both ends of the brine cooler 11 in the longitudinal direction. The brine liquid return port 21 is connected to the brine liquid discharge port 25 of the brine liquid water tank 10 via the first switching valve 23 and the brine liquid return pipe 24. The brine liquid discharge port 22 of the brine cooler 11 is connected to the brine liquid intake port 27 of the brine liquid water tank 10 via the second switching valve 26.

As the brine solution for freezing fish, concentrated salt water having a salt weight concentration of about 23 to 24% is used. Concentrated salt water of about 23 to 24% is an antifreeze liquid, and is maintained in a liquid state without freezing up to about -20 ° C.

The fish freezing operation by the brine freezing device 1 will be briefly described.
As a setup before the work, the first switching valve 23 is switched to a state in which the brine liquid discharge port 25 of the brine liquid water tank 10 and the brine liquid return port 21 of the brine cooler 11 are connected, and the second switching valve 26 is the brine liquid. The state is switched so that the brine liquid intake port 27 of the water tank 10 and the brine liquid discharge port 22 of the brine cooler 11 are connected.

The brine liquid is cooled to about -19 ° C to -20 ° C by exchanging heat with a refrigerant such as ammonia from the refrigerant supply device 12 in the brine cooler 11, and is cooled from the brine liquid discharge port 22 to the second switching valve. It is supplied into the brine liquid water tank 10 through the brine liquid intake port 27.

In the brine solution tank 10, the fish immediately after being acquired is immersed in the brine solution and frozen at about −19 ° C. to −20 ° C.

The brine liquid after being used for freezing fish in the brine liquid water tank 10 enters the brine cooler 11 from the brine liquid discharge port 25 through the brine liquid return pipe 24, the first switching valve 23, and the brine liquid return port 21. Be returned. In the brine cooler 11, the brine liquid is again heat-exchanged with a refrigerant such as ammonia, cooled to −19 ° C. to −20 ° C., and supplied to the brine liquid water tank 10.

Next, the configuration of the cleaning device 30 connected to the brine refrigerating device 1 will be described. The cleaning device 30 includes a cleaning liquid pump 31, an electric heater 32, a storage tank 33 for storing the cleaning liquid, an intermediate tank 35 containing the filter 34, and an external filter 38, and cleaning is required. At the time, it is connected to the brine refrigerating device 1.

The storage tank 33 is detachably connected to the brine liquid return port 21 of the brine cooler 11 via an external filter 38, a cleaning liquid recovery pipe (cleaning liquid recovery path) 40, and a first switching valve 23. That is, the brine liquid return port 21 of the brine cooler 11 is switchably connected to the brine liquid discharge port 25 of the brine liquid water tank 10 and the cleaning liquid recovery pipe 40 of the cleaning device 30 by the first switching valve 23.
The external filter 38 does not necessarily have to be provided.

The electric heater 32 is arranged in the storage tank 33 and can heat the cleaning liquid in the storage tank 33 to an arbitrary temperature. In this embodiment, it is set so that it can be heated to 40 ° C to 50 ° C.

The outlet of the storage tank 33 is connected to the inlet of the intermediate tank 35 having the built-in filter 34 via the on-off valve 36, and the outlet of the intermediate tank 35 is connected to the suction port 31a of the cleaning liquid pump 31.
The intermediate tank 35 (built-in filter 34) does not necessarily have to be provided, and the outlet of the storage tank 33 may be connected to the suction port 31a of the cleaning liquid pump 31 via the on-off valve 36.

The cleaning liquid pump 31 can circulate the cleaning liquid between the brine cooler 11 and the storage tank 33.
The discharge port 31b of the cleaning liquid pump 31 is connected to the brine liquid discharge port 22 of the brine cooler 11 via an on-off valve 37, a cleaning liquid supply pipe 39, and the above-mentioned second switching valve 26. That is, the brine liquid discharge port 22 of the brine cooler 11 is freely switched to the brine liquid intake port 27 of the brine liquid water tank 10 and the cleaning liquid discharge pipe 39 by the second switching valve 26.

As the cleaning solution, for example, an aqueous solution for dissolving a protein containing sodium carbonate, sodium hexametaphosphate, caustic soda and sodium gluconate is used. The aqueous solution for protein dissolution is prepared by mixing, for example, 35% by mass or more of water, 3% by mass or more of sodium carbonate, 3% by mass or more of sodium hexametaphosphate, 40% by mass or more of caustic soda 48% solution, and 10% by mass or more of sodium gluconate. This is a 900 liter cleaning solution produced by producing 300 liters of the aqueous solution and then mixing the aqueous solution with 600 liters of water.

The concentration of the aqueous protein solution for dissolution is preferably 20% by mass to 40% by mass, more preferably 25% by mass to 35% by mass with respect to water. By the way, when the concentration is 20% by mass or less, the protein removing function is hardly exhibited, but the effect does not change even if the concentration exceeds 40% by mass.

The aqueous solution for protein dissolution is strongly alkaline, and its pH is preferably 8 to 14.

According to the cleaning device 30 according to the first embodiment, proteins such as fish scallops and fins adhering to the inside of the brine cooler can be removed by the aqueous solution for dissolving the brine without removing the brine cooler from the hull.
That is, even if the scale of scallops and fins that accumulate or adhere to the brine cooler increases, the existing brine cooler can be returned to a good state without replacing it with a new brine cooler as in the past. it can.

Next, the cleaning operation of the brine cooler 11 (cleaning method of the brine cooler 11) will be described.

First, the cleaning device 30 is carried into the ship.
Next, the first switching valve 23 is switched to a state in which the cleaning liquid recovery pipe 40 of the cleaning device 30 and the brine liquid return port 21 of the brine cooler 11 are connected, and the second switching valve 26 is connected to the cleaning liquid discharge pipe of the cleaning device 30. The state is switched so that the 39 and the brine liquid discharge port 22 of the brine cooler 11 are connected. That is, the cleaning device 30 is connected to the brine cooler 11. Further, the residual liquid in the brine cooler 11 is drained in advance by the drain valve 16.

As a cleaning solution, as described above, an aqueous solution for protein dissolution containing sodium carbonate, sodium hexametaphosphate, caustic soda and sodium gluconate is charged into the storage tank 33 and heated by the electric heater 32 to raise the temperature of the cleaning solution to 40 to 50. Raise to ° C.

The cleaning liquid after heating is sucked into the suction port 31a from the storage tank 33 via the on-off valve 36 and the intermediate tank 35 having the filter 34 by the cleaning liquid pump 31, and the cleaning liquid supply pipe 39 and the second switching from the discharge port 31b. It is supplied into the brine cooler 11 via the valve 26.

In the brine cooler 11, the scales of proteins such as fish scallops and fins that have accumulated or adhered to the brine cooler 11 are dissolved and discharged from the brine liquid return port 21. From the brine liquid return port 21, it is collected to the storage rank 33 via the first switching valve 23, the cleaning liquid recovery pipe 40, and the external filter 38. In the external filter 38, when the scallops and fins are not completely dissolved, the scallops and fins are removed.
Such work is repeated for 40 hours, for example, to remove scallops and fins accumulated in the brine cooler 11. The cleaning liquid to be circulated is, for example, 900 liters.

As the storage tank 33, for example, a general drum can having a capacity of about 200 liters can be used, and a total of about 900 liters is used as described above, including the cleaning liquid supply pipe 39 and the amount of the brine cooler 11 of 600 liters. Initially, 200 liters are charged into the storage tank (drum can) 33, and then discharged to the cleaning liquid discharge pipe 39 or the like by the cleaning liquid pump 31, and a total of 900 liters of cleaning liquid is sequentially supplied by the cleaning liquid pump 31 and circulated for 40 hours.
The protein-dissolving aqueous solution as a cleaning solution is initially white and transparent, but when the filthy protein is dissolved, the transparency disappears, and it can be judged that the adhered scallops and fins have been removed.

When producing a cleaning solution, for example, water content of 35% by mass or more, sodium carbonate of 3% by mass or more, sodium hexametaphosphate of 3% by mass or more, caustic soda 48% solution of 40% by mass or more, and sodium gluconate 10% by mass are mixed. After producing 300 liters of the prepared aqueous solution, the aqueous solution is mixed with 600 liters of water to produce 900 liters of a strongly alkaline cleaning solution. In the first embodiment, the cleaning liquid is circulated for substantially 40 hours, whereby the scallops and fins that have accumulated or adhered to the brine cooler 11 can be removed even after the circulation for 40 hours. ..

According to the method for cleaning the brine cooler according to the first embodiment, the protein-dissolving aqueous solution removes proteins such as fish scallops and fins that have accumulated or adhered to the brine cooler, and the brine cooler is not replaced again. It can be used efficiently. In particular, by heating the cleaning liquid, scales such as scallops and fins can be efficiently removed.

[Embodiment 2]
As a cleaning solution, an aqueous solution for protein dissolution having the same components as in Embodiment 1 is prepared, and after producing 300 liters, the aqueous solution is mixed with 600 liters of water to produce 900 liters of cleaning solution.

Similar to the first embodiment, the cleaning device 30 provided with the storage tank 33 provided with the electric heater 32 and the cleaning liquid pump 31 is used, and 900 liters of the cleaning liquid is supplied in the storage tank 33 by the electric heater 32 at 40 to 50 ° C. After heating, it is supplied into the brine cooler 11 by the cleaning liquid pump 31 and circulated for 45 hours.

As a result, the scallops and fins accumulated in the brine cooler 11 could be removed even after 45 hours of circulation. Although not significantly different from the 40-hour circulation described above, slightly more scale can be removed.

[Embodiment 3]
As a cleaning solution, an aqueous solution for protein dissolution having the same components as in the first embodiment described above is prepared, and after producing 300 liters, the aqueous solution is mixed with 600 liters of water to produce 900 liters of cleaning solution.

Similar to the first embodiment, the cleaning device 30 having the storage tank 33 provided with the electric heater 32 and the cleaning liquid pump 31 is used, and 900 liters of the cleaning liquid is heated to 40 to 50 ° C. in the storage tank 33 by the electric heater 32. After that, it was supplied into the brine cooler 11 by the cleaning liquid pump 31 and circulated for 50 hours.

As a result, the back fins and the like accumulated in the brine cooler could be removed even after circulation for 50 hours. There is no significant difference from the 40-hour and 45-hour circulation described above, but slightly more scale can be removed.

[First comparative form]
As a cleaning solution, an aqueous solution for protein dissolution having the same components as in the first embodiment is prepared, and after producing 300 liters, the aqueous solution is mixed with 600 liters of water to produce 900 liters of cleaning solution.

In the unheated state, 900 liters of the cleaning liquid was supplied into the brine cooler 11 and circulated for 40 hours by using the storage tank 33 and the cleaning device 30 having the cleaning liquid pump 31 as in the first embodiment.

Since the cleaning liquid was not heated, it was not possible to effectively remove the scallops and fins and the like accumulated in the brine cooler 11.

[Second comparative form]
As a cleaning solution, an aqueous solution for protein dissolution having the same components as in the first embodiment is prepared, and after producing 300 liters, the aqueous solution is mixed with 600 liters of water to produce 900 liters of cleaning solution.

The temperature of the cleaning liquid is set to 30 ° C., and 900 liters of the cleaning liquid is supplied into the brine cooler 11 by using the cleaning device 30 having the storage tank 33 having the electric heater 32 and the cleaning liquid pump 31 as in the first embodiment. It was circulated for 50 hours.

Although the cleaning liquid was heated, it had a low temperature of 30 ° C., so that it was not possible to effectively remove the scallops and fins accumulated in the brine cooler 11.

[Third comparative form]
As a cleaning solution, an aqueous solution for protein dissolution having the same components as in the first embodiment is prepared, and after producing 150 liters, the aqueous solution is mixed with 750 liters of water to produce 900 liters of cleaning solution.

The temperature of the cleaning liquid is set to 50 ° C., and 900 liters of the cleaning liquid is supplied into the brine cooler 11 by using the cleaning device 30 having the storage tank 33 having the electric heater 32 and the cleaning liquid pump 31 as in the first embodiment. It was circulated for 50 hours.

Although the cleaning liquid was heated, the concentration was as low as 15% by mass, and the concentration was out of the range of 20% by mass to 40% by mass, so that the scallops and fins accumulated in the brine cooler 11 were removed. It was difficult.

According to the results of each of the above embodiments and comparative embodiments, the aqueous solution for protein dissolution heated to 40 ° C. to 50 ° C. in a concentration range of 20% by mass to 40% by mass was used as the cleaning solution in the brine cooler 11. It was confirmed that the scallops and fins remaining or adhering to the protein can be effectively dissolved and removed.

[Other Embodiments]
In the above-described embodiment, an aqueous solution for dissolving a protein containing sodium carbonate, sodium hexametaphosphate, caustic soda and sodium gluconate was used as a cleaning solution, and the aqueous solution was uniformly dissolved by heating. Not limited. For example, as long as the aqueous solution for protein dissolution is uniformly dissolved, a method other than heating may be used. Even in this case, the same effect as that of the present embodiment is obtained.

In the cleaning device of FIG. 1, the discharge port 31b of the cleaning liquid pump 31 is connected to the brine liquid discharge port 22 of the brine cooler 11, and the cleaning liquid recovery pipe 40 of the storage tank 33 is connected to the brine liquid return port 21 of the brine cooler 11. However, it is also possible to connect them on opposite sides. That is, the discharge port 31b of the cleaning liquid pump 31 can be connected to the brine liquid return port 21 of the brine cooler 11, and the cleaning liquid recovery pipe 40 of the storage tank 32 can be connected to the brine liquid discharge port 22 of the brine cooler 11.

Although the embodiments of the present invention have been described, the above embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

1 Brine refrigeration system 10 Brine liquid water tank 11 Brine cooler 30 Brine cooler cleaning device 31 Cleaning liquid pump 32 Electric heater 33 Cleaning liquid storage tank 40 Cleaning liquid recovery pipe (cleaning liquid recovery path)

Claims (3)

A reservoir tank for storing the washing liquid,
A cleaning liquid pump that circulates the cleaning liquid in the storage tank between the brine cooler and the storage tank.
A heater arranged in the storage tank and heating the cleaning liquid to 40 to 50 ° C. is provided .
A cleaning device for a brine cooler in which the cleaning solution is an aqueous solution for protein dissolution having a concentration of 20% by mass to 40% by mass and contains sodium carbonate, sodium hexametaphosphate, caustic soda and sodium gluconate . A storage tank for storing the cleaning liquid, a cleaning liquid pump for circulating the cleaning liquid in the storage tank between the brine cooler and the storage tank, a heater arranged in the storage tank to heat the cleaning liquid, and the like. It is a cleaning method using a cleaning device of a brine cooler equipped with.
The step of connecting the cleaning device of the brine cooler to the brine cooler, and
A step in which the cleaning liquid pump circulates the cleaning liquid between the brine cooler and the storage tank.
The heater is seen containing a step, the heating of the pre-Symbol cleaning liquid to 40 to 50 ° C.,
A cleaning method in which the cleaning solution is an aqueous solution for dissolving proteins having a concentration of 20% by mass to 40% by mass, and is an aqueous solution for dissolving proteins containing sodium carbonate, sodium hexametaphosphate, caustic soda and sodium gluconate . A storage tank for storing an aqueous solution for protein dissolution as a cleaning liquid, a cleaning liquid pump for circulating the cleaning liquid in the storage tank between the brine cooler and the storage tank, and the cleaning liquid arranged in the storage tank. A method for producing a cleaning solution used in a cleaning device for a brine cooler equipped with a heater for heating the protein to 40 to 50 ° C.
Sodium carbonate, the steps of sodium hexametaphosphate to prepare a sodium hydroxide and sodium gluconate, to produce a solution for the proteolytic,
A method for producing a cleaning solution, which comprises a step of adjusting the concentration of the aqueous solution for protein dissolution to 20% by mass to 40% by mass.