JP2015124964A - Refrigerator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a refrigerator capable of maintaining humidity in a vegetable chamber at a predetermined value without causing damage and deterioration in productivity.SOLUTION: Inside of a vegetable chamber container 55 is partitioned into a vegetable storage part 61 and a non-vegetable storage part 60 by a partition plate 59, an upper part of the vegetable storage part is covered by a lid member 58, and a moisture permeable film 62-2 is provided at a vertical partition plate. Thereby, the moisture permeable film is located between the vegetable storage part and the non-vegetable storage part in the vegetable chamber container, so that it is not damaged by vegetables and the like being placed on the top of it. Also, as the partition plate in which the moisture permeable film is mounted is a plate-like member, not a box-shaped like the vegetable chamber container, and its size is small as well, so that an opening for moisture permeable film mounting can be integrally molded at the time of partition plate molding, so that deterioration in productivity can be avoided.

Description

  The present invention relates to a vegetable compartment container configuration of a refrigerator.

  In general, a household refrigerator has a vegetable room, and various devices have been devised so that vegetables stored in the vegetable room can be well preserved. One of them is a vegetable container provided with a moisture permeable membrane in order to maintain the humidity in the vegetable room substantially constant (see, for example, Patent Document 1).

  FIG. 24 shows a refrigerator described in Patent Document 1. This refrigerator includes a vegetable compartment 104 between a refrigerator compartment 102 and a freezer compartment 103 of the refrigerator main body 101, and the vegetable compartment 104 is pulled out by opening and closing its drawer door 105. A vegetable compartment container 106 is provided, and a moisture permeable membrane 107 is provided on a part of the lid 108 of the vegetable compartment container 106.

  According to this refrigerator, when the humidity in the vegetable compartment 104 becomes a predetermined level or higher, the humidity component is permeated from the moisture permeable membrane 107 to the outside of the vegetable compartment container 106 to maintain a substantially constant humidity. It can be cooled and stored in good condition.

JP 2002-286358 A

  However, according to the configuration described in Patent Document 1, since the moisture permeable membrane 107 is provided on the lid 108 that seals the vegetable compartment container 106, the lid 108 is necessary and the vegetable compartment container 106 is moved up and down. In modern refrigerators that are made up of two-tiered containers and have a large amount of food storage, a moisture-permeable membrane is provided on the bottom surface of the upper container, and this moisture-permeable membrane is made up of fruits and vegetables stored in the upper container. This leads to the problem of damage.

  In order to avoid this, it is conceivable to provide a moisture permeable membrane on the outer peripheral wall of the vegetable compartment container 106. In this case, the outer shape is large, and an opening is formed in a part of the outer peripheral wall of the container molded into a box shape. Since the vegetable container is box-shaped, the moisture-permeable membrane opening cannot be integrally formed and a separate opening forming step is required, resulting in poor productivity. .

  This invention is made | formed in view of such a point, and it aims at provision of the refrigerator which enabled it to maintain the humidity in a vegetable compartment at a predetermined value, without causing damage and productivity fall.

  In order to solve the above-described conventional problems, the present invention partitions the interior of a vegetable compartment container into a vegetable storage portion and a non-vegetable storage portion by a partition plate, covers the upper portion of the vegetable storage portion with a lid member, and the partition plate The structure is provided with a moisture permeable membrane.

  As a result, the moisture permeable membrane is positioned between the vegetable storage portion and the non-vegetable storage portion in the vegetable compartment container so that vegetables and the like are not placed on the upper portion and are not damaged. Since the partition plate for mounting is not a box like a vegetable room container but a plate-like member and the size is small, the opening for installing the moisture permeable membrane can be integrally formed at the time of partition plate molding, and productivity can be reduced. Disappear.

  With the above configuration, the refrigerator of the present invention can be provided with a moisture permeable membrane without causing damage to the moisture permeable membrane or a decrease in productivity, so that the humidity of the vegetable storage portion can be maintained substantially constant, and the vegetables and the like are cooled and stored in a good state. can do.

Front view of the refrigerator in Embodiment 1 of the present invention Front view when opening the refrigerator door in the first embodiment 2 is a cross-sectional view taken along line AA in FIG. 2 showing the refrigerator according to the first embodiment. BB sectional drawing of FIG. 2 which shows the refrigerator in Embodiment 1 Schematic cross-sectional view for explaining the cold air flow of the refrigerator in the first embodiment Schematic front view for explaining the cold air flow of the refrigerator in the first embodiment The perspective view explaining the cool air flow of the cooling chamber back surface part of the refrigerator in Embodiment 1 The principal part expanded sectional view of FIG. 3 which shows the refrigerator in Embodiment 1 Schematic cross-sectional view for explaining the cold air flow in FIG. The principal part expanded sectional view of FIG. 4 which shows the refrigerator in Embodiment 1 Schematic sectional view for explaining the cold air flow in FIG. The enlarged front view which shows the vegetable compartment and freezer compartment of the refrigerator in Embodiment 1 The perspective view of the back surface partition plate block which comprises the back wall part of the vegetable compartment of the refrigerator shown in FIG. The disassembled perspective view which shows the vegetable compartment and vegetable compartment container of the refrigerator in Embodiment 1 The perspective view of the vegetable compartment container provided in the vegetable compartment of the refrigerator in Embodiment 1 15 is an exploded perspective view of the vegetable compartment container shown in FIG. The exploded perspective view of the partition plate used for the vegetable compartment container of the refrigerator in Embodiment 1 (A) (b) The perspective view which shows the attachment state to the lower container of the partition plate used for the vegetable compartment container of the refrigerator in Embodiment 1 Sectional drawing of the partition plate used for the vegetable compartment container of the refrigerator in Embodiment 1 Front sectional drawing of the vegetable compartment container provided in the vegetable compartment of the refrigerator in Embodiment 1 Front sectional drawing which shows the support structure of the upper container in the vegetable compartment of the refrigerator in Embodiment 1 The expanded sectional side view which shows the mounting structure of the upper container to the lower container of the vegetable compartment container provided in the vegetable compartment of the refrigerator in Embodiment 1 Control block diagram of the refrigerator in the first embodiment Schematic sectional view of a conventional refrigerator

  1st invention has a vegetable compartment provided with the vegetable compartment container, the said vegetable compartment container partitions the inside into a vegetable storage part and a non-vegetable storage part by a partition plate, and the upper part of the said vegetable storage part is by a lid member In addition to covering, the partition plate is provided with a moisture permeable membrane.

  As a result, the moisture permeable membrane is positioned between the vegetable storage portion and the non-vegetable storage portion in the vegetable compartment container so that vegetables and the like are not placed on the upper portion and are not damaged. The partition plate to which the sachet is attached is not a box-like member like a vegetable compartment container but is a plate-like member and is small in size, so that the opening for attaching the moisture permeable membrane can be integrally formed at the time of partition plate molding, and productivity is not reduced. .

  According to a second invention, in the first invention, the vegetable compartment container is composed of a lower container and an upper container placed slidably forward and backward on the upper container, and the interior of the lower container is partitioned by a vegetable storage section And the non-vegetable storage section, and the upper container is a lid member that covers the upper part of the vegetable storage section.

  As a result, the vegetable compartment container has three storage parts, a vegetable storage part in the lower container and a non-vegetable storage part, and a storage part in the upper container, so separate the non-vegetable ingredients such as vegetables, fruits and plastic bottles. It is possible to store efficiently, and at the same time, the upper container is used to cover the upper part of the vegetable storage part, and the humidity inside the vegetable storage part is kept substantially constant without causing damage to the moisture permeable membrane or reducing productivity. Thus, the vegetables can be stored in a well-cooled state.

  According to a third invention, in the first or second invention, the moisture permeable membrane is integrally formed on the resin frame and is provided on the partition plate as a moisture permeable membrane unit.

  Accordingly, the moisture permeable membrane itself can be easily attached to the partition plate, and the productivity is improved accordingly.

  According to a fourth invention, in the first to third inventions, the partition plate is provided with mounting piece portions at both ends thereof, and a hanging piece portion is formed downward from the placing piece portion, and the hanging piece portion is used as a lower container. The mounting piece is placed on the upper end of the outer peripheral wall of the lower container and fitted to a recess formed at the upper end of the outer peripheral wall.

  As a result, the partition plate can be attached simply by fitting into the lower container from the upper opening of the lower container, and is positioned and fixed by fitting into the recess of the hanging piece, so that the partition plate is not prepared in the lower container It is possible to prevent the volume of the vegetable storage part or the non-vegetable storage part from changing.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The present invention is not limited to the embodiment.

(Embodiment 1)
1 is a front view of a refrigerator according to Embodiment 1 of the present invention, FIG. 2 is a front view when the door of the refrigerator according to Embodiment 1 is opened, and FIG. 3 is a diagram illustrating the refrigerator according to Embodiment 1. AA sectional view of FIG. 4, FIG. 4 is a BB sectional view of FIG. 2 showing the refrigerator in the first embodiment, FIG. 5 is a schematic sectional view for explaining the cold air flow of the refrigerator in the first embodiment, FIG. 6 is a schematic front view for explaining the cold air flow of the refrigerator in the first embodiment, FIG. 7 is a perspective view for explaining the cold air flow in the rear portion of the cooling chamber of the refrigerator in the first embodiment, and FIG. 3 is an enlarged cross-sectional view of the main part of FIG. 3 showing the refrigerator in the first embodiment, FIG. 9 is a schematic cross-sectional view for explaining the cold air flow in FIG. 8, and FIG. 10 is the main part of FIG. 11 is an enlarged cross-sectional view, and FIG. 11 illustrates the cold air flow in FIG. 12 is an enlarged front view showing the vegetable compartment and freezer compartment of the refrigerator in the first embodiment, and FIG. 13 is a rear partition that constitutes the back wall portion of the vegetable compartment of the refrigerator shown in FIG. FIG. 14 is an exploded perspective view showing the vegetable compartment and vegetable compartment container of the refrigerator in the first embodiment, and FIG. 15 is a perspective view of the vegetable compartment container provided in the vegetable compartment of the refrigerator in the first embodiment. 16 is an exploded perspective view of the vegetable compartment container shown in FIG. 15, FIG. 17 is an exploded perspective view of a partition plate used for the vegetable compartment container of the refrigerator in the first embodiment, and FIGS. ) Is a perspective view showing a state in which the partition plate used in the vegetable compartment container of the refrigerator in the first embodiment is attached to the lower container, and FIG. 19 is a diagram of the partition plate used in the vegetable compartment container of the refrigerator in the first embodiment. Sectional view, FIG. 20 shows refrigeration in the first embodiment 21 is a front cross-sectional view of the vegetable compartment container provided in the vegetable compartment of FIG. 21, FIG. 21 is a front cross-sectional view showing the support structure of the upper container in the vegetable compartment of the refrigerator in the first embodiment, and FIG. FIG. 23 is a control block diagram of the refrigerator in the first embodiment, and FIG. 23 is an enlarged side cross-sectional view showing a configuration for placing the upper container on the lower container of the vegetable compartment container provided in the vegetable compartment.

  First, the whole structure of a refrigerator is demonstrated.

<Fridge body configuration>
1-6, the refrigerator which concerns on this Embodiment is equipped with the refrigerator main body 1 which opened the front, This refrigerator main body 1 has the outer case 2 mainly using the steel plate as shown in FIG. The inner box 3 is made of a hard resin such as ABS, and a foam heat insulating material 4 such as hard foam urethane filled between the outer box 2 and the inner box 3. The refrigerator main body 1 is divided into a plurality of storage rooms by a partition plate 5.6. The refrigerator main body 1 has a refrigerator compartment 7 at the top, a vegetable compartment 8 at the bottom of the refrigerator compartment 7, and a freezer compartment at the bottom. 9 is arranged, and it is a middle vegetable room type refrigerator. The front opening of each storage chamber is closed by a door 10, a door 11, and a door 12 so as to be opened and closed.

  A machine room 14 is provided in the upper rear region of the refrigerator main body 1, and houses high-pressure side components of the refrigeration cycle such as the compressor 15 and a dryer (not shown) for removing moisture.

  In addition, a cooling chamber 16 that generates cool air is provided on the back surface of the refrigerator body 1. The cooling chamber 16 is formed from the back surface of the freezing chamber 9 to the lower back surface of the vegetable chamber 8, and a back partition plate body 17 is provided between the vegetable chamber 8 and heat insulating properties by using polystyrene foam or the like. Insulated partitions.

  A cooler 18 is disposed in the cooling chamber 16, and a cooling fan 19 is disposed above the cooler 18. The cooling fan 19 forcibly circulates the cold air cooled by the cooler 18 to the refrigerating room 7, the vegetable room 8, and the freezing room 9 to cool each room.

  In the lower space of the cooler 18, a defrost heater 28 for defrosting the frost and ice adhering to the cooler 18 and its periphery is disposed as shown in FIGS. A drain pan 29 for receiving defrost water generated at the time of defrosting is disposed below the defrost heater 28, and the defrost water is discharged from the deepest part of the drain pan 29 to an evaporation tray outside the chamber through a drain tube (not shown). It is like that.

  Next, the cold air circulation configuration will be described.

<Cooling air circulation path configuration>
As shown in FIGS. 8 and 9, the cooling chamber 16 that generates cool air is connected to the cooling chamber cool air conveyance path 30 formed between the rear partition plate body 17 and the refrigerator main body 1. The downstream opens, and cool air is blown into each chamber through the cooling chamber cool air conveyance path 30.

  5, 6, 7, and particularly FIG. 7, the upper part of the cooling chamber cool air conveyance path 30 is a refrigerating cold air passage 32 formed in a substantially central portion of the back surface of the refrigerating chamber 7 through a refrigerating chamber damper 31. Communicated with. As shown in FIGS. 6 and 7, a refrigerated cold air return passage 33 from the refrigeration chamber 7 is provided adjacent to the side of the refrigerated cold air passage 32, and the lower part thereof communicates with the vegetable compartment 8 and the cooling compartment 16. Yes.

  As shown in FIG. 6, the refrigerating chamber 7 is provided with a refrigerating / cooling air inlet 35 of a refrigerating / refrigerating air passage 32 at an appropriate position in the upper part of the rear wall, and the refrigerating / refrigerating air opened to the refrigerating / refrigerating air return passage 33 at a lower position of the inner wall. A return port 36 is provided, and the cold air from the cooling chamber 16 is supplied to the refrigerating / refrigerating air passage 32 via the refrigerating chamber damper 31, and is supplied from the refrigerating / refrigerating air inlet 35 to the refrigerating chamber 7. On the other hand, the cold air after cooling in the refrigerating room is supplied from the refrigerating cold air return port 36 to the vegetable room 8 through the refrigerating cold air return passage 33 and circulates to the cooling room 16. As will be described later, the refrigerating chamber 7 is provided with a partial chamber in the lower portion thereof. The partial chamber has a partial chamber damper 31a, a partial chamber cool air passage 32a, a partial chamber cool air inlet as shown in FIG. It is supplied via 36a.

  In this embodiment, as is clear from FIG. 7, on the back surface of the rear surface partition plate body 17 and the partition plate 6, the cooling chamber cold air conveyance path 30, the refrigerated cold air passage 32, and the partial chamber cold air passage 32a. And a return passage 38 for connecting the refrigerated cold air return passage 33 to the vegetable compartment 8 and the cooling chamber 16. The refrigeration chamber damper 31 is provided in the forward passage 37. .

  A communication passage 39 is formed between the refrigerated cold air return passage 32 and the refrigerated cold air return passage 33 so that a part of the low temperature cold air flowing through the refrigerated cold air return passage 32 is mixed into the refrigerated cold air return passage 33. It is configured.

  Further, as shown in FIG. 7, a cold air return duct 40 is provided on the rear surface of the freezer compartment 9 so as to extend downward on the side of the cooler 18 of the cooling chamber 16. A passage 38 communicates with the vegetable compartment 8 and a lower portion thereof opens to the vicinity of the lower portion of the cooling chamber 16, and the cold air after cooling the vegetable compartment 8 is cooled from the lower opening through the cold air return duct 40. It is configured to circulate.

  On the other hand, as shown in FIG. 9, the freezing chamber 9 has a freezing cold air inlet 42 communicating with the lower part of the cooling chamber cold air conveyance path 30 on the back of the rear partition plate 17 at the upper portion of the rear wall 41 and the cooling chamber at the lower portion. A freezing cold air return port 43 is formed in the lower portion of the cooling chamber 16, and the cold air from the cooling chamber 16 is supplied from the lower portion of the cooling chamber cold air conveyance path 30 through the freezing cold air inlet 42. It circulates to the cooling chamber 16 via the cold air return port 43.

<Vegetable room configuration>
As shown in FIGS. 6 and 11, the vegetable room 8 is a portion closer to the left or right side of the back wall, in this embodiment, the lower portion of the right side when viewed from the front, and the return passage 38 portion from the refrigerated cold air return passage 33. An open vegetable cold air inlet 44 is provided, and a vegetable cold air return port 46 that opens to the return passage 38 and leads to the cooling chamber 16 is provided at a position substantially above the vegetable cold air inlet 44.

  Furthermore, in this vegetable compartment 8, as shown in FIG. 11, a vegetable compartment passage portion 50 is provided in the vertical direction at the front position of the cold air return passage 38 using the rear partition plate 17 on the back of the vegetable compartment 8. It is formed vertically. The vegetable chamber passage portion 50 has an upper portion positioned in the vicinity of the vegetable cold air return port 46 and a lower portion communicating with the vegetable cold air inlet 44, and a vegetable chamber comprising a propeller fan or the like at a portion communicating with the vegetable cold air inlet 44. A fan 53 is arranged.

  Furthermore, the vegetable compartment 8 has a first passage 47a formed on the upper surface of the vegetable compartment so as to be connected to the vegetable compartment passage section 50 and the vegetable cold air return port 46. One vegetable cold air inlet 47 is provided.

  In addition, in the vegetable compartment 8 of this embodiment, as shown in FIG. 12, FIG. 13, etc., it is the upper part of the rear surface partition plate body 17 which becomes the inner surface of the vegetable room 8 and is a diagonal position of the vegetable cold air inlet 44. As shown in FIG. 11, a second vegetable cold air inlet 51 is provided in the upper part of the left rear side in this embodiment, and the second passage 51a provided with the second vegetable cold air inlet 51 is also shown in FIG. In addition, the upper part of the vegetable compartment passage 50 and the vegetable cold air return port 46 communicate with each other.

<Vegetable room container configuration>
As shown in FIGS. 10 and 14, the vegetable compartment container 55 is disposed in the vegetable compartment 8. The vegetable compartment container 55 is a rail-like support member 56 (see FIG. 14) attached to the inner surface of the door 11. ) And withdrawing / withdrawing from the vegetable compartment 8 as the door 11 opens and closes.

  As shown in FIG. 15, the vegetable compartment container 55 includes a lower container 57 and an upper container 58 placed on the upper surface opening of the lower container 57.

  The lower container 57 is provided with a partition plate 59 that divides the inside thereof into left and right sides. One side partitioned by the partition plate 59, in this example, the right side when viewed from the front where the vegetable compartment fan 53 is installed, is a plastic bottle or pack. It is formed as a non-vegetable storage portion 60 for storing the like, and is formed deeper than the other vegetable storage portion 61.

  As shown in FIG. 17, the partition plate 59 is formed with a horizontally long opening 59-1 in a substantially central portion, and a moisture permeable membrane unit 62 is detachably attached to the opening 59-1. The moisture permeable membrane unit 62 is formed by integrally molding the moisture permeable membrane 62-2 on the resin frame 62-1, and the right end portion in the drawing is fitted into the opening edge of the partition plate 59, and the other engagement piece 62- 3 is fitted into the engagement recess 59-4 at the opening edge of the other end.

  There are various kinds of moisture permeable membranes 62-2. For example, a layer formed by laminating a thin silicon film having a thickness of 10 to 50 μm and hydrophilic nylon fibers is used, and the silicon thin film prevents passage of liquid. In addition, it has moderate gas permeability and prevents condensation with hydrophilic nylon fibers.

  Further, the partition plate 59 has mounting piece portions 59-2a and 59-2b formed at both ends thereof, and from the mounting piece portions 59-2a and 59-2b as shown in FIGS. 18 (a) and 18 (b). The suspended piece portions 59-3a and 59-3b are integrally formed, and the suspended piece portions 59-3a and 59-3b are fitted into a recess 57a formed at the upper end of the outer peripheral wall of the lower container 57, and the placing piece portion 59-2a and 59-2b are mounted on the upper end of the outer peripheral wall of the lower container 57 and mounted in the lower container 57.

  Further, the upper container 58 is placed on and covers the upper surface opening portion of the vegetable storage section 61 partitioned by the partition plate 59, and as shown in FIG. 20, the upper container rail section formed on the bottom surface thereof. 63 is mounted on the lower container rail portion 64 formed on the left side of the upper opening of the lower container 57 and the upper end of the partition plate 59, and the flange 65 provided on the upper opening of the upper container is a vegetable as shown in FIGS. It is slidable back and forth along guides 66a and 66b provided on the upper side wall and ceiling surface of the chamber 8.

  Here, the upper container rail portion 63 of the upper container 58 includes a straight portion 67 as shown in FIG. 22 and is provided with a projection 68 in front thereof, and the lower container rail portion 64 of the lower container 57 is a straight portion. 69 and a downward inclined slope portion 70 connected thereto, and has an intersection portion 71 connected to the straight portion 69 and the slope portion 70 in the rear portion, and a concave portion 72 for accommodating the projection portion 68 is provided in the front portion. As a configuration.

  As a result, the vegetable compartment container 55 is pulled out together with the door 11 together with the upper container 58 and the lower container 57 by pulling out the door 11, and the upper container 58 alone is brought out of the vegetable compartment. It becomes a structure which can be pushed and moved in 8.

  The vegetable compartment 8 is provided with a space between the vegetable compartment container 55 and the partition wall 6 below and the inner peripheral wall surface of the vegetable compartment 8, and the space is a wind through which cold air from the vegetable cold air inlet 44 flows. Constitutes the road.

Moreover, the upper opening edge of the upper container 58 of the vegetable compartment container 55 is located in a portion close to the partition plate 6 in the upper portion of the vegetable compartment 8 and is located above the vegetable cold air inlet 44 described above. The cool air from 44 does not enter directly into the upper container 58 and the lower container 57 of the vegetable compartment container 55. Note that a lid that closes the upper container 58 may be provided at the upper opening of the upper container 58 to prevent cold air from entering the vegetable compartment container 55 more reliably.

<Refrigerator configuration>
As shown in FIG. 3 and the like, the refrigerator compartment 7 includes a plurality of storage shelves 73 and a partial chamber 74 that can be cooled to a semi-refrigeration temperature zone. A mouth 36 (both see FIG. 6) is provided. An operation unit 75 for setting the internal temperature of each room, ice making, rapid cooling, and the like is disposed at an appropriate side wall of the refrigerator compartment 7.

<Freezer configuration>
Also. As already described with reference to FIG. 9, the freezing chamber 9 has a freezing cold air inlet 42 communicating with the lower portion of the cooling chamber cold air conveyance path 30 on the back of the rear partition plate 17 at the upper portion of the rear wall, and further the lower portion of the rear wall. A freezing cold air return port 43 communicating with the freezing chamber 9 is formed. Although not shown in the structural diagram, a freezer damper is also incorporated at an appropriate position in the passage from the cooling chamber 16 to the freezer compartment 9. The freezer compartment 9 is also provided with a freezer compartment container 76 placed on the frame of the door 12 as shown in FIG. 4 and the like, and an ice making device 77 is provided above the freezer compartment container 76. It has been incorporated.

  Next, the control configuration of the refrigerator will be described.

<Control configuration>
FIG. 23 shows a control block diagram in the refrigerator of the present embodiment, 78 is a refrigerator temperature detecting means, 79 is a vegetable room temperature detecting means, 80 is a freezer temperature detecting means, both are formed of a thermistor, They are installed at appropriate places in the refrigerator compartment 7, the vegetable compartment 8, and the freezer compartment 9, respectively. Reference numeral 81 denotes a control unit that performs overall control of the entire refrigerator, which is constituted by a microcomputer or the like, and is stored in the refrigerator compartment according to control software built in advance based on outputs from the refrigerator compartment temperature detecting means 78 and the freezer compartment temperature detecting means 80. The damper 31 and freezer compartment damper 34 are controlled to open and close, and the compressor 15 and the cooling fan 19 are driven to control each chamber to a set temperature. Further, the controller 81 controls the operation of the vegetable compartment fan 53 incorporated in the vegetable compartment passage portion 50 of the vegetable compartment 8 based on outputs from the refrigerator compartment temperature detecting means 78 and the vegetable compartment temperature detecting means 79. . Specifically, the vegetable compartment fan 53 is driven when one of the temperatures detected by the refrigerator compartment temperature detection means 78 and the vegetable compartment temperature detection means 79 detects a temperature higher than the set temperature.

  About the refrigerator comprised as mentioned above, the operation | movement and an effect | action are demonstrated below.

  First, the operation of the refrigeration cycle will be described.

  The refrigeration cycle is operated by a signal from the control unit 81 in accordance with the set temperature in the refrigerator, and the cooling operation is performed. The high-temperature and high-pressure refrigerant discharged by the operation of the compressor 15 is condensed to some extent by a condenser (not shown), and further, refrigerant piping (not shown) disposed on the side and rear surfaces of the refrigerator and the front opening of the refrigerator. Etc.), while condensing and liquefying while preventing condensation in the refrigerator, it reaches a capillary tube (not shown). Thereafter, the capillary tube is depressurized while exchanging heat with a suction pipe (not shown) to the compressor 15 and becomes a low-temperature and low-pressure liquid refrigerant and reaches the cooler 18 in the cooling chamber. Here, the refrigerant in the cooler 18 evaporates, and cool air for cooling each storage chamber is generated in the cooling chamber 16 having the cooler 18.

  Next, the cooling operation by the cold air circulation will be described.

  The low-temperature cold air generated in the cooling chamber 16 is sent by the cooling fan 19 from the cooling chamber cold-air conveyance path 30 to the refrigerator compartment 7 and the freezer compartment 9, and the cold air supplied to the refrigerator compartment 7 cools the refrigerator compartment 7. After that, it is supplied to the vegetable room 8 and each room is cooled to the set temperature. Then, the cold air after cooling each chamber returns to the cooling chamber 16 again, is cooled by the cooler 18, and is circulated to each chamber by the cooling fan 19. In addition, the cold air supply to each of the chambers is performed by the control unit 81 operating / stopping the compressor 15 and the cooling fan 19 based on the temperatures detected by the refrigerator temperature detecting means 78 and the freezer temperature detecting means 80, and the refrigerator compartment damper 31. The freezer damper 34 is controlled to open and close so that each chamber is maintained in a set temperature range.

  Next, the cooling operation of the vegetable compartment 8 will be described.

  The vegetable room 8 is cooled by the cold air after cooling from the refrigerated cold air return passage 33 being supplied from the vegetable cold air inlet 44 provided in the cold air return passage 38 as shown in FIG. The cold air gently flows into the vegetable room 8 from the vegetable cold air inlet 44 through the vegetable room passage portion 50 by the blowing pressure of the cooling fan 19, and the lower container 57 and the upper container 58 of the vegetable room container 55 and the inner peripheral wall of the vegetable room 8. The vegetables, plastic bottles, etc. stored in the vegetable compartment container 55 are indirectly cooled from the outer periphery of the container, and cool air is supplied from the vegetable cold air return port 46 via the refrigerated cold air return passage 33. It circulates from the return duct 40 to the cooling chamber 16.

  Here, in the refrigerator shown in this embodiment, as shown in FIG. 11, the vegetable room fan 53 is provided in the vegetable room passage portion 50 of the vegetable room 8, and when the vegetable room fan 53 rotates, the return passage 38 is opened. Most of the returned cold air flowing is sucked from the vegetable cold air inlet 44 into the vegetable room passage section 50 and supplied from the outlet 54 of the vegetable room fan 53 toward the rear surface of the lower container 57 in the vegetable room 8. .

  The cold air supplied toward the lower container 57 of the vegetable compartment 8 is circulated by the air pressure of the cooling fan 19 in the space between the lower container 57 and the upper container 58 and the bottom and inner peripheral walls of the vegetable compartment 8. It flows faster than the flow and returns to the cooling chamber 16 from the vegetable cold air return port 46 via the return passage 38 and circulates. At that time, cool air other than the cool air returning to the cooling chamber 16 is circulated from the first vegetable cold air inlet 47 and the second vegetable cold air inlet 51 provided in the upper portion of the vegetable chamber 8. Is sucked into the vegetable compartment fan 53 from the upper opening of the vegetable compartment passage portion 50 communicating with these passages 51a, and again from the air outlet 54 of the vegetable compartment fan 53 to the lower container in the vegetable compartment 8 again. It is supplied toward 57 and diffuses or circulates in the vegetable compartment 8.

  Next, the effect of the vegetable compartment container, which is a feature of the present invention, will be described.

  First, in the vegetable compartment container 55 of the refrigerator, a lower container 57 is divided into a vegetable storage part 61 and a non-vegetable storage part 60 by a partition plate 59, and an upper container 58 is placed on the upper opening of the vegetable storage part 61. Since the three storage units are configured, food is divided into the respective storage units, for example, fruits are stored in the upper container 58, vegetables are stored in the vegetable storage unit 61, and plastic bottles are stored in the non-vegetable storage unit 60. Drinks such as packs can be stored efficiently.

  Moreover, since the said vegetable compartment container 55 equips the partition plate 59 which forms the vegetable storage part 61 with the moisture permeable membrane unit 62, it can maintain the humidity in the vegetable storage part 61 substantially constant, Can be cooled and stored in good condition. That is, the inside of the vegetable storage unit 61 is in a high humidity state due to moisture transpiration from the vegetables stored in the vegetable storage unit 61. However, when the humidity is higher than a predetermined humidity, for example, higher than the saturation humidity, the humidity component is indicated by a broken line arrow in FIG. Through the moisture permeable membrane 62-2 provided on the partition plate 59, the moisture is gradually permeated into the non-vegetable storage unit 60, and the inside of the vegetable storage unit 61 has a humidity of 80 to 95% R.D. H. To be kept.

  Here, since the moisture permeable membrane 62-2 is located between the vegetable storage unit 61 and the non-vegetable storage unit 60 in the vegetable compartment container, vegetables or the like may be placed on the top and be damaged. Disappear. Moreover, since the partition plate 59 to which the moisture permeable membrane 62-2 is attached is not a box-like member like the vegetable compartment container 55 but is a plate-like member and has a small size, the opening 59-1 for attaching the moisture permeable membrane is provided in the partition plate. There is no need to reduce the productivity due to the integral molding at the time of molding.

  In this embodiment, as described above, the vegetable compartment container 55 is composed of a lower container 57 and an upper container 58 placed on the upper part of the vegetable container so as to be slidable back and forth. The upper part of the vegetable storage unit 61 can be reasonably covered using the upper container 58, and the humidity can be prevented while preventing the cold air from entering the vegetable storage unit 61. Can be maintained in a substantially constant state, and the vegetables can be well preserved by cooling.

  Further, since the moisture permeable membrane 62-2 is integrally formed with the resin frame 62-1, and is attached to the partition plate 59 as the moisture permeable membrane unit 62, the moisture permeable membrane itself can be easily attached to the partition plate 59. .

  Further, the partition plate 59 is fitted with recesses 57a formed at the upper end of the outer peripheral wall of the lower container 57 with the hanging piece portions 59-3a and 58-3b formed at both ends thereof, and the mounting piece portions 59-2a and 59-. Since 2b is placed on the upper end of the outer peripheral wall of the lower container 57 and attached to the lower container 57, the partition plate 59 can be attached simply by being fitted into the lower container from the upper opening of the lower container 57. Moreover, the partition plate 59 is fixed by being positioned in the left-right direction by fitting the hanging pieces 59-3a and 58-3b into the recesses 57a, and the partition plate 59 moves carelessly in the lower container. The volume of the storage unit 61 or the non-vegetable storage unit 60 changes, or a plastic bottle or the like stored in the non-vegetable storage unit 60 moves each time the door is opened and closed, pushing the partition plate 59 toward the vegetable storage unit 61 and vegetables. It is possible to prevent the pressure from being deteriorated. Further, since the partition plate 59 can be removed, there is an advantage that the moisture permeable membrane unit 62 can be easily cleaned and maintained.

  As described above, this refrigerator is provided with the moisture permeable membrane 62-2 without causing damage to the moisture permeable membrane or lowering the productivity, so that the humidity of the vegetable storage unit 61 can be maintained substantially constant. Although the refrigerator can be stored in a refrigerator, the upper container 58 constituting the vegetable compartment container 55 can be slid lightly and at the same time, the lower container 57 and the upper container 58 are brought into close contact with each other without any gap. This can prevent the intrusion of cold air into the lower container, and this point will be further described.

  That is, when the upper container 58 of the vegetable compartment container 55 slides back and forth on the lower container 57, the protrusion 68 provided on the upper container rail 63 is a straight line of the lower container rail 64 as shown in FIG. The straight portion 67 of the upper container rail portion 63 contacts the intersection portion 71 of the lower container rail portion 64 and is supported at these two points, and slides on the lower container rail portion 64 of the lower container 57. Therefore, the upper container 58 can accommodate a large amount of fruit and can be slid lightly even if it is heavy.

  When the vegetable compartment container 55 is stored in the vegetable compartment 8 with the door 11 closed, the protrusion 68 of the upper container rail portion 63 enters the concave portion 72 of the lower container rail portion 64 to enter the upper container rail portion 63. The straight portion 67 and the straight portion 69 of the lower container rail portion 64 are in contact with each other, and the contact portions of these both come into close contact with no gap. Therefore, the cold air flowing around the vegetable compartment container 55 can be prevented from entering the vegetable storage part 61 of the lower container 57 from between the lower container 57 and the upper container 58, and is stored in the vegetable storage part 61. The vegetables can be stored in a cool state without being deteriorated by drying.

  Moreover, since this refrigerator has various effects also about vegetable room cooling, this is also demonstrated below.

  First, in this embodiment, a vegetable room fan 53 is provided in the vegetable room 8, and this vegetable room fan 53 is provided on the back part of the vegetable room on the non-vegetable storage part 60 side of the vegetable room container 55. The cool air in the vegetable compartment is diffused or circulated toward the vegetable storage section 60. Therefore, the cold air from the vegetable compartment fan 53 circulates intensively around the non-vegetable storage unit 60, and the plastic bottles and packs stored in the non-vegetable storage unit 60 can be efficiently cooled. . In particular, drinking water such as PET bottles and packs stored in the non-vegetable storage unit 60 is effective because it has a larger heat capacity than vegetables and is difficult to cool. Can be efficiently suppressed.

  Further, since the first vegetable cold air inlet 47 provided in the vegetable chamber 8 together with the vegetable chamber fan 53 is provided in the front portion of the vegetable chamber container 55 on the non-vegetable storage portion 60 side, The cold air to the vegetable cold air return port 46 can be circulated more efficiently and intensively to the non-vegetable storage portion, which is effective.

  Further, the second vegetable cold air suction port 51 serving as another suction port for circulating the cold air in the vegetable chamber 8 is provided at the upper portion of the vegetable chamber substantially diagonally with the vegetable chamber fan 53. Therefore, the cold air from the vegetable compartment fan 53 diffuses and circulates through the bottom portion of the non-vegetable storage portion 60 of the vegetable compartment container 55 forward and diagonally through the vegetable compartment 8, and then circulates in the upper part of the vegetable compartment. The second vegetable cold air inlet 51 flows, so that cold air is diffused over the outer circumference of the vegetable chamber container 55 while preventing the cold air from entering the vegetable chamber container consisting of the lower container 57 and the upper container 58. And can be circulated to effectively cool vegetables, plastic bottles, and the like.

  Further, in this refrigerator, a communication passage 39 is formed between the refrigerated cold air return passage 32 and the refrigerated cold air return passage 33, and when the vegetable compartment fan 53 rotates, the suction force of the vegetable compartment fan 53 causes the low temperature in the refrigerated cold air passage 32 Fresh cold air is mixed into the refrigerated cold air return passage 33 and supplied from the vegetable cold air inlet 44 into the vegetable compartment 8 through the return passage 38. Therefore, in this refrigerator, the vegetable compartment 8 is cooled by the low-temperature cold air by mixing the low-temperature fresh cold air into the cold air after cooling the refrigerator compartment by the rotation of the vegetable compartment fan 53. Therefore, the vegetable compartment 8 can be effectively cooled, and the vegetable compartment 8 is reliably cooled even when the cooling load condition is bad, for example, when many vegetables, plastic bottles, etc. are temporarily stored. be able to. In addition, the amount of low-temperature fresh cold air taken in through the communication passage 39 can be increased by increasing the number of rotations of the vegetable compartment fan 53, and a large amount of room temperature PET bottles having a large heat capacity are stored in summer. Even at times, this can be reliably cooled. Moreover, since the vegetable compartment 8 can be reliably cooled, the occurrence of dew condensation due to cold radiation from the cooling compartment 16 can be efficiently suppressed, and the vegetables can be stored in a cooled state in a good state.

  The vegetable compartment fan 53 operates when the refrigerator compartment damper 31 is opened by the output from the refrigerator compartment temperature detecting means 78 to cool the refrigerator compartment 7 and the vegetable compartment 8 and diffuses the cold air in the vegetable compartment 8 or Although it circulates, in this embodiment, since it controls also based on the detection temperature of the vegetable compartment temperature detection means 79 provided in the vegetable compartment 8, the temperature of the refrigerator compartment 7 is high, and cooling operation is not performed. Even when the temperature of the vegetable compartment 8 becomes equal to or higher than the set temperature, the vegetable compartment 8 starts to rotate and diffuses and / or circulates cold air in the vegetable compartment 8. Therefore, when the temperature of the vegetable room becomes high and a large temperature difference is caused by the cold radiation from the cooling chamber 16 and the condition is likely to cause dew condensation, the vegetable room fan 53 rotates to eliminate this and effectively generate dew condensation. Can be prevented.

If the temperature of the vegetable room 8 becomes higher than the second set temperature set to a temperature slightly higher than the set temperature in spite of the rotation of the vegetable room fan 53, the vegetable room fan The number of rotations of 53 can be increased to increase the diffusion or circulation of the cold air, and the amount of fresh cold air taken in can be increased and the vegetable room 8 can be reliably cooled. Therefore, the lack of cooling in the summer can be resolved, and good cooling storage of vegetables and the like can be reliably realized to increase the reliability of the refrigerator.

  Although the embodiment of the present invention has been described above, the configuration described in the above embodiment is shown as an example for carrying out the present invention, and various modifications can be made within the scope of achieving the object of the present invention. Needless to say.

  For example, although the moisture permeable film 62-2 illustrated what laminated | stacked the silicon thin film and the hydrophilic nylon fiber, it was not restricted to this, and when the humidity in a vegetable storage part becomes more than predetermined value, the humidity component Any material can be used as long as it allows moisture to be maintained at a constant humidity.

  The refrigerator according to the present invention can maintain a substantially constant humidity in the vegetable storage section by providing the vegetable compartment container with a moisture permeable membrane without damaging the moisture permeable membrane or reducing productivity, and cooling vegetables in a good state. Can be saved. Therefore, it can be widely applied to refrigerators for business use as well as home use.

DESCRIPTION OF SYMBOLS 1 Refrigerator main body 5,6 Partition plate 7 Refrigeration room 8 Vegetable room 9 Freezing room 10,11,12 Door 30 Cooling room cold air conveyance path 32 Refrigeration cold air return passage 33 Refrigeration cold air return passage 35 Refrigeration cold air inlet 36 Refrigeration cold air return port 37 Outward Passage 38 return passage 39 communication passage 40 cold air return duct 42 refrigeration cold air inlet 43 refrigeration cold air return port 44 vegetable cold air inlet 46 vegetable cold air return port 47 first vegetable cold air inlet 47a first passage 50 vegetable compartment passage portion 51 second Vegetable cold air inlet 51a second passage 52 second cold air circulation passage 53 vegetable room fan 54 outlet 55 vegetable room container 56 support member 57 lower container 57a recess 58 upper container (lid member)
59 Partition plate 59-1 Opening 59-2a, 59-2b Placement piece 59-3a, 58-3b Hanging piece 59-4 Engaging recess 60 Non-vegetable storage 61 Vegetable storage 62 Moisture permeable membrane unit 62- DESCRIPTION OF SYMBOLS 1 Resin frame 62-2 Moisture permeable membrane 62-3 Engagement piece 63 Upper container rail part 64 Lower container rail part 67 Straight part of upper container 68 Projection part 69 Straight part of lower container 70 Inclination part 71 Intersection part 72 Recessed part 78 Refrigeration Room temperature detection means 79 Vegetable room temperature detection means 80 Freezer room temperature detection means 81 Control unit

Claims (4)

The vegetable compartment container includes a vegetable compartment, the vegetable compartment container is partitioned into a vegetable storage portion and a non-vegetable storage portion by a partition plate, and an upper portion of the vegetable storage portion is covered by a lid member, and the partition plate A refrigerator equipped with a moisture permeable membrane. The vegetable compartment container is composed of a lower container and an upper container placed on the upper part thereof so as to be freely slidable back and forth, and the interior of the lower container is partitioned into a vegetable storage part and a non-vegetable storage part by a partition plate, and the upper container The refrigerator according to claim 1, wherein the lid member covers the upper part of the vegetable storage unit. The refrigerator according to claim 1 or 2, wherein the moisture permeable membrane is integrally formed on the resin frame and is provided on the partition plate as a moisture permeable membrane unit. The partition plate is provided with mounting piece portions at both ends thereof, and a hanging piece portion is formed downward from the placing piece portion, and the hanging piece portion is fitted into a recess formed at the upper end of the outer peripheral wall of the lower container. The refrigerator according to any one of claims 1 to 3, wherein one piece is placed on the upper end of the outer peripheral wall of the lower container and attached to the lower container.

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