JP6676914B2 - Marine refrigeration equipment - Google Patents

Description

    TECHNICAL FIELD The present invention relates to a marine refrigeration system including a water-cooled condenser and used for an air conditioner of a marine vessel or the like.

    2. Description of the Related Art Conventionally, a water-cooled condenser has been used in a marine refrigerating device such as an air conditioner of a ship (for example, see Patent Document 1 below). The water-cooled condenser of Patent Literature 1 has a shell in which a refrigerant chamber through which a refrigerant flows is formed, and a plurality of cooling pipes that are inserted into the refrigerant chamber in the shell and through which cooling water flows. It is configured to exchange heat with the refrigerant. In a water-cooled condenser mounted on such a marine refrigeration system, a cooling pipe through which cooling water flows and which is always in contact with the cooling water may have a hole due to corrosion.

    Therefore, conventionally, in the above-described water-cooled condenser, a sacrificial anode made of zinc or the like having a higher ionization tendency than the metal (mainly copper) constituting the cooling pipe is provided, and the sacrificial anode is corroded before the cooling pipe. By doing so, the corrosion of the cooling pipe is prevented.

JP 2012-122670 A

    However, if the amount of the cooling water passing through the cooling pipe is too large, the cooling pipe may be corroded and a hole may be formed even when the sacrificial anode is provided. When a hole is formed in the cooling pipe, the high-pressure refrigerant leaks into the cooling pipe, and when the pressure inside and outside the cooling pipe becomes equal, the cooling water in the cooling pipe infiltrates into the refrigerant circuit. If the cooling water enters the refrigerant circuit, the components of the refrigerant circuit may be damaged by the cooling water. In the conventional marine refrigeration system, there is no means for measuring the amount of cooling water flowing through the cooling pipe, and it is not possible to prevent a hole in the cooling pipe.

    The present invention has been made in view of such a point, and an object of the present invention is to prevent damage to a cooling pipe of a condenser in a marine refrigerating apparatus including a water-cooled condenser.

According to a first aspect of the present invention, a cooling mechanism (30) is mounted on a vessel, and a shell (41) in which a refrigerant chamber (S1) in which a refrigerant flows is formed inside the refrigerant chamber (S1). A marine refrigeration system including a refrigerant circuit (20) in which a water-cooled condenser (40) having a flowing cooling pipe (42), an expansion mechanism (50), and an evaporator (60) are sequentially connected. When the abnormality determination unit (81) that determines whether the amount of cooling water flowing into the condenser (40) is in an excessively abnormal state and the abnormality determination unit (81) determines that the state is abnormal, An abnormal operation section (82) for performing a predetermined abnormal operation for reducing the amount of cooling water flowing into the condenser (40) while the marine refrigeration apparatus is operated .

    In the first aspect, in the refrigerant circuit (20), the refrigerant circulates to perform a refrigeration cycle. At this time, in the water-cooled condenser (40), between the refrigerant flowing into the refrigerant chamber (S1) and the cooling water flowing through the cooling pipe (42) inserted into the refrigerant chamber (S1). Heat exchange is performed, and the refrigerant releases heat to the cooling water and condenses.

    Meanwhile, in the water-cooled condenser (40), the cooling pipe (42) through which the cooling water flows and is always in contact with the cooling water may have a hole due to corrosion. In particular, if the amount of water in the cooling pipe (42) is too large, there is a high possibility that a hole will be formed. When a hole is formed in the cooling pipe (42), high-pressure refrigerant in the refrigerant chamber (S1) leaks into the cooling pipe (42), and the pressure in the refrigerant chamber (S1) decreases. When the pressure in the refrigerant chamber (S1) decreases until it becomes equal to the pressure in the cooling pipe (42), the cooling water in the cooling pipe (42) leaks into the refrigerant chamber (S1), and the refrigerant circuit (20) Of the refrigerant circuit (20).

    Therefore, in the first invention, an abnormality determination unit (81) and an abnormal operation unit (82) are provided, and the amount of cooling water flowing into the condenser (40) is excessive, and a hole is formed in the cooling pipe (42). When a possible abnormal state is determined, a predetermined abnormal operation is performed to reduce the amount of cooling water flowing into the condenser (40).

    According to a second invention, in the first invention, a high-pressure sensor (93) for detecting a high pressure of the refrigerant circuit (20) and a low-pressure sensor (94) for detecting a low pressure of the refrigerant circuit (20). An inlet temperature sensor (95) for detecting the temperature of the cooling water flowing into the condenser (40), and an outlet temperature sensor (96) for detecting the temperature of the cooling water flowing out of the condenser (40). The abnormality determination unit (81) is configured such that a detection value of the high-pressure pressure sensor (93) and a detection value of the low-pressure pressure sensor (94) are pressures within a predetermined normal range, respectively, and the outlet temperature sensor When the temperature difference obtained by subtracting the detection value of the entrance temperature sensor (95) from the detection value of (96) is smaller than a predetermined value, it is determined that the above-mentioned abnormal state has occurred.

    By the way, when the high pressure and the low pressure in the refrigerant circuit (20) are within the normal range, it can be estimated that the refrigeration cycle is normally performed in the refrigerant circuit (20). In addition, when the amount of heat released from the condenser (40) is too small during the normal operation of the refrigeration cycle in the refrigerant circuit (20), it is determined that the amount of cooling water flowing into the condenser (40) is excessive. Can be estimated.

    Therefore, in the second invention, utilizing this estimation, the high-pressure pressure and the low-pressure pressure of the refrigerant circuit (20) are each within the normal range, and the cooling water flowing out of the condenser (40) and the condenser When the temperature difference of the cooling water flowing into the condenser (40) is too small, it is determined that the cooling water flowing into the condenser (40) is in an abnormal state in which the amount of the cooling water is excessive.

    In a third aspect based on the first aspect, an inlet pressure sensor (97) for detecting a pressure of the cooling water flowing into the condenser (40) and a pressure of the cooling water flowing out of the condenser (40) are detected. An outlet pressure sensor (98) for detecting, and the abnormality determination unit (81) is configured to detect a head loss obtained by subtracting a detected value of the outlet pressure sensor (98) from a detected value of the inlet pressure sensor (97). If the value is larger than the normal value, it is determined that the state is abnormal.

    By the way, when the flow rate of the cooling water in the condenser (40) is too large, the head loss increases, and conversely, when the flow rate of the cooling water in the condenser (40) is too small, the head loss decreases. Therefore, when the head loss in the condenser (40) is larger than a predetermined normal value, it can be estimated that the cooling water in the condenser (40) is in an abnormal state in which the flow rate of the cooling water is excessive.

    Therefore, in the third invention, using this estimation, a pressure difference (head loss) obtained by subtracting the pressure of the cooling water flowing out of the condenser (40) from the pressure of the cooling water flowing into the condenser (40), If the value is larger than a predetermined normal value, it is determined that the cooling water flowing into the condenser is in an abnormal state in which the amount of cooling water is excessive.

    In a fourth aspect based on any one of the first to third aspects, the abnormal operation section (82) issues an alarm as the abnormal operation.

    In the fourth aspect, when the abnormality determination section (81) determines that the flow rate of the cooling water in the condenser (40) is in an abnormal state, the abnormal state operation section (82) sets the condenser (40). A warning is issued as a predetermined abnormal operation for reducing the flow rate of the cooling water in the above.

    In a fifth aspect based on any one of the first to third aspects, the inflow pipe (71) through which the cooling water flows into the condenser (40) and the cooling water flowing out of the condenser (40) are formed. A flowing outflow pipe (72), a bypass pipe (76) having one end connected to the inflow pipe (71) and the other end connected to the outflow pipe (72), and the bypass pipe (76); An on-off valve (77) for opening and closing the bypass pipe (76), and the abnormal operation section (82) controls the on-off valve (77) from a closed state to an open state as the abnormal operation.

    In the fifth aspect, when the abnormality determining unit (81) determines that the cooling water in the condenser (40) is in an abnormal state in which the flow rate of the cooling water is excessive, the abnormal state operation unit (82) sets the condenser (40). The on-off valve (77) provided in the bypass pipe (76) is controlled from the closed state to the open state as a predetermined abnormal operation for reducing the flow rate of the cooling water in the above. Thereby, a part of the cooling water flowing through the inflow pipe (71) flows into the bypass pipe (76) and bypasses the condenser (40). Therefore, the flow rate of the cooling water flowing into the condenser (40) is reduced.

    According to the first invention, the marine refrigerating apparatus includes an abnormality determining unit (81) that determines whether the amount of cooling water flowing into the water-cooled condenser (40) is in an excessively abnormal state. An abnormal operation section (82) for performing a predetermined abnormal operation for reducing the amount of cooling water flowing into the condenser (40) when the abnormality judgment section (81) judges that the state is abnormal is provided. Such an abnormality judging section (81) and an abnormal operation section (82) allow the cooling water flowing into the condenser (40) to have an excessive amount of water and to cause a hole in the cooling pipe (42). At a certain time, by performing the predetermined abnormal operation, the amount of the cooling water flowing into the condenser (40) can be reduced, and it is possible to prevent the cooling pipe (42) from being perforated. That is, in the marine refrigeration system including the water-cooled condenser (40), the cooling pipe (42) of the condenser (40) can be prevented from being damaged.

    According to the second aspect, when the high pressure and the low pressure in the refrigerant circuit (20) are within the normal range, it is estimated that the refrigeration cycle is normally performed in the refrigerant circuit (20). However, when the refrigeration cycle is normal and the amount of heat radiation in the condenser (40) is too small, it is assumed that an abnormal state is caused in which the amount of cooling water flowing into the condenser (40) is excessive. Therefore, by detecting the high pressure and low pressure of the refrigerant circuit (20), the temperature of the cooling water flowing into the condenser (40), and the temperature of the cooling water flowing out of the condenser (40), the condenser can be easily formed. An abnormal state in which the amount of cooling water flowing into (40) is excessive can be detected.

    Further, according to the third aspect, when the head loss of the cooling water in the condenser (40) is larger than a predetermined normal value, the abnormal state in which the flow rate of the cooling water in the condenser (40) is excessive. It is assumed that there is. Therefore, by calculating the head loss from the pressure of the cooling water flowing into the condenser (40) and the pressure of the cooling water flowing out of the condenser (40), the cooling water flowing into the condenser (40) can be easily calculated. An abnormal state in which the amount of water is excessive can be detected.

    According to the fourth aspect, the abnormal operation section (82) issues an alarm as an abnormal operation. By this alarm, the operator can detect that the flow rate of the cooling water in the condenser (40) is excessive, which is an abnormal state. By taking measures, it is possible to prevent the cooling pipe (42) of the condenser (40) from being damaged (perforated).

    According to the fifth aspect, the abnormal operation section (82) controls the open / close valve (77) provided in the bypass pipe (76) to be in an open state as the abnormal operation. As a result, a part of the cooling water flowing through the inflow pipe (71) flows into the bypass pipe (76) and bypasses the condenser (40), thereby reducing the flow rate of the cooling water flowing into the condenser (40). can do. Therefore, it is possible to prevent the cooling pipe (42) of the condenser (40) from being damaged (perforated).

FIG. 1 is a schematic configuration diagram of the air-conditioning apparatus according to Embodiment 1 of the present invention. FIG. 2 is an overall view of the water-cooled condenser according to Embodiment 1 of the present invention, with a part cut away. FIG. 3 is a view of the front lid of the water-cooled condenser according to Embodiment 1 of the present invention as viewed from the rear side. FIG. 4 is a schematic configuration diagram of the air-conditioning apparatus according to Embodiment 2 of the present invention.

    Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

<< First Embodiment of the Invention >>
FIG. 1 is a schematic configuration diagram of an air conditioner (10) according to Embodiment 1 of the present invention. The air conditioner (10) of the present embodiment is provided in an air conditioning system for ships. Specifically, the air conditioner (10) is provided outdoors, such as a deck for a ship, and takes in indoor air in a ship's cabin (not shown) and outdoor outdoor air through a suction duct, After the temperature is adjusted, the air is supplied into the cabin through an air supply duct (not shown).

    As shown in FIG. 1, the air conditioner (10) of the present embodiment houses a refrigerant circuit (20), a water circuit (70), a blower fan (15), a controller (80), and these. A casing (11).

<Refrigerant circuit>
The refrigerant circuit (20) is a closed circuit composed of a compressor unit (compression mechanism) (30), a condenser (40), an expansion valve (expansion mechanism) (50), and an evaporator (60) connected in order by piping. It is. In the refrigerant circuit (20), the compressor unit (30) and the condenser (40) are connected by a high-pressure gas pipe (24), and the condenser (40) and the expansion valve (50) are connected to a high-pressure liquid pipe (25). The expansion valve (50) and the evaporator (60) are connected by a low-pressure liquid pipe (26), and the evaporator (60) and the compressor unit (30) are connected by a low-pressure gas pipe (27). ing. An electromagnetic valve (29) is provided in the high-pressure liquid pipe (25). The refrigerant circuit (20) is filled with a refrigerant.

-Compressor unit-
The compressor unit (30) includes three compressors, that is, first to third compressors (31, 32, 33). The number of compressors (31, 32, 33) provided in the compressor unit (30) is merely an example. Each of the first to third compressors (31, 32, 33) is constituted by a hermetic scroll compressor.

    In the compressor unit (30), the first and second compressors (31, 32) are connected in parallel to each other, and the third compressor (33) is connected to the first and second compressors ( 31, 32) are connected in parallel.

    Specifically, the suction pipes (21a, 22a) of the first and second compressors (31, 32) are connected to each other, and the low pressure gas pipe (27) connected to the outlet of the evaporator (60). )It is connected to the. On the other hand, the suction pipe (23a) of the third compressor (33) is directly connected to the low-pressure gas pipe (27). The discharge pipes (21b, 22b, 23b) of the first to third compressors (31, 32, 33) are all connected to a high-pressure gas pipe (24) connected to a refrigerant inlet of the condenser (40). I have. Each discharge pipe (21b, 22b, 23b) allows refrigerant to flow from each compressor (31, 32, 33) toward the high-pressure gas pipe (24), while preventing the refrigerant from flowing in the opposite direction. A check valve (28) is provided.

    With such a configuration, in the compressor unit (30), the first to third compressors (31, 32, 33) suck in from the low-pressure gas pipe (27) via the suction pipes (21a, 22a, 23a). The compressed refrigerant is compressed, and the compressed refrigerant is discharged to the high-pressure gas pipe (24) via the discharge pipes (21b, 22b, 23b).

−Condenser−
The condenser (40) is connected to the refrigerant circuit (20) and the water circuit (70), and is a water-cooled type in which the refrigerant exchanges heat with cooling water (specifically, water taken in from seawater or a river). As shown in FIG. 2, the condenser is a so-called shell-and-tube heat exchanger, and includes a closed cylindrical shell (41) and a plurality of shells (41) provided inside the shell (41). A cooling pipe (42) made of copper. The shell (41) includes a body (41a), a pair of tube plates (end plates) (41b, 41c), and a pair of lid plates (41d, 41e).

    The body (41a) is formed in a cylindrical shape that is long in the front-rear direction. Both ends of the body (41a) are closed by a pair of tube sheets (41b, 41c), and a refrigerant chamber (S1) through which a refrigerant flows is formed inside. An introduction pipe (43) for introducing the refrigerant into the refrigerant chamber (S1) is connected to an upper portion of the body (41a), and an outlet for deriving the refrigerant in the refrigerant chamber (S1) is connected to a lower portion of the body (41a). Tube (44) is connected. The other end of the inlet pipe (43) is connected to the high-pressure gas pipe (24) of the refrigerant circuit (20), and the other end of the outlet pipe (44) is connected to the high-pressure liquid pipe (25) of the refrigerant circuit (20). Have been.

    The pair of tube sheets (41b, 41c) includes a front tube sheet (41b) and a rear tube sheet (41c). The front tube sheet (41b) and the rear tube sheet (41c) are formed of crimp steel (cladding steel) of Naval brass and iron. The front tube sheet (41b) closes the front end of the body (41a), and the rear tube sheet (41c) closes the rear end of the body (41a).

    The pair of lid plates (41d, 41e) is constituted by a front lid plate (41d) and a rear lid plate (41e). The front lid plate (41d) and the rear lid plate (41e) are made of aluminum bronze, and are each formed in a dome shape.

    As shown in FIG. 3, the front lid plate (41d) is provided on the front side of the body (41a), and forms a front water chamber (S2) through which cooling water flows between the front lid plate (41d) and the front tube plate (41b). doing. The front lid plate (41d) has a partition plate portion (41f) that partitions the front water chamber (S2) into an inlet water chamber (S21) and an outlet water chamber (S22). A water supply pipe (45) and a drain pipe (46) are connected to the front lid plate (41d). The water supply pipe (45) opens to the inlet water chamber (S21), and the drain pipe (46) opens to the outlet water chamber (S22). Further, two sacrificial anodes (47) are attached to the front lid plate (41d). Two sacrificial anodes (47) are provided, one each for the inlet water chamber (S21) and the outlet water chamber (S22).

    On the other hand, the rear lid plate (41e) is provided on the rear side of the body (41a), and forms a rear water chamber (S3) through which cooling water flows between the rear lid plate (41e) and the rear tube plate (41c). . Two sacrificial anodes (47) are attached to the rear lid plate (41e), similarly to the front lid plate (41d).

    As shown in FIG. 1, the plurality of cooling pipes (42) extend in the refrigerant chamber (S1) in parallel with the axis of the body (41a) and are arranged at intervals. The plurality of cooling tubes (42) are inserted into both tube sheets (41b, 41c) such that the front ends are supported by the front tube sheet (41b), while the rear ends are supported by the rear tube sheet (41c). ing. The inlet water chamber (S21), the rear water chamber (S3), and the outlet water chamber (S22) are communicated by the plurality of cooling pipes (42), and these three water chambers (S3, S21, S22) are connected to the plurality of cooling pipes. A plurality of cooling water passages are formed by the pipe (42).

-Expansion valve-
The expansion valve (50) is a so-called automatic temperature expansion valve. The temperature sensing tube (51) of the expansion valve (50) is attached to the low pressure gas pipe (27) near the outlet of the evaporator (60), and is in contact with the surface of the low pressure gas pipe (27).

− Solenoid valve −
The solenoid valve (29) is used at the time of starting and before stopping the first to third compressors (31, 32, 33), and protects the first to third compressors (31, 32, 33). It is provided in order to. If the liquid refrigerant remains in the evaporator (60) after stopping the first to third compressors (31, 32, 33), then the first to third compressors (31, 32, 33) 31, 32, 33), the liquid refrigerant enters the first to third compressors (31, 32, 33) and is excessively large in the first to third compressors (31, 32, 33). Load will be applied. Therefore, when stopping the first to third compressors (31, 32, 33), the first to third compressors are kept until the liquid refrigerant in the evaporator (60) runs out with the solenoid valve (29) closed. The compressors (31, 32, 33) are operated for a while, and then the first to third compressors (31, 32, 33) are stopped. Further, when the first to third compressors (31, 32, 33) are started, the first refrigerant is returned to the evaporator (60) with the solenoid valve (29) closed, until the liquid refrigerant returns to the evaporator (60). The third compressor (31, 32, 33) is operated for a while, and then the solenoid valve (29) is opened.

-Evaporator-
The evaporator (60) is a so-called cross-fin type fin-and-tube heat exchanger, and includes a copper heat transfer tube and aluminum fins. The evaporator (60) causes the refrigerant to exchange heat with air.

<Water circuit>
The water circuit (70) includes an inflow pipe (71) through which cooling water (specifically, water taken in from seawater or a river) flows into the condenser (40), and cooling water flowing out of the condenser (40). An outflow pipe (72) for discharging water and a manual flow control valve (73) are provided. The inflow pipe (71) is connected between a cooling water inlet (74) provided outside the casing (11) and a water supply pipe (45) of the condenser (40), and the outflow pipe (72) is connected to the casing (71). It is connected between the cooling water outlet (75) provided outside the (11) and the drain pipe (46) of the condenser (40).

    By the way, in the air conditioner (10) of the present application, water taken in from seawater or a river is used as cooling water for the water-cooled condenser (40). In addition, in ships, in addition to cooling water for the condenser (40) of the air conditioner (10), cooling water for engines, refrigerators, electric devices, and generators is usually taken in from seawater or rivers. Water is used. Normally, seawater or river water is pumped up and distributed to equipment (including the condenser (40) of the air conditioner (10)) that uses cooling water. That is, seawater or river water is transported to the water circuit (70) of the condenser (40) of the air conditioner (10) by a pump shared with other devices that use cooling water. Therefore, the amount of cooling water flowing into the water circuit (70) cannot be adjusted by the pump. Therefore, in the present embodiment, the bypass pipe (76) and the on-off valve (77) are provided.

    Specifically, one end of the bypass pipe (76) is connected between the condenser (40) and the flow control valve (73) at the inflow pipe (71), and the other end is connected to the outflow pipe (72). ing. The on-off valve (77) is configured by an electromagnetic valve that is opened and closed by the controller (80).

    With such a configuration, in the water circuit (70), when the on-off valve (77) is in the closed state, the cooling water flowing into the inflow pipe (71) directly flows into the condenser (40) and is condensed. After exchanging heat with the refrigerant in the vessel (40), it flows out to the outflow pipe (72). On the other hand, when the on-off valve (77) is switched from the closed state to the open state in the water circuit (70), part of the cooling water flowing into the inflow pipe (71) flows into the bypass pipe (76), It flows out to the outlet pipe (72) bypassing the condenser (40). That is, when the on-off valve (77) is switched to the open state, a part of the cooling water flowing into the inflow pipe (71) flows into the bypass pipe (76) and bypasses the condenser (40), thereby condensing the water. The amount of cooling water flowing into the vessel (40) is reduced.

<Blower fan>
The blower fan (15) communicates with a duct (not shown) in the casing (11) and is provided in a space where the evaporator (60) of the refrigerant circuit (20) is installed. The blower fan (15) takes in the indoor air in the cabin and the outdoor air outside into the casing (11) through a duct, and evaporates the air so as to exchange heat with the refrigerant in the evaporator (60). To the vessel (60). Further, the blower fan (15) supplies the air, the temperature of which has been adjusted through the evaporator (60), to an interior space such as a cabin through a duct.

<Sensors and controllers>
-Sensor-
The air conditioner (10) includes a high pressure switch (91), a low pressure switch (92), a high pressure sensor (93), a low pressure sensor (94), an inlet temperature sensor (95), and an outlet temperature sensor ( 96).

    One high-pressure switch (91) is provided between each compressor (31, 32, 33) and each check valve (28) in each discharge pipe (21b, 22b, 23b). Each high-pressure switch (91) is activated when the pressure of the high-pressure gas refrigerant discharged from each of the compressors (31, 32, 33) exceeds a predetermined upper limit, and outputs an ON signal to the controller ( 80) is configured to send.

    The low pressure switch (92) is provided in the low pressure gas pipe (27). The low pressure switch (92) is activated and turned on when the pressure of the low pressure gas refrigerant flowing out of the evaporator (60) and sucked into the compressor unit (30) falls below a predetermined lower limit. It is configured to send a signal to the controller (80).

    The high pressure sensor (93) is provided in the high pressure gas pipe (24). The high pressure sensor (93) is configured to detect the pressure of the high pressure gas refrigerant discharged from the compressor unit (30) and transmit the detected pressure to the controller (80).

    The low pressure sensor (94) is provided in the low pressure gas pipe (27). The low-pressure pressure sensor (94) is configured to detect the pressure of the low-pressure gas refrigerant flowing out of the evaporator (60) and sucked into the compressor unit (30), and transmit the detected pressure to the controller (80).

    The inlet temperature sensor (95) is provided in the inflow pipe (71). The inlet temperature sensor (95) is configured to detect the temperature of the cooling water flowing into the condenser (40) through the inflow pipe (71) and transmit the detected temperature to the controller (80).

    The outlet temperature sensor (96) is provided in the outflow pipe (72). The outlet temperature sensor (96) is configured to detect the temperature of the cooling water flowing out of the condenser (40) to the outflow pipe (72), and transmit the detected temperature to the controller (80).

    In the present embodiment, a high-pressure pressure sensor (93), a low-pressure pressure sensor (94), an inlet temperature sensor (95), and an outlet temperature sensor (96) are used for determining an abnormal state by an abnormality determining unit (81) described later. Is used.

-Controller-
The controller (80) is configured to adjust the operating capacity of the compressor unit (30). Specifically, a detection value of the high pressure sensor (93) and a detection value of the low pressure sensor (94) are input to the controller (80). These detected values are used by the controller (80) to adjust the operating capacity of the compressor unit (30). Further, the controller (80) is configured to perform protection control for stopping the operation of the compressor unit (30) when receiving an ON signal from the high-pressure switch (91) or the low-pressure switch (92). .

    Further, the controller (80) includes an abnormality determination unit (81) and an abnormality operation unit (82). In the water-cooled condenser (40), the amount of cooling water flowing into the condenser (40) is reduced. When the cooling pipe (42) is excessively likely to have a hole, the amount of cooling water flowing into the condenser is reduced.

    The abnormality determination unit (81) determines whether or not the amount of cooling water flowing into the condenser (40) is in an excessively abnormal state in the water-cooled condenser (40). Specifically, in the present embodiment, the abnormality determination unit (81) is configured to control the high pressure (detected value of the high pressure sensor (93)) of the refrigerant circuit (20) and the low pressure (low pressure pressure sensor) of the refrigerant circuit (20). (94) is a pressure within a predetermined normal range, and the temperature of the cooling water flowing out of the condenser (40) (the detected value of the outlet temperature sensor (96)) is Abnormal condition where the amount of cooling water flowing into the condenser (40) is excessive when the temperature difference obtained by subtracting the temperature of the cooling water flowing into the condenser (detected value of the inlet temperature sensor (95)) is smaller than a predetermined value. Is configured to be determined.

    The abnormal operation section (82) is configured to perform a predetermined abnormal operation for reducing the amount of cooling water flowing into the condenser (40) when the abnormality determining section (81) determines that the state is abnormal. ing. In the present embodiment, the abnormal operation section (82) is configured to control the open / close valve (77) provided in the bypass pipe (76) of the water circuit (70) to an open state as the abnormal operation. . By this abnormal operation, a part of the cooling water flowing through the inflow pipe (71) flows into the bypass pipe (76) and flows out to the outflow pipe (72). That is, the abnormal operation section (82) performs an abnormal operation by causing a part of the cooling water flowing through the inflow pipe (71) to flow into the bypass pipe (76) to bypass the condenser (40). It is configured to reduce the amount of cooling water flowing into the condenser (40).

    In the present embodiment, the controller (80) includes a microcomputer as a processing unit that controls each element of the air conditioner (10) as disclosed in the present application, and a memory or a hard disk that stores an executable control program. And The controller (80) is an example of a control unit of the air conditioner (10), and the detailed structure and algorithm of the controller (80) may be any hardware and software that execute the functions according to the present invention. May be combined.

-Driving operation-
The operation of the air conditioner (10) will be described.

    First, the controller (80) controls the solenoid valve (29) of the refrigerant circuit (20) and the flow control valve (73) of the water circuit (70) to be in an open state. In this state, the controller (80) starts the operation of the first to third compressors (31, 32, 33) and the blower fan (15) of the compressor unit (30), thereby causing the cooled air to flow into the ship. Is performed.

    Specifically, the high-pressure gas refrigerant compressed and discharged in the first to third compressors (31, 32, 33) flows into the condenser (40) via the high-pressure gas pipe (24). In the water-cooled condenser (40), the refrigerant exchanges heat (radiates heat) with the cooling water flowing through the plurality of cooling pipes (42) and condenses in the refrigerant chamber (S1). The refrigerant condensed in the condenser (40) is guided to the expansion valve (50) by the high-pressure liquid pipe (25), and is decompressed when passing through the expansion valve (50) to be in a gas-liquid two-phase state.

    The refrigerant that has passed through the expansion valve (50) passes through the low-pressure liquid pipe (26) and flows into the evaporator (60). In the evaporator (60), the refrigerant flowing through the heat transfer tube exchanges heat with the air passing between the fins (absorbs heat from the air) and evaporates. The refrigerant evaporated in the evaporator (60) becomes superheated steam and flows into the compressor unit (30) via the low-pressure gas pipe (27).

    The refrigerant flowing into the compressor unit (30) is divided into two parts, one of which is sucked into the first and second compressors (31, 32) connected in parallel with each other, and the other of which is the third compressor (33). ) Is inhaled. The refrigerant sucked into each compressor (31, 32, 33) is compressed and then discharged from each compressor (31, 32, 33).

<Judgment of abnormal state and operation at abnormal time>
In the air conditioner (10), in the water-cooled condenser (40), when the amount of cooling water flowing into the condenser (40) is excessive and there is a possibility that a hole is formed in the cooling pipe (42) (in the abnormal condition). In this case, an abnormal operation is performed to reduce the amount of cooling water flowing into the condenser.

    Specifically, when the high pressure and the low pressure in the refrigerant circuit (20) are within the normal range, it can be estimated that the refrigeration cycle is normally performed in the refrigerant circuit (20). In addition, when the amount of heat released from the condenser (40) is too small during the normal operation of the refrigeration cycle in the refrigerant circuit (20), it is determined that the amount of cooling water flowing into the condenser (40) is excessive. Can be estimated.

    Therefore, the controller (80) uses the above-mentioned estimation to calculate the high pressure (the value detected by the high pressure sensor (93)) of the refrigerant circuit (20) and the low pressure (the low pressure pressure sensor (94)) of the refrigerant circuit (20). Is a pressure within a predetermined normal range, and flows into the condenser (40) from the temperature of the cooling water flowing out of the condenser (40) (detected value of the outlet temperature sensor (96)). If the temperature difference obtained by subtracting the cooling water temperature (detected value of the inlet temperature sensor (95)) is smaller than a predetermined value, the abnormality determining unit (81) determines that the amount of the cooling water flowing into the condenser (40) is smaller. It is determined that the state is an excessive abnormal state. When the abnormality determining unit (81) determines that the state is abnormal, the abnormal state operation unit (82) performs an abnormal state operation of controlling the on-off valve (77) provided in the bypass pipe (76) to the open state.

    By such an abnormal operation, a part of the cooling water flowing through the inflow pipe (71) flows into the bypass pipe (76) and flows out to the outflow pipe (72). That is, in the abnormal operation, a part of the cooling water flowing through the inflow pipe (71) flows out of the outflow pipe (72) by bypassing the condenser (40), so that the cooling water flowing into the condenser (40) is cooled. The amount of water is reduced.

-Effects of Embodiment 1-
As described above, according to the present embodiment, the air conditioner (10) constituting the marine refrigeration system according to the present invention has an abnormal condition in which the amount of cooling water flowing into the water-cooled condenser (40) is excessive. An abnormality determination unit (81) for determining whether or not a predetermined abnormality is detected when the abnormality determination unit (81) determines that the state is abnormal, for reducing the amount of cooling water flowing into the condenser (40). An abnormal operation section (82) for performing the operation is provided. Such an abnormality judging section (81) and an abnormal operation section (82) allow the cooling water flowing into the condenser (40) to have an excessive amount of water and to cause a hole in the cooling pipe (42). At a certain time, by performing the predetermined abnormal operation, the amount of the cooling water flowing into the condenser (40) can be reduced, and it is possible to prevent the cooling pipe (42) from being perforated. That is, in the air conditioner (10) as a marine refrigerating apparatus including the water-cooled condenser (40), it is possible to prevent the cooling pipe (42) of the condenser (40) from being damaged.

    Further, according to the present embodiment, when the high pressure and the low pressure in the refrigerant circuit (20) are within the normal range, it is estimated that the refrigeration cycle is normally performed in the refrigerant circuit (20). When the refrigeration cycle is normal and the amount of heat radiation in the condenser (40) is too small, it is assumed that an abnormal state is caused in which the amount of cooling water flowing into the condenser (40) is excessive. Therefore, by detecting the high pressure and low pressure of the refrigerant circuit (20), the temperature of the cooling water flowing into the condenser (40), and the temperature of the cooling water flowing out of the condenser (40), the condensation is easily performed. An abnormal state where the amount of cooling water flowing into the vessel (40) is excessive can be detected.

    Further, according to the present embodiment, the abnormal operation section (82) controls the open / close valve (77) provided in the bypass pipe (76) to the open state as the abnormal operation. As a result, a part of the cooling water flowing through the inflow pipe (71) flows into the bypass pipe (76) and bypasses the condenser (40), thereby reducing the flow rate of the cooling water flowing into the condenser (40). can do. Therefore, it is possible to prevent the cooling pipe (42) of the condenser (40) from being damaged (perforated).

<< Embodiment 2 of the invention >>
The air conditioner (10) according to the second embodiment is obtained by partially changing the configuration of the air conditioner (10) of the first embodiment. As shown in FIG. 4, in the second embodiment, an inlet pressure sensor (97) is provided instead of the inlet temperature sensor (95) provided in the inflow pipe (71) of the first embodiment. An outlet pressure sensor (98) is provided instead of the outlet temperature sensor (96) provided in the outflow pipe (72).

    The inlet pressure sensor (97) is provided at the same position as the inlet temperature sensor (95), that is, between the bypass pipe (76) of the inflow pipe (71) and the condenser (40). The inlet pressure sensor (97) is configured to detect a pressure of the cooling water flowing into the condenser (40) through the inflow pipe (71) and transmit the detected pressure to the controller (80).

    On the other hand, the outlet pressure sensor (98) is provided at the same position as the outlet temperature sensor (96), that is, between the bypass pipe (76) of the outflow pipe (72) and the condenser (40). The outlet pressure sensor (98) is configured to detect a pressure of the cooling water flowing out of the condenser (40) to the outflow pipe (72) and transmit the detected pressure to the controller (80).

    In the second embodiment, the abnormality determination unit (81) of the controller (80) is configured to perform an abnormality determination different from that of the first embodiment. Specifically, the abnormality determination unit (81) determines that the differential pressure (head loss) obtained by subtracting the detection value of the outlet pressure sensor (98) from the detection value of the inlet pressure sensor (97) is larger than a predetermined normal value. In this case, it is configured to determine that the amount of the cooling water flowing into the condenser is in an abnormal state where the amount is excessive. The abnormal operation performed by the abnormal operation unit (82) is the same as that of the first embodiment.

<Judgment of abnormal state and operation at abnormal time>
Also in the second embodiment, in the air conditioner (10), in the water-cooled condenser (40), there is a possibility that the amount of cooling water flowing into the condenser (40) is excessive and a hole is formed in the cooling pipe (42). At a certain time (in an abnormal state), an abnormal operation is performed to reduce the amount of cooling water flowing into the condenser.

    Specifically, when the flow rate of the cooling water in the condenser (40) is too large, the head loss increases, and conversely, when the flow rate of the cooling water in the condenser (40) is too small, the head loss decreases. Therefore, when the head loss in the condenser (40) is larger than a predetermined normal value, it can be estimated that the cooling water in the condenser (40) is in an abnormal state in which the flow rate of the cooling water is excessive.

    Therefore, the controller (80) uses the above estimation to calculate the cooling water flowing out of the condenser (40) from the pressure of the cooling water flowing into the condenser (40) (the detection value of the inlet pressure sensor (97)). If the differential pressure (head loss) obtained by reducing the pressure (detected value of the outlet pressure sensor (98)) is larger than a predetermined normal value, the amount of cooling water flowing into the condenser (40) is excessive. It is determined that it is in the state.

    When the abnormality determination section (81) determines that the state is abnormal, the abnormality operation section (82) controls the open / close valve (77) provided in the bypass pipe (76) of the water circuit (70) to an open state. Perform the operation. Specifically, the abnormal-time operation unit (82) controls the on-off valve (77) to open so that a part of the cooling water flowing through the inflow pipe (71) bypasses the condenser (40). By flowing into the bypass pipe (76), the amount of cooling water flowing into the condenser (40) is reduced.

    Due to the abnormal operation described above, a part of the cooling water flowing through the inflow pipe (71) flows into the bypass pipe (76) and flows out to the outflow pipe (72). That is, in the abnormal operation, a part of the cooling water flowing through the inflow pipe (71) flows out of the outflow pipe (72) by bypassing the condenser (40), so that the cooling water flowing into the condenser (40) is cooled. The amount of water is reduced.

-Effects of Embodiment 2-
According to the second embodiment, when the head loss of the cooling water in the condenser (40) is larger than a predetermined normal value, it is determined that the abnormal state is such that the flow rate of the cooling water in the condenser (40) is excessive. It was estimated. Therefore, by calculating the head loss from the pressure of the cooling water flowing into the condenser (40) and the pressure of the cooling water flowing out of the condenser (40), the cooling water flowing into the condenser (40) can be easily calculated. An abnormal state in which the amount of water is excessive can be detected. That is, in the second embodiment, the same effect as in the first embodiment can be obtained.

<< Other embodiments >>
In each of the above embodiments, the controller (80) controls the on-off valve (77) provided in the bypass pipe (76) of the water circuit (70) to be in the open state, with the abnormal operation section (82) operating as abnormal. It was configured to perform an abnormal operation. However, the abnormal operation is not limited to the above embodiments. For example, the on-off valve (77) may be configured as a manual on-off valve, and the controller (80) may be configured such that the abnormal operation section (82) issues an alarm as an abnormal operation. In such a case, it is possible to detect that the operator is in an abnormal state by an alarm issued by the abnormal operation section (82). Therefore, the operator should take measures to reduce the flow rate of the cooling water in the condenser (40), such as opening the on-off valve (77) provided in the bypass pipe (76) of the water circuit (70). Accordingly, similarly to the above embodiments, breakage (perforation) of the cooling pipe (42) of the condenser (40) can be prevented.

    As described above, when the abnormal operation section (82) issues an alarm as an abnormal operation, the operator adjusts the opening degree of the manual flow control valve (73) provided on the inflow pipe (71). It may be reduced. Since the amount of cooling water flowing into the inflow pipe (71) is reduced by reducing the opening of the flow control valve (73), the amount of cooling water flowing into the condenser (40) can be reduced. it can. Therefore, similarly to the above embodiments, breakage (perforation) of the cooling pipe (42) of the condenser (40) can be prevented. In this case, the bypass pipe (76) and the on-off valve (77) may be omitted.

    INDUSTRIAL APPLICABILITY As described above, the present invention is useful for a marine refrigeration system including a water-cooled condenser and used for an air conditioner of a ship.

10 Air conditioner
20 refrigerant circuit
30 Compressor unit (compression mechanism)
40 condenser
41 shell
42 cooling pipe
50 Expansion valve (expansion mechanism)
60 evaporator
71 Inflow pipe
72 Outflow pipe
76 Bypass pipe
77 On-off valve
81 Abnormality judgment unit
82 Abnormal operation section
93 High pressure sensor
94 Low pressure sensor
95 Inlet temperature sensor
96 outlet temperature sensor
97 Inlet pressure sensor
98 Outlet pressure sensor
S1 Refrigerant chamber

Claims (5)

A shell (41), which is mounted on a ship and has a compression mechanism (30), a refrigerant chamber (S1) through which refrigerant flows, and a cooling pipe (42) through which the cooling water flows through the refrigerant chamber (S1) A refrigeration system for marine vessels, comprising: a refrigerant circuit (20) in which a water-cooled condenser (40) having an expansion mechanism (50) and an evaporator (60) are sequentially connected.
An abnormality determination unit (81) that determines whether the amount of cooling water flowing into the condenser (40) is in an excessively abnormal state;
When the abnormality determination unit (81) determines that the state is abnormal, the abnormality determination unit (81) performs a predetermined abnormality operation for reducing the amount of cooling water flowing into the condenser (40) while operating the marine refrigeration apparatus. A marine refrigeration system comprising an operation unit (82). In claim 1,
A high pressure sensor (93) for detecting a high pressure of the refrigerant circuit (20);
A low pressure sensor (94) for detecting a low pressure of the refrigerant circuit (20);
An inlet temperature sensor (95) for detecting a temperature of cooling water flowing into the condenser (40);
An outlet temperature sensor (96) for detecting a temperature of the cooling water flowing out of the condenser (40),
The abnormality determination section (81) determines that the detected value of the high-pressure pressure sensor (93) and the detected value of the low-pressure pressure sensor (94) are within a predetermined normal range, respectively, and that the outlet temperature sensor (96) A) a refrigeration system for a boat, characterized in that when the temperature difference obtained by subtracting the detection value of the inlet temperature sensor (95) from the detection value of the above) is smaller than a predetermined value, the abnormal state is determined. In claim 1,
An inlet pressure sensor (97) for detecting a pressure of cooling water flowing into the condenser (40),
An outlet pressure sensor (98) for detecting a pressure of the cooling water flowing out of the condenser (40),
The abnormality determination unit (81) is configured to determine whether or not the head loss is greater than a predetermined normal value by subtracting the detection value of the outlet pressure sensor (98) from the detection value of the inlet pressure sensor (97). A marine refrigeration system characterized by determining that there is a refrigeration system. In any one of claims 1 to 3,
The marine refrigerating apparatus, wherein the abnormal operation section (82) issues an alarm as the abnormal operation. In any one of claims 1 to 3,
An inflow pipe (71) through which cooling water flows into the condenser (40);
An outlet pipe (72) through which the cooling water flowing out of the condenser (40) flows;
A bypass pipe (76) having one end connected to the inflow pipe (71) and the other end connected to the outflow pipe (72);
An on-off valve (77) provided on the bypass pipe (76) for opening and closing the bypass pipe (76);
The refrigeration unit for boats, wherein the abnormal operation section (82) controls the on-off valve (77) from a closed state to an open state as the abnormal operation.

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