The present invention relates to a defrost system applied to a refrigeration apparatus that cools the interior of a cold storage room by circulating a CO2 refrigerant in a cooler provided in the cold storage room, and for removing frost attached to a fin-tube heat exchanger provided in the cooler.
From the viewpoint of preventing ozone layer depletion, preventing global warming, and the like, a refrigeration apparatus in which, as a refrigerant of a refrigeration apparatus used for indoor air conditioning, refrigeration of food, and the like, ammonia that has high cooling performance but is toxic is used as a primary refrigerant and CO2 that is non-toxic and odorless is used as a secondary refrigerant has widely been used.
In such a refrigeration apparatus, a primary refrigerant circuit in which ammonia refrigerant circulates and a secondary refrigerant circuit in which CO2 refrigerant circulates are connected by a cascade condenser, and heat is transferred between the ammonia refrigerant and the CO2 refrigerant in the cascade condenser. The CO2 refrigerant cooled and liquefied by the ammonia refrigerant is sent to the cooler provided inside the cold storage room, and cools the air inside the cold storage room via the fin-tube heat exchanger provided inside the casing of the cooler. The CO2 refrigerant partially vaporized by cooling the air in the cold storage room returns to a CO2 receiver via the secondary refrigerant circuit and is again cooled and liquefied by the cascade condenser.
During operation of the refrigeration apparatus, frost forms on the heat exchange tube provided in the cooler and reduces the heat transfer efficiency, and therefore it is necessary to perform defrosting (frost removal).
In this regard, for example, in Patent Literature 1 below, a defrost system in which a defrost circuit (thermosiphon defrost circuit) and a warm brine circuit are installed and which includes a first heat exchanger for heating a CO2 refrigerant circulating in the defrost circuit with warm brine is disclosed. With the defrost system configured as described above, a CO2 refrigerant liquid in a closed circuit drops by gravity to the first heat exchanger in the defrost circuit, and is heated and vaporized by the warm brine in the first heat exchanger. The vaporized CO2 refrigerant rises in the defrost circuit by the thermosiphon effect, and the risen CO2 refrigerant gas heats and melts the frost attached to the outer surface of the fin-tube heat exchanger provided inside the cooler. The CO2 refrigerant that is liquefied by heating the fin-tube heat exchanger descends in the defrost circuit by gravity. The CO2 refrigerant liquid that has descended to the first heat exchanger is again heated and vaporized in the first heat exchanger.
In the defrost system disclosed in Patent Literature 1, since the warm brine circuit is installed, a warm brine facility becomes bulky and the concentration control of the warm brine is required.
On the other hand, it is important to prevent icicles from forming in the lower part of the cooler by melting water flowing from the upper part of the cooler during defrosting.
The present invention was invented to solve the above problems, and an object is to provide a defrost system capable of preferable defrosting of a cooler and preventing icicles from being generated in a fin-tube heat exchanger at a lower part of a casing without having to install a warm brine circuit for heating a thermosiphon defrost circuit.
According to one aspect, a refrigeration apparatus comprises: a cold storage room; a cooler located in the cold storage room, wherein the cooler includes a casing and a fin-tube heat exchanger, with the fin-tube heat exchanger being positioned inside the casing; a drain pan located in the cold storage room at a position below the fin-tube heat exchanger; a circulation line connected to the fin-tube heat exchanger and configured to circulate a CO2 refrigerant having a low temperature at a time of cooling; a refrigeration cycle that cools and reliquefies the CO2 refrigerant in a gaseous form with a refrigerant that circulates inside the refrigeration cycle; and a defrost system positioned inside the cold storage room and outside the cooler to melt and remove frost attached to an outer surface of the fin-tube heat exchanger during defrosting. The defrost system comprises a thermosiphon defrost circuit that forms a CO2 circulation path together with the fin-tube heat exchanger, wherein the thermosiphon defrost circuit branches from the circulation line so that during the defrosting the CO2 refrigerant staying inside the fin-tube heat exchanger repeats a two-phase change of a gaseous form and reliquefaction. The defrost system also comprises an opening/closing valve that is closed during the defrosting and that sets the CO2 circulation path to a closed circuit in which the CO2 refrigerant is naturally circulated during the defrosting. The thermosiphon defrost circuit includes a first line branching from the circulation line of the CO2 refrigerant; a first header to which an end of the first line is connected, with the first header to which the end of the first line is connected including first and second parts that are spaced apart from one another; and a second header provided at a position higher than the first header, the second header including first and second parts that are spaced apart from one another. The first part of the first header and the first part of the second header are closest parts of the first and second headers, the second part of the first header and the second part of the second header are most distant parts of the first and second headers, and a straight line distance between the closest parts of the first and second headers is less than a straight line distance between the most distant parts of the first and second headers. Plural second lines extend between and communicate the first and second headers, and the plural second lines include a line connecting the most distant parts of the first header and the second header in a meander shape, and a line connecting the closest parts of the first header and the second header in a meander shape. The thermosiphon defrost circuit also includes a third line that is connected to and communicates with both the second header and the circulation line, and an electric heater positioned inside the cold storage room and outside the casing. The electric heater is positioned above all of the plural second lines that extend between and communicate the first and second headers, and the electric heater is configured to heat and vaporize the CO2 refrigerant liquid in the plural second lines of the closed circuit during the defrosting so that the CO2 refrigerant liquid that is vaporized rises in the thermosiphon defrost circuit by the principle of thermosiphon.
With the defrost system configured as described above, the CO2 refrigerant liquid in the closed circuit drops by gravity to the first electric heater in the thermosiphon defrost circuit, and is heated and vaporized by the first electric heater. The vaporized CO2 refrigerant rises in the thermosiphon defrost circuit by the principle of thermosiphon, and the risen CO2 refrigerant gas heats the fin-tube heat exchanger provided inside the cooler, and heats and melts the frost attached to the outer surface of the fin-tube heat exchanger. The CO2 refrigerant that is liquefied by heating the fin-tube heat exchanger descends in the thermosiphon defrost circuit by gravity. The CO2 refrigerant liquid that has descended to the first electric heater is heated and vaporized again by the first electric heater. From the above, it is possible to preferably perform defrosting of a cooler and prevent icicles from being generated in a fin-tube heat exchanger at a lower part of a casing without having to install a warm brine circuit for heating a thermosiphon defrost circuit.
According to another aspect, a refrigeration apparatus comprises a cold storage room and a cooler located in the cold storage room, wherein the cooler includes a casing and a heat exchanger, and the heat exchanger is positioned inside the casing. The heat exchanger comprises plural heat exchange tubes through which CO2 refrigerant flows, wherein the plural heat exchange tubes each have a lower end and an upper end, with the lower end of each of the plural heat exchange tubes being coupled to a lower header and the upper end of each of the plural heat exchange tubes being coupled to an upper header, and the upper header being positioned vertically above the lower header. The refrigeration apparatus also comprises: a drain pan located in the cold storage room at a position below the heat exchanger; a circulation line connected to the heat exchanger and configured to circulate a CO2 refrigerant having a low temperature at a time of cooling; a refrigeration cycle that cools and reliquefies the CO2 refrigerant in a gaseous form with a refrigerant that circulates inside the refrigeration cycle; and a defrost system positioned inside the cold storage room and outside the cooler to melt and remove frost attached to an outer surface of the heat exchanger during defrosting. The defrost system comprises: a thermosiphon defrost circuit that forms a CO2 circulation path together with the heat exchanger, with the thermosiphon defrost circuit branching from the circulation line so that during the defrosting the CO2 refrigerant staying inside the heat exchanger repeats a two-phase change of a gaseous form and reliquefaction. The defrost system also includes an opening/closing valve that is closed during the defrosting and that sets the CO2 circulation path to a closed circuit in which the CO2 refrigerant is naturally circulated during the defrosting. The thermosiphon defrost circuit includes: a first line branching from the circulation line of the CO2 refrigerant; a first header to which an end of the first line is connected, with the first header to which the end of the first line is connected including first and second parts that are spaced apart from one another, and the first line providing communication between the first header of the thermosiphon defrost circuit and the lower header of the heat exchanger so that the CO2 refrigerant that has entered the lower header after flowing through the plural heat exchange tubes flows toward the first header; and a second header provided at a position higher than the first header, the second header including first and second parts that are spaced apart from one another. The first part of the first header and the first part of the second header are closest parts of the first and second headers, the second part of the first header and the second part of the second header are most distant parts of the first and second headers, and a straight line distance between the closest parts of the first and second headers is less than a straight line distance between the most distant parts of the first and second headers. The thermosiphon defrost circuit also includes plural second lines that extend between and communicate the first and second headers, wherein the plural second lines include a line connecting the most distant parts of the first header and the second header in a meander shape, and a line connecting the closest parts of the first header and the second header in a meander shape. The thermosiphon defrost circuit further includes a third line that provides communication between the second header of the thermosiphon defrost circuit and the upper header of the heat exchanger, and an electric heater positioned inside the cold storage room and outside the casing, the electric heater positioned above all of the second lines that extend between and communicate the first and second headers. The electric heater is configured to heat and vaporize the CO2 refrigerant liquid in the second lines during the defrosting and without a brine circuit so that the CO2 refrigerant liquid that is vaporized rises in the thermosiphon defrost circuit by the principle of thermosiphon.
An embodiment of the present invention will be described with reference to
As shown in
In the cold storage room 10, as shown in
As shown in
As shown in
The fin-tube heat exchanger 13 includes the heat exchange tube 13A and fins 13B as shown in
As shown in
The fan 15 is arranged above the casing 12 as shown in
The defrost system 20 is provided for melting and removing (defrosting) frost attached to a surface of the fin-tube heat exchanger 13. As shown in
As shown in
As shown in
The configuration of the thermosiphon defrost circuit 21 will be described below in detail with reference to
As shown in
The three second lines 21D, 21E, 21F, as shown in
As shown in
The second electric heater 23 is, as shown in
The third electric heater 24 is, as shown in
As shown in
The circulation line 30 is configured to circulate the CO2 refrigerant. The circulation line 30, as shown in
The CO2 feed line 31 is, as shown in
Further, a first pump P1 is provided in the CO2 feed line 31, and the CO2 refrigerant in a liquid form in the CO2 receiver 40 is fed to the cooler 11 in the cold storage room 10 by the first pump P1.
As shown in
The first feed line 31A is connected to a first return line 32A via the one cooler 11. Further, the second feed line 31B is connected to a second return line 32B via the other cooler 11. The first return line 32A and the second return line 32B join again and are coupled to the CO2 return line 32.
The first feed line 31A is, as shown in
As shown in
At the time of defrosting, the control portion 35 can reduce the temperature of the first electric heater 22 or reduce the number of heaters of the first electric heater 22 among the six heaters to be turned on when the pressure of the CO2 circulation path measured by the pressure sensor 34 is higher than a predetermined pressure.
Further, the first return line 32A is provided with a branch circuit 37 that branches from the first return line 32A, the branch circuit 37 is provided with a pressure adjusting valve 38, and when the pressure is higher than a predetermined pressure, the pressure adjusting valve 38 is opened to reduce the pressure.
The reliquefaction line 33 is connected an upper part of the CO2 receiver 40. When passing through the reliquefaction line 33, the CO2 refrigerant in a gaseous form in the CO2 receiver 40 is reliquefied by a heat exchanger 51 of the ammonia refrigeration cycle 50 described below. Then, the reliquefied CO2 refrigerant in a liquid form returns to the CO2 receiver 40.
The ammonia refrigeration cycle 50 circulates the ammonia refrigerant. The ammonia refrigeration cycle 50 cools and liquefies the CO2 refrigerant in a gaseous form. As shown in
The ammonia refrigerant gas evaporated by the heat of the CO2 refrigerant in a gaseous form in the heat exchanger 51 is compressed by the refrigeration compressor 52, the high temperature and high pressure ammonia refrigerant gas is cooled and condensed in the condenser 53, the liquefied ammonia refrigerant liquid is stored in the ammonia receiver 54, the ammonia refrigerant liquid in the ammonia receiver 54 is fed to and expanded by the expansion valve 55, and the low-pressure ammonia refrigerant liquid is fed to the heat exchanger 51 and is used for cooling CO2 refrigerant in a gaseous form.
The cooling water circuit 60 is installed on the condenser 53. The cooling water circulating in the cooling water circuit 60 is heated by the ammonia refrigerant in the condenser 53.
The cooling water circuit 60 is connected to the closed cooling tower 70. The cooling water is circulated in the cooling water circuit 60 by a cooling water pump 61. The cooling water that has absorbed the exhaust heat of the ammonia refrigerant in the condenser 53 comes into contact with the outside air and spray water in the closed cooling tower 70, and is cooled by the latent heat of vaporization of the spray water.
The closed cooling tower 70 includes a cooling coil 71 connected to the cooling water circuit 60, a fan 72 for ventilating outside air a through the cooling coil 71, a sprinkling pipe 73 and a pump 74 for spraying the cooling water on the cooling coil 71. A part of the cooling water sprayed from the sprinkling pipe 73 evaporates, and the latent heat of vaporization is used to cool the cooling water flowing through the cooling coil 71.
The configuration of the refrigeration apparatus 1 has been described heretofore. Next, with reference to
The CO2 refrigerant liquid in the closed circuit drops by gravity in the thermosiphon defrost circuit 21 to the first header 21C and the three second lines 21D, 21E, 21F extending from the first header 21C, is heated and vaporized by the first electric heater 22. The vaporized CO2 refrigerant rises in the check valve 21J of the thermosiphon defrost circuit 21 by the principle of thermosiphon, and the risen CO2 refrigerant gas heats and melts the frost attached to the outer surface of the fin-tube heat exchanger 13 provided inside the cooler 11. The CO2 refrigerant that is liquefied by heating the fin-tube heat exchanger 13 descends in the thermosiphon defrost circuit 21 by gravity. The CO2 refrigerant liquid that has descended to the first header 21C and the three second lines 21D, 21E, 21F extending from the first header 21C is again heated and vaporized by the first electric heater 22.
The melt water obtained as the frost is heated and melted falls toward the drain pan 83. At this time, for example, with the configuration in which the second electric heater 23 is not provided, there is a possibility that icicles are formed as refreezing occurs below the fin-tube heat exchanger 13. On the other hand, with the defrost system 20 according to the present embodiment, since the second electric heater 23 and the third electric heater 24 are provided at the lowermost part inside the casing 12, it is possible to prevent icicles from being formed below the casing 12. Further, at the time of defrosting, as shown in
As described above, in the defrost system 20 of the refrigeration apparatus 1 according to the present embodiment, the cooler 11 including the casing 12, the fin-tube heat exchanger 13 provided inside the casing 12, and the drain pan 83 provided below the fin-tube heat exchanger 13 is provided inside the cold storage room 10. It is the defrost system 20 of the refrigeration apparatus 1 including the circulation line (secondary refrigerant circuit) 30 connected to the fin-tube heat exchanger 13 of the cooler 11 and in which a low-temperature CO2 refrigerant circulates at the time of cooling, and the refrigeration cycle 50 that cools and reliquefies the CO2 refrigerant in a gaseous form with a refrigerant circulating inside.
The defrost system 20 includes the thermosiphon defrost circuit 21 that is provided by being branched from the circulation line 30, in which, at the time of defrosting, the CO2 refrigerant staying inside the fin-tube heat exchanger 13 repeats a two-phase change of a gaseous form and reliquefaction, and which forms a CO2 circulation path together with the fin-tube heat exchanger 13; the opening/closing valves 34A and 34B that are closed at the time of defrosting and sets the CO2 circulation path to a closed circuit; and the first electric heater 22 arranged above the thermosiphon defrost circuit 21 so as to be adjacent to the thermosiphon defrost circuit 21.
The CO2 refrigerant is naturally circulated in the closed circuit at the time of defrosting. With the defrost system 20 configured in this way, the CO2 refrigerant liquid in the closed circuit is heated and vaporized by the first electric heater 22, and rises in the thermosiphon defrost circuit 21 by the principle of thermosiphon, the risen CO2 refrigerant gas heats the fin-tube heat exchanger 13 provided inside the cooler 11, and heats and melts the frost attached to the outer surface of the fin-tube heat exchanger 13. The CO2 refrigerant that is liquefied by heating the fin-tube heat exchanger 13 descends in the thermosiphon defrost circuit 21 by gravity. The CO2 refrigerant liquid that has descended to the first electric heater 22 is heated and vaporized by the first electric heater 22. Further, since the second electric heater 23 is provided at a lower part inside the casing 12, water droplets descending the fin-tube heat exchanger 13 can be recovered in the drain pan 83 without being refrozen to be icicles in the fin-tube heat exchanger 13 at a lower part of the casing 12. From the above, it is possible to preferably perform defrosting without installing a brine circuit, and it is possible to prevent the generation of icicles on the heat exchange tubes 13A and the fins 13B at a lower part of the casing 12.
Further, it includes the pressure sensor 34 for measuring the pressure of the CO2 circulation path at the time of defrosting, and the control portion 35 that controls the first electric heater 22 such that the pressure of the CO2 circulation path decreases when the measurement value measured by the pressure sensor 34 is higher than a predetermined pressure. With the defrost system 20 configured in this way, it is possible to prevent the pressure inside the thermosiphon defrost circuit 21 and the fin-tube heat exchanger 13 from becoming extremely high at the time of defrosting, and therefore it is possible to preferably prevent damage to the pipes of the thermosiphon defrost circuit 21 and the fin-tube heat exchanger 13.
Further, the thermosiphon defrost circuit 21 includes the first line 21B branched from the CO2 feed line 31 of the circulation line 30 of the CO2 refrigerant, the first header 21C to which an end of the first line 21B is connected, the three second lines 21D, 21E, 21F extending from the first header 21C, the second header 21G to which the three second lines 21D, 21E, 21F are connected and which is provided at a position higher than the first header 21C, and the third line 21H extending from the second header 21G and connected to the CO2 return line 32 of the circulation line 30.
The three second lines 21D, 21E, 21F include the second line 21D connecting the most distant parts of the first header 21C and the second header 21G in a meander shape, the second line 21E connecting the closest parts of the first header 21C and the second header 21G in a meander shape, and the second line 21F arranged between the second line 21D and the second line 21E. With this configuration, because the three second lines 21D, 21E, 21F, which are arranged without crossing one another, can be preferably heated by the first electric heater 22 via the heat transfer plate 82, the CO2 refrigerant can be naturally circulated.
With the defrost system 20 configured in this way, at the time of defrosting, it can be performed only by the first electric heater 22 that heats and naturally circulates the CO2 refrigerant remaining in the pipes of the thermosiphon defrost circuit 21 and the fin-tube heat exchanger 13 and enables heating and draining of the drain pan 83 and the second electric heater 23 for preventing re-freezing at the fin-tube heat exchanger 13 at a lower part of the casing 12 (the third electric heater 24 if the dummy pipe L is present), and therefore it is possible to perform defrosting with very little electric power as compared with heater defrost in which heaters are evenly arranged in the arrangement of the fin-tube heat exchanger 13. Further, since the fin-tube heat exchanger 13 is directly heated, the delay in starting the defrosting can be eliminated.
Further, it further includes the branch circuit 37 provided by being branched from the circulation line 30, and on the branch circuit 37, the pressure adjusting valve 38 for reducing the pressure when the pressure in the circulation line 30 is higher than a predetermined pressure is arranged. With the defrost system 20 configured in this way, it is possible to prevent the pressure inside the thermosiphon defrost circuit 21 and the fin-tube heat exchanger 13 from becoming extremely high at the time of defrosting operation, and therefore it is possible to preferably prevent damage to the thermosiphon defrost circuit 21 and the fin-tube heat exchanger 13.
It should be noted that the present invention is not limited to the above-described embodiment, but can be variously modified within the scope of the claims.
For example, in the above-described embodiment, the thermosiphon defrost circuit 21 includes the first line 21B branched from the circulation line 30, the first header 21C to which an end of the first line 21B is connected, the three second lines 21D, 21E, 21F extending from the first header 21C, the second header 21G to which the three second lines 21D, 21E, 21F are coupled, and the third line 21H extending from the second header 21G and connected to the circulation line 30, but is not particularly limited as long as it is configured to form the CO2 circulation path together with the fin-tube heat exchanger 13.
Further, in the above-described embodiment, the three second lines 21D, 21E, 21F are provided, but two or more may be provided.
Further, in the above-described embodiment, ammonia is used as the refrigerant of the refrigeration cycle, but it is not limited thereto, but chlorofluorocarbon or other natural refrigerants may be used.
Further, in the above-described embodiment, the two coolers 11 are provided, but one or three or more coolers 11 may be provided.
This application is a continuation of U.S. patent application Ser. No. 16/982,326 filed Sep. 18, 2020, which is a U.S. national stage application based on International Patent Application No. PCT/JP2019/028629 filed Jul. 22, 2019, the entire content of both of which is incorporated herein by reference.
Number | Date | Country | |
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Parent | 16982326 | Sep 2020 | US |
Child | 18145963 | US |