JP4290617B2 - Showcase - Google Patents

Description

  The present invention relates to a showcase in which products are displayed in a display chamber whose upper surface is open and cooled by circulating cold air heat exchanged with a cooler.

  Conventionally, this type of showcase, in particular, a showcase with an opening on the upper surface called a flat type, has a display room (inside a cabinet) with an upper surface opened in a heat insulating wall (heat insulating box). A cooler and a blower are installed in a duct for circulating cold air configured on the outdoor side. Then, the cool air exchanged with the cooler is discharged into the display chamber from the discharge port configured in the upper part of the display chamber by a blower, and is displayed in the display chamber by sucking into the duct from the suction port configured in the upper front part. Products such as food were cooled (see Patent Document 1).

There are two types of showcases of this type, one with an opening that can be opened and closed by a transparent door, and the other with an opening as described in Patent Document 1.
JP 2000-12001 A

  By the way, in such a showcase, since the moisture in circulating air adheres to a cooler as frost by cooling operation, defrosting is performed regularly, for example. This defrosting usually stops the supply of the refrigerant to the cooler, causes the electric heater provided in the cooler to generate heat, and operates the blower. The frost that has grown on the cooler is melted by the heat of the electric heater and the air blown from the blower, but the temperature of the cooler also rises as the defrosting progresses. The air that has exchanged heat with the raised temperature cooler is circulated by the blower.

  Since the cooling operation in the display room stops during the defrosting of the cooler, there is a concern that the temperature in the display room will rise, but in a flat showcase, the cold air tends to stay in the display room. The temperature rise during defrosting is smaller than that of a so-called vertical showcase that is open. However, when high-temperature air is circulated by the blower as described above, the temperature rise in the display room is promoted, and a solution has been desired.

  The present invention has been made to solve the conventional technical problem, and in a so-called flat type showcase, the cooler is quickly defrosted and the temperature rise in the display room is suppressed. For the purpose.

The showcase of the present invention constitutes a display chamber having an upper surface opened in a heat insulating wall, and circulates cool air exchanged with a cooler installed in a cool air circulation duct into the display chamber by a cooling fan, thereby A cooling air bypass means for returning the air discharged from the cooler to the air suction side of the cooling fan without passing through the display room, and a control device. When the control device operates the cooling fan during the defrosting of the cooler and starts the defrosting of the cooler, the temperature of the cooler or the temperature of the air exiting the cooler increases to a predetermined temperature. Further, it is characterized in that the air discharged from the cooler is returned to the air suction side of the cooling fan by the cold air bypass means.

The showcase of the invention of claim 2 constitutes a display chamber whose upper surface is open in the heat insulation wall, and circulates the cool air exchanged with the cooler installed in the cool air circulation duct into the display chamber by a cooling fan. A cooling air bypass means for cooling the product displayed in the display room and returning the air discharged from the cooler to the air suction side of the cooling fan without passing through the display room, and a control device. The control device operates the cooling fan during defrosting of the cooler, and after the start of defrosting of the cooler, when the predetermined delay period passes, It is characterized by returning to the air suction side of the cooling fan.

According to a third aspect of the present invention , in the above inventions, the cool air bypass means is operated and cooled by a bypass duct that communicates the air outflow side of the cooler and the air suction side of the cooling fan without passing through the display room. It is characterized by being comprised by the bypass fan which flows the air which came out of the vessel into the bypass duct.

The showcase of the invention of claim 4 is the bypass duct in which the cool air bypass means communicates the air outflow side of the cooler and the air suction side of the cooling fan without passing through the display chamber in the invention of claim 1 or claim 2 And a damper that opens and closes the inlet of the bypass duct. The damper closes the inlet of the bypass duct in a state where the air discharged from the cooler is discharged into the display chamber, and opens the inlet of the bypass duct for cooling. It is characterized by drawing the air that comes out of the vessel into the bypass duct.

The showcase of the invention of claim 5 is characterized in that, in the above, the damper prevents air discharged from the cooler from being discharged into the display chamber in a state where the inlet of the bypass duct is opened.

  In the present invention, a display room having an open top surface is formed in the heat insulating wall, and the cool air exchanged with the cooler installed in the cool air circulation duct is circulated into the display room by a cooling fan, so that In the showcase formed by cooling the displayed merchandise, the air conditioner includes cold air bypass means for returning the air discharged from the cooler to the air suction side of the cooling fan without passing through the display room, and a control device. The cooling fan is operated during defrosting of the cooler, and the air that has been discharged from the cooler is returned to the air intake side of the cooling fan by the cold air bypass means. It becomes possible to prevent or suppress an increase in temperature in the display room due to circulation in the display room.

  In particular, during the defrosting of the cooler, air that has not passed through the display chamber is circulated between the cooling fan and the cooler by the cold air bypass means, so that the defrosting of the cooler also proceeds quickly, The time required for defrosting is also shortened. Thereby, it becomes possible to suppress effectively the temperature rise in the display chamber during the defrosting of the cooler as a whole.

In particular, after starting the defrosting of the cooler , the control device removes the air from the cooler by the cold air bypass means when the temperature of the cooler or the temperature of the air leaving the cooler rises to a predetermined temperature. Since it returns to the air suction side of the cooling fan, at the start of defrosting of the cooler, cool air having a low temperature can be circulated in the display chamber until the temperature of the cooler rises to a temperature that adversely affects the display chamber. As a result, the temperature rise in the display chamber during defrosting can be further suppressed.

In the second aspect of the invention, the control device starts the defrosting of the cooler, and then, when a predetermined delay period elapses, causes the cooler air to bypass the air that has been discharged from the cooler to the air suction side of the cooling fan. Therefore, when the cooler starts to defrost, during the period when the temperature of the cooler is still low, it becomes possible to circulate cool air having a low temperature in the display room, and increase the temperature in the display room during the defrosting. Further suppression can be achieved.

According to a third aspect of the present invention , in addition to each of the above-described inventions, the cool air bypass means includes a bypass duct that communicates the air outflow side of the cooler and the air suction side of the cooling fan without passing through the display chamber, Because it is configured with a bypass fan that flows the air from the bypass duct to the bypass duct, the cool air coming out of the cooler during the defrosting of the cooler is drawn into the bypass duct smoothly by operating the bypass fan. It will be possible to return. Further, since air is drawn into the bypass duct by the operation of the bypass fan, there is no opening / closing portion, and therefore there is no risk of malfunction due to freezing or the like.

In the invention of claim 4, in addition to the invention of claim 1 or claim 2, the cold air bypass means includes a bypass duct that communicates the air outflow side of the cooler and the air suction side of the cooling fan without passing through the display chamber. The damper is configured by a damper that opens and closes the inlet of the bypass duct. The damper closes the inlet of the bypass duct in a state in which air discharged from the cooler is discharged into the display chamber, and opens the inlet of the bypass duct to cool the cooler. Since the air from the air is drawn into the bypass duct, the inlet of the bypass duct is opened by a damper during the defrosting of the cooler, and the cool air coming out of the cooler is drawn into the bypass duct smoothly, and the air is sucked into the cooling fan. It will be possible to return to the side. Further, since the opening and closing is performed by the damper, the bypass circuit can be reliably ensured.

In the invention of claim 5, in addition to the above, the damper prevents air discharged from the cooler from being discharged into the display chamber in a state where the inlet of the bypass duct is opened. The air whose temperature has risen is circulated in the display room, and the inconvenience of the temperature rise can be reliably prevented.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  1 and 2 are longitudinal side views of a showcase 1 according to an embodiment of the present invention, FIG. 3 is an electrical circuit diagram of the showcase 1, and FIG. 4 is a timing chart for explaining the operation of the showcase 1. 1 and 2, a showcase 1 of the embodiment is a flat type low temperature showcase for freezing or refrigeration (in the embodiment, for freezing) installed in a store such as a supermarket, and includes a heat insulating wall 2 and a front transparent wall 3. A display chamber 6 having an open upper surface is formed on the inner side of the partition plate 4 attached with a space inside.

  Between the partition plate 4 and the heat insulating wall 2 and the front transparent wall 3, a duct 7 for circulating cold air is configured below and in front and rear outside of the display chamber 6, and at the upper rear side of the display chamber 6. A cold air discharge port 8 communicating with the upper end portion of the rear duct 7 is configured, and a cold air suction port 9 communicating with the upper end portion of the front duct 7 is configured in the upper front side of the display chamber 6. In addition, a plurality of sliding door type transparent doors 11 are slidably attached to the upper surface opening of the display chamber 6 in the left-right direction, and the upper surface opening of the display chamber 6 is closed openably.

  Further, a cooler 12 is installed vertically in the lower part of the rear duct 7, and a cooling fan (cooling air circulation fan) 14 is installed in the fan case 13 in the lower duct 7. ing. The cooling fan 14 is operated and sucks air from the front (air suction side) and blows out into the fan case 13 toward the rear (air discharge side) cooler 12. The fan case 13 extends to the lower part of the cooler 12. A defrost heater (electric heater for defrosting) 16 for defrosting the cooler 12 is provided below the cooler 12 located on the air discharge side of the cooling fan 14 and on the air inflow side of the cooler 12. It is attached. The cooler 12 is supplied with a refrigerant from a refrigerator (not shown) installed in a store machine room or the like via a liquid electromagnetic valve 17 described later.

  Further, another partition plate 18 is attached to the surface of the cooler 12 on the partition plate 4 side with a space therebetween, and the lower end thereof reaches the fan case 13. Further, the fan case 13 is also spaced from the partition plate 4, whereby a series of bypass ducts 19 partitioned from the inside of the duct 7 between the partition plate 4, the partition plate 18 and the fan case 13. Is formed. The inlet 19A of the bypass duct 19 is open on the lower side (windward side) of the cool air outlet 8 and on the upper side of the cooler 12, and the outlet 19B is opened on the air suction side of the cooling fan 14. is doing.

  Thus, the bypass duct 19 communicates the air outflow side of the cooler 12 and the air suction side of the cooling fan 14 outside the partition plate 4, that is, without passing through the display chamber 6. A bypass fan 21 is attached to the inlet 19 </ b> A of the bypass duct 19. The bypass fan 21 is operated and plays a role of sucking air in the duct 7 on the upper side of the cooler 12, that is, on the air outflow side, into the bypass duct 19. The bypass fan 21 and the bypass duct 19 constitute the cold air bypass means of the present invention.

  Next, in FIG. 3, the defrost heater 16 is connected to a three-phase 200 V power source via a contact 22 </ b> A of the relay 22 and an overheat preventer 23. Reference numeral 24 denotes a temperature controller as a control device. The liquid electromagnetic valve 17 is connected to a single-phase 200 V power source via a temperature adjustment contact 26 of the temperature controller 24. The relay 22 is connected to a single-phase 200 V power source via a defrost (defrost) contact 27 of the temperature controller 24. The bypass fan 21 is connected to a single-phase 200 V power source via a bypass fan defrost contact 28 of the temperature controller 24 and a bypass fan control thermo 29. The bypass fan control thermo 29 detects the temperature of the cooler 12 or the temperature of the cool air that has exited the cooler 12 (in the embodiment, the temperature of the cool air that has exited the cooler 12), and is a predetermined temperature, for example, When the temperature exceeds -10 ° C, the contact is closed.

  The cooling fan 14 is connected to a single-phase 200V power source. In the figure, reference numeral 31 denotes a dew proof heater. This dew-proof heater 31 is attached to the upper end of the front transparent wall 3 and the like, and generates heat to prevent dew condensation on the upper end and the like, and is connected to a single-phase 200V power source.

  With the above configuration, the operation of the showcase 1 of the embodiment will be described next with reference to FIG. When the three-phase 200V and single-phase 200V power supplies are turned on in the showcase 1, the cooling fan 14 is energized and operated, and the dew proof heater 31 is energized to generate heat. The temperature controller 24 performs a cooling operation based on the temperature in the display chamber 6, for example, closing the temperature adjustment contact 26 at −14 ° C. and opening the temperature adjustment contact 26 at −16 ° C. In this cooling operation, the temperature controller 24 opens the defrost contact 27 and the bypass fan defrost contact 28. Therefore, the relay 22 is not energized and the defrost heater 16 does not generate heat because the contact 22A is open. Further, the bypass fan 22 is not energized, and the bypass fan 22 is stopped.

  In this cooling operation, when the temperature control contact 26 is closed, the liquid electromagnetic valve 17 is energized and opened. When the liquid electromagnetic valve 17 is opened, it is discharged from a compressor of a refrigerator (not shown) in a high-temperature and high-pressure state, dissipates heat in a condenser (not shown), condenses, and then the refrigerant decompressed by an expansion valve (not shown) is supplied to the cooler 12. Where it evaporates. The refrigerant then repeats circulation to return to the compressor of the refrigerator.

  Due to the evaporation of the refrigerant in the cooler 12, the cooler 12 exhibits a cooling action. The air in the duct 7 that exchanges heat with the cooler 12, that is, the cold air, is blown upward by operating the cooling fan 14, and is discharged from the cold air discharge port 8 to the lower portion of the upper surface opening of the display chamber 6. The cool air discharged into the display chamber 6 cools the inside of the display chamber 6 while forming a cool air curtain below the upper surface opening, flows into the duct 7 from the cool air suction port 9, and is sucked into the cooling fan 14. The state of the cold air circulation during this cooling operation is indicated by arrows in FIG.

  The temperature controller 25 opens the temperature adjustment contact 26 when the temperature in the display chamber 6 decreases to -16 ° C. Thereby, since the liquid electromagnetic valve 17 is closed, the refrigerant supply to the cooler 12 is stopped, and the cooling action of the cooler 12 is interrupted. During this time, the cooling fan 14 continues to operate. After that, when the temperature of the display chamber 6 rises to reach −14 ° C., the temperature controller 25 closes the temperature adjusting contact 26, so that the liquid electromagnetic valve 17 is opened again, and the refrigerant is supplied to the cooler 12 to perform the cooling action. Demonstrated. As a result, the inside of the display room 6 is cooled to an average freezing temperature of about −15, and the products stored in the display room 6 are displayed in a frozen state.

  By such a cooling operation, moisture in the circulating cold air, moisture generated from the product, moisture entering from the outside, and the like adhere to the cooler 12 as frost and grow. Therefore, the temperature controller 24 starts defrosting (defrosting) of the cooler 12 at a predetermined time (or a predetermined cooling operation time), for example.

  That is, when defrosting of the cooler 12 is started, the temperature controller 24 opens the temperature adjustment contact 26 regardless of the temperature in the display chamber 6 and closes the defrost contact 27 and the bypass fan defrost contact 28. Thereby, since the liquid electromagnetic valve 17 is closed, the supply of the refrigerant to the cooler 12 is stopped. Further, since the relay 22 is energized, the contact 22A is closed, and the defrost heater 16 is energized to generate heat.

  The defrost contact 28 for the bypass fan is also closed. At this time, the temperature of the cooler 12 is still low, and the temperature of the cool air coming out of the defrost contact 28 has not reached −10 ° C., so the bypass fan control thermo 29 opens the contact. ing. Therefore, at the beginning of the defrosting, the bypass fan 22 is stopped without being energized. On the other hand, since the cooling fan 14 is continuously operated, the cool air (cool air having a temperature lower than −10 ° C.) from the cooler 12 is still discharged from the cool air discharge port 8 to the display chamber 6 as shown by an arrow in FIG. Is done. Thereby, the inside of the display chamber 6 is cooled as much as possible at the start of the defrosting.

  On the other hand, since the cold air blown out from the cooling fan 14 is heated by the defrost heater 16 and then flows into the cooler 12, the cooler 12 is heated and defrosted. As the defrosting of the cooler 12 proceeds, the temperature of the cool air that has left the cooler 12 gradually rises, and when the temperature reaches −10 ° C., the bypass fan control thermo 29 closes the contact point. The bypass fan 21 is energized to start operation. When the bypass fan 21 is operated, all or most of the air discharged from the cooler 12 is drawn into the bypass fan 21 and flows into the bypass duct 19 from the inlet 19A (arrow in FIG. 2). .

  The air flowing into the bypass duct 19 passes through it and flows out from the outlet 19B to the air suction side of the cooling fan 14, so that the air is sucked into the cooling fan 14, heated by the defrost heater 16, and then cooled. The container 12 will be sprayed. In this way, thereafter, as indicated by arrows in FIG. 2, the air is circulated sequentially in the cooling fan 14, the defrost heater 16, the cooler 12, the bypass fan 21, the bypass duct 19, and the cooling fan 14. The defrosting proceeds quickly. On the other hand, since the air warmed by defrosting is not discharged into the display chamber 6, the temperature rise of the cool air staying in the display chamber 6 is not promoted.

  When the defrosting of the cooler 12 is performed in this way and the temperature of the cooler 12 reaches a predetermined defrosting end temperature, the temperature controller 24 opens the defrost contact 27 based on the output of a defrost return thermostat (not shown). . As a result, the relay 22 is de-energized and the contact 22A is opened, so that the defrost heater 16 stops generating heat and the defrosting of the cooler 12 ends. After that, when a predetermined draining period (time until the defrost water decreases from the cooler 12) elapses, the temperature controller 24 opens the bypass fan defrost contact 28 and closes the temperature adjustment contact 26. As a result, the bypass fan 21 is stopped and the liquid electromagnetic valve 17 is opened to restart the above-described cooling operation.

  Thus, when the cooling fan 12 is defrosted, the cooling fan 14 is operated, and the bypass fan 21 returns the air discharged from the cooler 12 via the bypass duct 19 to the air suction side of the cooling fan 14. The temperature rise in the display chamber 6 due to the circulation of the air whose temperature has increased during the defrosting of the cooler 12 into the display chamber 6 can be prevented or suppressed.

  In particular, air that has not passed through the display chamber 6 (air heated by the defrost heater 16) is circulated between the cooling fan 14 and the cooler 12 through the bypass duct 19 when the cooler 12 is defrosted. Therefore, the defrosting of the cooler 12 also proceeds quickly, and the time required for the defrosting is shortened. Thereby, the temperature rise in the display chamber 6 during the defrosting of the cooler 12 as a whole can be effectively suppressed.

  In addition, after defrosting of the cooler 12 is started, when the temperature of the air exiting the cooler 12 (or the temperature of the cooler 12 may be increased) to −10 ° C. (predetermined temperature) described above, the bypass is performed. Since the fan 21 is operated and the air discharged from the cooler 12 is returned to the air suction side of the cooling fan 14, the temperature of the cooler 12 enters the display chamber 6 at the start of defrosting of the cooler 12. Until the temperature rises to an adverse temperature, cold air having a low temperature can be circulated in the display chamber 6, and the temperature rise in the display chamber 6 during defrosting can be further suppressed. Become.

  In particular, the bypass duct 19 that allows the air outflow side of the cooler 12 and the air suction side of the cooling fan 14 to communicate with each other without passing through the display chamber 6, and the air that has been operated and has exited the cooler 12 flow to the bypass duct 19. Since the cold air bypass means of the present invention is configured by the bypass fan 21, the cold air discharged from the cooler 12 during the defrosting of the cooler 12 is smoothly drawn into the bypass duct 19 by operating the bypass fan 21. It becomes possible to return to the air suction side. Further, since the air is drawn into the bypass duct 19 by the operation of the bypass fan 21, the opening / closing portion is eliminated as compared with the case where a damper or the like is used, and therefore the risk of malfunction due to icing or the like is eliminated.

  In the above embodiment, the bypass fan 22 is operated after the temperature of the cooler 12 rises to −10 ° C. after the start of defrosting using the bypass fan control thermo 29, but this is not a limitation. At 30, the bypass fan 22 may be energized with a delay from the start of defrosting. In that case, as shown in FIG. 5, a delay timer 30 is connected to the position of the bypass fan control thermo 29 in the circuit of FIG. The delay timer 30 is connected to an internal contact after a predetermined delay period, for example, any time (for example, 5 minutes to 10 minutes) (set according to usage conditions) has elapsed after the bypass fan defrost contact 28 is closed. Is to close.

  By configuring in this manner, the bypass fan 22 is stopped without energization during a period when the temperature of the cooler 12 is still low after the start of defrosting (the delay period), and the cooling fan 14 causes the display chamber to be stopped from the cool air discharge port 8. It becomes possible to discharge cool air at a low temperature to 6 and to cool the inside of the display chamber 6 as much as possible at the start of defrosting as described above.

  Next, a showcase 1 according to another embodiment of the present invention will be described with reference to FIGS. In addition, what is shown with the same code | symbol as FIG. 1 thru | or FIG. 5 in each figure shall show | play the same or similar function, and abbreviate | omits description. 6 and 7, in this case, a damper (motor drive) 34 is attached to the inlet 19 </ b> A of the bypass duct 19 instead of the bypass fan 21. Therefore, in this case, the damper 34 and the bypass duct 19 constitute the cold air bypass means of the present invention. The damper 34 is driven by a motor and closes the inlet 19A as shown in FIG. 6, opens the inlet 19A as shown in FIG. 7, and opens the inlet 19A, while the duct 19 above the cooler 12, that is, the cold air outlet 8 is opened. The duct 7 on the windward side is closed to prevent the cool air from the cooler 12 from being discharged into the display chamber 6 from the cool air discharge port 8.

  Next, in FIG. 8, 37 is a relay, and this relay 37 is connected to a single-phase 200V power source via a damper defrost contact 28A of the temperature controller 24 and a damper control thermo 29A. The damper defrost contact 28A performs the same operation as the bypass fan defrost contact 28 described above, and the damper control thermo 29A performs the same operation as the bypass fan control thermo 29 described above. That is, the damper control thermo 29A detects the temperature of the cooler 12 or the temperature of the cool air that has exited the cooler 12 (in the embodiment, the temperature of the cool air that has exited the cooler 12), and the predetermined temperature, for example, When the temperature exceeds -10 ° C, the contact is closed.

  The damper 34 (actually the motor that drives the damper 34) is connected to a single-phase 200V power source via a switching contact 37A of the relay 37 and limit switches 38 and 39. The limit switch 38 is connected to the forward rotation terminal 37AA of the switching contact 37A, and the limit switch 39 is connected to the reverse rotation terminal 37AB. When the relay 37 is not energized, the switching contact 37A closes to the forward rotation terminal 37AA, and the damper 34 (motor) rotates forward to close the inlet 19A of the bypass duct 19. The limit switch 38 opens when the damper 34 closes the inlet 19A, and stops the forward rotation of the damper 34. Further, when the relay 37 is energized and the switching contact 37A closes to the reverse rotation terminal 37AB, the damper 34 (the motor thereof) reverses and opens the inlet 19A of the bypass duct 19. The limit switch 39 opens when the damper 34 opens the inlet 19A and closes the duct 7, and stops the reverse rotation of the damper 34.

  With the above configuration, the operation of the showcase 1 of the embodiment in this case will be described next with reference to FIG. When the three-phase 200V and single-phase 200V power supplies are turned on in the showcase 1, the cooling fan 14 is energized and operated, and the dew proof heater 31 is energized to generate heat. The temperature controller 24 performs a cooling operation based on the temperature in the display chamber 6, for example, closing the temperature adjustment contact 26 at −14 ° C. and opening the temperature adjustment contact 26 at −16 ° C. In this cooling operation, the temperature controller 24 opens the defrost contact 27 and the damper defrost contact 28A. Therefore, the relay 22 is not energized and the defrost heater 16 does not generate heat because the contact 22A is open. Further, since the relay 37 is also de-energized, the switching contact 37A is closed to the normal rotation terminal 37AA. Accordingly, the damper 34 is rotated forward to close the inlet 19A.

  In this cooling operation, when the temperature control contact 26 is closed, the liquid electromagnetic valve 17 is energized and opened. When the liquid electromagnetic valve 17 is opened, it is discharged from a compressor of a refrigerator (not shown) in a high-temperature and high-pressure state, dissipates heat in a condenser (not shown), condenses, and then the refrigerant decompressed by an expansion valve (not shown) is supplied to the cooler 12. Where it evaporates. The refrigerant then repeats circulation to return to the compressor of the refrigerator.

  Due to the evaporation of the refrigerant in the cooler 12, the cooler 12 exhibits a cooling action. The air in the duct 7 that exchanges heat with the cooler 12, that is, the cold air, is blown upward by operating the cooling fan 14, and is discharged from the cold air discharge port 8 to the lower portion of the upper surface opening of the display chamber 6. The cool air discharged into the display chamber 6 cools the inside of the display chamber 6 while forming a cool air curtain below the upper surface opening, flows into the duct 7 from the cool air suction port 9, and is sucked into the cooling fan 14. The state of the cold air circulation during this cooling operation is indicated by arrows in FIG.

  The temperature controller 25 opens the temperature adjustment contact 26 when the temperature in the display chamber 6 decreases to -16 ° C. Thereby, since the liquid electromagnetic valve 17 is closed, the refrigerant supply to the cooler 12 is stopped, and the cooling action of the cooler 12 is interrupted. During this time, the cooling fan 14 continues to operate. After that, when the temperature of the display chamber 6 rises to reach −14 ° C., the temperature controller 25 closes the temperature adjusting contact 26, so that the liquid electromagnetic valve 17 is opened again, and the refrigerant is supplied to the cooler 12 to perform the cooling action. Demonstrated. As a result, the inside of the display room 6 is cooled to a freezing temperature of about −15 on average, and the goods stored in the display room 6 are displayed in a frozen state.

  By such a cooling operation, moisture in the circulating cold air, moisture generated from the product, moisture entering from the outside, and the like adhere to the cooler 12 as frost and grow. Therefore, the temperature controller 24 starts defrosting (defrosting) of the cooler 12 at a predetermined time (or a predetermined cooling operation time), for example.

  That is, when the defrosting of the cooler 12 is started, the temperature controller 24 opens the temperature adjustment contact 26 regardless of the temperature in the display chamber 6, and closes the defrost contact 27 and the damper defrost contact 28A. Thereby, since the liquid electromagnetic valve 17 is closed, the supply of the refrigerant to the cooler 12 is stopped. Further, since the relay 22 is energized, the contact 22A is closed, and the defrost heater 16 is energized to generate heat.

  The damper defrost contact 28A is also closed, but at this time, the temperature of the cooler 12 is still low, and the temperature of the cool air coming out of it does not reach -10 ° C., so the damper control thermo 29A is open. . Therefore, at the beginning of this defrosting, the relay 37 is not energized, and the damper 34 does not reverse but closes the inlet 19A. On the other hand, since the cooling fan 14 is continuously operated, cold air (cool air having a temperature lower than −10 ° C.) from the cooler 12 is still discharged from the cold air discharge port 8 to the display chamber 6 as shown by an arrow in FIG. Is done. Thereby, the inside of the display chamber 6 is cooled as much as possible at the start of the defrosting.

  On the other hand, since the cold air blown out from the cooling fan 14 is heated by the defrost heater 16 and then flows into the cooler 12, the cooler 12 is heated and defrosted. As the defrosting of the cooler 12 proceeds, the temperature of the cool air that has left the cooler 12 gradually rises. When the temperature reaches −10 ° C., the damper control thermo 29A closes the contact point, so that the relay 37 is energized. Then, the switching contact 37A is closed to the reverse rotation terminal 37AB, and from that time, the damper 34 opens the inlet 19A and closes the duct 7. The limit switch 39 opens when the damper 34 closes the duct 7 and stops the damper 34. When the damper 34 opens the inlet 19A and closes the duct 7, all of the air discharged from the cooler 12 comes into the bypass duct 19 from the inlet 19A (arrow in FIG. 7).

  Since the air flowing into the bypass duct 19 passes there and flows out from the outlet 19B to the air suction side of the cooling fan 14, the air is sucked into the cooling fan 14, heated by the defrost heater 16, and then cooled. The container 12 will be sprayed. In this way, thereafter, as indicated by arrows in FIG. 7, air is sequentially circulated through the cooling fan 14, the defrost heater 16, the cooler 12, the damper 34, the bypass duct 19, and the cooling fan 14. Defrosting proceeds quickly. On the other hand, since the air warmed by defrosting is not discharged into the display chamber 6, the temperature rise of the cool air staying in the display chamber 6 is not promoted.

  When the defrosting of the cooler 12 is performed in this way and the temperature of the cooler 12 reaches a predetermined defrosting end temperature, the temperature controller 24 opens the defrost contact 27 based on the output of a defrost return thermostat (not shown). . As a result, the relay 22 is de-energized and the contact 22A is opened, so that the defrost heater 16 stops generating heat and the defrosting of the cooler 12 ends. Thereafter, when a predetermined draining period (time until the defrost water decreases from the cooler 12) elapses, the temperature controller 24 opens the damper defrost contact 28A and closes the temperature adjustment contact 26. As a result, the relay 37 is de-energized, and the damper 34 is rotated forward to close the inlet 19A, the duct 7 is opened, the liquid electromagnetic valve 17 is opened, and the cooling operation described above is resumed. .

  In this way, the cooling fan 14 is operated during defrosting of the cooler 12, the inlet 19 </ b> A of the bypass duct 19 is opened by the damper 34 to close the duct 7, and the air discharged from the cooler 12 is passed through the bypass duct 19. Since the cooling fan 14 is returned to the air suction side, the temperature rise in the display chamber 6 due to the circulation of the air whose temperature has increased during the defrosting of the cooler 12 into the display chamber 6 is prevented or suppressed. Will be able to.

  In particular, also in this case, air that has not passed through the display chamber 6 (air heated by the defrost heater 16) is circulated between the cooling fan 14 and the cooler 12 through the bypass duct 19 when the cooler 12 is defrosted. As a result, the defrosting of the cooler 12 proceeds quickly, and the time required for the defrosting is shortened. Thereby, the temperature rise in the display chamber 6 during the defrosting of the cooler 12 as a whole can be effectively suppressed.

  Also in this case, after the defrosting of the cooler 12 is started, the temperature of the air exiting the cooler 12 (or the temperature of the cooler 12 may be increased) to -10 ° C. (predetermined temperature) described above. In this case, the inlet 19A is opened by the damper 34 so that the air discharged from the cooler 12 is returned from the bypass duct 19 to the air suction side of the cooling fan 14, so that the cooler 12 is started when defrosting is started. Until the temperature rises to a temperature that adversely affects the display room 6, cold air having a low temperature can be circulated in the display room 6, and the temperature rise in the display room 6 during defrosting is not increased. Further suppression can be achieved.

  In particular, in this case, since the damper 19 opens and closes the inlet 19A of the bypass duct 19, the air discharged from the cooler 12 through the bypass duct 19 is returned to the air suction side of the cooling fan 14 as compared with the bypass fan described above. A bypass circuit can be ensured reliably. Further, the damper 34 prevents the air discharged from the cooler 12 from being discharged into the display chamber 6 in a state where the inlet 19A of the bypass duct 19 is opened, so that the air whose temperature has increased during defrosting is displayed. It is possible to reliably prevent the inconvenience that the temperature rises due to circulation to the chamber 6.

  In the above-described embodiment, after the defrosting is started using the damper control thermo 29A, the relay 37 is energized after the temperature of the cooler 12 rises to -10 ° C. The relay 37 may be energized with a delay from the start of defrosting. In that case, as shown in FIG. 10, a delay timer 30A is connected to the position of the damper control thermo 29A in the circuit of FIG. After the damper defrost contact 28A is closed, the delay timer 30A is connected to the internal contact after a predetermined delay period, for example, any one of 5 minutes to 10 minutes (set according to usage conditions, etc.) elapses. Close.

  With this configuration, the inlet 19 </ b> A is closed without reversing the damper 34 during the period when the temperature is still low after the defrosting of the cooler 12 (the delay period), and the display chamber is opened from the cool air discharge port 8 by the cooling fan 14. It becomes possible to discharge cool air at a low temperature to 6 and to cool the inside of the display chamber 6 as much as possible at the start of defrosting as described above.

  In each of the above embodiments, the cooler 12 is heated by the defrost heater at the time of defrosting. However, in the case of a showcase for refrigeration, the cooling fan is not limited thereto, and the cooling fan supplies air to the cooler while the cooling fan is stopped. The present invention is effective even in so-called off-cycle defrosting. In each of the above embodiments, the upper surface opening of the display chamber 6 is closed by the sliding door type transparent door. However, the present invention is not limited to this, and the present invention has a tremendous effect even in a constantly open type showcase having no door.

It is a vertical side view of the showcase of one Example of this invention. Example 1 It is another vertical side view of the showcase of FIG. It is an electric circuit diagram of the showcase of FIG. It is a timing chart explaining operation | movement of the showcase of FIG. It is an electric circuit diagram of the other Example of the showcase of FIG. It is a vertical side view of the showcase of the other Example of this invention. (Example 2) It is another vertical side view of the showcase of FIG. It is an electric circuit diagram of the showcase of FIG. It is a timing chart explaining operation | movement of the showcase of FIG. It is an electric circuit diagram of the other Example of the showcase of FIG.

DESCRIPTION OF SYMBOLS 1 Showcase 2 Heat insulation wall 4 Partition plate 6 Display room 7 Duct 8 Cold air outlet 9 Cold air inlet 12 Cooler 14 Cooling fan 16 Defrost heater 19 Bypass duct 21 Bypass fan 24 Temperature controller 28 Defrost contact for bypass fan 28A Damper defrost Contact 29 Bypass fan control thermo 29A Damper control thermo 30, 30A Delay timer 34 Damper

Claims (5)

A display room having an upper surface opened in the heat insulating wall is constructed, and the cool air exchanged with the cooler installed in the cool air circulation duct is circulated in the display room by a cooling fan, thereby being displayed in the display room. In a showcase that cools the product,
Cold air bypass means for returning the air that has exited the cooler without passing through the display chamber to the air suction side of the cooling fan, and a control device,
The control device operates the cooling fan at the time of defrosting the cooler and, after starting the defrosting of the cooler, the temperature of the cooler or the temperature of the air exiting the cooler is set to a predetermined temperature. The showcase according to claim 1, wherein when the air is raised, the cool air bypass means returns the air discharged from the cooler to the air suction side of the cooling fan. A display room having an upper surface opened in the heat insulating wall is constructed, and the cool air exchanged with the cooler installed in the cool air circulation duct is circulated in the display room by a cooling fan, thereby being displayed in the display room. In the showcase that cools the product,
Cold air bypass means for returning the air that has exited the cooler without passing through the display chamber to the air suction side of the cooling fan, and a control device,
The control device operates the cooling fan at the time of defrosting the cooler, and after the start of defrosting of the cooler, when the predetermined delay period has elapsed, the cooler bypass means exits the cooler. Showcase, wherein the air is returned to the air suction side of the cooling fan. The cold air bypass means includes a bypass duct that communicates the air outflow side of the cooler and the air suction side of the cooling fan without passing through the display chamber, and air that is operated and exits from the cooler. The showcase according to claim 1, wherein the showcase is configured by a bypass fan that flows through the fan. The cold air bypass means includes a bypass duct that communicates the air outflow side of the cooler and the air suction side of the cooling fan without passing through the display room, and a damper that opens and closes the inlet of the bypass duct, The damper closes the inlet of the bypass duct in a state where the air discharged from the cooler is discharged into the display chamber, opens the inlet of the bypass duct, and draws the air discharged from the cooler into the bypass duct. The showcase according to claim 1 or 2, characterized in that. 5. The showcase according to claim 4, wherein the damper prevents air discharged from the cooler from being discharged into the display chamber in a state where an inlet of the bypass duct is opened.

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