JP2008002699A - Refrigerator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve capacity efficiency by disposing an air blower at a rear part in comparison with a conventional one to widen a depth of a refrigerating compartment. <P>SOLUTION: This refrigerator comprises a temperature switching compartment discharge damper 37 for opening and closing an introduction ventilation passage 15 connecting a cooler 11 and an inflow side of a temperature switching compartment 3, a temperature switching compartment return damper 38 for opening and closing a return ventilation passage 17 connecting the cooler 11 and an outflow side of the temperature switching compartment 3, a temperature switching compartment air blower 18 for taking-in and discharging the cold air to the temperature switching compartment when the temperature switching compartment discharge damper 37 and the temperature switching compartment return damper 38 are opened, and a communication passage 30 for guiding the air discharged from the temperature switching compartment 3 to an air suction side of the temperature switching compartment air blower 18. The return ventilation passage 17 is formed in a state of extending downward from the temperature switching compartment return damper 38, the communication passage 30 is formed from the temperature switching compartment return damper 38 to a rear part, and the return ventilation passage 17 and the communication passage 30 are selectively opened by a baffle 38c. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a refrigerator having first and second storage chambers in which cold air circuits are arranged in parallel.

  Patent Document 1 discloses a refrigerator that includes a temperature switching chamber in addition to a freezer compartment and a refrigerator compartment. This refrigerator includes a damper device that opens and closes a passage of cool air sent to the temperature switching chamber, and a heater that raises the temperature of the temperature switching chamber. Thereby, the room temperature of the temperature switching chamber can be switched to a desired low temperature range such as freezing, refrigeration, partial, chilled, etc. according to the user's application.

  Patent Document 2 discloses a refrigerator in which a heater is provided in a temperature switching chamber and the temperature switching chamber can be maintained at a temperature higher than room temperature by driving the heater. Thereby, heat insulation of a heating thing, warm cooking, etc. can be performed.

  FIG. 10 is a side sectional view showing the temperature switching chamber of the refrigerator. The back surface of the temperature switching chamber 3 is covered with a back plate 40. An air inlet 40 a through which air flows into the temperature switching chamber 3 is provided at the upper part of the back plate 40. An air outlet 40 b through which air flows out from the temperature switching chamber 3 is provided at the lower part of the back plate 40. The temperature switching chamber blower 18 is provided facing the air inlet 40a, and the heater 16 is disposed between the temperature switching chamber blower 18 and the air inlet 40a.

  A temperature switching chamber discharge damper 37 is provided behind the temperature switching chamber blower 18. The temperature switching chamber discharge damper 37 opens and closes an introduction ventilation path communicating with a cooler (not shown). A temperature switching chamber return damper 38 is disposed behind the air outlet 40b. The temperature switching chamber return damper 38 is formed with an opening 38a that opens rearward and a 38b that opens upward, and has a baffle 38c that opens one side and closes the other by turning. The opening 38 a extends rearward and faces the return ventilation path 17 communicating with the cooler, and the opening 38 b communicates with the intake side of the temperature switching chamber blower 18 through the communication path 30.

  When the temperature switching chamber 3 is switched to the low temperature side, the temperature switching chamber blower 18 is driven by opening the openings 38a of the temperature switching chamber discharge damper 37 and the temperature switching chamber return damper 38. Thereby, the cold air generated by the cooler is guided from the temperature switching chamber discharge damper 37 to the intake side of the temperature switching chamber blower 18, and the cold air flows into the temperature switching chamber 3 through the air inlet 40a. The cold air flows through the temperature switching chamber 3 and flows out from the air outlet 40b, returns from the opening 38a through the ventilation passage 17, and returns to the cooler.

When the opening 38b of the temperature switching chamber return damper 38 is opened, the air flowing out from the air outlet 40b is guided to the intake side of the temperature switching chamber blower 18, and the return ventilation path 17 is closed. Therefore, when the opening 38 a and the temperature switching chamber discharge damper 37 (see FIG. 4) are closed, the air in the temperature switching chamber 3 can be circulated by driving the temperature switching chamber blower 18. As a result, the heater 16 is driven to raise the temperature in the temperature switching chamber 3 and to maintain a high temperature.
Japanese Patent Laid-Open No. 10-288440 JP 2006-125705 A

  According to the refrigerator disclosed in Patent Document 2, the return ventilation path 17 extends rearward from the opening 38a on the back surface of the temperature switching chamber return damper 38 and is bent downward. The communication path 30 extends upward from the opening 38 b on the upper surface of the temperature switching chamber return damper 38 and guides air to the intake side of the temperature switching chamber blower 18.

  When the temperature switching chamber blower 18 is arranged behind the opening 38b of the temperature switching chamber return damper 38, the communication passage 30 is bent in a U shape. Thereby, the pressure loss of the air led to the temperature switching chamber blower 18 increases. For this reason, the temperature switching chamber blower 18 is disposed vertically above the opening 38 b on the upper surface of the temperature switching chamber return damper 38.

  Since the return ventilation path 17 is arranged behind the temperature switching chamber return damper 38, a space wider than the depth of the return ventilation path 17 is provided behind the temperature switching chamber blower 18. Thereby, the depth of the temperature switching chamber 3 became narrow, and there existed a problem that the volumetric efficiency of a refrigerator was bad.

  An object of this invention is to provide the refrigerator which can improve volumetric efficiency.

  In order to achieve the above object, the refrigerator of the present invention has first and second storage chambers that are insulated from each other, and the cold air generated by the cooler branches into the first and second storage chambers arranged in parallel. In the refrigerator that flows in and flows out from the first and second storage chambers and returns to the cooler, the first air passage that connects the cooler and the inflow side of the second storage chamber is opened and closed. A damper, a second damper that opens and closes a return air passage that connects the cooler and the outflow side of the second storage chamber, and when the first and second dampers are opened, cool air is taken into the second storage chamber and discharged. And a communication passage that guides air discharged from the second storage chamber to the intake side of the blower when the return air passage is closed by the second damper, and extends downward from the second damper. The return ventilation path is formed and the communication path is formed rearward from the second damper. , The second damper is characterized by having a baffle opening alternatively pivot and the return air path between the said communicating passage at the rear end.

  According to this configuration, the cold air generated in the cooler flows into the first storage chamber, flows through the first storage chamber, and returns to the cooler. Further, when the first and second dampers are opened and the blower is driven, the cool air of the cooler flows into the second storage chamber through the introduction ventilation path. The cold air flowing into the second storage chamber flows through the room and returns to the cooler via the return ventilation path. When the return air passage is closed by the rotation of the baffle to open the communication path and the first damper is closed, the air in the second storage chamber is circulated through the communication path by driving the blower. Thereby, the stored item can be cooled and stored in the first storage chamber, and the heated item can be kept warm in the second storage chamber.

  Moreover, the present invention is characterized in that, in the refrigerator configured as described above, the intake side of the blower is arranged behind the second damper.

  Further, in the refrigerator having the above-described configuration, the present invention is provided with a heating device that raises the temperature of the second storage chamber. The second storage chamber opens the first and second dampers and cools by the cooler; It is characterized by comprising a temperature switching chamber that can be switched to a room temperature on the high temperature side that is heated to a temperature higher than the normal temperature by the heating device with the second damper closed.

  According to the present invention, since the first and second storage chambers are arranged in parallel with the cold air circuit, the first and second dampers are closed while cooling in the first storage chamber, and the heated object is kept warm in the second storage chamber. be able to. In addition, since the return air passage formed extending downward from the second damper and the communication passage disposed behind are selectively opened by the second damper, the blower in which air is guided to the intake side through the communication passage There is no need to return to the back of the ventilation path. Therefore, it is possible to improve the volumetric efficiency of the refrigerator by disposing the blower rearward and increasing the depth of the second storage chamber. In addition, the amount of storage that can be kept warm in the second storage room increases, and the convenience of the refrigerator can be improved.

  Further, according to the present invention, since the intake side of the blower is disposed behind the second damper, the depth of the temperature switching chamber can be reliably widened.

  In addition, according to the present invention, the second storage chamber is composed of a temperature switching chamber that can be switched between a low temperature side for storing stored items in a cold state and a high temperature side that is higher than normal temperature. The amount of stored goods can be increased and the convenience of the refrigerator can be improved.

  Embodiments of the present invention will be described below with reference to the drawings. For convenience of explanation, the same reference numerals are given to the same parts as in the conventional example shown in FIG. 1 and 2 are a front view and a right side view showing a refrigerator according to one embodiment. The refrigerator 1 is provided with a refrigerator compartment 2 at the top, and below the refrigerator compartment 2, a temperature switching chamber 3 and an ice making chamber 4 are arranged side by side. A freezing room 6 is arranged below the temperature switching room 3 and the ice making room 4, and a vegetable room 5 is arranged below the freezing room 6.

  The refrigerator compartment 2 stores stored items in a refrigerator, and the vegetable compartment 5 cools and preserves vegetables at a room temperature (about 8 ° C.) higher than the refrigerator compartment 2. As will be described later in detail, the temperature switching chamber 3 can be switched by the user at room temperature. The freezer 6 stores the stored items in a frozen state, and the ice making chamber 4 communicates with the freezer 6 to make ice.

  FIG. 3 is a right side sectional view of the refrigerator 1. The main body of the refrigerator 1 is filled with a foam heat insulating material 1c between the outer box 1a and the inner box 1b. The ice making chamber 4 and the temperature switching chamber 3 are separated from the refrigerator compartment 2 by a heat insulating wall 7, and the freezer compartment 6 and the vegetable compartment 5 are separated from each other by a heat insulating wall 8. Further, the temperature switching chamber 3 and the freezing chamber 6 are separated by a heat insulating wall 35 (see FIG. 5), and the temperature switching chamber 3 and the ice making chamber 4 are separated by a vertical heat insulating wall 36 (see FIG. 5). ing.

  When the foam heat insulating material 1c is filled between the outer box 1a and the inner box 1b, the heat insulating walls 7 and 8 are filled simultaneously. That is, the stock solution of the foam heat insulating material 1c is injected simultaneously between the outer box 1a and the inner box 1b and into the heat insulating walls 7 and 8 communicating with the outer box 1a, and is foamed integrally. Thereby, the heat insulation walls 7 and 8 can be easily formed thinly, and the volume of the refrigerator compartment 2 can be ensured widely.

  The ice making room 4, the freezing room 6, the vegetable room 5 and the temperature switching room 3 are provided with a storage case 43 for storing stored items. The refrigerator compartment 2 is provided with a plurality of storage shelves 41 on which stored items are placed. A plurality of storage pockets 42 are provided on the door of the refrigerator compartment 2. Thereby, the usability of the refrigerator 1 is improved. A chilled chamber 21 maintained at a chilled temperature zone (about 0 ° C.) is provided in the lower part of the refrigerator compartment 2.

  A machine room 50 is provided behind the vegetable room 5, and a compressor 57 is disposed in the machine room 50. The compressor 57 is connected to a condenser, an expander (not shown), and a cooler 11, and a refrigerant such as isobutane is circulated by driving the compressor 57 to operate a refrigeration cycle. Thereby, the cooler 11 becomes the low temperature side of the refrigeration cycle.

  6 to 8 show a side view, a rear view, and a plan view in the machine room 50. An electrical box 52 attached to the main body of the refrigerator 1 is installed at the rear of the machine room 50. The back surface of the machine room 50 is covered with a back cover 50a made of metal. The electrical box 52 is open at the back and is sealed by the back cover 50a. Thereby, the electrical component 51 covered with the back cover 50a and the electrical box 52 is provided.

  The electrical component 51 includes electrical components including a control board 53 that controls the compressor 57 and each blower. Since the electrical unit 51 is installed in the machine room 50, it is possible to secure a large volume of the refrigerator room 2 that is frequently used as compared with the case where it is installed behind the refrigerator room 2, and to improve the convenience of the refrigerator 1. it can.

  A hole 52 a is provided on the side surface of the electrical box 52. A lead wire holding portion 54 made of a resin molded product is fitted into the hole 52a. The lead wire holding unit 54 relays a lead wire (not shown) connected to the electrical component in the electrical component unit 51.

  The back cover 50a and the electrical box 52 are in close contact with each other by an annular seal member 58, and the lead wire holding portion 54 and the hole portion 52a are sealed with a seal member (not shown). Thereby, while the inside of the electrical equipment part 51 is sealed and waterproofed, when the combustible refrigerant leaks, it is possible to prevent ignition due to the intrusion of the combustible refrigerant into the electrical equipment part 51.

  The electrical box 52 is formed by drawing a metal plate and can easily dissipate heat generated by the electrical components. Also, a resin support base 55 that supports the control board 53 is in close contact with the electrical box 52 so that heat generated by the control board 53 can be easily transmitted to the electrical box 52.

  A condenser (not shown) is disposed on the bottom surface of the main body portion in front of the machine room 50, and a condenser fan 60 that cools the condenser is provided on the front surface of the machine room 50. When the condenser fan 60 is driven, outside air is taken in from an intake port 56 provided on the bottom surface of the main body, and the air exchanged heat with the condenser flows into the machine chamber 50 via the condenser fan 60. The condenser fan 60 sends air toward the exposed front surface of the electrical box 52, exchanges heat with the electrical box 52, cools the compressor 57, and flows out to the outside.

  Since air is sent toward the front surface of the electrical box 52 by the condenser fan 60, the heat generated by the electrical components can be radiated more efficiently. Alternatively, the electrical box 52 may be formed of a resin molded product having a frame part on the front side, and a metal plate may be fitted to the frame part.

  In FIG. 3, a cold air passage 31 is provided behind the freezer compartment 6, and a cooler 11 is disposed in the cold air passage 31. Behind the refrigerator compartment 2 is provided a cold air passage 32 communicating with the cold air passage 31 via the refrigerator compartment damper 20. The cooler 11 on the low temperature side of the refrigeration cycle exchanges heat with the air flowing through the cold air passage 31 to generate cold air. A defrost heater 33 for defrosting the cooler 11 is provided below the cooler 11.

  In the cold air passages 31 and 32, the freezer compartment fan 12 and the refrigerator compartment fan 23 are respectively arranged. As will be described in detail later, the cold air generated by the cooler 11 flows through the front portion 31 a of the cold air passage 31 by driving the freezer compartment fan 12, and is supplied to the ice making chamber 4, the freezer compartment 6, and the temperature switching chamber 3. . The cold air is supplied to the refrigerator compartment 2, the chilled compartment 21 and the vegetable compartment 5 through the cold passage 32 by driving the refrigerator compartment fan 23.

  The refrigerating room blower 23 is composed of an axial fan, and is arranged with the axial direction directed up and down. Thereby, the refrigerator compartment fan 23 becomes low in a height direction, and the refrigerator compartment fan 23 and the heat insulation wall 7 can be arrange | positioned in the same horizontal surface so that it may overlap in a front projection. Therefore, the volume of the refrigerator compartment 2 with high use frequency can be secured widely. Further, the cold air can be guided to the cold air passage 32 with a low pressure loss. The refrigerator compartment fan 23 may be formed by a centrifugal fan.

  FIG. 4 shows a front sectional view of the refrigerator 1. The cold air passage 31 behind the freezer compartment 6 opens the front of the freezer compartment fan 12, and air is sent out to the ice making chamber 4 by the freezer compartment fan 12. A freezer return damper 22 is provided at the lower part of the freezer compartment 6 communicating with the ice making chamber 4. The air volume of the air flowing out of the freezer compartment 6 is adjusted by opening and closing the freezer return damper 22. Further, an introduction ventilation path 15 that branches from the cold air passage 31 and guides the cold air to the temperature switching chamber 3 is provided.

  The upper part of the cold air passage 31 communicates with the cold air passage 32 via the refrigerator compartment damper 20. When the refrigerator compartment damper 20 is opened and the freezer compartment fan 12 is driven, cold air is supplied to the refrigerator compartment 2 and the chilled compartment 21. The refrigerator compartment damper 20 is arranged behind the vertical heat insulation wall 36 so as to overlap the vertical heat insulation wall 36 in front projection.

  A refrigerator compartment outlet 2 a is opened at the lower back of the refrigerator compartment 2, and a vegetable compartment inlet (not shown) is provided in the vegetable compartment 5. The refrigerator compartment outlet 2 a and the vegetable compartment inlet are connected by a connection path 34 that passes through the back surface of the temperature switching chamber 3, and the refrigerator compartment 2 and the vegetable compartment 5 communicate with each other. A return ventilation path 46 (see FIG. 3) communicating with the cold air passage 31 is provided at the upper back of the vegetable compartment 5.

  A temperature switching chamber blower 18 and a heater 16 are disposed on the upper portion of the temperature switching chamber 3. A temperature switching chamber discharge damper 37 is provided at the lower right of the temperature switching chamber 3. The temperature switching chamber discharge damper 37 is disposed on the introduction ventilation path 15, and the temperature switching chamber blower 18 is disposed above the introduction ventilation path 15. When the temperature switching chamber discharge damper 37 is opened and the temperature switching chamber blower 18 is driven, cold air flows from the cooler 11 into the temperature switching chamber 3 through the introduction ventilation path 15. The amount of air flowing into the temperature switching chamber 3 from the introduction ventilation path 15 is adjusted by the opening / closing amount of the temperature switching chamber discharge damper 37.

  A temperature switching chamber return damper 38 is provided at the lower left portion of the temperature switching chamber 3. The temperature switching chamber return damper 38 opens and closes the return ventilation path 17 extending downward, and the air in the temperature switching chamber 3 returns to the cool air passage 31 via the return ventilation path 17.

  The cooler 11 is formed by meandering refrigerant pipes 11a through which refrigerant flows, and left and right ends of the refrigerant pipes 11a are supported by end plates 11b. The air flowing through the return air passage 17 is returned to the cooler 11 from an outlet 17 a provided in the middle of the cooler 11 in the vertical direction. As a result, the cold air that has flowed through the temperature switching chamber 3 having a small volume is cooled at the upper part of the cooler 11, and the cold air that has flowed through the large-sized refrigerator compartment 3, vegetable room 5, and freezer room 6 It is cooled as a whole. Therefore, the cold air flowing out from the temperature switching chamber 3 is not heat exchanged with the cooler 11 more than necessary, and the heat exchange efficiency of the cooler 11 can be improved.

  Further, the cold air flowing out from the freezer compartment 3 through the freezer return damper 22 is guided between the end plates 11b on both sides. The cold air flowing out from the vegetable compartment 5 is guided to the entire left and right direction inside and outside the end plates 11b on both sides of the cooler 11 via a return ventilation path 46 (see FIG. 3).

  Thereby, the heat exchange area of the cold air flowing out from the vegetable compartment 5 becomes larger than the heat exchange area of the cold air flowing out from the freezer compartment 6. Therefore, the low temperature cold air returning from the freezer compartment 6 is not cooled more than necessary, and the high temperature cold air returning from the vegetable compartment 5 is cooled by the entire cooler 11 so that the heat exchange efficiency of the cooler 11 can be further improved.

  Since the temperature switching chamber 3 may be maintained at the freezing temperature, the end plate 11b is provided with a notch (not shown) at a position facing the outlet 17a of the return ventilation path 17. Thereby, the cold air that has flowed out of the temperature switching chamber 3 can be guided between the end plates 11b on both sides.

  An accumulator 45 is connected to the upper part of the refrigerant pipe 11a. The accumulator 45 is disposed at the end of the ice making chamber 4 away from the temperature switching chamber 3. Thereby, even if the temperature switching chamber discharge damper 37 is disposed below the temperature switching chamber 3, it does not interfere with the accumulator 45. As a result, it is possible to avoid the interference between the refrigerator compartment damper 20 and the temperature switching chamber discharge damper 37 and arrange the refrigerator compartment damper 20 behind the vertical heat insulating wall 36.

  FIG. 5 shows a side sectional view of the temperature switching chamber 3. The upper and lower surfaces of the temperature switching chamber 3 are insulated from the refrigerator compartment 2 and the freezer compartment 6 by heat insulation walls 7 and 35. The front surface of the temperature switching chamber 3 can be opened and closed by a pivotable door 9. The back surface of the temperature switching chamber 3 is covered with a back plate 40. An air inlet 40 a through which air flows into the temperature switching chamber 3 is provided at the upper part of the back plate 40. An air outlet 40 b through which air flows out from the temperature switching chamber 3 is provided at the lower part of the back plate 40.

  The temperature switching chamber blower 18 is provided facing the air inlet 40a, and the heater 16 is disposed between the temperature switching chamber blower 18 and the air inlet 40a. The heater 16 is formed of a heat radiation type glass tube heater, and raises the temperature of the temperature switching chamber 3 by radiant heat released through the back plate 40. The temperature switching chamber blower 18 is disposed so as to blow toward the surface of the heater 16. Thereby, the surface temperature of the heater 16 can be lowered and safety can be improved. Above the heater 16, a temperature sensor 24 for detecting the temperature in the temperature switching chamber 3 is provided.

  A panel heater 44 that uniformly dissipates heat from the entire surface is provided below the temperature switching chamber 3. The panel heater 44 is disposed between the heat insulating wall 35 via a gap d, and uniformly heats from the upper and lower surfaces to raise the temperature in the temperature switching chamber 3. Heat dissipation can be improved by dissipating heat from both sides. The gap d is preferably 10 to 20 mm. Thereby, while ensuring the volume in the temperature switching chamber 3, the raise of the surface temperature of the heat insulation wall 35 can be suppressed, and the heat leak to the freezer compartment 6 can be prevented.

  The storage case 43 in the temperature switching chamber 3 is made of metal and placed on the panel heater 44. Thereby, the stored item in the storage case 43 can be efficiently heated. The panel heater 44 may be pivotally supported at the rear end. Thereby, the front part of the panel heater 44 can be lifted and the lower part of the panel heater 44 can be easily cleaned.

  A temperature switching chamber return damper 38 is disposed behind the air outlet 40b. The temperature switching chamber return damper 38 is formed with an opening 38a that opens downward and a 38b that opens backward, and has a baffle 38c that opens one side and closes the other by turning. The opening 38a faces the return ventilation path 17 extending downward, and the opening 38b faces the communication path 30 arranged rearward.

  The communication path 30 extends rearward and bends upward to connect the intake side of the temperature switching chamber blower 18 and the opening 38b. Since the communication path 30 is arranged behind the temperature switching chamber return damper 38, the intake side of the temperature switching chamber blower 18 can be arranged behind the temperature switching chamber return damper 38. Thereby, the depth of the temperature switching chamber 3 can be widened.

  When the opening 38b of the temperature switching chamber return damper 38 is opened, the air flowing out from the air outlet 40b is guided to the intake side of the temperature switching chamber blower 18, and the return ventilation path 17 is closed. Therefore, when the opening 38 a and the temperature switching chamber discharge damper 37 (see FIG. 4) are closed, the air in the temperature switching chamber 3 can be circulated by driving the temperature switching chamber blower 18. In the following description, when the opening 38a is opened and the opening 38b is closed, the temperature switching chamber return damper 38 is open, and when the opening 38a is closed and the opening 38b is opened, the temperature is switched. The chamber return damper 38 is in a closed state.

  FIG. 9 is a cold air circuit diagram showing the flow of cold air in the refrigerator 1. The freezer compartment 6, the refrigerator compartment 2, and the temperature switching chamber 3 are each arranged in parallel. The ice making room 4 is arranged in series with the freezer room 6, and the vegetable room 5 is arranged in series with the refrigerator room 2. The cold air generated by the cooler 11 is sent to the ice making chamber 4 by driving the freezer blower 12. The cold air sent to the ice making room 4 flows through the ice making room 4 and the freezing room 6, flows out from the freezing room return damper 22, and returns to the cooler 17. As a result, the ice making chamber 4 and the freezing chamber 6 are cooled.

  The cold air branched on the exhaust side of the freezer compartment fan 12 is sent to the refrigerating compartment 2 and the chilled compartment 21 through the refrigerating compartment damper 20 by driving the refrigerating compartment blower 23. The cold air that has flowed through the refrigerator compartment 2 and the chilled compartment 21 and exchanged heat with the stored material flows into the vegetable compartment 5 through the connection path 34. The cold air flowing into the vegetable compartment 5 circulates in the vegetable compartment 5 and returns to the cooler 11 through the return ventilation path 46. Thereby, the inside of the refrigerator compartment 2 and the vegetable compartment 5 is cooled, and when it becomes preset temperature, the refrigerator compartment damper 20 will be closed.

  Further, the cold air branched on the exhaust side of the freezer compartment fan 12 flows into the temperature switching chamber 3 through the temperature switching chamber discharge damper 37 by driving the temperature switching chamber blower 18. The cold air that has flowed into the temperature switching chamber 3 flows through the temperature switching chamber 3, flows out of the temperature switching chamber return damper 38, and returns to the cooler 11 through the return ventilation path 17. Thereby, the inside of the temperature switching chamber 3 is cooled.

  As described above, the temperature switching chamber 3 can switch the room temperature by a user's operation. The operation modes of the temperature switching chamber 3 are wine (8 ° C.), refrigeration (3 ° C.), chilled (0 ° C.), soft freezing (−8 ° C.), and freezing (−15 ° C.) depending on the temperature zone. Provided.

  Thus, the user can store the refrigerated product at a desired temperature by refrigeration or refrigeration. The room temperature can be switched by varying the amount of opening of the temperature switching chamber discharge damper 37. For example, the heater 16 or the panel heater 44 may be energized to switch the temperature from the frozen room temperature to the refrigerated room temperature. Thereby, it can switch to desired room temperature rapidly.

  Further, by energizing the heater 16 and the panel heater 44, the room temperature of the temperature switching chamber 3 can be switched from the low temperature side where the stored items are cooled and stored to the high temperature side higher than the normal temperature. Thereby, temporary heat insulation, warm cooking, etc. of the cooked heated food can be performed.

  When the temperature switching chamber 3 is switched to the high temperature side, the opening 38a of the temperature switching chamber return damper 38 and the temperature switching chamber discharge damper 37 are closed. Then, the temperature switching chamber blower 18, the heater 16, and the panel heater 44 are driven to shift to a temperature raising period in which the temperature in the temperature switching chamber 3 is raised.

  When the temperature switching chamber 3 is heated to a predetermined temperature, the temperature switching chamber blower 18 and the heater 16 are stopped, and the panel heater 44 is driven. Thereby, it transfers to the heat retention period which maintains the temperature switching chamber 3 at predetermined temperature, and heats a stored thing. During the heat retention period, the panel heater 44 is turned on and off in the vicinity of the set temperature to maintain the set temperature.

  By driving the heater 16 and the panel heater 44 having a large capacity during the temperature raising period, the temperature can be quickly raised to a desired room temperature. Further, since the temperature switching chamber blower 18 and the heater 16 are stopped and the panel heater 44 having a small capacity is driven during the heat retention period, the power can be saved and the room can be easily maintained at a uniform temperature. Moreover, since the temperature switching chamber blower 18 is stopped, the stored product can be prevented from drying.

  Since the growth temperature of the main food poisoning bacteria is 30 ° C. to 45 ° C., the indoor temperature on the high temperature side is preferably set to 50 ° C. or more in consideration of the tolerance of the heater capacity, the temperature distribution in the temperature switching chamber 3, and the like. Thereby, propagation of food poisoning bacteria can be prevented.

  Moreover, since the heat-resistant temperature of the general resin parts used for a refrigerator is 80 degreeC, when the room temperature of a high temperature side shall be 80 degrees C or less, it can implement | achieve cheaply. In addition, in order to sterilize food poisoning bacteria, for example, in the case of enterohemorrhagic E. coli (pathogenic E. coli O157), heating at 75 ° C. for 1 minute is required. Therefore, it is more desirable to set the indoor temperature on the high temperature side to 75 ° C. to 80 ° C.

The following are the test results on the sterilization of food poisoning bacteria at 55 ° C. In the initial state, E. coli 2.4 × 10 ³ CFU / mL, Staphylococcus aureus 2.0 × 10 ³ CFU / mL, Salmonella 2.1 × 10 ³ CFU / mL, Vibrio parahaemolyticus 1.5 × 10 ³ CFU / ML, Cereus 4.0 × 10 ³ CFU / mL. This test sample was heated from 3 ° C. to 55 ° C. over 40 minutes, kept at 55 ° C. for 3.5 hours, then returned from 55 ° C. to 3 ° C. over 80 minutes, and the amount of each bacterium was examined again. As a result, all the bacteria were reduced to a level of 10 CFU / mL or less (not detected). Therefore, even if the set temperature on the high temperature side of the temperature switching chamber 3 is 55 ° C., there is a sufficient sterilization effect.

  According to the present embodiment, since the refrigerator compartment 2, the temperature switching chamber 3, the freezer compartment 6, and the vegetable compartment 5 are arranged in this order from the top, the width of the freezer compartment 6 and the vegetable compartment 5 is widened, and the convenience of the refrigerator 1 is improved. To do. In addition, since the temperature switching chamber 3 and the freezer compartment 6 are adjacent to each other, the cool air path from the cooler 11 provided close to the freezer compartment 6 to the temperature switching chamber 3 is shortened. For this reason, the temperature rise of the cold air supplied to the temperature switching chamber 3 maintained at the freezing temperature can be prevented, and the cooling efficiency can be improved.

  Moreover, the convenience of the refrigerator 1 improves by arrange | positioning the refrigerator compartment 2 with a high usage frequency in the uppermost stage. In addition, since the vegetable compartment 5 is disposed below the refrigerator compartment 2, the cold air in the refrigerator compartment 2 can be easily guided to the vegetable compartment 5 by its own weight, and a reduction in blowing efficiency can be prevented. Furthermore, since the temperature switching chamber 3 is disposed above the freezer compartment 6 and the vegetable compartment 3, it is possible to easily put in and out a heavy and hot pan or the like while the user is standing. Therefore, the convenience of the refrigerator 1 can be further improved, and the risk of turning over the pan or the like can be reduced, thereby improving safety.

  In addition, the return air passage 17 formed extending downward from the temperature switching chamber return damper 38 and the communication passage 30 disposed on the rear side are alternatively opened by the temperature switching chamber return damper 38. The depth of the ventilation path 17 is not required by returning to the rear of the temperature switching chamber blower 18 through which air is guided to the intake side. Therefore, the temperature switching chamber blower 18 can be arranged behind the conventional one, and the depth of the temperature switching chamber 3 can be widened to improve the volumetric efficiency of the refrigerator 1. In addition, the amount of storage that can be kept warm in the temperature switching chamber 3 is increased, and the convenience of the refrigerator can be improved.

  The heater 16 and the panel heater 44 in the temperature switching chamber 3 may be omitted, and the temperature switching chamber 3 may be used as a storage that can keep the heated food and the like warm. At this time, since the heating by the heater 16 and the panel heater 44 is not performed, the heat retention time is shortened. However, similarly to the above, the storage amount that can be kept warm is increased and the convenience of the refrigerator can be improved.

  In the present embodiment, a damper may be provided at the outlet of the vegetable compartment 5. Thereby, when the temperature switching chamber 3 is switched from the high temperature side to the low temperature side, it is possible to prevent the hot air from the temperature switching chamber 3 from flowing backward into the vegetable chamber 5 by closing the damper. In addition, when the freezer compartment fan 12 is stopped when the temperature switching chamber 3 is switched from the high temperature side to the low temperature side, the freezer compartment return damper 22 is closed. Thereby, it is possible to prevent hot air from flowing backward from the freezer return damper 22 into the freezer compartment 6 by driving the temperature switching chamber blower 18.

  According to this invention, it can utilize for the refrigerator which has a 1st, 2nd store room where a cold air circuit is parallel.

The front view which shows the refrigerator of embodiment of this invention The right view which shows the refrigerator of embodiment of this invention Sectional drawing of right side which shows the refrigerator of embodiment of this invention Front sectional drawing which shows the refrigerator of embodiment of this invention Cross section of the right side showing the temperature switching chamber of the refrigerator of the embodiment of the present invention The side view which shows the machine room of the refrigerator of embodiment of this invention The rear view which shows the machine room of the refrigerator of embodiment of this invention The top view which shows the machine room of the refrigerator of embodiment of this invention Cold air circuit diagram showing the flow of cold air in the refrigerator of the embodiment of the present invention Cross-sectional view on the right side showing a temperature switching chamber of a conventional refrigerator

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Refrigerator 2 Refrigeration room 3 Temperature switching room 4 Ice making room 5 Vegetable room 6 Freezer room 7, 8, 35 Insulation wall 9 Door 11 Cooler 11a Refrigerant pipe 11b End plate 12 Freezer room blower 15 Inlet ventilation path 16 Heater 17 Return ventilation path 18 Temperature switching chamber blower 20 Refrigeration chamber damper 22 Freezing chamber return damper 23 Refrigeration chamber blower 24 Temperature sensor 36 Vertical heat insulation wall 37 Temperature switching chamber discharge damper 38 Temperature switching chamber return damper 38a, 38b Opening 38c Baffle 44 Panel heater 45 Accumulator 50 Machine room 50a Back cover 51 Electrical part 52 Electrical box 53 Control board 54 Lead wire holding part 57 Compressor 60 Condenser fan

Claims (3)

  The first and second storage chambers are insulated and isolated, and the cool air generated by the cooler branches into the first and second storage chambers arranged in parallel and flows out from the first and second storage chambers. A first damper that opens and closes an introduction ventilation path connecting the cooler and the inflow side of the second storage chamber, and an outflow of the cooler and the second storage chamber A second damper that opens and closes a return ventilation path that connects the side, a blower that takes in and discharges cool air into the second storage chamber when the first and second dampers are opened, and a second damper that opens the return ventilation path. A communication passage that guides air discharged from the second storage chamber to the intake side of the blower when closed, and extends downward from the second damper to form the return ventilation path and from the second damper The communication path is formed at the rear, and the second damper is pivotally supported at the rear end to return the return air. Refrigerator and having a baffle opening alternatively with said communication passage and.   The refrigerator according to claim 1, wherein an intake side of the blower is arranged behind the second damper.   A heating device for raising the temperature of the second storage chamber is provided, the second storage chamber is opened at the low temperature side where the first and second dampers are opened and cooled by the cooler, and the first and second dampers are closed by the heating device. The refrigerator according to claim 1 or 2, comprising a temperature switching chamber that can be switched to a room temperature on a high temperature side that is heated to a temperature higher than normal temperature.

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